WO2000001575A2 - Multi axis marine propulsion system - Google Patents

Multi axis marine propulsion system Download PDF

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Publication number
WO2000001575A2
WO2000001575A2 PCT/GB1999/002139 GB9902139W WO0001575A2 WO 2000001575 A2 WO2000001575 A2 WO 2000001575A2 GB 9902139 W GB9902139 W GB 9902139W WO 0001575 A2 WO0001575 A2 WO 0001575A2
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WO
WIPO (PCT)
Prior art keywords
fin
axis
craft
fins
thrust
Prior art date
Application number
PCT/GB1999/002139
Other languages
French (fr)
Other versions
WO2000001575A3 (en
Inventor
Ralph Peter Steven Bailey
Original Assignee
Ralph Peter Steven Bailey
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from GBGB9814489.2A external-priority patent/GB9814489D0/en
Priority claimed from GBGB9814490.0A external-priority patent/GB9814490D0/en
Priority claimed from GBGB9814491.8A external-priority patent/GB9814491D0/en
Application filed by Ralph Peter Steven Bailey filed Critical Ralph Peter Steven Bailey
Publication of WO2000001575A2 publication Critical patent/WO2000001575A2/en
Publication of WO2000001575A3 publication Critical patent/WO2000001575A3/en

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B63SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
    • B63HMARINE PROPULSION OR STEERING
    • B63H1/00Propulsive elements directly acting on water
    • B63H1/02Propulsive elements directly acting on water of rotary type
    • B63H1/04Propulsive elements directly acting on water of rotary type with rotation axis substantially at right angles to propulsive direction
    • B63H1/06Propulsive elements directly acting on water of rotary type with rotation axis substantially at right angles to propulsive direction with adjustable vanes or blades
    • B63H1/08Propulsive elements directly acting on water of rotary type with rotation axis substantially at right angles to propulsive direction with adjustable vanes or blades with cyclic adjustment
    • B63H1/10Propulsive elements directly acting on water of rotary type with rotation axis substantially at right angles to propulsive direction with adjustable vanes or blades with cyclic adjustment of Voith Schneider type, i.e. with blades extending axially from a disc-shaped rotary body

Definitions

  • This invention concerns an improved marine propulsion system, which is more readily direction vectored and is more efficient than conventional alternatives. While the invention will be described hereinafter with reference to submersible craft, those possessed of the appropriate skills and imagination will readily appreciate that the invention is capable of wider applications.
  • This invention also concerns a marine propulsion system suited to high speed craft which benefit from being able to vector their thrust about two tilt axes.
  • a personal hybrid submersible craft is proposed which ideally utilizes such a drive system.
  • ROV Remote Operated Vehicle
  • ducted propeller units acting in various fixed directions to permit multi axis thrust.
  • Voight Schneider drive a propulsion system known as a Voight Schneider drive. This was first developed in Germany in the 1930's for use on tug boats and the like. It is able to generate thrust along a two axis vector; but is difficult to seal, has limited efficiency and is prone to fouling.
  • a very welcome craft concept would be safe and 'green', easy to use well in any water condition, intimate and exhilarating in a strange new world. Such a craft is proposed by this invention.
  • This invention proposes to replace propeller based thrusters with an arrangement of rotating or oscillating fins. Three different concepts are described.
  • the fins act like paddles in an underwater paddle wheel as shown in Fig 3.
  • the fins are attached to a boss rotating in the thrust plane such their axes are substantially parallel to each other.
  • the fins also rotate about their own axes in the same direction as the boss but at half its rotation rate. This ensures that when a particular fin is moving in the desired thrust direction it is presenting it's full face area to the water, optimizing the thrust; whereas when the boss has rotated 180 degrees with the fin now moving 'upstream', the fin has only rotated 90 degrees and is now edge on, minimizing the drag.
  • the changing fin incidence angle to the flow direction ensures that it continues to provide a cooperating thrust vector over most of its cycle, ingesting water at the top and expelling it at the bottom.
  • the thrust direction is therefore substantially normal to the fin which is at the point in its cycle when it's surface lies at a radial orientation to the boss
  • This timing position is governed by the rotational offset between the boss and fin axes. In this invention this can be readily varied by the simple expedient of rotating a reference shaft. This is accomplished with minimum inertia or drag, as the fins are thereby only increasing or decreasing their own rotation rate about their own axes as they advance or retard to the new radial offset or thrust vector. If the reference shaft is continuously rotated so the thrust vector will continuously rotate; and in a 1 : 1 relationship.
  • the charm of this concept is the ability to mechanically drive the fin axes from the boss rotation at constant angular velocity; thereby permitting the system to be run at high speeds (rather than where the fins have to accelerate back and forwards as they oscillate).
  • the arrangement benefits from employing three or some greater odd number of blades to balance reaction forces and to reduce thrust and torque ripple.
  • each such drive unit can generate a two axis co-planar thrust vector, in order to achieve full 6 axis control of a submersible craft a minimum of three units need to be deployed.
  • the most symmetrical thrust vectoring is achieved when the units are arranged such that their boss axes are radial about a common origin every 120 degrees.
  • individual fins describe a conical (or fructoconical) surface as they orbit around a central drive axis. Thrust is generated by also rotating the fins about their own axis such that they act as blades with a variable pitch angle; and timed to focus the thrust in a particular vector.
  • Each fin can thereby generate variable thrust in two axes with a sinusoidal swim action.
  • Various arrangements and drive methods are proposed.
  • the fin does not continuously rotate about it's own axis; it merely oscillates, while also orbiting it's pivot point.
  • the down side is that this requires continuously varying acceleration
  • fin units arranged in a cross can provide synchronous six degrees of motion.
  • the minimum arrangement for 6 axis control is 3 fins arranged as a "Y" in a common plane, but reaction forces cannot then be balanced resulting in some movement ripple.
  • the fins are permitted to oscillate more freely around a pivot point with separate drive power to each of the two tilt axes and fin rotation.
  • the fin can then be closed loop processor controlled to provide a sinusoidal swim action in any vector.
  • Propulsion with fins can be up to around 80% efficient, compared to 50%) for a good propeller thruster.
  • the proposed craft will operate is in the near region above and below the water. It will plane on the surface, it will shallow dive, it will porpoise, it will surf. With an eye line not far above the water, thrills will come at low speed and with low risk.
  • the craft is like an electric powered surfboard that envelopes you, with arms and legs controlling fins and thrust direction. It has minimal displacement and rests partially submerged; breaking through the waves rather than climbing over them. It has a total of 7 control axes (compared with the 2 of a regular boat); as such it offers many control combinations which permit the acquisition of skill and agility but without demanding it.
  • the users limbs act intuitively as they become control surfaces.
  • the craft is really more like a 'dolphin man' superhero costume than a boat - you wear it more than ride on it.
  • the craft features a novel 2 axis vectored propulsion unit that lets it steer up and down as well as the usual left and right.
  • the drive has been fully integrated into the hydrodynamics of the hull. Reversible power output is adjusted with a hand throttle.
  • the craft has minimum displacement such that when resting, the users legs and lower body lie mostly submerged. It is designed to permit planing above modest speeds but is axially drag balanced such that it retains it's stability under the water. It achieves this partly by shedding the bow wave or the impact of oncoming water to either side of the craft rather than under (and over).
  • the user lies feet first with a low back and head rest.
  • the hull surrounds him; it is self draining, and with the cushion leaves little space for puddled water.
  • a transparent cowl can be pulled forward from the headrest (over and around the head) when dive or splash protection is needed.
  • the users arms rest in buoyant articulated winglets that serve to provide stationary balance and extra control agility.
  • the users feet operate a 2 axis tilt pad which effects synchronously both the thrust vector and the attitude of small forward control fins.
  • the winglets are engineered with 2 pivot axes emulating the shoulder.
  • the axis arrangement permits up, down and rotational movements, but not back and forward. This minimized the arm load necessary to maintain winglet stability.
  • the use of the winglets is intuitive, being like turning your arms into fins. You can use them as stabilizers, acting both as floats and paddles which can come clear of the water at speed. You can lean into them, turning them into offset rudders to assist in tight turns or hydroplanes to add lift. They also enhance attitude control when submerged.
  • the tilt pad can work in several ways but in the preferred embodiment it acts about a central 2 axis pivot point both as a 'rudder bar' (left / right) for turns and 'elevators' (back / forward) for dive / climb. In sync with this, the thrust is vectored in the mirror image of the tilt pad to augment and enhance the steerage control.
  • the user has access to a portable air reserve.
  • a portable air reserve In one embodiment this is a simple passive system operating at ambient pressure. It uses an inflatable bladder (that can double as a cushion) which is filled with an open cell foam acting as an expansion spring. Whenever the craft is on the surface, the cushion will re-inflate with fresh air. When submerged, the user can breath out of this supply. No regulator is necessary because the air will be at about lung pressure regardless of depth. A simple non return valve ensures exhausted air is expelled. The effort necessary to breath is proportional to the air reserve, so the user has an intuitive feel for how many useful breaths remain.
  • Fig. 1 shows a functional schematic of the Voight Schneider drive in plan view, with the blades shown as a progression of positions.
  • Fig. 2 shows the sinusoidal swim action created by fin movement as employed by the second concept drive system.
  • Fig. 3 shows the 'paddle wheel' fin motion employed by the first concept drive system.
  • Fig. 4 shows a hybrid motion possible where fin axis control is independent of boss rotation; in this case causing water to be ingested radially and expelled along the fin axis.
  • Fig. 5 shows a sectional and plan view of a two axis water turbine with attached in-line motor and direction vector control servo.
  • Fig. 6 shows a further embodiment of a two axis turbine with additional performance enhancing feature.
  • Fig.7 shows a further embodiment of a two axis turbine optimized to perform in a high ambient pressure environment.
  • Fig. 8 shows how a two axis turbine can be implemented using belt rather than gear coupling.
  • Fig. 9 shows a sectional view of the mechanical arrangement employed to control the movement of a non-rotating fin set.
  • Fig. 10 shows an example craft featuring such a non-rotating fin set.
  • Fig. 11 shows an example of a craft featuring two, 3 axis twin blade drive units.
  • Fig. 12 shows an example of a craft featuring three, two axis drive units.
  • Fig. 13 shows a schematic of the force vectors generated by a four orthogonal fin craft.
  • Fig. 14 shows a side and plan view of a proposed personal hybrid surface/submersible craft.
  • Fig. 15 shows the extending pitch propeller in a wire frame mesh graphical format.
  • Fig. 16 shows two views of the extending pitch propeller in a wire frame graphical format.
  • Fig. 17 shows a wire frame view of the assembled motor, propeller, stator support ring and stator - shown with the duct oriented to effect the sideways vectoring of the thrust.
  • Fig. 18 shows a wire frame view of the stator unit.
  • Fig. 19 shows a sectional view through the drive system as installed in the craft.
  • Fig. 20 shows the three elevations of the yolk used to attach the stator to the control rods.
  • a shaft (F5.3) connects the vectoring servo (F5.7) through the hollow drive shaft to a gear at the center of an upper gear set (F5.4).
  • Intermediate gears (F5.5) whose rotational axis is held by the mounting boss then orbit this reference gear as the boss is rotated - in turn being obliged to rotate about their own axis.
  • the blades also have individual gears (F5.6) each driven from the intermediate gears. The use of intermediate gears has the effect of reversing the direction of rotation (rather than the blade gear acting directly against the reference gear).
  • the reference gear must have half as many teeth as the blade gear, such that as the boss rotates, the intermediate gears are forced to rotate and in turn rotate the blade gear, with the rotation speed of the blade gear then being half that of the boss.
  • the blades are orientated such that successive blades lie at the same angle as a single blade would be if driven around to the successive positions as shown in Fig. 3.
  • a blade (F3.1) lies in a radial plane, after 120 degrees of boss rotation it has rotated 60 degrees, and again after a further 120 degrees of boss rotation it has rotated a further 60 degrees.
  • the motor could be offset and drive the boss shaft via a side driven mechanical coupling (such as a gear or belt).
  • a side driven mechanical coupling such as a gear or belt.
  • a disc which connects the blade tips freely at their rotational pivot axes. This is achieved by capturing a 'spinner' and hex socket fastener (F6.3) in the disc and then fixing it to the blade by accessing it with a hex key through a hole in the disc.
  • the disc has the effect of protecting the blade tips during their orbit, and also to lock the three blade axes together to again make the whole assembly more durable.
  • a ring could be employed.
  • the blades themselves benefit from being blended into rigid discs at either end (F6.4). These discs can be arranged such that they are countersunk into the surface of the boss (F6.5). This ensures that there is no opportunity for the ingress of 'stringy' matter, which might otherwise jam between the blade and boss.
  • the blades may also advantageously be designed such that they present a larger surface area near their mounting axle where the leverages are more readily sustained. In order to avoid excess turbulence within the gear set (when otherwise flooded) helical gears rather than spur gears should be employed.
  • the boss would advantageously include internal pockets (F6.6) adjacent to where the gears mesh to assist the flow of fluid being ejected from the gear mesh.
  • the embodiment described includes a mounting hub bearing cartridge
  • a water pump (used for motor cooling) is integrated between the hub and the underside of the boss (F6.9). Water is trapped by the turbine blades and flung out centrifugally as it rotates. The low pressure in the center causes more water to be sucked up the feed pipes (F6.10) to effect the forced water circulation.
  • Fig. 7 shows another embodiment optimized for deep sea submersibles.
  • the shaft seal diameters for both drive shaft (F7.1) and control servo (F7.2) can have minimum diameters and it permits the servo shaft to be offset from the drive shaft allowing the in line use of standard motors without a hollow core.
  • the drive shaft (F7.3) runs up through the control shaft tube (F7.4) and attaches to the boss (F7.5) on its upper surface.
  • a disc (F7.6) is employed to support both the control tube and the underside of the boss, against which it also maintains a seal (F7.7).
  • the pressure proof housing (F7.9) can be extended to include the motor (and potentially also the servo). This has the advantage of obviating the need for high pressure seals, although such motors with their power amplifiers tend to be of much higher cost.
  • the boss underside may advantageously be chamfered or otherwise blended at its periphery (F7.l l) so as to inhibit the ingress of particulate contamination by obliging it to be flung out centrifugally.
  • Another method employs belt rather than gear coupling as shown in Fig. 8.
  • the belt (F8.1) must be double sided. It runs around the blade pulleys (F8.2) and inwards to orbit the control pulley (F8.3).
  • a tensioning device can be imposed against the belt although in practice centrifugal force increases the belt tension as the boss rotational speed increases.
  • One objective in good belt design is to minimize the turbulent disturbance caused by the belt when running through a fluid bath. Rather than relying on an external tooth form to prevent belt slip, a thin alloy belt with punched index holes could be used. Conforming protrusions at the same pitch on the pulleys would then prevent belt slip.
  • the second drive concept uses blade oscillation rather than rotation as shown in
  • the preferred method is to employ a mechanical drive and control system equivalent to a helicopters 'collective'.
  • each movement axis can be separately powered. The first embodiment of this concept will be described with reference to
  • Fig. 9 It is a low cost solution, which does not require closed loop control as synchronization occurs by direct mechanical coupling of all four fins.
  • Each fin describes a conical surface by moving it's tip in a continuous largely circular pattern, achieving thrust vector control by the timing of the fin's rotation about it's own axis as shown in Fig 2. Note that the fin oscillates about a fixed reference rather than rotating with the boss enabling a fixed elastomeric seal to be used (F9.14) rather than a dynamic radial one.
  • the key element of the arrangement is a swashplate like system, which acts to effect the fin's rotation about its own axis.
  • Two servo controls can then be employed both to rotate the swashplate tilt axis to change the thrust angle, and to change the tilt (which effects the degree of fin pitch oscillation) and vary the thrust.
  • Reaction forces resulting from moving the fins are balanced by synchronizing the 4 fin actions into diagonally opposite contra-rotating pairs where the fin placement largely describes an X as shown in Fig. 9a.
  • a single motor acts through a reduction gearbox (F9.1) and bevel gears
  • Each drive shaft holds the fin axis (F9.4) at an angular offset, in this case 22.5 degrees.
  • the fin can also rotate about it's own axis, being retained in suitable bearings (F9.19).
  • the rotating drive shaft causes the fin to describe a conical surface.
  • a long lead multi start non-recirculating ballscrew (F9.5) is used such that varying the axial displacement of the nut part (F9.6) causes the fin to rotate about it's axis.
  • the nut part rotation is constrained by a bar running in a slot through it's body (F9.7).
  • the slot is long enough to permit both tilt and axial displacement.
  • the bar retains it's reference angle by virtue of being supported within a pulley (F9.16), with a timing belt coupling it to a principally non rotating 'reference' pulley (F9.20) supported by a reference tube acting around the main drive shaft (F9.8).
  • the rotation of the nut is constrained by the timing belt causing motion like a planet orbiting a sun where each day is equal to each year.
  • the fin can not rotate about it's own axis as it describes the conical surface; this is subsequently caused by the (fin) axial displacement of the nut as a result of the swashplate system described below.
  • the fin plane angle defines any subsequent thrust angle.
  • the plane can be rotated by rotating the reference tube which acts through the timing belt to cause a radial offset to the nut and hence fin axis.
  • the bar constraining the nut (F9.7) can be replaced by other means able to permit two axis tilt and axial displacement but constrain rotation, such as a gimbal (or constrained ball and socket) keyed to move in the nut axis but not around it.
  • a gimbal or constrained ball and socket
  • Constraining the fin's axial rotation can be achieved in two other ways.
  • gears can be employed.
  • idler gears act between the non rotating gear on the reference tube and the gear circumscribing the constraint bar such as to reverse its direction of rotation.
  • rotation constraint can be achieved by including a pivot element and keyway between a ball on the fin shaft and a radially adjustable annular socket at the fins pivot point (or a radially controlled gimbal). The radial control of the constraint reference becomes part of the thrust angle control.
  • the end of the nut features a ball which is retained in a cylindrical pocket in a swash plate system (F9.9).
  • the pocket permits ball rotation about the nut axis, rotation in the plane described by the drive shaft and fin axis and some displacement along the pocket axis, but crucially not along the nut axis.
  • the pocket extends from a swash ring supported by a large diameter radial bearing.
  • the inner race of the bearing retains a disc (F9.21) featuring a single axis pivot (F9.17) connected to the reference tube (F9.8) and a point on the rim displaced orthogonally from the pivot axis (F9.11). This is connected to a forcing element whose position axial to the reference tube establishes the swash tilt angle.
  • This forcing element can be displaced along the reference tube axis by use of a rack and pinion (F9.12) where the pinion drive shaft is driven by one of the control servos.
  • the rack is attached to the forcing element via a radial bearing (F9.18), permitting rotation of the reference tube without effecting the position of the rack.
  • the reference tube is connected by pulley to the other control servo. As the reference tube is rotated, so the swash tilt axis is radially offset as is the reference position for the fin angle; thereby rotating the thrust vector.
  • the drive shaft Without tilting the swash plate system, the drive shaft causes the ball at the end of the nut to describe a circular path. When tilted, this path becomes parabolic (as a section through a cone), forcing the nut to be displaced along the fin axis as it rides from peak to trough. This displacement of nut against screw shaft then forces the rotation of the fin about it's axis such that in each revolution of the drive shaft, the fin rotates first one way and then the other.
  • an elastomeric "boot' connects the fin to the crafts body shell (F9.14), such that it provides a hermetic pressure proof seal.
  • the boot must permit about 22.5 degrees of tilt and +- 135 degrees of rotation (+- 90 degrees of thrust angle, +- 45 degrees of radial oscillation).
  • the boot bearing part of the fin shaft can have an enveloping linear array of short tubular spacers or washers (F9.15). These can rotate with the boot, distributing the shear forces along the available length. A further layer of very soft elastomer can then also be employed between the washers and main boot skin, improving the averaging of shear forces.
  • a low cost variant could be readily produced from injection moulded thermoplastic parts with a suitably low coefficient of friction.
  • Small 'model aircraft' type servos can be employed to effect the thrust vector control.
  • the single motor has no seal issues and can be a low cost DC unit.
  • the ⁇ n can pivot in a plane, rather than describing a conical surface.
  • a direct means is then employed to effect the synchronized oscillatory rotation about the fin axis.
  • a servo can also rotate the pivot plane to alter the thrust angle and again adjusting fin pitch oscillation varies the thrust.
  • each fin unit need not be mechanically coupled, permitting their placement where most convenient for the craft. Rather than use multiple geared electric motors, a particularly suitable drive system is hydraulic. This lends itself to distributed high power densities operating at relatively low speeds. Also a hydraulic system will work fine at any ambient pressure, employing as it does pressure difference rather than net pressure to transmit it's power. This means that it is possible to design each fin unit as a hermetically sealed but not pressure proofed part, simplifying it's design and improving the performance of the boot (by fluid filling it).
  • the motor that drives the pump could also be fluid filled to balance shaft seal pressure, or a magnetic 'through bulkhead' coupling could be employed - thereby leaving the motor (and control electronics) in a dry space.
  • Each fin needs three motors.
  • the main 'power' motor causes the basic planar oscillation of the fin about a pivot axis.
  • Another motor rotates the pivot axis thereby effecting thrust angle control.
  • the third motor rotates the fin about its axis to create the sinusoidal swim action.
  • Each axis needs closed loop positional control or a means to effect synchronisation between the fins to balance the reaction forces.
  • thrust vectoring occurs by establishing the best possible thrust plane (like a joystick being able to oscillate anywhere within the confines of it's limiting bumper). The thrust plane can then not only rotate
  • a further advantage occurs as the thrust angle can in effect continuously rotate because two tilt axes do not introduce any twist into the protective cover.
  • the thrust angle is confined within twist limits resulting in a possible situation where the angle needs to be 'unwound'
  • FIG. 11 Two fins are connected to a rotatable boss, in such a way that the fins can also be independently rotated about their own axes.
  • Such units are able to generate 3 axis thrust vectors, x,y and torque in the boss axis; acting functionally like two independent fins. They are powered by a common high power motor rotating the boss and have smaller motors or other limited angle actuators controlling each fin axis.
  • the different swim methods need not be mutually exclusive.
  • a 2 fin module with independent fin axis control could be run in the 1 : 2 synchronous mode if the axis servos are able to rotate continuously as a motor.
  • a system with independent fin control can cause overall water ingestion by reversing part of the tilt direction. Where the fins are otherwise describing a cone, this results in exhaust thrusting out of the open cone end principally along it's axis. This effect can be employed to increase thrust in that vector.
  • the Control System The Control System:
  • Fin 1 and Fin 3 are capable of generating thrust in the xz plane (y normal) and Fin
  • the units of C and R represent the maximum maneuvering speed and are determined experimentally.
  • the guidance system knows it has to live within these limits.
  • the thrust angle and pitch rates for each fin can be calculated from each fins required thrust vector.
  • the required pitch rate to achieve a given thrust can again be determined experimentally and implemented as a look up table.
  • the pitch can be optimized to the true incidence vector of the oncoming water (reducing pitch as speed increases). This is like a variable pitch propeller where pitch is lengthened for high water speeds; the object being to maintain an optimum work rate without increasing the rpm - or in this case flap rate.
  • All the above thrust vector control can occur at a constant flap rate; however controlling the flap rate can avoid needless 'running on the spot' power consumption. If the guidance system has little requirement for craft movement in the current time period, then the flap rate can be minimized. Equally if the craft has to work hard (through load, drag or acceleration) the flap rate can be maximized for the available motor power.
  • Control of flap rate can also be employed to reduce / increase the crafts command responsiveness; if for example conditions dictate a stealthy approach, or alternately high speed maneuvering or variable load compensation is required.
  • This control system works best in the context of a computer controlled guidance system providing craft movement and positional feedback, such that the control loop can be closed.
  • the user need merely establish the required final position or movement vector and the craft will then manage it's own implementation by setting the appropriate flap rate and individual fin thrust vectors. This is particularly useful as drag from the umbilical or prevailing current conditions can then be automatically compensated for.
  • all fins must flap at the same rate and to the same angular extent. This can result in some reaction force imbalance where for example a fin is not required to produce a thrust vector; because that fin will generate a higher reaction force that a fin pitching through an angle.
  • the system permits individual control of the extent of the flap angle (as in the hydraulic embodiments), a more complete balancing of the reaction forces is possible.
  • the arrangement differs in vector summation when three, 2 axis modules are employed (like the constant angular blade rotation design in the first concept). Torque is not balanced with an equal and opposite symmetry as in a 4 fin system, but by adjusting the overall direction thrust of each module to create a unified counteracting torque about their common axis point. A craft which utilizes such a drive system is shown in Fig 12.
  • the hybrid surface / submersible craft An embodiment of such a craft is shown in (stylized) section and plan views in Fig. 14.
  • the hydrodynamic design is a compromise to achieve minimum forward resistance, minimum static displacement consistent with the users head and shoulders being clear of the water, wave piercing rather than climbing, axial drag and buoyancy balancing when submerged, a form which can hydrofoil or plane to enable good top speeds at low power, protection for the user without too much restriction and integrated flow management for the drive system to minimize drag and 'prime' the hybrid thruster.
  • the bow has to protect the feet and forward control system. It features side deflecting scallops between twin vertically displaced prows (F14.1). This mitigates water breaking over the top of the craft into the lap of the user where it would drain momentum. By breaking the flow it assists in letting the nose climb as the craft speed increases to get on the plane. It also avoids an otherwise more raked nose creating unbalancing lift when the craft is completely submerged.
  • the main hull body blends from a shallow V at the nose into a shallow tunnel at the rear. This allows trapped air to lubricate the underside skin thereby reducing drag, provides for largely parallel lower 'rails' (F14.2) to assist in longitudinal stability at speed and in turn blends into the inlet concavity for the thruster (F14.3). From the rails it scoops up to the varying beam of the craft such that drag falls swiftly as the hull rises at speed. The rails also act as rubbing strips when the craft is beached thereby protecting the underside surface. They blend into the thruster cowling leading edge.
  • the hull rises between the knees to provide an enclosed volume to hold the battery packs (F14.4). It then dips down around and below the body shape of a reclined user.
  • an air filled cushion (F14.5) provides for generous padding under the user, tailored with variable thickness to reflect the local shock load if the craft 'slams' full face onto the water (e.g. a flat landing after coming off a wave or jump).
  • Extending from the back support is an adjustable head rest and protection system
  • the head rest and support system The head rest and support system:
  • the visor (F14.8) fully retracts so need only be deployed when required, it does not remain a permanent encumbrance for even undemanding craft usage. It consists of a hydrodynamically sculpted integrated helmet and visor adjustably attached to the top of the back support.
  • the helmet is attached to the craft rather than to the user - he need only sit forward to release himself.
  • the large visor pivots around the head over the back of the rear fairing such that when fully back it does not protrude much forward of the head rest. It has a softly padded open edge. When needed, it can be pulled forward to approaches the users chest or even rest upon it. Because it is substantially spherical, any external load (apart from minimal friction) acts surface normal into the pivot axis, thereby avoiding any rotational displacement.
  • the pivot (F14.9) is arranged such that any internal load (like hitting it from inside with your head) causes it to dislocate.
  • the helmet body has a generously padded lining into which the back of the head up to the ears fits; and an optional padded band that can be pulled down over the forehead (to protect the head if it comes forward against the visor). It is more of an enveloping head rest from which you can readily extract your head than a typical crash helmet.
  • Alternative embodiments have the padding on a separately wearable cap with the headrest as a rigid surface or keeps the helmet with the user which is then attached to the craft with an overload releasable fitting.
  • the helmet is not designed as a swim mask in that it has an inadequate lower edge seal and will flood with sustained submerged use, however is adequate for short duck dives where it acts as a diving TjeH'. With the visor down the user needs a mouthpiece to access fresh air from the snorkel or any reserved supply. A secondary face mask will therefore be necessary for sustained submergence.
  • the winglets (F14.10) are each connected to the craft through a 2 axis pivot behind the shoulder position (F14.7).
  • the user controls them by placing his arms partially inside and gripping the individual handle bars (F14.l l). As such they become hydrodynamically faired arm extensions, emanating backwards from the elbows. They are force balanced such that they support the weight of the users arms in their neutral control position.
  • the 2 axis pivot can be arranged in several ways, but importantly such that it both allows the winglet to ride substantially level on the surface of the water and to introduce a lifting or turning component in moving water depending on how deployed.
  • the water normal axis is constrained, thereby preventing the winglet being forced back by the onrush of water.
  • the pivot axes require an increasing control force to rotate up to their articulation limits; with a neutral control resting position.
  • both axes are adjacently packaged at the shoulder and run orthogonal to each other at roughly 45 degrees to the craft axis in the horizontal plane (at neutral control); the inner pivot being backward facing and the outer pivot forward facing (F14.7).
  • the craft has no keel and a minimum beam, it will be subject to instability at relatively small list angles when the addition of the user raises its centre of gravity above it's centre of buoyancy.
  • the winglets act as sponsons and help retain balance in difficult conditions.
  • the hydrodynamics stabilize the platform such that the sponsons can be raised clear of the water (also as the craft lifts) to minimize drag especially when moving into planning conditions.
  • the winglets also act as control or lift surfaces to sharpen turns and generally increase agility. If the wing is lowered (as on the outer facing side of a fast turn) on it's inner tilt axis, the fin generates lift to provide a positive heel force and a side acting component to enhance steerage. If the wing is raised
  • the tip of the sponson acts as a rudder in the water but this time with minimum lift. They also act in parallel to increase or decrease rear lift like hydrofoils, thereby helping the craft onto the plane or in the extreme acting like sea brakes.
  • the sponsons act like hydroplanes and can introduce a left / right independent rear up or down force. This enhances agility and can help the craft stay submerged at modest speeds.
  • the fin and thrust vectoring system Extending at an upward angle from either side of the nose are two small hydroplanes (F14.12) designed to assist in diving and enhance submerged agility by providing lift / dive as well as rotational reaction forces. They work complimentary to and synchronous with the 2 axis displacement of the rear mounted thrust vectoring nozzle (F14.18), such that they enhance each others control effect.
  • F14.12 the thrust vectors down to make the front dive
  • the thrust vectors down to make the back rise and vice versa
  • the fins generate a side acting vector the thrust vectors to the opposite side. Because the fins are displaced from the craft's axis they also generate a useful axial torque tending to bank the craft into any turn - particularly when submerged.
  • a mechanically mixed system uses push / pull rods to connect the control pad to the fins and nozzle.
  • Many other arrangements are possible including cable or hydraulic linkage.
  • the foot pad (F14.13) has a central 2 axis pivot point (F14.14), with two control rod coupling points (F14.15) displaced such that they are roughly twice as far apart as their common parallel offset from the pivot point; thereby ensuring a similar control sensitivity to forward / back tilting as left / right tilting.
  • the pivot support shaft (F14.16) can be lengthened telescopically on the craft to an appropriate position for the height of the user, and the control rods (F14.17) lengthened or shortened to reflect this.
  • the control rods have ball and socket or 'rose joint' ends and link the pad coupling points to control horns (F14.19) on a special common axis bar (F14.20). Tilting the pad alters the effective lengths of the rods thereby rotating the control horns.
  • the mechanical mixing acts such that forward / back tilting causes common axis rotation and dive / climb reaction forces, while left / right tilting causes opposite axis rotation and right / left turn forces.
  • the common axis bar is a tube within a tube such that the inner tube connects to the fin pivot with a universal joint on one side, and the outer to a U.J. on the other side.
  • control horn for the fin connected to the outer tube can then be directly attached to it, near it's outer end, while the control rod for the inner tube acts through a radial slot in the outer tube near it's inner end.
  • the control horn should have the same leverage length as the parallel displacement of the control rod / pad coupling points from the pivot, the distance between the control horns should be roughly the same as the distance between the two pad coupling points and the neutral angles of the control horns should be roughly the same as the neutral angle of the foot pad.
  • the common axis bar is supported at either end with a 'pillow block' that integrates the push pull drive for the thrust vectoring nozzle (F14.18). As the horn moves forward the nozzle control rod must move back.
  • a spur gear effectively attaches to each control horn and an idler spur gear acts against it.
  • the idler gear traps and in turn acts against an axially displaceable rack, such that moving the control horn outwards pushes the rack inwards.
  • the end of the rack is attached to the end of the nozzle control rod with a further connecting rod permitting some angular displacement. This is to minimize any bend in the control rod and allow it to approach and act from it's natural angle.
  • the two nozzle control rods connect to the nozzle rim alternately left and right, 45 degrees from the vertical enabling the craft hull to readily integrate the mechanism. If the connection points were on the underside of the nozzle, idler gear direction reversal would not be necessary, but the nozzle push rod mechanism would be less conveniently located in the thin lower part of the thruster ducting.
  • Fig 17 is a an assembled view of the system but without it's rear annular socket; and Fig. 19 which shows the nozzle and push rod detail with the upper section in the plane of the push rod and the lower section in the plane of the constraint pin.
  • the craft uses a brushless DC motor (F17.1 & F19.1) for its reliability, efficiency and in particular ease of cooling the external stator through water contacting the motor housing.
  • a basic servo amplifier is used to control the motor; in this embodiment in current mode such that the throttle acts like a car's to vary the power output (rather than the rpm).
  • the throttle is hand operated and located on the winglet handle bars.
  • the maximum current is kept at a manageable level by using quite a high bus voltage - in this case 120v.
  • the motor can maintain a continuous 4 kW output at 3,000 rpm, and with higher short term peaks.
  • Power is provided by two removable 60v, 7Ah NiCad battery packs, each weighing about 12 kg. Together they will enable full power for about 12.5 minutes. A further 4.3 Ah is provided by a removable reserve. In practice full power is only used in short bursts, with an average power consumption of less than 1 kW; giving a total running time of about 80 minutes (reserve included). The battery packs are removed for charging and can be immediately replaced with fully charged alternates.
  • the prop can be connected directly to the motor shaft resulting in a simple in line thruster pod which can be hermetically sealed and hence run fully submerged.
  • the propeller / thrust vectoring system is an original hybrid designed to offer the safety of a jet drive and efficiency of a propeller. It is fully integrated and recessed into the hull form enabling the craft to be safely 'beached'. Water flows readily into the prop cavity; thereby requiring little suction to prime the cavity after immersion. It also means that the prop can generate reverse thrust without near 180 degree flow vectoring (unlike a jet drive).
  • the prop as shown in Fig 15 and Fig 16 is relatively large to efficiently provide a good thrust at low speeds, particularly beneficial for the higher drag submerged use. It extends from the motor pod in a slow progression of diameter and pitch, then curves round such that it's surface of revolution becomes spherical. This allows it to run within a conforming spherical thrust vectoring duct (F17.2 and F18.2 and F19.2) which in turn is retained in an annular socket (F17.3 and F19.3); keeping the system very compact.
  • the relatively large diameter at the start of the prop core, slow radial growth and lack of a contaminant snaring blade tip reduce the risk of fouling around the shaft.
  • the prop has an extending pitch (in this embodiment of about 60%) and a soft leading edge which together reduces the leading edge 'shock' and hence the risk of cavitation; especially on initial craft acceleration. It achieves this without compromising the high maximum exhaust velocity needed for fast running. With lower point stresses this style of prop may lend itself to moulding in engineering grade plastics.
  • the spherical duct thrust nozzle can rotate about 2 axes within the annular socket.
  • the third axis (about the plane of the socket) is constrained by two horizontally opposed inward facing pivot / slide pins (F17.5 and F19.5) retained in the socket and running in a longitudinal radial groove (F18.1) in the outside of the duct.
  • the annular socket is comprised of two rings (F19.3 and F19.4) with internal truncated hemispherical surfaces which trap the spherical duct and constraint pins (F19.5) between them.
  • the inner ring is firmly retained against the craft with the outer ring releasable from the inner; permitting the duct to be extracted.
  • the duct has two 90 degree displaced outward facing coupling points (F17.6 and F19.6) which connect to the control rods via two axis yolks as shown in Fig 20 (permitting the angular displacement caused by the ducts two axis rotation).
  • the duct coupling points are symmetrically arranged about the constraint pins and at 45 degrees from the vertical.
  • the constraint need only have one engaging protrusion; where it has two their common pivot axis must intersect the focal point of the spherical parts. It can be outward facing (retained in the duct, groove in the socket) as well as inward facing as in this embodiment. In all cases: rotation in the plane of the socket is constrained, the two coupling points should be around 90 degrees radially displaced from each other and to achieve control symmetry they should in turn be symmetrical about the constraint(s).
  • the duct nozzle features an array of inward bearing stator blades (F18.3 and F19.7). They serve both to unwind the props exhaust vortex thereby reducing the crafts axial torque reaction and to enhance the effect of the nozzle in vectoring the flow. As they bear inwards with a backwards rake they are unlikely to foul as there is no axial shaft around which things can tangle.
  • the breathing system In the preferred embodiment the breathing system is simple and passive, utilizing air reserved in the cushions (and / or other bladders) as a third lung.
  • the energy that powers the system comes directly from the work done by the craft in getting submerged. If such a system holds around 30 litres of air it will serve the user with a few minutes of careful use; more than adequate for his duck dive needs.
  • the cushions can be either a complete bag with an internal open cell foam core or can utilize the adjacent upper craft shell as the lower surface, with a flexible upper skin only.
  • This design variation has the advantage of effectively sealing the cushion to the craft such that it is not able to float away from the craft when submerged. To effect this, an air tight seal has to be made between the flexible skin and the craft. As the seal can be releasable, it can be occasionally removed to clean the foam core.
  • the foam core has a coefficient of restitution sufficient to lift the user a little and fill out the spaces around him when the craft is surfaced.
  • the single opening acts as a damper to enhance the apparent cushion hardness when subjected to shock loads. Such air has to be evacuated through the snorkel system.
  • the snorkel is of a style which closes the air channel automatically when submerged and opens again on surfacing, even if subjected to a low back pressure. It connects both to the 'lung' and breathing tube.
  • the mouthpiece of the breathing tube incorporates a one way valve so as to exhaust stale air out of the system.
  • the user can breath through the snorkel at the same time as the lung is re-inflating.
  • the snorkel shuts off and the user begins to breath the air from the lung.
  • ambient pressure differential between the slightly lower lung and the user becomes insufficient to further collapse the foam lung core, requiring suction assist from the user. This serves as a useful intuitive indicator of the amount of remaining air, leaving time to reach the surface.
  • lung pressure compared to ambient pressure can be processed to enable a digital air volume indication.
  • the safety systems are The safety systems:
  • the craft is capable of deep dives and fast climbs which would be a serious hazard to the user. However because of it's intrinsic buoyancy it requires a high power output to stay submerged; any loss of power would result in immediate surfacing.
  • the craft is therefore fitted with a depth limiter that cuts off the power above a safe pressure. This will be set to less than 2 Bar leaving a maximum dive depth of less than 10m.
  • a potentially more sensitive system would be processor controlled and relate dive duration to depth. Because nitrogen narcosis (the bends) requires many breaths to super saturate the bodies fluids, fast deep dives can be less hazardous than prolonged shallow ones (in both cases with quick assent).
  • the preferred breathing system requires increasing suction as reserves deplete and is therefore safe and intuitive. In any event because of depth limits worst case surfacing will still only take a few seconds.
  • Power reserves are shown by a bar graph comprised of LED's located along the trailing edge of the foot well cowling, along with a main or reserve indicator. Present drain rate (or time remaining at present rate) could optionally also be displayed. Other possible locations for instrumentation include in the users peripheral vision around the rim of the headrest / helmet.
  • the battery packs connect with watertight couplings and are separately enabled when their integrity has been confirmed by electronically checking for power leakage. Any subsequent leakage automatically switches them back off.
  • the cell packs include one way pressure relief valves which permit the venting of gases (particularly during charging). In ideal conditions the craft could have a range of 30 km, so the inclusion of a compartment within the body shell which can house safety equipment (flares, radio, compass etc.) is helpful.
  • Submarines generally have a large displacement and could not be considered as personal. Small submarines have tended to be 'wet', in that they don't protect the occupant(s) from the high water pressure at depth.
  • This invention proposes a design of pressure proof containment vessel suitable for a personal submersible.
  • the design is optimised to provide for good pressure resisting characteristics with the minimum use of materials, consistent with human factors. It employs ellipsoid forms for the body and a spherical view dome.
  • a method is proposed to permit the application of an extendible arm in retrieving samples or specimens and returning them to within the craft.
  • the method also permits the end effector of the arm to be changed from within the craft.
  • the craft is well suited to a 6 axis marine drive system permitting the craft to be held at any attitude and position in the water.
  • Alternatives are proposed.
  • the perfect pressure vessel is the sphere, but to comfortably enclose a person within a sphere would require one of around 1.8 m diameter. This would displace over 3,000 kg.
  • Wall thickness is directly proportional to radius for a given maximum loading (for thin walled vessels - where the thickness is approximately less than the radius/10), e.g. halving the radius would permit a halving of the wall thickness. There is therefore a significant economic benefit in keeping the maximum hoop radius as small as possible.
  • This invention proposes the use of two hemi ellipsoids (Fl.l & F1.2). They both have the same minor diameter, but differing major axes such that one is approximately twice as long as the other.
  • the vessel hinges at this interface (shown in F2.1), opening up to permit the user to enter.
  • the view dome is now a small hemisphere of about 450 mm OD, rather than the complete upper hemi ellipsoid. It is thereby much lower cost to produce. It is also more readily scaled up in wall thickness to enable ever higher loads and consequently dive depths. The ellipsoid shell can then be more efficiently made without the constraint of transparency.
  • the entire craft now has a displacement of around 500 kg, making it commensurately easier to operate than spherical designs.
  • the form is also very hydrodynamically efficient and in nose forward cruising attitude would require minimal drive power. Reducing the power requirements has other beneficial spin-offs; especially in extending duration with small battery packs.
  • the seal between the two ellipsoids (F2.2 & F2.3) is easy to make because it is round; and the pressure will bare down equal and opposite as the ellipsoids achieve common tangency at the interface.
  • This invention also proposes a method to deploy additional temporary floats.
  • a sytsem is shown inflated in Fig. 2.
  • the floats are pneumatic and are stored uninflated, coiled up within pod like structures otherwise attached to the outside of the lower hemi ellipsoid (F1.6). They function like that well known party toy that unrolls as a tube when you blow behind it (also then wailing as it jiggles it's end feather). Only in this case it is a reinforced tube preferably tapered, constructed similar to inflatable dinghies, caused to coil by the inclusion of flat band constant force type springs.
  • the air pressure required to uncoil it is provided by a reserved supply, or an air pump which breaths through a snorkel.
  • the pods open up like clam shells and permit the expanding coil to extend out (F2.5). Air is filled until the tube (or fructo cone) is suitably rigid as shown in F2.4a, 4b, 4c and 4d.
  • This process occurs at least two points and preferably four, around the outside circumference of the hemi ellipsoid; thereby conferring flotational stability on the craft while also raising the hatch clear of the water.
  • the floats act as a suitable staging post to gain entry to the craft, either directly from the water of from a support boat. To provide added security, it is advisable that the floats contribute sufficient buoyancy that even if one of their number were to fail the craft will still float. The assumption must also be that in the worst case the inside of the craft is completely flooded out. When the user wishes to dive, he seals his hatch and then checks that not too much water has invaded the craft (and can deploy a bilge pump to evacuate any that has).
  • the float valves are then opened permitting the air to escape; firstly the premium over atmospheric and then the remainder as the coil springs begin to wind the floats back up.
  • the pod covers close. At this stage the craft should be at near neutral buoyancy just below the water's surface; ready for the marine drive to take command.
  • manipulators One limitation of manipulators is that you never seem to have the right kind of end effector - or indeed you may not want an effector at all, perhaps an extra camera or other instrumentation. Surfacing in order to re-designate the manipulator is inefficient, especially when otherwise operating at extreme depth.
  • Fig. 5 It is to fix the hatch cover (F5.1) for the internal pressure lock to the manipulator (F5.2), rather than to the craft. Being a permanent fixture around the arm it need not compromise integrity.
  • the manipulator returns the cover into position (as shown in F1.4), leaving the effector and anything collected within a small 'bell jar' like internal facing pressure lock. Water is evacuated from inside the lock to either outside the craft by a high pressure compressor or more conveniently to an internal water tank. The bell jar can then be released, giving clear access to the effector and samples.
  • the bell jar When the effector is to be re-deployed, the bell jar is attached and allowed to flood with external water or water from the internal tank. When filled, a valve can open and connect the internal bell jar with the outside, thereby equalising the pressure and permitting the hatch cover to be withdrawn.
  • a convenient arrangement is to make the manipulators base axis hollow such that it can contain part of the pressure lock (F5.6).
  • the manipulator can then fold back in a single axis to replace the cover over the pressure lock in it's correct position.
  • rotation about the manipulators base axis when the cover is in position can be used to mechanically lock it closed.
  • the internal bell jar can be deployed by a novel method as also proposed by this invention as shown in Fig. 6.
  • the bell jar has a fructo conical flange or flange member around it's outer annulus (F6.1).
  • the jar fits over a conforming mounting tube (F6.2) such that it is slid into place along the tube axis.
  • the tube leads to the outside of the lock.
  • Seal rings (F6.3) are fitted to act between the interface as the jar is slid home.
  • a collar (F6.4) otherwise retained around the jar annulus can be screwed or otherwise clamped to the craft body shell at a conforming annular hatch fitting (F6.5).
  • An ancillary feature of the pressure lock concept will enable wet samples such as marine life to be collected and preserved in their own sealed mini aquaria.
  • the end effector will be adapted from a gripper like mechanism (F5.3) to hold two transparent plastic hemispheres (F5.4 & 5.5).
  • the hemispheres When brought together, the hemispheres snap shut with a waterproof seal. The resulting sphere is released when the 'gripper' is opened.
  • the hemispheres are loaded into the effector when in the dry internal space.
  • the manipulator leaves the lock and deploys the sample collector as desired. It is then retrieved into the lock. Once evacuated, the manipulator releases the sphere for closer examination and / or storage.
  • the sample aquaria need not be spheres, but can be any viable watertight container. As spheres and with additional preparation a pressure proof lock could be effected between the two shells - enabling life forms to be recovered and preserved at their normal habitat pressure.
  • One method would be to provide the effector with an additional axis in order to screw two shells together rather than just snap them shut. A little dive pressure air must then be introduced or otherwise be permanently trapped inside of the shells. This could be enabled by a flexible membrane containing some gas or piece of closed cell foam. This device then acts as a hydraulic accumulator and will retain the pressure within the shells (by itself expanding as the pressure otherwise falls) even if the shells are able to expand slightly as they are returned to normal pressure.
  • Fig 1.5 Illustrated in Fig 1.5 is a concept employing two pairs of twin fin drive units as described in the patent application titled “Multi Axis Submarine Propulsion System". They create a variable thrust about two vectors and with a variable torque (total of 3 axes). Two such units - one on each side of the craft - then provide thrust in all six axes.
  • a submersible craft for accommodating a single person, the craft comprising a hull having two interengagably hemi ellipsoidal parts together defining a personl carrying space therein.
  • a craft as in 3 where the floats are comprised of sealed tubes or fructo cone shells which are caused to coil by the application of integrated springs, but can uncoil when sufficient gas pressure is supplied to the outer end of the coil.
  • a small pressure lock comprising of a bell jar like internal form with a fructo conical flange which is slid into position over a conforming mounting tube leading to the outer opening with seal rings between the interface; and then retained by a collar bearing down around the flange such that once the collar is fixed, increasing pressure otherwise trying to blow out the bell jar like a piston also causes the bell jar to be compressed around its open annulus by the conical flange part so as to retain seal pressure to the mounting tube.
  • a marine specimen containment system comprising of two shells designed to clip together with a watertight seal that are deployed with their open side inward facing in a holding device, otherwise able to couple the two shells by bringing them together; and then release the now closed specimen container.
  • a hull for a personal submersible craft comprising of substantially two hemi ellipsoids, where entry is gained by opening the craft at the common tangent interface between them APPENDIX 2 (Pages 40 - 56)
  • a very welcome craft concept would be safe and 'green', easy to use well in any water condition, intimate and exhilarating in a strange new world.
  • the craft is like an electric powered surfboard that envelopes you, with arms and legs controlling fins and thrust direction. It has minimal displacement and rests partially submerged; breaking through the waves rather than climbing over them. It has a total of 7 control axes (compared with the 2 of a regular boat); as such it offers many control combinations which permit the acquisition of skill and agility but without demanding it.
  • the users limbs act intuitively as they become control surfaces.
  • the craft is really more like a 'dolphin man' superhero costume than a boat - you wear it more than ride on it.
  • the craft features a novel 2 axis vectored propulsion unit that lets it steer up and down as well as the usual left and right. It is safe (shrouded and foul proof), clean and quiet (battery electric), potent (efficient water cooled brushless DC) and flexible (using hybrid propeller / impeller).
  • the drive has been fully integrated into the hydrodynamics of the hull. Reversible power output is adjusted with a hand throttle.
  • the craft has minimum displacement such that when resting, the users legs and lower body lie mostly submerged. It is designed to permit planing above modest speeds but is axially drag balanced such that it retains it's stability under the water. It achieves this partly by shedding the bow wave or the impact of oncoming water to either side of the craft rather than under (and over).
  • the user lies feet first with a low back and head rest.
  • the hull surrounds him; it is self draining, and with the cushion leaves little space for puddled water.
  • a transparent cowl can be pulled forward from the headrest (over and around the head) when dive or splash protection is needed.
  • the users arms rest in buoyant articulated winglets that serve to provide stationary balance and extra control agility.
  • the users feet operate a 2 axis tilt pad which effects synchronously both the thrust vector and the attitude of small forward control fins.
  • the winglets are engineered with 2 pivot axes emulating the shoulder.
  • the axis arrangement permits up, down and rotational movements, but not back and forward. This minimised the arm load necessary to maintain winglet stability.
  • the use of the winglets is intuitive, being like turning your arms into fins. You can use them as stabilisers, acting both as floats and paddles which can come clear of the water at speed. You can lean into them, turning them into offset rudders to assist in tight turns or hydroplanes to add lift. They also enhance attitude control when submerged.
  • the tilt pad can work in several ways but in the preferred embodiment it acts about a central 2 axis pivot point both as a 'rudder bar' (left / right) for turns and 'elevators' (back / forward) for dive / climb.
  • the thrust is vectored in the mirror image of the tilt pad to augment and enhance the steerage control.
  • the user has access to a portable air reserve.
  • this is a simple passive system operating at ambient pressure. It uses an inflatable bladder (that can double as a cushion) which is filled with an open cell foam acting as an expansion spring. Whenever the craft is on the surface, the cushion will re-inflate with fresh air. When submerged, the user can breath out of this supply. No regulator is necessary because the air will be at about lung pressure regardless of depth. A simple non return valve ensures exhausted air is expelled. The effort necessary to breath is proportional to the air reserve, so the user has an intuitive feel for how many useful breaths remain.
  • the hydrodynamic intent is to provide a compromise between minimum forward resistance, minimum static displacement consistent with the users head and shoulders being clear of the water, wave piercing rather than climbing, axial drag and buoyancy balancing when submerged, a form which can hydrofoil or plane to enable good top speeds at low power, protection for the user without too much restriction and integrated flow management for the drive system to minimise drag and 'prime' the hybrid thruster.
  • the bow has to protect the feet and forward control system. It features side deflecting scallops between twin vertically displaced prows (Fl.l). This mitigates water breaking over the top of the craft into the lap of the user where it would drain momentum. By breaking the flow it assists in letting the nose climb as the craft speed increases to get on the plane. It also avoids an otherwise more raked nose creating unbalancing lift when the craft is completely submerged.
  • the main hull body blends from a shallow V at the nose into a shallow tunnel at the rear. This allows trapped air to lubricate the underside skin thereby reducing drag, provides for largely parallel lower 'rails' (FI .2) to assist in longitudinal stability at speed and in turn blends into the inlet concavity for the thruster (F1.3). From the rails it scoops up to the varying beam of the craft such that drag falls swiftly as the hull rises at speed. The rails also act as rubbing strips when the craft is beached thereby protecting the underside surface. They blend into the thruster cowling leading edge.
  • the hull rises between the knees to provide an enclosed volume to hold the battery packs (F1.4). It then dips down around and below the body shape of a reclined user.
  • an air filled cushion (F1.5) provides for generous padding under the user, tailored with variable thickness to reflect the local shock load if the craft 'slams' full face onto the water (e.g. a flat landing after coming off a wave or jump).
  • Extending from the back support is an adjustable head rest and protection system (F1.6). Behind the 'shoulders' is the attachment for the winglet pivot axes (F1.7). Across the lap is a restraint with overload release.
  • the head rest and support system The head rest and support system:
  • the visor (F1.8) fully retracts so need only be deployed when required, it does not remain a permanent encumbrance for even undemanding craft usage. It consists of a hydrodynamically sculpted integrated helmet and visor adjustably attached to the top of the back support. The helmet is attached to the craft rather than to the user - he need only sit forward to release himself.
  • the large visor pivots around the head over the back of the rear fairing such that when fully back it does not protrude much forward of the head rest.
  • the pivot (F1.9) is arranged such that any internal load (like hitting it from inside with your head) causes it to dislocate.
  • the helmet body has a generously padded lining into which the back of the head up to the ears fits; and an optional padded band that can be pulled down over the forehead (to protect the head if it comes forward against the visor). It is more of an enveloping head rest from which you can readily extract your head than a typical crash helmet. Alternative embodiments have the padding on a separately wearable cap with the headrest as a rigid surface or keeps the helmet with the user which is then attached to the craft with an overload releasable fitting.
  • the helmet is not designed as a swim mask in that it has an inadequate lower edge seal and will flood with sustained submerged use, however is adequate for short duck dives where it acts as a diving "bell'. With the visor down the user needs a mouthpiece to access fresh air from the snorkel or any reserved supply. A secondary face mask will therefore be necessary for sustained submergence.
  • the winglets (F1.10) are each connected to the craft through a 2 axis pivot behind the shoulder position (F1.7).
  • the user controls them by placing his arms partially inside and gripping the individual handle bars (Fl.l 1). As such they become hydrodynamically faired arm extensions, emanating backwards from the elbows. They are force balanced such that they support the weight of the users arms in their neutral control position.
  • the 2 axis pivot can be arranged in several ways, but importantly such that it both allows the winglet to ride on the surface of the water in a
  • both axes are adjacently packaged at the shoulder and run orthogonal to each other at roughly 45 degrees to the craft axis in the horizontal plane (at neutral control); the inner pivot being backward facing and the outer pivot forward facing (F1.7).
  • the craft As the craft has no keel and a minimum beam, it will be subject to instability at relatively small list angles when the addition of the user raises it's centre of gravity above it's centre of buoyancy. While balance by weight shifting may be sufficient in calm conditions, waves may frustrate the potential instability.
  • the winglets act as sponsons and help retain balance in difficult conditions.
  • the hydrodynamics stabilise the platform such that the sponsons can be raised clear of the water (also as the craft lifts) to minimise drag especially when moving into planning conditions.
  • the winglets also act as control or lift surfaces to sharpen turns and generally increase agility. If the wing is lowered (as on the outer facing side of a fast turn) on it's inner tilt axis, the fin generates lift to provide a positive heel force and a side acting component to enhance steerage. If the wing is raised (as on the inner facing side of a turn) on it's outer tilt axis the tip of the sponson acts as a rudder in the water but this time with minimum lift. They also act in parallel to increase or decrease rear lift like hydrofoils, thereby helping the craft onto the plane or in the extreme acting like sea brakes.
  • the sponsons act like hydroplanes and can introduce a left / right independent rear up or down force. This enhances agility and can help the craft stay submerged at modest speeds.
  • the fin and thrust vectoring system is the fin and thrust vectoring system
  • Extending at an upward angle from either side of the nose are two small hydroplanes (Fl.l 2) designed to assist in diving and enhance submerged agility by providing lift / dive as well as rotational reaction forces. They work complimentary to and synchronous with the 2 axis displacement of the rear mounted thrust vectoring nozzle (Fl.l 8), such that they enhance each others control effect.
  • the fins angle down to make the front dive the thrust vectors down to make the back rise and vice versa, and when the fins generate a side acting vector the thrust vectors to the opposite side. Because the fins are displaced from the craft's axis they also generate a useful axial torque tending to bank the craft into any turn - particularly when submerged.
  • a mechanically mixed system uses push / pull rods to connect the control pad to the fins and nozzle.
  • Many other arrangements are possible including cable or hydraulic linkage.
  • the foot pad (F1.13) has a central 2 axis pivot point (F1.14), with two control rod coupling points (Fl .l 5) displaced such that they are roughly twice as far apart as their common parallel offset from the pivot point; thereby ensuring a similar control sensitivity to forward / back tilting as left / right tilting.
  • the pivot support shaft (Fl.l 6) can be lengthened telescopically on the craft to an appropriate position for the height of the user, and the control rods (Fl.l 7) lengthened or shortened to reflect this.
  • the control rods have ball and socket or 'rose joint' ends and link the pad coupling points to control horns (Fl.l 9) on a special common axis bar (F1.20). Tilting the pad alters the effective lengths of the rods thereby rotating the control horns.
  • the mechanical mixing acts such that forward / back tilting causes common axis rotation and dive / climb reaction forces, while left / right tilting causes opposite axis rotation and right / left turn forces. To make the system as intuitive as possible, tilting by pressing with your left leg should cause a turn to the right and vice versa.
  • both the horns and coupling points need to be below their respective axes or the left horn has to control the right fin and vice versa. This is more desirable because it enables the fin to act from as low in the craft as possible (with the horn acting upwards). In any case the thrust vector control rods also require a left / right crossover.
  • the common axis bar is a tube within a tube such that the inner tube connects to the fin pivot with a universal joint on one side, and the outer to a U.J. on the other side.
  • the control horn for the fin connected to the outer tube can then be directly attached to it, near it's outer end, while the control rod for the inner tube acts through a radial slot in the outer tube near it's inner end.
  • the control hom should have the same leverage length as the parallel displacement of the control rod / pad coupling points from the pivot, the distance between the control horns should be roughly the same as the distance between the two pad coupling points and the neutral angles of the control horns should be roughly the same as the neutral angle of the foot pad.
  • the common axis bar is supported at either end with a 'pillow block' that integrates the push pull drive for the thrust vectoring nozzle.
  • a spur gear effectively attaches to each control horn and an idler spur gear acts against it.
  • the idler gear traps and in turn acts against an axially displaceable rack, such that moving the control horn outwards pushes the rack inwards.
  • the end of the rack is attached to the end of the nozzle control rod with a further connecting rod permitting some angular displacement. This is to minimise any bend in the control rod and allow it to approach and act from it's natural angle.
  • the two nozzle control rods connect to the nozzle rim alternately left and right, 45 degrees from the vertical enabling the craft hull to readily integrate the mechanism. If the connection points were on the underside of the nozzle, idler gear direction reversal would not be necessary, but the nozzle push rod mechanism would be less conveniently located in the thin lower part of the thruster ducting.
  • Fig 2 is a an assembled view of the system but without it's rear annular socket and Fig 3 which shows the nozzle and push rod detail with the upper section in the plane of the push rod and the lower section in the plane of the constraint pin.
  • the craft uses a brushless DC motor (F3.1) for it's reliability, efficiency and in particular ease of cooling the external stator through water contacting the motor housing.
  • a basic servo amplifier is used to control the motor; in this embodiment in current mode such that the throttle acts like a car's to vary the power output (rather than the rpm).
  • the throttle is hand operated and located on the winglet handle bars.
  • the maximum current is kept at a manageable level by using quite a high bus voltage - in this case 120v.
  • the motor can maintain a continuous 4 kW output at 3,000 rpm, and with higher short term peaks.
  • Power is provided by two removable 60v, 7Ah NiCad battery packs, each weighing about 12 kg. Together they will enable full power for about 12.5 minutes. A further 4.3 Ah is provided by a removable reserve. In practise full power is only used in short bursts, with an average power consumption of less than 1 kW; giving a total running time of about 80 mins (reserve included).
  • the battery packs are removed for charging and can be immediately replaced with fully charged alternates. Because DC motors are small for their power output, the prop can be connected directly to the motor shaft resulting in a simple in line thruster pod which can be hermetically sealed and hence run fully submerged.
  • the propeller / thrust vectoring system is an original hybrid designed to offer the safety of a jet drive and efficiency of a propeller. It is fully integrated and recessed into the hull form enabling the craft to be safely 'beached'. Water flows readily into the prop cavity; thereby requiring little suction to prime the cavity after immersion. It also means that the prop can generate reverse thrust without near 180 degree flow vectoring (unlike a jet drive).
  • the prop as shown in Fig 4 is relatively large to efficiently provide a good thrust at low speeds, particularly beneficial for the higher drag submerged use. It extends from the motor pod in a slow progression of diameter and pitch, then curves round such that it's surface of revolution becomes spherical. This allows it to run within a conforming spherical thrust vectoring duct (F3.2) which in turn is retained in an annular socket (F3.3 and 3.4); keeping the system very compact.
  • F3.2 conforming spherical thrust vectoring duct
  • annular socket F3.3 and 3.4
  • the prop has an extending pitch (in this embodiment of about 60%) and a soft leading edge which together reduces the leading edge 'shock' and hence the risk of cavitation; especially on initial craft acceleration. It achieves this without compromising the high maximum exhaust velocity needed for fast running. With lower point stresses this style of prop may lend itself to moulding in engineering grade plastics.
  • the spherical duct extends into the thrust nozzle (F3.2 and F2.1) and can rotate about 2 axes within the annular socket.
  • the third axis (about the plane of the socket) is constrained by two horizontally opposed inward facing pivot / slide pins (F3.5 and F2.2) retained in the socket and running in a longitudinal radial groove (F2.3) in the outside of the duct.
  • the annular socket is comprised of two rings (F3.3 and 3.4) with internal truncated hemispherical surfaces which trap the spherical duct (and constraint pins (F3.5) between them.
  • the inner ring is firmly retained against the craft with the outer ring releasable from the inner; permitting the duct to be extracted.
  • the duct has two 90 degree displaced outward facing coupling points (F3.6 and F2.4) which connect to the control rods via two axis yolks as shown in Fig 5 (permitting the angular displacement caused by the ducts two
  • the duct coupling points are symmetrically arranged about the constraint pins and at 45 degrees from the vertical. As the control rods extend or retract they turn the duct within the annular socket about orthogonal tilt axes. In this embodiment common in / out action will tilt the nozzle up / down; opposed action will tilt the socket left / right. Any combination will mix into the combined 2 axis rotation.
  • the constraint need only have one engaging protrusion; where it has two their common pivot axis must intersect the focal point of the spherical parts. It can be outward facing (retained in the duct, groove in the socket) as well as inward facing as in this embodiment. In all cases: rotation in the plane of the socket is constrained, the two coupling points should be around 90 degrees radially displaced from each other and to achieve control symmetry they should in turn be symmetrical about the constraint(s).
  • the duct nozzle features an array of inward bearing stator blades (F3.7 and F2.5). They serve both to unwind the props exhaust vortex thereby reducing the crafts axial torque reaction and to enhance the effect of the nozzle in vectoring the flow. As they bear inwards with a backwards rake they are unlikely to foul as there is no axial shaft around which things can tangle.
  • the breathing system :
  • the breathing system is simple and passive, utilising air reserved in the cushions (and / or other bladders) as a third lung.
  • the energy that powers the system comes directly from the work done by the craft in getting submerged. If such a system holds around 30 litres of air it will serve the user with a few minutes of careful use; more than adequate for his duck dive needs.
  • the cushions (F1.5) can be either a complete bag with an internal open cell foam core or can utilise the adjacent upper craft shell as the lower surface, with a flexible upper skin only.
  • This design variation has the advantage of effectively sealing the cushion to the craft such that it is not able to float away from the craft when submerged. To effect this, an air tight seal has to be made between the flexible skin and the craft. As the seal can be releasable, it can be occasionally removed to clean the foam core.
  • the foam core has a coefficient of restitution sufficient to lift the user a little and fill out the spaces around him when the craft is surfaced.
  • the single opening acts as a damper to enhance the apparent cushion hardness when subjected to shock loads. Such air has to be evacuated through the snorkel system.
  • the snorkel is of a style which closes the air channel automatically when submerged and opens again on surfacing, even if subjected to a low back pressure. It connects both to the 'lung' and breathing tube.
  • the mouthpiece of the breathing tube incorporates a one way valve so as to exhaust stale air out of the system.
  • the user can breath through the snorkel at the same time as the lung is re-inflating.
  • the snorkel shuts off and the user begins to breath the air from the lung.
  • ambient pressure differential between the slightly lower lung and the user becomes insufficient to further collapse the foam lung core, requiring suction assist from the user. This serves as a useful intuitive indicator of the amount of remaining air, leaving time to reach the surface.
  • lung pressure compared to ambient pressure can be processed to enable a digital air volume indication.
  • the safety systems are The safety systems:
  • the craft is capable of deep dives and fast climbs which would be a serious hazard to the user. However because of it's intrinsic buoyancy it requires a high power output to stay submerged; any loss of power would result in immediate surfacing.
  • the craft is therefore fitted with a depth limiter that cuts off the power above a safe pressure. This will be set to less than 2 Bar leaving a maximum dive depth of less than 10m.
  • a potentially more sensitive system would be processor controlled and relate dive duration to depth. Because nitrogen narcosis (the bends) requires many breaths to super saturate the bodies fluids, fast deep dives can be less hazardous than prolonged shallow ones (in both cases with quick assent).
  • the preferred breathing system requires increasing suction as reserves deplete and is therefore safe and intuitive. In any event because of depth limits worst case surfacing will still only take a few seconds.
  • Power reserves are shown by a bar graph comprised of LED's located along the trailing edge of the foot well cowling, along with a main or reserve indicator. Present drain rate (or time remaining at present rate) could optionally also be displayed. Other possible locations for instrumentation include in the users peripheral vision around the rim of the headrest / helmet.
  • the battery packs connect with watertight couplings and are separately enabled when their integrity has been confirmed by electronically checking for power leakage. Any subsequent leakage automatically switches them back off.
  • the cell packs include one way pressure relief valves which permit the venting of gases (particularly during charging).
  • the craft could have a range of 30 km, so the inclusion of a compartment within the body shell which can house safety equipment (flares, radio, compass etc.) is helpful.
  • a personal water craft for use with a person lying lengthwise of the craft to plane on or submerge below the surface of a mass of water at will, the craft comprising a hull for receiving a person thereon, the hull including a low curvature planning underside, a plurality of independent control means, each operable by the legs or arms of the said person, respectively, for controlling the direction and use of the craft, the pwer means for driving the craft on or through the water.
  • a marine propulsion system where thrust vectoring occurs when a substantially spherical duct with exhaust nozzle, otherwise retained in an annular socket, tracks with two degrees of freedom around a propeller, the propeller having a conforming spherical surface of revolution to maintain a small clearance to the duct and the constrained third axis being normal to the plane of the socket. 4.
  • a system as in 3. where two control coupling points for push / pull action or 3 or more control coupling points for pull / release action are located on the outer side of the duct, each connected through a two axis linkage to the control effect mechanism.
  • control effect mechanism is a push / pull rod linking the thrust vectoring with forward controls.
  • a marine propeller which has a large starting core diameter from which the blades extend progressively in diameter moving along the axis, as also the core diameter reduces. Similarly the blade pitch lengthens by a minimum of 50% as the diameter increases. The propellers length is sufficient to accommodate at least 270 degrees of blade spiral. The trailing edge of the blades undercut the tips and blend back into the reducing hub.
  • An underwater breathing system where an air tight cushion or bladder can be used as a reserve of air, said reserve having at least one expandable side and containing an elastomeric open cell foam core able to expand it against a small load; the internal volume being connected both to a fresh air source which automatically closes on water immersion and a one way flow means of air delivery to the user.
  • 20. A system as in 1 where the bladder is expanded by air pressure, mechanical or other elastomeric means.
  • APPENDIX 3 (Pages 57 - 71)
  • ROV Remote Operated Vehicle
  • ducted propeller units acting in various directions to permit multi axis thrust.
  • This invention proposes to replace propeller based thrusters with an arrangement of powered fins. Three different concepts are described.
  • the fins describe a conical (or fructoconical) surface as they orbit around a central drive axis. Thrust is generated by turning the fins on their own axis such that they act as blades with a variable pitch angle; and timed to focus the thrust in a particular vector. Each fin can thereby generate variable thrust in two axes with a sinusoidal swim action.
  • Various arrangements and drive methods are proposed. Four of such fin units arranged in a cross can provide synchronous six degrees of motion with balanced thrust reaction forces. The minimum arrangement for 6 axis control is 3 fins arranged as a "Y" in a common plane.
  • the fins are permitted to oscillate more freely around a pivot point with separate power of each of the two tilt axes and fin rotation.
  • a particular solution to fin propulsion is proposed which minimises the cyclical accelerations as the fins oscillate about their own axes.
  • Propulsion with fins can be up to around 80% efficient, compared to 50% for a good propeller thruster.
  • An oscillating fin can have an elastomeric joint cover over it's pivot point rather than needing a rotating seal; as such it is taking a lesson from nature where there isn't a single example of a continuously rotating shaft.
  • a minimum of 50% and a maximum of 100% of available thrust can be applied to any vector or rotation.
  • a long fin can move a large water mass slowly, providing good lift leverage; it does so without compromising it's ability to propel the craft quickly by adjusting fin pitch control. Fins resting in the move plane cause minimal drag. A non rotating fin cannot foul. Turbulence is minimised and acoustic patterns can be avoided. Fins have less inertia and can change their motion and hence thrust vector very quickly; this makes them very responsive and enables the tight positional control needed in closed loop robotic applications. Description:
  • Fig 1 shows the functional schematic of the Voight Schneider drive. As the blades rotate (shown as a progression of plan views) they are caused to tilt first one way and then the other. Overall the blade rotates at the same rate as the boss.
  • the fin describes a conical surface by moving it's tip in a continuous largely circular pattern, achieving thrust vector control by the timing of the fin's rotation about it's own axis as shown in Fig 2. Note that the fin now oscillates about a fixed reference rather than rotating with the boss.
  • a single motor acts through a reduction gearbox (F5.1) and bevel gears (F5.2) to cause the rotation of four orthogonal shafts in a common plane, with contra-rotating opposites.
  • F5.1 reduction gearbox
  • F5.2 bevel gears
  • Each drive shaft (F5.3) holds the fin axis (F5.4) at an angular offset, in this case 22.5 degrees.
  • the fin can freely rotate about it's axis, being retained in suitable bearings.
  • the rotating drive shaft causes the fin to describe a conical surface.
  • a long lead multi start non-recirculating ballscrew (F5.5) is used such that varying the axial displacement of the nut part causes the fin to rotate about it's axis.
  • the nut part (F5.6) is prevented from rotating by a bar running in a slot through it's body (F5.7). The slot is long enough to permit both tilt and axial displacement.
  • the bar retains it's reference angle by virtue of a timing belt connecting it to a principally non rotating reference tube acting around the main drive shaft (F5.8).
  • the rotation of the nut is constrained by the timing belt causing motion like a planet orbiting a sun where each day is equal to each year.
  • the fin will not rotate about it's own axis as it describes the conical surface; the fin plane angle defining the thrust angle.
  • the plane can be rotated by rotating the reference tube which acts through the timing belt to cause an offset about the nut (and hence fin) axis.
  • Constraining the fin can be achieved in two other ways. Instead of using a timing belt scheme, gears can be employed. In this embodiment idler gears act between the non rotating gear on the reference tube and the gear circumscribing the constraint bar such as to reverse its direction of rotation. Also rotation constraint can be achieved by including a pivot element and keyway between a ball on the fin shaft and a radially adjustable annular socket at the fins pivot point (or radially controlled gimbal). The radial control of the constraint reference becomes part of the thrust angle control.
  • the bar constraining the nut can be replaced by other means able to permit two axis tilt and axial displacement but constrain rotation, such as a gimbal (or constrained ball and socket) keyed to move in the nut axis but not around it.
  • a gimbal or constrained ball and socket
  • the end of the nut features a ball which is retained in a cylindrical pocket in a swash plate system (F5.9).
  • the pocket permits ball rotation about the nut axis, rotation in the plane described by the drive shaft and fin axis and some displacement along the pocket axis, but crucially not along the nut axis.
  • the swash plate system consists of a means to displace a radially offset forcing element (F5.10) axially along the drive shaft. This forcing element is linked to a pivot acting about the reference tube (F5.11) such that displacing it causes the pivot to tilt. A bearing then acts in the tilt plane, in turn connected to the swash plate pocket (F5.9) such that it can rotate freely about the drive shaft but at the prescribed tilt angle.
  • the drive shaft causes the ball at the end of the nut to describe a circular path.
  • this path becomes parabolic (as a section through a cone), forcing the nut to be displaced along the fin axis as it rides from peak to trough.
  • This displacement of nut against screw shaft then forces the rotation of the fin about it's axis such that in each revolution of the drive shaft, the fin rotates first one way and then the other.
  • Increasing the swash tilt extends the displacement and hence fin rotation. This has the effect of varying the fin's pitch oscillation angle and hence thrust in the water.
  • the reference tube can be rotated by a rack acting against a spur gear around the tube (F5.13).
  • the swash forcing element being connected to a pivot on the reference tube similarly rotates, however a further rack and pinion (F5.12) causing the axial displacement of the forcing element can be rotationally constrained by isolating it from the reference tube with a radial bearing. Two servos can then be readily connected to effect both the rotation of the reference tube (defining the thrust vector) and tilting of the swash plate (defining the thrust extent).
  • An elastomeric "boot' connects the fin to the crafts body shell (F5.14), such that it provides a hermetic pressure proof seal.
  • the boot must permit about 22.5 degrees of tilt and +- 135 degrees of rotation (+-
  • the boot bearing part of the fin shaft can have an enveloping linear array of short tubular spacers or washers (F5.15). These can rotate with the boot, distributing the shear forces along the available length. A further layer of very soft elastomer can then also be employed between the washers and main boot skin, improving the averaging of shear forces.
  • a low cost variant could be readily produced from injection moulded thermoplastic parts with a suitably low coefficient of friction.
  • Small 'model aircraft' type servos can be employed to effect the thrust vector control.
  • the single motor has no seal issues and can be a low cost DC unit.
  • the fin can pivot in a plane, rather than describing a conical surface.
  • a direct means is then employed to effect the synchronised oscillatory rotation about the fin axis.
  • a servo can then also rotate the pivot plane to alter the thrust angle and again adjusting fin pitch oscillation varies the thrust.
  • each fin unit need not be mechanically coupled, permitting their placement where most convenient for the craft. Rather than use multiple geared electric motors, a particularly suitable drive system is hydraulic. This lends itself to distributed high power densities operating at relatively low speeds. Also a hydraulic system will work fine at any ambient pressure, employing as it does pressure difference rather than net pressure to transmit it's power. This means that it is possible to design each fin unit as a hermetically sealed but not pressure proofed part, simplifying it's design and improving the performance of the boot (by fluid filling it).
  • the motor that drives the pump could also be fluid filled to balance shaft seal pressure, or a magnetic 'through bulkhead' coupling could be employed - thereby leaving the motor (and control electronics) in a dry space.
  • Each fin needs three motors.
  • the main 'power' motor causes the basic planar oscillation of the fin about a pivot axis.
  • Another motor rotates the pivot axis thereby effecting thrust angle control.
  • the third motor rotates the fin about it's axis to create the sinusoidal swim action.
  • Each axis needs closed loop positional control or a means to effect synchronisation between the fins to balance the reaction forces.
  • a craft which utilises such a drive system is shown in Fig 6.
  • thrust vectoring occurs by establishing the best possible thrust plane (like a joystick being able to oscillate anywhere within the confines of it's limiting bumper).
  • the thrust plane can then not only rotate (as in the previous embodiment) but can also be set at a tilt offset.
  • a further advantage occurs as the thrust angle can in effect continuously rotate because two tilt axes do not introduce any twist into the protective cover.
  • the thrust angle is confined within twist limits resulting in a possible situation where the angle needs to be 'unwound'
  • FIG. 7 Other arrangements are possible where multiple fins notionally share a common axis point.
  • two fins are connected to a rotatable boss, in such a way that the fins can also be independently rotated about their own axis.
  • Such units are able to generate 3 axis thrust vectors, x,y and torque in the boss axis; acting functionally like two independent fins. They are powered by a common high power motor rotating the boss and have smaller motors or other limited angle actuators controlling each fin axis.
  • a further style of fin propulsion has a different swim drive concept.
  • the fins act more directly as paddles as shown in concept in Fig 3 and in use on a craft in Fig 8.
  • the charm of this variant is the ability to mechanically drive the fin axis from the boss rotation at constant angular velocity; thereby permitting the system to be run at high speeds (rather than where the fins have to accelerate back and forwards as they oscillate).
  • the arrangement lends itself to multiple blades to balance reaction forces; apart from torque which is balanced by multiple units.
  • the secret of the ability to generate thrust with constant rotation in the blade axis is that the blades rotate at half the speed of the boss - in the same direction. If they otherwise rotate with the boss, then relative to the boss they are rotated backwards at half the boss speed.
  • Three or some greater odd number is appropriate as a blade number, serving to reduce thrust and torque ripple.
  • Changing the thrust vector occurs as the reference to the blade rotation is advanced or retarded. This is accomplished by enabling a servo control to rotate the otherwise static reference gear around which the gears effecting the blade axes orbit. Synchronisity at 1 : 2 rotation speeds is then re-established, but now with the thrust at a new vector. The change only effects rotation about the blade axes (not a change in speed of the boss) and can thus be accomplished quite quickly. Because this embodiment is 2 axis only, there is no intrinsic need to arrange the blades such that they describe a cone. They can be arranged with parallel axes, separated by a larger boss diameter.
  • FIG. 9 A suitable method is shown in Fig 9. It features a hollow drive shaft
  • a shaft (F9.3) connects the vectoring servo through the hollow drive shaft to a gear at the centre of an upper gear set (F9.4).
  • the blades also have individual gears (F9.6) each driven from the intermediate gears.
  • the use of intermediate gears has the effect of reversing the direction of rotation.
  • the reference gear must have half the tooth number of the blade gear, such that the rotation speed of the blade gear becomes half that of the boss.
  • the different swim methods need not be mutually exclusive.
  • a 2 fin module with independent fin axis control could be run in the 1 : 2 synchronous mode if the axis servos are able to rotate continuously as a motor.
  • a system with independent fin control can cause overall water ingestion by reversing part of the tilt direction. Where the fins are otherwise describing a cone, this results in exhaust thrusting out of the open cone end principally along it's axis. This effect can be employed to increase thrust in that vector.
  • any of the embodiments using two or more fins or blades rotating from a common boss can benefit from a hoop which connects the fin tips such that the fins or blades can still rotate about their own axes (as shown in Fig 7 and
  • Fig 8 This has the benefit of stabilising the fins against bending moments, and also acts as a guard to mitigate the effect of a fin striking an obstruction.
  • Control System A solution to the requirement of 6 axis control from a number of fins will be described with particular reference to a craft with 4 opposing fins rotating at a common speed.
  • Fin 1 and Fin 3 are capable of generating thrust in the xz plane (y normal) and Fin
  • the units of C and R represent the maximum manoeuvring speed and are determined experimentally. The guidance system knows it has to live within these limits.
  • the thrust angle and pitch rates for each fin can be calculated from each fins required thrust vector.
  • the required pitch rate to achieve a given thrust can again be determined experimentally and implemented as a look up table. If the craft has a high speed through the water relative to it's fin rate, the pitch can be optimised to the true incidence vector of the oncoming water
  • flap rate (reducing pitch as speed increases). This is like a variable pitch propeller where pitch is lengthened for high water speeds; the object being to maintain an optimum work rate without increasing the rpm - or in this case flap rate. All the above thrust vector control can occur at a constant flap rate; however controlling the flap rate can avoid needless 'running on the spot' power consumption. If the guidance system has little requirement for craft movement in the current time period, then the flap rate can be minimised. Equally if the craft has to work hard (through load, drag or acceleration) the flap rate can be maximised for the available motor power. Control of flap rate can also be employed to reduce / increase the crafts command responsiveness; if for example conditions dictate a stealthy approach, or alternately high speed manoeuvring or variable load compensation is required.
  • This control system works best in the context of a computer controlled guidance system providing craft movement and positional feedback, such that the control loop can be closed.
  • the user need merely establish the required final position or movement vector and the craft will then manage it's own implementation by setting the appropriate flap rate and individual fin thrust vectors. This is particularly useful as drag from the umbilical or prevailing current conditions can then be automatically compensated for.
  • all fins must flap at the same rate and to the same angular extent. This can result in some reaction force imbalance where for example a fin is not required to produce a thrust vector; because that fin will generate a higher reaction force that a fin pitching through an angle.
  • the arrangement differs in vector summation when three, 2 axis modules are employed (like the constant angular blade rotation design).
  • Torque is not balanced with an equal and opposite symmetry as in a 4 fin system, but by adjusting the overall direction thrust of each module to create a torque about their common axis point.

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Abstract

There is disclosed a multi axis marine propulsion system in which one or more propulsion fins are mounted on a boss (7) rotatable by a drive shaft (1). The fins are each rotatable about a rotational axis which is displaced laterally from the axis of the drive shaft. Coupling (4) between the drive shaft and fins, preferably by gearing or drive belt, rotates the fins at substantially half the rotational speed of the boss.

Description

Multi Axis Marine Propulsion Svstem
Field of the Invention:
This invention concerns an improved marine propulsion system, which is more readily direction vectored and is more efficient than conventional alternatives. While the invention will be described hereinafter with reference to submersible craft, those possessed of the appropriate skills and imagination will readily appreciate that the invention is capable of wider applications.
This invention also concerns a marine propulsion system suited to high speed craft which benefit from being able to vector their thrust about two tilt axes. A personal hybrid submersible craft is proposed which ideally utilizes such a drive system.
Background of the Invention: There is a growing need for submersible craft to be controlled synchronously over multiple degrees of freedom. An example is a class of craft known as a ROV (Remotely Operated Vehicle); particularly employed as a camera and manipulator platform, but also performing many specialist mining and exploration tasks. These craft use a number of ducted propeller units acting in various fixed directions to permit multi axis thrust.
This approach has several limitations. True 6 axis control from fixed thrusters requires a minimum of 6 thrust vectors in a generally inconvenient arrangement. Having to combine various fixed thrust vectors is inefficient compared with combining fewer multi-axis units. Thrusters not aligned such that they can assist in the current craft movement only cause drag. Also rotational inertia in the prop and motor limit the rate at which direction can be reversed; compromising 'closed loop' positional control.
Recently there has been a resurgence of interest in a propulsion system known as a Voight Schneider drive. This was first developed in Germany in the 1930's for use on tug boats and the like. It is able to generate thrust along a two axis vector; but is difficult to seal, has limited efficiency and is prone to fouling.
Many novel personal craft are now available for pleasure and sometimes utility above and below the water. Examples are craft powered by gravity (surf boards), wind (windsailers), internal combustion engines (jet bikes), humans
(canoes) and electricity (scuba tugs). Each has been optimized for it's own domain.
These craft have grown in popularity with the increase in leisure, access and disposable income - because they are fun. They are intimate and empowering through a sense of synergy with the water. They exhilarate in a safe world.
But in many cases their physical demands take them out of reach of the casual user. Both in terms of general fitness and skill acquisition. Also in the case of jet bikes their antisocial qualities limit their use, and generally they need the right weather to have fun.
A very welcome craft concept would be safe and 'green', easy to use well in any water condition, intimate and exhilarating in a strange new world. Such a craft is proposed by this invention.
To power such a craft a new type of marine propulsion system is proposed which provides for two axis tilt vectoring of the thrust in a package which is more efficient than a water jet.
Objects and Summary of the Invention:
This invention proposes to replace propeller based thrusters with an arrangement of rotating or oscillating fins. Three different concepts are described.
In the first concept, the fins act like paddles in an underwater paddle wheel as shown in Fig 3. The fins are attached to a boss rotating in the thrust plane such their axes are substantially parallel to each other. As the boss rotates, the fins also rotate about their own axes in the same direction as the boss but at half its rotation rate. This ensures that when a particular fin is moving in the desired thrust direction it is presenting it's full face area to the water, optimizing the thrust; whereas when the boss has rotated 180 degrees with the fin now moving 'upstream', the fin has only rotated 90 degrees and is now edge on, minimizing the drag. In the transition stages the changing fin incidence angle to the flow direction ensures that it continues to provide a cooperating thrust vector over most of its cycle, ingesting water at the top and expelling it at the bottom.
The thrust direction is therefore substantially normal to the fin which is at the point in its cycle when it's surface lies at a radial orientation to the boss
(or parallel to the fin when it lies tangential to the boss). This timing position is governed by the rotational offset between the boss and fin axes. In this invention this can be readily varied by the simple expedient of rotating a reference shaft. This is accomplished with minimum inertia or drag, as the fins are thereby only increasing or decreasing their own rotation rate about their own axes as they advance or retard to the new radial offset or thrust vector. If the reference shaft is continuously rotated so the thrust vector will continuously rotate; and in a 1 : 1 relationship.
The charm of this concept is the ability to mechanically drive the fin axes from the boss rotation at constant angular velocity; thereby permitting the system to be run at high speeds (rather than where the fins have to accelerate back and forwards as they oscillate).
The arrangement benefits from employing three or some greater odd number of blades to balance reaction forces and to reduce thrust and torque ripple.
As each such drive unit can generate a two axis co-planar thrust vector, in order to achieve full 6 axis control of a submersible craft a minimum of three units need to be deployed. The most symmetrical thrust vectoring is achieved when the units are arranged such that their boss axes are radial about a common origin every 120 degrees. In the second concept individual fins describe a conical (or fructoconical) surface as they orbit around a central drive axis. Thrust is generated by also rotating the fins about their own axis such that they act as blades with a variable pitch angle; and timed to focus the thrust in a particular vector. Each fin can thereby generate variable thrust in two axes with a sinusoidal swim action. Various arrangements and drive methods are proposed.
A possible benefit of this method is that the fin does not continuously rotate about it's own axis; it merely oscillates, while also orbiting it's pivot point. The down side is that this requires continuously varying acceleration
(compared to the first concept), but it does enable an elastomeric 'gaiter' to be employed around the fin's pivot point rather than a rotating seal. Such a gaiter is taking a lesson from nature - where there isn't a single example of a continuously rotating shaft seal. It enables a high integrity hermetic seal able to operate at any depth when internally pressure balanced.
Four of such fin units arranged in a cross can provide synchronous six degrees of motion. The minimum arrangement for 6 axis control is 3 fins arranged as a "Y" in a common plane, but reaction forces cannot then be balanced resulting in some movement ripple. In the third the fins are permitted to oscillate more freely around a pivot point with separate drive power to each of the two tilt axes and fin rotation. The fin can then be closed loop processor controlled to provide a sinusoidal swim action in any vector.
Propulsion with fins can be up to around 80% efficient, compared to 50%) for a good propeller thruster. A minimum of 50% and a maximum of
100% of available thrust can be applied to any vector or rotation in a six axis drive configuration. A long fin can move a large water mass slowly, providing good lift leverage; it does so without compromising it's ability to propel the craft quickly by adjusting fin pitch control. Fins resting in the move plane cause minimal drag. A non-rotating fin cannot foul. Turbulence and acoustic footprints are minimized. Fins have less inertia and can change their motion and hence thrust vector very quickly; this makes them very responsive and enables the tight positional control needed in closed loop robotic applications. In the Voight Schneider drive, as the blades rotate they are caused to tilt first one way and then the other creating thrust by virtue of their angle of incidence; first sucking water in and then expelling it. Overall the blade rotates at the same rate as the boss.
The disadvantage of this system is the mechanical complexity and robustness necessary to support the oscillation accelerations and the significant loss of efficiency which occurs when operating in a moving water steam (due to limited pitch angles and high drag on the return leg).
The proposed craft will operate is in the near region above and below the water. It will plane on the surface, it will shallow dive, it will porpoise, it will surf. With an eye line not far above the water, thrills will come at low speed and with low risk.
In overview, the craft is like an electric powered surfboard that envelopes you, with arms and legs controlling fins and thrust direction. It has minimal displacement and rests partially submerged; breaking through the waves rather than climbing over them. It has a total of 7 control axes (compared with the 2 of a regular boat); as such it offers many control combinations which permit the acquisition of skill and agility but without demanding it. The users limbs act intuitively as they become control surfaces. The craft is really more like a 'dolphin man' superhero costume than a boat - you wear it more than ride on it. The craft features a novel 2 axis vectored propulsion unit that lets it steer up and down as well as the usual left and right. It is safe (shrouded and foul proof), clean and quiet (battery electric), potent (efficient water cooled brushless DC) and flexible (using hybrid propeller / impeller). The drive has been fully integrated into the hydrodynamics of the hull. Reversible power output is adjusted with a hand throttle. The craft has minimum displacement such that when resting, the users legs and lower body lie mostly submerged. It is designed to permit planing above modest speeds but is axially drag balanced such that it retains it's stability under the water. It achieves this partly by shedding the bow wave or the impact of oncoming water to either side of the craft rather than under (and over).
The user lies feet first with a low back and head rest. The hull surrounds him; it is self draining, and with the cushion leaves little space for puddled water. A transparent cowl can be pulled forward from the headrest (over and around the head) when dive or splash protection is needed. The users arms rest in buoyant articulated winglets that serve to provide stationary balance and extra control agility. The users feet operate a 2 axis tilt pad which effects synchronously both the thrust vector and the attitude of small forward control fins. The winglets are engineered with 2 pivot axes emulating the shoulder.
The axis arrangement permits up, down and rotational movements, but not back and forward. This minimized the arm load necessary to maintain winglet stability. The use of the winglets is intuitive, being like turning your arms into fins. You can use them as stabilizers, acting both as floats and paddles which can come clear of the water at speed. You can lean into them, turning them into offset rudders to assist in tight turns or hydroplanes to add lift. They also enhance attitude control when submerged.
The tilt pad can work in several ways but in the preferred embodiment it acts about a central 2 axis pivot point both as a 'rudder bar' (left / right) for turns and 'elevators' (back / forward) for dive / climb. In sync with this, the thrust is vectored in the mirror image of the tilt pad to augment and enhance the steerage control.
Preferably the user has access to a portable air reserve. In one embodiment this is a simple passive system operating at ambient pressure. It uses an inflatable bladder (that can double as a cushion) which is filled with an open cell foam acting as an expansion spring. Whenever the craft is on the surface, the cushion will re-inflate with fresh air. When submerged, the user can breath out of this supply. No regulator is necessary because the air will be at about lung pressure regardless of depth. A simple non return valve ensures exhausted air is expelled. The effort necessary to breath is proportional to the air reserve, so the user has an intuitive feel for how many useful breaths remain.
Brief Description of the Drawings: Fig. 1 shows a functional schematic of the Voight Schneider drive in plan view, with the blades shown as a progression of positions.
Fig. 2 shows the sinusoidal swim action created by fin movement as employed by the second concept drive system.
Fig. 3 shows the 'paddle wheel' fin motion employed by the first concept drive system.
Fig. 4 shows a hybrid motion possible where fin axis control is independent of boss rotation; in this case causing water to be ingested radially and expelled along the fin axis.
Fig. 5 shows a sectional and plan view of a two axis water turbine with attached in-line motor and direction vector control servo.
Fig. 6 shows a further embodiment of a two axis turbine with additional performance enhancing feature.
Fig.7 shows a further embodiment of a two axis turbine optimized to perform in a high ambient pressure environment. Fig. 8 shows how a two axis turbine can be implemented using belt rather than gear coupling.
Fig. 9 shows a sectional view of the mechanical arrangement employed to control the movement of a non-rotating fin set.
Fig. 10 shows an example craft featuring such a non-rotating fin set. Fig. 11 shows an example of a craft featuring two, 3 axis twin blade drive units.
Fig. 12 shows an example of a craft featuring three, two axis drive units.
Fig. 13 shows a schematic of the force vectors generated by a four orthogonal fin craft.
Fig. 14 shows a side and plan view of a proposed personal hybrid surface/submersible craft.
Fig. 15 shows the extending pitch propeller in a wire frame mesh graphical format. Fig. 16 shows two views of the extending pitch propeller in a wire frame graphical format.
Fig. 17 shows a wire frame view of the assembled motor, propeller, stator support ring and stator - shown with the duct oriented to effect the sideways vectoring of the thrust. Fig. 18 shows a wire frame view of the stator unit.
Fig. 19 shows a sectional view through the drive system as installed in the craft.
Fig. 20 shows the three elevations of the yolk used to attach the stator to the control rods.
Detailed Descriptions of the Embodiments:
An embodiment of the first drive concept is described with reference to Fig 5.
It features a hollow drive shaft (F5.1) running through the core of the motor (F5.8), directly or via reduction gearing rotating the blade mounting boss (F5.2). A shaft (F5.3) connects the vectoring servo (F5.7) through the hollow drive shaft to a gear at the center of an upper gear set (F5.4). Intermediate gears (F5.5) whose rotational axis is held by the mounting boss then orbit this reference gear as the boss is rotated - in turn being obliged to rotate about their own axis. The blades also have individual gears (F5.6) each driven from the intermediate gears. The use of intermediate gears has the effect of reversing the direction of rotation (rather than the blade gear acting directly against the reference gear).
The reference gear must have half as many teeth as the blade gear, such that as the boss rotates, the intermediate gears are forced to rotate and in turn rotate the blade gear, with the rotation speed of the blade gear then being half that of the boss.
When the servo (F5.7) rotates the reference gear, it can now be seen to have the effect of advancing or retarding the blade rotation, without otherwise effecting their orbit (the rotation of the boss).
For any given thrust vector, the blades are orientated such that successive blades lie at the same angle as a single blade would be if driven around to the successive positions as shown in Fig. 3. For example in a three blade embodiment, if a blade (F3.1) lies in a radial plane, after 120 degrees of boss rotation it has rotated 60 degrees, and again after a further 120 degrees of boss rotation it has rotated a further 60 degrees. These offsets and angles will be the starting positions for blades (F3.2) and (F3.3).
Instead of the motor being in line with the boss axis, it could be offset and drive the boss shaft via a side driven mechanical coupling (such as a gear or belt). This configuration permits the use of motors without a hollow core if the gear or pulley on the boss shaft has a hollow core.
A more refined embodiment can be seen in Fig. 6
While operationally similar to that described in Fig 5 it has a number of features designed to improve its performance.
Firstly a disc is shown (F6.1) which connects the blade tips freely at their rotational pivot axes. This is achieved by capturing a 'spinner' and hex socket fastener (F6.3) in the disc and then fixing it to the blade by accessing it with a hex key through a hole in the disc. The disc has the effect of protecting the blade tips during their orbit, and also to lock the three blade axes together to again make the whole assembly more durable. Instead of a disc, a ring could be employed.
The blades themselves (F6.7) benefit from being blended into rigid discs at either end (F6.4). These discs can be arranged such that they are countersunk into the surface of the boss (F6.5). This ensures that there is no opportunity for the ingress of 'stringy' matter, which might otherwise jam between the blade and boss. The blades may also advantageously be designed such that they present a larger surface area near their mounting axle where the leverages are more readily sustained. In order to avoid excess turbulence within the gear set (when otherwise flooded) helical gears rather than spur gears should be employed. In addition the boss would advantageously include internal pockets (F6.6) adjacent to where the gears mesh to assist the flow of fluid being ejected from the gear mesh. The embodiment described includes a mounting hub bearing cartridge
(F6.7). This facilitates the ready attachment of the drive unit to the side of a craft by a mounting flange (F6.8).
In this embodiment a water pump (used for motor cooling) is integrated between the hub and the underside of the boss (F6.9). Water is trapped by the turbine blades and flung out centrifugally as it rotates. The low pressure in the center causes more water to be sucked up the feed pipes (F6.10) to effect the forced water circulation.
Fig. 7 shows another embodiment optimized for deep sea submersibles. In this configuration the shaft seal diameters for both drive shaft (F7.1) and control servo (F7.2) can have minimum diameters and it permits the servo shaft to be offset from the drive shaft allowing the in line use of standard motors without a hollow core.
In this case the drive shaft (F7.3) runs up through the control shaft tube (F7.4) and attaches to the boss (F7.5) on its upper surface. A disc (F7.6) is employed to support both the control tube and the underside of the boss, against which it also maintains a seal (F7.7).
Under the support disc (F7.7) is a cavity in which a gear set or pulley can connect the control tube to the control shaft (F7.8). Under and around this runs the pressure proof housing (F7.9), also supporting the shafts and pressure seals (F7.1 & F7.2).
In operation the internal oil in the boss gear set and control gear cavity is trapped behind low pressure blade seals (F7.10) and low pressure boss seal (F7.7). The presumably high external pressure is kept away from the craft internals by the high pressure shaft seals (F7.1 & F7.2).
Where a motor is employed which can operate within an oil bath the pressure proof housing (F7.9) can be extended to include the motor (and potentially also the servo). This has the advantage of obviating the need for high pressure seals, although such motors with their power amplifiers tend to be of much higher cost.
The boss underside may advantageously be chamfered or otherwise blended at its periphery (F7.l l) so as to inhibit the ingress of particulate contamination by obliging it to be flung out centrifugally.
Another method employs belt rather than gear coupling as shown in Fig. 8.
This has the advantage of not requiring intermediate gears to reverse the rotation, as belt drives do this anyway. The same rule of requiring a control pulley of half the PCD of the blade pulleys applies.
The belt (F8.1) must be double sided. It runs around the blade pulleys (F8.2) and inwards to orbit the control pulley (F8.3).
A tensioning device can be imposed against the belt although in practice centrifugal force increases the belt tension as the boss rotational speed increases.
One objective in good belt design is to minimize the turbulent disturbance caused by the belt when running through a fluid bath. Rather than relying on an external tooth form to prevent belt slip, a thin alloy belt with punched index holes could be used. Conforming protrusions at the same pitch on the pulleys would then prevent belt slip.
The second drive concept uses blade oscillation rather than rotation as shown in
Fig. 2.
The preferred method is to employ a mechanical drive and control system equivalent to a helicopters 'collective'. Alternatively for more flexible control each movement axis can be separately powered. The first embodiment of this concept will be described with reference to
Fig. 9. It is a low cost solution, which does not require closed loop control as synchronization occurs by direct mechanical coupling of all four fins.
Each fin describes a conical surface by moving it's tip in a continuous largely circular pattern, achieving thrust vector control by the timing of the fin's rotation about it's own axis as shown in Fig 2. Note that the fin oscillates about a fixed reference rather than rotating with the boss enabling a fixed elastomeric seal to be used (F9.14) rather than a dynamic radial one.
The key element of the arrangement is a swashplate like system, which acts to effect the fin's rotation about its own axis. Two servo controls can then be employed both to rotate the swashplate tilt axis to change the thrust angle, and to change the tilt (which effects the degree of fin pitch oscillation) and vary the thrust. Reaction forces resulting from moving the fins are balanced by synchronizing the 4 fin actions into diagonally opposite contra-rotating pairs where the fin placement largely describes an X as shown in Fig. 9a. A single motor acts through a reduction gearbox (F9.1) and bevel gears
(F9.2) to cause the rotation of four orthogonal shafts in a common plane, with contra-rotating opposites.
Each drive shaft (F9.3) holds the fin axis (F9.4) at an angular offset, in this case 22.5 degrees. The fin can also rotate about it's own axis, being retained in suitable bearings (F9.19). The rotating drive shaft causes the fin to describe a conical surface.
A long lead multi start non-recirculating ballscrew (F9.5) is used such that varying the axial displacement of the nut part (F9.6) causes the fin to rotate about it's axis. The nut part rotation is constrained by a bar running in a slot through it's body (F9.7). The slot is long enough to permit both tilt and axial displacement. The bar retains it's reference angle by virtue of being supported within a pulley (F9.16), with a timing belt coupling it to a principally non rotating 'reference' pulley (F9.20) supported by a reference tube acting around the main drive shaft (F9.8). As the drive shaft rotates, the rotation of the nut is constrained by the timing belt causing motion like a planet orbiting a sun where each day is equal to each year. Without further action, the fin can not rotate about it's own axis as it describes the conical surface; this is subsequently caused by the (fin) axial displacement of the nut as a result of the swashplate system described below.
The fin plane angle defines any subsequent thrust angle. The plane can be rotated by rotating the reference tube which acts through the timing belt to cause a radial offset to the nut and hence fin axis.
The bar constraining the nut (F9.7) can be replaced by other means able to permit two axis tilt and axial displacement but constrain rotation, such as a gimbal (or constrained ball and socket) keyed to move in the nut axis but not around it.
Constraining the fin's axial rotation can be achieved in two other ways. Instead of using a timing belt scheme, gears can be employed. In this embodiment idler gears act between the non rotating gear on the reference tube and the gear circumscribing the constraint bar such as to reverse its direction of rotation. Also rotation constraint can be achieved by including a pivot element and keyway between a ball on the fin shaft and a radially adjustable annular socket at the fins pivot point (or a radially controlled gimbal). The radial control of the constraint reference becomes part of the thrust angle control.
The end of the nut features a ball which is retained in a cylindrical pocket in a swash plate system (F9.9). The pocket permits ball rotation about the nut axis, rotation in the plane described by the drive shaft and fin axis and some displacement along the pocket axis, but crucially not along the nut axis.
The pocket extends from a swash ring supported by a large diameter radial bearing. The inner race of the bearing retains a disc (F9.21) featuring a single axis pivot (F9.17) connected to the reference tube (F9.8) and a point on the rim displaced orthogonally from the pivot axis (F9.11). This is connected to a forcing element whose position axial to the reference tube establishes the swash tilt angle.
This forcing element (F9.10) can be displaced along the reference tube axis by use of a rack and pinion (F9.12) where the pinion drive shaft is driven by one of the control servos. The rack is attached to the forcing element via a radial bearing (F9.18), permitting rotation of the reference tube without effecting the position of the rack. As the servo changes the swash tilt angle, so the fin oscillation extent and hence thrust changes.
The reference tube is connected by pulley to the other control servo. As the reference tube is rotated, so the swash tilt axis is radially offset as is the reference position for the fin angle; thereby rotating the thrust vector.
Without tilting the swash plate system, the drive shaft causes the ball at the end of the nut to describe a circular path. When tilted, this path becomes parabolic (as a section through a cone), forcing the nut to be displaced along the fin axis as it rides from peak to trough. This displacement of nut against screw shaft then forces the rotation of the fin about it's axis such that in each revolution of the drive shaft, the fin rotates first one way and then the other.
An elastomeric "boot' connects the fin to the crafts body shell (F9.14), such that it provides a hermetic pressure proof seal. In this embodiment, the boot must permit about 22.5 degrees of tilt and +- 135 degrees of rotation (+- 90 degrees of thrust angle, +- 45 degrees of radial oscillation). To assist in the progressive take up of the boot twist, the boot bearing part of the fin shaft can have an enveloping linear array of short tubular spacers or washers (F9.15). These can rotate with the boot, distributing the shear forces along the available length. A further layer of very soft elastomer can then also be employed between the washers and main boot skin, improving the averaging of shear forces.
Whereas the above mechanism features radial ball bearings to mitigate friction, a low cost variant could be readily produced from injection moulded thermoplastic parts with a suitably low coefficient of friction. Small 'model aircraft' type servos can be employed to effect the thrust vector control. The single motor has no seal issues and can be a low cost DC unit.
In the second embodiment the Ωn can pivot in a plane, rather than describing a conical surface.
A direct means is then employed to effect the synchronized oscillatory rotation about the fin axis. A servo can also rotate the pivot plane to alter the thrust angle and again adjusting fin pitch oscillation varies the thrust.
The fins need not be mechanically coupled, permitting their placement where most convenient for the craft. Rather than use multiple geared electric motors, a particularly suitable drive system is hydraulic. This lends itself to distributed high power densities operating at relatively low speeds. Also a hydraulic system will work fine at any ambient pressure, employing as it does pressure difference rather than net pressure to transmit it's power. This means that it is possible to design each fin unit as a hermetically sealed but not pressure proofed part, simplifying it's design and improving the performance of the boot (by fluid filling it). The motor that drives the pump could also be fluid filled to balance shaft seal pressure, or a magnetic 'through bulkhead' coupling could be employed - thereby leaving the motor (and control electronics) in a dry space. In all hydraulic applications it may be convenient to assemble a central pilot valve set providing the synchronized proportional control and then locating the high flow rate valves at the motor / cylinder location. This approach also avoids any need for electrical connections at the fin assemblies. Instead of radial motors to effect the necessary rotations, axial hydraulic cylinders can be employed acting as a push rod against a crank. A good compromise can be utilizing one or more cylinders for powering the fin tilt
(whether one or two axis) and radial motors for fin pitch adjustment (and thrust angle control in a single axis tilt system). Each fin needs three motors. The main 'power' motor causes the basic planar oscillation of the fin about a pivot axis. Another motor rotates the pivot axis thereby effecting thrust angle control. The third motor rotates the fin about its axis to create the sinusoidal swim action. Each axis needs closed loop positional control or a means to effect synchronisation between the fins to balance the reaction forces.
Improved efficiency can be achieved if the fin oscillation was effected by a two tilt axes system, with a third radial axis for the fin pitch control.
In this embodiment thrust vectoring occurs by establishing the best possible thrust plane (like a joystick being able to oscillate anywhere within the confines of it's limiting bumper). The thrust plane can then not only rotate
(as in the previous embodiment) but can also be set at a tilt offset.
A further advantage occurs as the thrust angle can in effect continuously rotate because two tilt axes do not introduce any twist into the protective cover. In the previous embodiment the thrust angle is confined within twist limits resulting in a possible situation where the angle needs to be 'unwound'
180 degrees before further rotation can be achieved.
In all cases it is necessary to synchronize the fin action to balance the reaction forces. Where not directly mechanically or fluidically coupled, synchronization can occur by explicit positional encoding and suitable data processing. Relative fin thrust can then be controlled both by fin pitch oscillation rate and tilt extent.
Other arrangements are possible where multiple fins notionally share a common axis point. In one such case as shown in Fig. 11 two fins are connected to a rotatable boss, in such a way that the fins can also be independently rotated about their own axes. Such units are able to generate 3 axis thrust vectors, x,y and torque in the boss axis; acting functionally like two independent fins. They are powered by a common high power motor rotating the boss and have smaller motors or other limited angle actuators controlling each fin axis.
The different swim methods need not be mutually exclusive. For example a 2 fin module with independent fin axis control could be run in the 1 : 2 synchronous mode if the axis servos are able to rotate continuously as a motor. Also as shown in Fig 4, A system with independent fin control can cause overall water ingestion by reversing part of the tilt direction. Where the fins are otherwise describing a cone, this results in exhaust thrusting out of the open cone end principally along it's axis. This effect can be employed to increase thrust in that vector.
The Control System:
A solution to the requirement of 6 axis control from a number of fins will be described with particular reference to a craft with 4 opposing fins rotating at a common speed as proposed in the second drive concept. In order to smoothly vary the fin thrust vectors in response to a six axis movement command, a vector summation strategy needs to be employed. With reference to Fig 13 the fins can be considered as split into two pairs. Fin
1 and Fin 3 are capable of generating thrust in the xz plane (y normal) and Fin
2 and Fin 4 generate thrust in the yz plane (x normal). All 4 fins combine to generate thrust in the xy plane (z normal). Each fin is capable of creating a thrust vector of variable magnitude at any angle within it's plane.
Given a six axis thrust vector with a Cartesian component of C and a rotational component of R the thrust vectors of each of the four fins (F1...F4) can be calculated as follows:
Fix = 1/2 Cx + 1/2 Ra F3x = 1/2 Cx - 1/2 Ra
Fly = 0 F3y = 0
Flz = 1/4 Cz + 1/4 Re F3z - 1/4 Cz - 1/4 Re
F2x = 0 F4x = 0
F2y = l/2 Cy + l/2 Rb F4y = 1/2 Cy - 1/2 Rb
F2z - 1/4 Cz + 1/4 Re F4z = 1/4 Cz - 1/4 Re
Such that C = F1+F2+F3+F4, and R = (F1-F3) + (F2-F4)
The units of C and R represent the maximum maneuvering speed and are determined experimentally. The guidance system knows it has to live within these limits. The thrust angle and pitch rates for each fin can be calculated from each fins required thrust vector. The required pitch rate to achieve a given thrust can again be determined experimentally and implemented as a look up table.
If the craft has a high speed through the water relative to it's fin rate, the pitch can be optimized to the true incidence vector of the oncoming water (reducing pitch as speed increases). This is like a variable pitch propeller where pitch is lengthened for high water speeds; the object being to maintain an optimum work rate without increasing the rpm - or in this case flap rate.
All the above thrust vector control can occur at a constant flap rate; however controlling the flap rate can avoid needless 'running on the spot' power consumption. If the guidance system has little requirement for craft movement in the current time period, then the flap rate can be minimized. Equally if the craft has to work hard (through load, drag or acceleration) the flap rate can be maximized for the available motor power.
Control of flap rate can also be employed to reduce / increase the crafts command responsiveness; if for example conditions dictate a stealthy approach, or alternately high speed maneuvering or variable load compensation is required.
This control system works best in the context of a computer controlled guidance system providing craft movement and positional feedback, such that the control loop can be closed. The user need merely establish the required final position or movement vector and the craft will then manage it's own implementation by setting the appropriate flap rate and individual fin thrust vectors. This is particularly useful as drag from the umbilical or prevailing current conditions can then be automatically compensated for. In the mechanically synchronized embodiment (Fig. 9a) all fins must flap at the same rate and to the same angular extent. This can result in some reaction force imbalance where for example a fin is not required to produce a thrust vector; because that fin will generate a higher reaction force that a fin pitching through an angle. Where the system permits individual control of the extent of the flap angle (as in the hydraulic embodiments), a more complete balancing of the reaction forces is possible.
Where fins are connected in pairs to a common rotating boss (Fig. 11), the same control concept applies; but now requiring at least two, 2 fin modules. From a control perspective the fins can be considered independent.
The arrangement differs in vector summation when three, 2 axis modules are employed (like the constant angular blade rotation design in the first concept). Torque is not balanced with an equal and opposite symmetry as in a 4 fin system, but by adjusting the overall direction thrust of each module to create a unified counteracting torque about their common axis point. A craft which utilizes such a drive system is shown in Fig 12.
The hybrid surface / submersible craft. An embodiment of such a craft is shown in (stylized) section and plan views in Fig. 14.
The hydrodynamic design is a compromise to achieve minimum forward resistance, minimum static displacement consistent with the users head and shoulders being clear of the water, wave piercing rather than climbing, axial drag and buoyancy balancing when submerged, a form which can hydrofoil or plane to enable good top speeds at low power, protection for the user without too much restriction and integrated flow management for the drive system to minimize drag and 'prime' the hybrid thruster.
The bow has to protect the feet and forward control system. It features side deflecting scallops between twin vertically displaced prows (F14.1). This mitigates water breaking over the top of the craft into the lap of the user where it would drain momentum. By breaking the flow it assists in letting the nose climb as the craft speed increases to get on the plane. It also avoids an otherwise more raked nose creating unbalancing lift when the craft is completely submerged.
The main hull body blends from a shallow V at the nose into a shallow tunnel at the rear. This allows trapped air to lubricate the underside skin thereby reducing drag, provides for largely parallel lower 'rails' (F14.2) to assist in longitudinal stability at speed and in turn blends into the inlet concavity for the thruster (F14.3). From the rails it scoops up to the varying beam of the craft such that drag falls swiftly as the hull rises at speed. The rails also act as rubbing strips when the craft is beached thereby protecting the underside surface. They blend into the thruster cowling leading edge.
Internally, the hull rises between the knees to provide an enclosed volume to hold the battery packs (F14.4). It then dips down around and below the body shape of a reclined user. In the preferred embodiment an air filled cushion (F14.5) provides for generous padding under the user, tailored with variable thickness to reflect the local shock load if the craft 'slams' full face onto the water (e.g. a flat landing after coming off a wave or jump). Extending from the back support is an adjustable head rest and protection system
(F14.6). Behind the 'shoulders' is the attachment for the winglet pivot axes (F14.7). Across the lap is a restraint with overload release.
The head rest and support system:
This has to protect the user from side shocks and any oncoming high speed wall of water. The visor (F14.8) fully retracts so need only be deployed when required, it does not remain a permanent encumbrance for even undemanding craft usage. It consists of a hydrodynamically sculpted integrated helmet and visor adjustably attached to the top of the back support.
The helmet is attached to the craft rather than to the user - he need only sit forward to release himself.
The large visor pivots around the head over the back of the rear fairing such that when fully back it does not protrude much forward of the head rest. It has a softly padded open edge. When needed, it can be pulled forward to approaches the users chest or even rest upon it. Because it is substantially spherical, any external load (apart from minimal friction) acts surface normal into the pivot axis, thereby avoiding any rotational displacement. The pivot (F14.9) is arranged such that any internal load (like hitting it from inside with your head) causes it to dislocate.
The helmet body has a generously padded lining into which the back of the head up to the ears fits; and an optional padded band that can be pulled down over the forehead (to protect the head if it comes forward against the visor). It is more of an enveloping head rest from which you can readily extract your head than a typical crash helmet. Alternative embodiments have the padding on a separately wearable cap with the headrest as a rigid surface or keeps the helmet with the user which is then attached to the craft with an overload releasable fitting.
The helmet is not designed as a swim mask in that it has an inadequate lower edge seal and will flood with sustained submerged use, however is adequate for short duck dives where it acts as a diving TjeH'. With the visor down the user needs a mouthpiece to access fresh air from the snorkel or any reserved supply. A secondary face mask will therefore be necessary for sustained submergence.
The 'winglet' system:
The winglets (F14.10) are each connected to the craft through a 2 axis pivot behind the shoulder position (F14.7). The user controls them by placing his arms partially inside and gripping the individual handle bars (F14.l l). As such they become hydrodynamically faired arm extensions, emanating backwards from the elbows. They are force balanced such that they support the weight of the users arms in their neutral control position.
The 2 axis pivot can be arranged in several ways, but importantly such that it both allows the winglet to ride substantially level on the surface of the water and to introduce a lifting or turning component in moving water depending on how deployed. The water normal axis is constrained, thereby preventing the winglet being forced back by the onrush of water. In normal conditions, the pivot axes require an increasing control force to rotate up to their articulation limits; with a neutral control resting position. In this embodiment both axes are adjacently packaged at the shoulder and run orthogonal to each other at roughly 45 degrees to the craft axis in the horizontal plane (at neutral control); the inner pivot being backward facing and the outer pivot forward facing (F14.7). As the craft has no keel and a minimum beam, it will be subject to instability at relatively small list angles when the addition of the user raises its centre of gravity above it's centre of buoyancy.
While balance by weight shifting may be sufficient in calm conditions, waves may frustrate the potential instability. The winglets act as sponsons and help retain balance in difficult conditions.
To perform this efficiently they use the two axis pivot to let them ride along the surface of the water regardless of local topology; they also have a form optimised to act with a proportionally large section intersecting the water - together ensuring a large up force in a small volume package. As well as riding on the surface of the water the user can push them hard into the water for an immediate reaction effect (like a canoeist would use his paddle for balance).
Once the craft is in motion, the hydrodynamics stabilize the platform such that the sponsons can be raised clear of the water (also as the craft lifts) to minimize drag especially when moving into planning conditions.
The winglets also act as control or lift surfaces to sharpen turns and generally increase agility. If the wing is lowered (as on the outer facing side of a fast turn) on it's inner tilt axis, the fin generates lift to provide a positive heel force and a side acting component to enhance steerage. If the wing is raised
(as on the inner facing side of a turn) on it's outer tilt axis the tip of the sponson acts as a rudder in the water but this time with minimum lift. They also act in parallel to increase or decrease rear lift like hydrofoils, thereby helping the craft onto the plane or in the extreme acting like sea brakes. When the craft is fully submerged, the sponsons act like hydroplanes and can introduce a left / right independent rear up or down force. This enhances agility and can help the craft stay submerged at modest speeds.
The fin and thrust vectoring system: Extending at an upward angle from either side of the nose are two small hydroplanes (F14.12) designed to assist in diving and enhance submerged agility by providing lift / dive as well as rotational reaction forces. They work complimentary to and synchronous with the 2 axis displacement of the rear mounted thrust vectoring nozzle (F14.18), such that they enhance each others control effect. When the fins angle down to make the front dive the thrust vectors down to make the back rise and vice versa, and when the fins generate a side acting vector the thrust vectors to the opposite side. Because the fins are displaced from the craft's axis they also generate a useful axial torque tending to bank the craft into any turn - particularly when submerged.
In this embodiment a mechanically mixed system uses push / pull rods to connect the control pad to the fins and nozzle. Many other arrangements are possible including cable or hydraulic linkage.
The foot pad (F14.13) has a central 2 axis pivot point (F14.14), with two control rod coupling points (F14.15) displaced such that they are roughly twice as far apart as their common parallel offset from the pivot point; thereby ensuring a similar control sensitivity to forward / back tilting as left / right tilting. The pivot support shaft (F14.16) can be lengthened telescopically on the craft to an appropriate position for the height of the user, and the control rods (F14.17) lengthened or shortened to reflect this.
The control rods have ball and socket or 'rose joint' ends and link the pad coupling points to control horns (F14.19) on a special common axis bar (F14.20). Tilting the pad alters the effective lengths of the rods thereby rotating the control horns. The mechanical mixing acts such that forward / back tilting causes common axis rotation and dive / climb reaction forces, while left / right tilting causes opposite axis rotation and right / left turn forces.
To make the system as intuitive as possible, tilting by pressing with your left leg should cause a turn to the right and vice versa. To enable this apparent control reversal, either both the horns and coupling points need to be below their respective axes or the left horn has to control the right fin and vice versa. This is more desirable because it enables the fin to act from as low in the craft as possible (with the horn acting upwards). In any case the thrust vector control rods also require a left / right crossover. The common axis bar is a tube within a tube such that the inner tube connects to the fin pivot with a universal joint on one side, and the outer to a U.J. on the other side. The control horn for the fin connected to the outer tube can then be directly attached to it, near it's outer end, while the control rod for the inner tube acts through a radial slot in the outer tube near it's inner end. For even gearing: the control horn should have the same leverage length as the parallel displacement of the control rod / pad coupling points from the pivot, the distance between the control horns should be roughly the same as the distance between the two pad coupling points and the neutral angles of the control horns should be roughly the same as the neutral angle of the foot pad. The common axis bar is supported at either end with a 'pillow block' that integrates the push pull drive for the thrust vectoring nozzle (F14.18). As the horn moves forward the nozzle control rod must move back. In this embodiment a spur gear effectively attaches to each control horn and an idler spur gear acts against it. The idler gear traps and in turn acts against an axially displaceable rack, such that moving the control horn outwards pushes the rack inwards. The end of the rack is attached to the end of the nozzle control rod with a further connecting rod permitting some angular displacement. This is to minimize any bend in the control rod and allow it to approach and act from it's natural angle. The two nozzle control rods connect to the nozzle rim alternately left and right, 45 degrees from the vertical enabling the craft hull to readily integrate the mechanism. If the connection points were on the underside of the nozzle, idler gear direction reversal would not be necessary, but the nozzle push rod mechanism would be less conveniently located in the thin lower part of the thruster ducting. The drive power system:
This will be described particularly with reference to Fig 17 which is a an assembled view of the system but without it's rear annular socket; and Fig. 19 which shows the nozzle and push rod detail with the upper section in the plane of the push rod and the lower section in the plane of the constraint pin.
The craft uses a brushless DC motor (F17.1 & F19.1) for its reliability, efficiency and in particular ease of cooling the external stator through water contacting the motor housing. A basic servo amplifier is used to control the motor; in this embodiment in current mode such that the throttle acts like a car's to vary the power output (rather than the rpm). The throttle is hand operated and located on the winglet handle bars. To keep the amplifier compact and low cost the maximum current is kept at a manageable level by using quite a high bus voltage - in this case 120v. In this embodiment the motor can maintain a continuous 4 kW output at 3,000 rpm, and with higher short term peaks.
Power is provided by two removable 60v, 7Ah NiCad battery packs, each weighing about 12 kg. Together they will enable full power for about 12.5 minutes. A further 4.3 Ah is provided by a removable reserve. In practice full power is only used in short bursts, with an average power consumption of less than 1 kW; giving a total running time of about 80 minutes (reserve included). The battery packs are removed for charging and can be immediately replaced with fully charged alternates.
Because DC motors are small for their power output, the prop can be connected directly to the motor shaft resulting in a simple in line thruster pod which can be hermetically sealed and hence run fully submerged.
The propeller / thrust vectoring system is an original hybrid designed to offer the safety of a jet drive and efficiency of a propeller. It is fully integrated and recessed into the hull form enabling the craft to be safely 'beached'. Water flows readily into the prop cavity; thereby requiring little suction to prime the cavity after immersion. It also means that the prop can generate reverse thrust without near 180 degree flow vectoring (unlike a jet drive).
The prop as shown in Fig 15 and Fig 16 is relatively large to efficiently provide a good thrust at low speeds, particularly beneficial for the higher drag submerged use. It extends from the motor pod in a slow progression of diameter and pitch, then curves round such that it's surface of revolution becomes spherical. This allows it to run within a conforming spherical thrust vectoring duct (F17.2 and F18.2 and F19.2) which in turn is retained in an annular socket (F17.3 and F19.3); keeping the system very compact. The relatively large diameter at the start of the prop core, slow radial growth and lack of a contaminant snaring blade tip reduce the risk of fouling around the shaft. The prop has an extending pitch (in this embodiment of about 60%) and a soft leading edge which together reduces the leading edge 'shock' and hence the risk of cavitation; especially on initial craft acceleration. It achieves this without compromising the high maximum exhaust velocity needed for fast running. With lower point stresses this style of prop may lend itself to moulding in engineering grade plastics.
The spherical duct thrust nozzle can rotate about 2 axes within the annular socket. The third axis (about the plane of the socket) is constrained by two horizontally opposed inward facing pivot / slide pins (F17.5 and F19.5) retained in the socket and running in a longitudinal radial groove (F18.1) in the outside of the duct. The annular socket is comprised of two rings (F19.3 and F19.4) with internal truncated hemispherical surfaces which trap the spherical duct and constraint pins (F19.5) between them. The inner ring is firmly retained against the craft with the outer ring releasable from the inner; permitting the duct to be extracted. The duct has two 90 degree displaced outward facing coupling points (F17.6 and F19.6) which connect to the control rods via two axis yolks as shown in Fig 20 (permitting the angular displacement caused by the ducts two axis rotation). The duct coupling points are symmetrically arranged about the constraint pins and at 45 degrees from the vertical. As the control rods extend or retract they turn the duct within the annular socket about orthogonal tilt axes. In this embodiment common in / out action will tilt the nozzle up / down; opposed action will tilt the socket left / right. Any combination will mix into the combined 2 axis rotation.Many constraint and coupling permutations are possible. The constraint need only have one engaging protrusion; where it has two their common pivot axis must intersect the focal point of the spherical parts. It can be outward facing (retained in the duct, groove in the socket) as well as inward facing as in this embodiment. In all cases: rotation in the plane of the socket is constrained, the two coupling points should be around 90 degrees radially displaced from each other and to achieve control symmetry they should in turn be symmetrical about the constraint(s).
The duct nozzle features an array of inward bearing stator blades (F18.3 and F19.7). They serve both to unwind the props exhaust vortex thereby reducing the crafts axial torque reaction and to enhance the effect of the nozzle in vectoring the flow. As they bear inwards with a backwards rake they are unlikely to foul as there is no axial shaft around which things can tangle.
The breathing system: In the preferred embodiment the breathing system is simple and passive, utilizing air reserved in the cushions (and / or other bladders) as a third lung. The energy that powers the system comes directly from the work done by the craft in getting submerged. If such a system holds around 30 litres of air it will serve the user with a few minutes of careful use; more than adequate for his duck dive needs.
As the air is depleted the buoyancy of the craft reduces, making it possible to stay submerged at lower speeds. This can also be used as a trim feature in conjunction with a stop valve to reduce the craft's submerged displacement as a trade off against lung volume. The cushions (F14.5) can be either a complete bag with an internal open cell foam core or can utilize the adjacent upper craft shell as the lower surface, with a flexible upper skin only. This design variation has the advantage of effectively sealing the cushion to the craft such that it is not able to float away from the craft when submerged. To effect this, an air tight seal has to be made between the flexible skin and the craft. As the seal can be releasable, it can be occasionally removed to clean the foam core.
The foam core has a coefficient of restitution sufficient to lift the user a little and fill out the spaces around him when the craft is surfaced. The single opening acts as a damper to enhance the apparent cushion hardness when subjected to shock loads. Such air has to be evacuated through the snorkel system.
The snorkel is of a style which closes the air channel automatically when submerged and opens again on surfacing, even if subjected to a low back pressure. It connects both to the 'lung' and breathing tube. The mouthpiece of the breathing tube incorporates a one way valve so as to exhaust stale air out of the system. When on the surface, the user can breath through the snorkel at the same time as the lung is re-inflating. When submerged, the snorkel shuts off and the user begins to breath the air from the lung. As the reserve depletes, ambient pressure differential between the slightly lower lung and the user becomes insufficient to further collapse the foam lung core, requiring suction assist from the user. This serves as a useful intuitive indicator of the amount of remaining air, leaving time to reach the surface. Also lung pressure compared to ambient pressure can be processed to enable a digital air volume indication.
The safety systems:
The craft is capable of deep dives and fast climbs which would be a serious hazard to the user. However because of it's intrinsic buoyancy it requires a high power output to stay submerged; any loss of power would result in immediate surfacing. The craft is therefore fitted with a depth limiter that cuts off the power above a safe pressure. This will be set to less than 2 Bar leaving a maximum dive depth of less than 10m. A potentially more sensitive system would be processor controlled and relate dive duration to depth. Because nitrogen narcosis (the bends) requires many breaths to super saturate the bodies fluids, fast deep dives can be less hazardous than prolonged shallow ones (in both cases with quick assent).
As previously explained, the preferred breathing system requires increasing suction as reserves deplete and is therefore safe and intuitive. In any event because of depth limits worst case surfacing will still only take a few seconds.
Power reserves are shown by a bar graph comprised of LED's located along the trailing edge of the foot well cowling, along with a main or reserve indicator. Present drain rate (or time remaining at present rate) could optionally also be displayed. Other possible locations for instrumentation include in the users peripheral vision around the rim of the headrest / helmet.
While one hand controls the proportional throttle, the other can select between forward / stop / reverse with a 3 position tilt switch. Reserve power is separately enabled with a switch not prone to accidental setting. The battery packs connect with watertight couplings and are separately enabled when their integrity has been confirmed by electronically checking for power leakage. Any subsequent leakage automatically switches them back off. The cell packs include one way pressure relief valves which permit the venting of gases (particularly during charging). In ideal conditions the craft could have a range of 30 km, so the inclusion of a compartment within the body shell which can house safety equipment (flares, radio, compass etc.) is helpful.
Embodiments of the above described invention are further disclosed in more detail in each of the attached Appendix 1 ; Appendix 2 and Appendix 3. APPENDIX 1 (Pages 31 - 39) Personal Submarine
Submarines generally have a large displacement and could not be considered as personal. Small submarines have tended to be 'wet', in that they don't protect the occupant(s) from the high water pressure at depth.
There have been attempts to make small pressure protected craft, but these have still been relatively large because of the requirement to 'package' a human being often within a spherical volume. Pressure proof suits have also been developed, but these become unwieldy at depth because of the increasing resistance around the large spherical tracking pressure seals.
Although remote tethered craft have taken up much of the need for deep sea exploration, there is and always will be a need for first hand experience.
Marine based leisure is growing, with levels of user commitment ranging from snorkelling, organised submarine rides to scuba diving. Snorkelling is limited to shallow water, submarine rides are too orchestrated for some, and scuba requires good fitness and the assumption of physical discomfort and risk. A personal dry sub that was low cost and easy to use would be a good option, by providing freedom with comfort.
Summarv of the Invention:
This invention proposes a design of pressure proof containment vessel suitable for a personal submersible. The design is optimised to provide for good pressure resisting characteristics with the minimum use of materials, consistent with human factors. It employs ellipsoid forms for the body and a spherical view dome.
Also proposed is a solution to the need to make such a small craft float high enough in the water to permit the user ready access without risk of the craft flooding.
To maximise the utility of such a craft, a method is proposed to permit the application of an extendible arm in retrieving samples or specimens and returning them to within the craft. The method also permits the end effector of the arm to be changed from within the craft.
The craft is well suited to a 6 axis marine drive system permitting the craft to be held at any attitude and position in the water. Alternatives are proposed.
Description of the Invention:
The perfect pressure vessel is the sphere, but to comfortably enclose a person within a sphere would require one of around 1.8 m diameter. This would displace over 3,000 kg.
Wall thickness is directly proportional to radius for a given maximum loading (for thin walled vessels - where the thickness is approximately less than the radius/10), e.g. halving the radius would permit a halving of the wall thickness. There is therefore a significant economic benefit in keeping the maximum hoop radius as small as possible.
As shown in Fig. 1. This invention proposes the use of two hemi ellipsoids (Fl.l & F1.2). They both have the same minor diameter, but differing major axes such that one is approximately twice as long as the other.
The vessel hinges at this interface (shown in F2.1), opening up to permit the user to enter.
While it is possible to consider the shorter hemi ellipsoid (F 1.2) as a transparent view dome, it is not optimum for human factors. A preferred solution is to attach a partial spherical view dome shell on the ellipsoids surface (F1.3) which is then cut away such that the user can insert his head into it as the 'hatch' is closed. The benefits are that the user can then relax on a recliner with his head at an upwards attitude and can enjoy forward vision. Also side facing and peripheral vision is improved.
The view dome is now a small hemisphere of about 450 mm OD, rather than the complete upper hemi ellipsoid. It is thereby much lower cost to produce. It is also more readily scaled up in wall thickness to enable ever higher loads and consequently dive depths. The ellipsoid shell can then be more efficiently made without the constraint of transparency.
The entire craft now has a displacement of around 500 kg, making it commensurately easier to operate than spherical designs. The form is also very hydrodynamically efficient and in nose forward cruising attitude would require minimal drive power. Reducing the power requirements has other beneficial spin-offs; especially in extending duration with small battery packs.
The seal between the two ellipsoids (F2.2 & F2.3) is easy to make because it is round; and the pressure will bare down equal and opposite as the ellipsoids achieve common tangency at the interface.
In order to gain safe entry and exit while the craft is at sea, additional buoyancy must be provided to raise the hatch interface clear of the water.
Because the craft is of minimum displacement, this cannot be generated by internal variable buoyancy compartments. This invention also proposes a method to deploy additional temporary floats.
One embodiment of such a sytsem is shown inflated in Fig. 2. The floats are pneumatic and are stored uninflated, coiled up within pod like structures otherwise attached to the outside of the lower hemi ellipsoid (F1.6). They function like that well known party toy that unrolls as a tube when you blow behind it (also then wailing as it jiggles it's end feather). Only in this case it is a reinforced tube preferably tapered, constructed similar to inflatable dinghies, caused to coil by the inclusion of flat band constant force type springs.
The air pressure required to uncoil it is provided by a reserved supply, or an air pump which breaths through a snorkel. The pods open up like clam shells and permit the expanding coil to extend out (F2.5). Air is filled until the tube (or fructo cone) is suitably rigid as shown in F2.4a, 4b, 4c and 4d.
This process occurs at least two points and preferably four, around the outside circumference of the hemi ellipsoid; thereby conferring flotational stability on the craft while also raising the hatch clear of the water. The floats act as a suitable staging post to gain entry to the craft, either directly from the water of from a support boat. To provide added security, it is advisable that the floats contribute sufficient buoyancy that even if one of their number were to fail the craft will still float. The assumption must also be that in the worst case the inside of the craft is completely flooded out. When the user wishes to dive, he seals his hatch and then checks that not too much water has invaded the craft (and can deploy a bilge pump to evacuate any that has). The float valves are then opened permitting the air to escape; firstly the premium over atmospheric and then the remainder as the coil springs begin to wind the floats back up. When home the pod covers close. At this stage the craft should be at near neutral buoyancy just below the water's surface; ready for the marine drive to take command.
Part of the benefits of such a craft is the ability to get up close. An extendible manipulator system is now proposed which enables interaction between the inside of the craft and the pressure hostile outside as shown at different positions in Figs 3 and 4.
One limitation of manipulators is that you never seem to have the right kind of end effector - or indeed you may not want an effector at all, perhaps an extra camera or other instrumentation. Surfacing in order to re-designate the manipulator is inefficient, especially when otherwise operating at extreme depth.
Because of the small scale of the craft it is not possible to enclose the entire manipulator within a pressure lock, it is however possible to enclose just the end effector. The difficulty then arises as how to create a reliable enough seal around the effector to resist potentially very high pressures. This invention proposes an elegant solution to this dilemma as shown in
Fig. 5. It is to fix the hatch cover (F5.1) for the internal pressure lock to the manipulator (F5.2), rather than to the craft. Being a permanent fixture around the arm it need not compromise integrity. The manipulator returns the cover into position (as shown in F1.4), leaving the effector and anything collected within a small 'bell jar' like internal facing pressure lock. Water is evacuated from inside the lock to either outside the craft by a high pressure compressor or more conveniently to an internal water tank. The bell jar can then be released, giving clear access to the effector and samples.
When the effector is to be re-deployed, the bell jar is attached and allowed to flood with external water or water from the internal tank. When filled, a valve can open and connect the internal bell jar with the outside, thereby equalising the pressure and permitting the hatch cover to be withdrawn.
A convenient arrangement is to make the manipulators base axis hollow such that it can contain part of the pressure lock (F5.6). The manipulator can then fold back in a single axis to replace the cover over the pressure lock in it's correct position. Also rotation about the manipulators base axis when the cover is in position can be used to mechanically lock it closed.
The internal bell jar can be deployed by a novel method as also proposed by this invention as shown in Fig. 6.
The bell jar has a fructo conical flange or flange member around it's outer annulus (F6.1). The jar fits over a conforming mounting tube (F6.2) such that it is slid into place along the tube axis. The tube leads to the outside of the lock. Seal rings (F6.3) are fitted to act between the interface as the jar is slid home.
A collar (F6.4) otherwise retained around the jar annulus can be screwed or otherwise clamped to the craft body shell at a conforming annular hatch fitting (F6.5).
When pressure is introduced into the jar, it tries to blow into the inside of the craft like a hydraulic piston. The collar however, retained behind the conical flange, acts as an end stop to this motion. As the pressure mounts the conical flange interface causes inward radial forces which act to try and compress the open annulus of the jar around the mounting tube. This effect counteracts the expansion of the jar under the internal pressure which would otherwise release some of the pressure on the seals to the mounting tube. The exact axial position of the jar when retained is not critical, because the seals act like a piston and are not compressed by the jar being retained
(until internal pressure acts as described above). This is a good safety feature because it does not require perfect fitting to achieve and retain good seal integrity.
An ancillary feature of the pressure lock concept will enable wet samples such as marine life to be collected and preserved in their own sealed mini aquaria.
As shown in Fig 5.2, the end effector will be adapted from a gripper like mechanism (F5.3) to hold two transparent plastic hemispheres (F5.4 & 5.5).
When brought together, the hemispheres snap shut with a waterproof seal. The resulting sphere is released when the 'gripper' is opened.
In use, the hemispheres are loaded into the effector when in the dry internal space. The manipulator leaves the lock and deploys the sample collector as desired. It is then retrieved into the lock. Once evacuated, the manipulator releases the sphere for closer examination and / or storage.
The sample aquaria need not be spheres, but can be any viable watertight container. As spheres and with additional preparation a pressure proof lock could be effected between the two shells - enabling life forms to be recovered and preserved at their normal habitat pressure. One method would be to provide the effector with an additional axis in order to screw two shells together rather than just snap them shut. A little dive pressure air must then be introduced or otherwise be permanently trapped inside of the shells. This could be enabled by a flexible membrane containing some gas or piece of closed cell foam. This device then acts as a hydraulic accumulator and will retain the pressure within the shells (by itself expanding as the pressure otherwise falls) even if the shells are able to expand slightly as they are returned to normal pressure.
Most submersibles have no more than 4 drive axes as they rely on upper buoyancy and lower ballast to keep the craft vertical. This craft however would benefit from a drive that would hold any orientation and move in any direction. This amounts to all six degrees of freedom.
Illustrated in Fig 1.5 is a concept employing two pairs of twin fin drive units as described in the patent application titled "Multi Axis Submarine Propulsion System". They create a variable thrust about two vectors and with a variable torque (total of 3 axes). Two such units - one on each side of the craft - then provide thrust in all six axes.
If more conventional 2 axis thrusters are employed (e.g. Voight
Schneider, stearable prop or Schottel units) then three must be arranged around or about the craft such that their stealing axes point away from each other and lie significantly in a common plane. If single axis thrusters are employed then a minimum of 6 would be required.
Claims:
1. A submersible craft for accommodating a single person, the craft comprising a hull having two interengagably hemi ellipsoidal parts together defining a personl carrying space therein.
2. A craft as in 1 where one hemi ellipsoid has a larger major axis than the other, and where the shorter hemi ellipsoid becomes the hatch and where this also has a further spherical protrusion in a transparent material, cut away such that the user can insert his head as the hatch closes. 3. A craft as in 1 where pneumatic floats, otherwise stowed compactly, can be extended by inflation to provide buoyancy such as to lift the hatch ellipsoid clear of the water with the craft axis principally vertical.
4. A craft as in 3 where the floats are comprised of sealed tubes or fructo cone shells which are caused to coil by the application of integrated springs, but can uncoil when sufficient gas pressure is supplied to the outer end of the coil.
5. A craft as in 3 where the floats are comprised of a circumferal ring below the hatch interface.
6. An integrated submersible manipulator and pressure lock system where the cover for the outside of the pressure lock is attached to the end of the manipulator, positioned and removed by the manipulator and such that the end effector of the manipulator is on the other side of the cover and hence inside of the lock when the cover is in the closed position.
7. A system as in 6 where the manipulators base axis is hollow such that it can contain part of the pressure lock and where the manipulator can fold back in a single axis to replace the cover over the pressure lock in it's correct position.
8. A system as in 7 where rotation about the manipulators base axis when the cover is in position causes the cover to mechanically lock closed. 9. A system as in 6 where the end effector can be readily detached and replaced with alternate equipment once the inside of the pressure lock has been opened.
10. A small pressure lock comprising of a bell jar like internal form with a fructo conical flange which is slid into position over a conforming mounting tube leading to the outer opening with seal rings between the interface; and then retained by a collar bearing down around the flange such that once the collar is fixed, increasing pressure otherwise trying to blow out the bell jar like a piston also causes the bell jar to be compressed around its open annulus by the conical flange part so as to retain seal pressure to the mounting tube.
11. A marine specimen containment system comprising of two shells designed to clip together with a watertight seal that are deployed with their open side inward facing in a holding device, otherwise able to couple the two shells by bringing them together; and then release the now closed specimen container.
12. A system as in 1 1 where the containment shells are substantially hemispherical and able to withstand internal pressure when joined; and where the joining involves a mechanical act of engagement such as a screw thread; and where the containment vessel also encloses a means to entrap some gas which will act as a device to retain containment pressure even if the vessel slightly expands.
13. A hull for a personal submersible craft comprising of substantially two hemi ellipsoids, where entry is gained by opening the craft at the common tangent interface between them APPENDIX 2 (Pages 40 - 56)
Personal Hybrid Submersible Craft
Background:
Many novel personal craft are now available for pleasure and sometimes utility above and below the water. Examples are craft powered by gravity (surf boards), wind (windsailers), internal combustion engines (jet bikes), humans
(canoes) and electricity (scuba tugs). Each has been optimised for it's own domain.
These craft have grown in popularity with the increase in leisure, access and disposable income - because they are fun. They are intimate and empowering through a sense of synergy with the water. They exhilarate in a safe world. But in many cases their physical demands take them out of reach of the casual user. Both in terms of general fitness and skill acquisition. Also in the case of jet bikes their antisocial qualities limit their use, and generally they need the right weather to have fun.
A very welcome craft concept would be safe and 'green', easy to use well in any water condition, intimate and exhilarating in a strange new world.
Such a craft is proposed by this invention.
Summarv of the Invention:
The "strange new world" in which this craft will operate is in the near region above and below the water. It will plane on the surface, it will shallow dive, it will porpoise, it will surf. With an eye line not far above the water, thrills come at low speed and with low risk.
In overview, the craft is like an electric powered surfboard that envelopes you, with arms and legs controlling fins and thrust direction. It has minimal displacement and rests partially submerged; breaking through the waves rather than climbing over them. It has a total of 7 control axes (compared with the 2 of a regular boat); as such it offers many control combinations which permit the acquisition of skill and agility but without demanding it. The users limbs act intuitively as they become control surfaces. The craft is really more like a 'dolphin man' superhero costume than a boat - you wear it more than ride on it.
The craft features a novel 2 axis vectored propulsion unit that lets it steer up and down as well as the usual left and right. It is safe (shrouded and foul proof), clean and quiet (battery electric), potent (efficient water cooled brushless DC) and flexible (using hybrid propeller / impeller). The drive has been fully integrated into the hydrodynamics of the hull. Reversible power output is adjusted with a hand throttle.
The craft has minimum displacement such that when resting, the users legs and lower body lie mostly submerged. It is designed to permit planing above modest speeds but is axially drag balanced such that it retains it's stability under the water. It achieves this partly by shedding the bow wave or the impact of oncoming water to either side of the craft rather than under (and over).
The user lies feet first with a low back and head rest. The hull surrounds him; it is self draining, and with the cushion leaves little space for puddled water. A transparent cowl can be pulled forward from the headrest (over and around the head) when dive or splash protection is needed. The users arms rest in buoyant articulated winglets that serve to provide stationary balance and extra control agility. The users feet operate a 2 axis tilt pad which effects synchronously both the thrust vector and the attitude of small forward control fins.
The winglets are engineered with 2 pivot axes emulating the shoulder.
The axis arrangement permits up, down and rotational movements, but not back and forward. This minimised the arm load necessary to maintain winglet stability. The use of the winglets is intuitive, being like turning your arms into fins. You can use them as stabilisers, acting both as floats and paddles which can come clear of the water at speed. You can lean into them, turning them into offset rudders to assist in tight turns or hydroplanes to add lift. They also enhance attitude control when submerged. The tilt pad can work in several ways but in the preferred embodiment it acts about a central 2 axis pivot point both as a 'rudder bar' (left / right) for turns and 'elevators' (back / forward) for dive / climb. In sync with this, the thrust is vectored in the mirror image of the tilt pad to augment and enhance the steerage control. Preferably the user has access to a portable air reserve. In one embodiment this is a simple passive system operating at ambient pressure. It uses an inflatable bladder (that can double as a cushion) which is filled with an open cell foam acting as an expansion spring. Whenever the craft is on the surface, the cushion will re-inflate with fresh air. When submerged, the user can breath out of this supply. No regulator is necessary because the air will be at about lung pressure regardless of depth. A simple non return valve ensures exhausted air is expelled. The effort necessary to breath is proportional to the air reserve, so the user has an intuitive feel for how many useful breaths remain.
Description:
An embodiment of the craft will be described with reference to Fig 1. The Hull:
The hydrodynamic intent is to provide a compromise between minimum forward resistance, minimum static displacement consistent with the users head and shoulders being clear of the water, wave piercing rather than climbing, axial drag and buoyancy balancing when submerged, a form which can hydrofoil or plane to enable good top speeds at low power, protection for the user without too much restriction and integrated flow management for the drive system to minimise drag and 'prime' the hybrid thruster. The bow has to protect the feet and forward control system. It features side deflecting scallops between twin vertically displaced prows (Fl.l). This mitigates water breaking over the top of the craft into the lap of the user where it would drain momentum. By breaking the flow it assists in letting the nose climb as the craft speed increases to get on the plane. It also avoids an otherwise more raked nose creating unbalancing lift when the craft is completely submerged.
The main hull body blends from a shallow V at the nose into a shallow tunnel at the rear. This allows trapped air to lubricate the underside skin thereby reducing drag, provides for largely parallel lower 'rails' (FI .2) to assist in longitudinal stability at speed and in turn blends into the inlet concavity for the thruster (F1.3). From the rails it scoops up to the varying beam of the craft such that drag falls swiftly as the hull rises at speed. The rails also act as rubbing strips when the craft is beached thereby protecting the underside surface. They blend into the thruster cowling leading edge.
Internally, the hull rises between the knees to provide an enclosed volume to hold the battery packs (F1.4). It then dips down around and below the body shape of a reclined user. In the preferred embodiment an air filled cushion (F1.5) provides for generous padding under the user, tailored with variable thickness to reflect the local shock load if the craft 'slams' full face onto the water (e.g. a flat landing after coming off a wave or jump). Extending from the back support is an adjustable head rest and protection system (F1.6). Behind the 'shoulders' is the attachment for the winglet pivot axes (F1.7). Across the lap is a restraint with overload release.
The head rest and support system:
This has to protect the user from side shocks and any oncoming high speed wall of water. The visor (F1.8) fully retracts so need only be deployed when required, it does not remain a permanent encumbrance for even undemanding craft usage. It consists of a hydrodynamically sculpted integrated helmet and visor adjustably attached to the top of the back support. The helmet is attached to the craft rather than to the user - he need only sit forward to release himself.
The large visor pivots around the head over the back of the rear fairing such that when fully back it does not protrude much forward of the head rest.
It has a softly padded open edge. When needed, it can be pulled forward to approaches the users chest or even rest upon it. Because it is substantially spherical, any external load (apart from minimal friction) acts surface normal into the pivot axis, thereby avoiding any rotational displacement. The pivot (F1.9) is arranged such that any internal load (like hitting it from inside with your head) causes it to dislocate.
The helmet body has a generously padded lining into which the back of the head up to the ears fits; and an optional padded band that can be pulled down over the forehead (to protect the head if it comes forward against the visor). It is more of an enveloping head rest from which you can readily extract your head than a typical crash helmet. Alternative embodiments have the padding on a separately wearable cap with the headrest as a rigid surface or keeps the helmet with the user which is then attached to the craft with an overload releasable fitting. The helmet is not designed as a swim mask in that it has an inadequate lower edge seal and will flood with sustained submerged use, however is adequate for short duck dives where it acts as a diving "bell'. With the visor down the user needs a mouthpiece to access fresh air from the snorkel or any reserved supply. A secondary face mask will therefore be necessary for sustained submergence.
The 'winglet' system:
The winglets (F1.10) are each connected to the craft through a 2 axis pivot behind the shoulder position (F1.7). The user controls them by placing his arms partially inside and gripping the individual handle bars (Fl.l 1). As such they become hydrodynamically faired arm extensions, emanating backwards from the elbows. They are force balanced such that they support the weight of the users arms in their neutral control position.
The 2 axis pivot can be arranged in several ways, but importantly such that it both allows the winglet to ride on the surface of the water in a
'gimballed' fashion and to introduce a lifting or turning component in moving water depending on how deployed. The water normal axis is constrained, thereby preventing the winglet being forced back by the onrush of water. In normal conditions, the pivot axes require an increasing control force to rotate up to their articulation limits; with a neutral control resting position. In this embodiment both axes are adjacently packaged at the shoulder and run orthogonal to each other at roughly 45 degrees to the craft axis in the horizontal plane (at neutral control); the inner pivot being backward facing and the outer pivot forward facing (F1.7). As the craft has no keel and a minimum beam, it will be subject to instability at relatively small list angles when the addition of the user raises it's centre of gravity above it's centre of buoyancy. While balance by weight shifting may be sufficient in calm conditions, waves may frustrate the potential instability. The winglets act as sponsons and help retain balance in difficult conditions.
To perform this efficiently they use the two axis pivot to let them ride along the surface of the water regardless of local topology; they also have a form optimised to act with a proportionally large section intersecting the water - together ensuring a large up force in a small volume package. As well as riding on the surface of the water the user can push them hard into the water for an immediate reaction effect (like a canoeist would use his paddle for balance).
Once the craft is in motion, the hydrodynamics stabilise the platform such that the sponsons can be raised clear of the water (also as the craft lifts) to minimise drag especially when moving into planning conditions. The winglets also act as control or lift surfaces to sharpen turns and generally increase agility. If the wing is lowered (as on the outer facing side of a fast turn) on it's inner tilt axis, the fin generates lift to provide a positive heel force and a side acting component to enhance steerage. If the wing is raised (as on the inner facing side of a turn) on it's outer tilt axis the tip of the sponson acts as a rudder in the water but this time with minimum lift. They also act in parallel to increase or decrease rear lift like hydrofoils, thereby helping the craft onto the plane or in the extreme acting like sea brakes.
When the craft is fully submerged, the sponsons act like hydroplanes and can introduce a left / right independent rear up or down force. This enhances agility and can help the craft stay submerged at modest speeds.
The fin and thrust vectoring system:
Extending at an upward angle from either side of the nose are two small hydroplanes (Fl.l 2) designed to assist in diving and enhance submerged agility by providing lift / dive as well as rotational reaction forces. They work complimentary to and synchronous with the 2 axis displacement of the rear mounted thrust vectoring nozzle (Fl.l 8), such that they enhance each others control effect. When the fins angle down to make the front dive the thrust vectors down to make the back rise and vice versa, and when the fins generate a side acting vector the thrust vectors to the opposite side. Because the fins are displaced from the craft's axis they also generate a useful axial torque tending to bank the craft into any turn - particularly when submerged.
In this embodiment a mechanically mixed system uses push / pull rods to connect the control pad to the fins and nozzle. Many other arrangements are possible including cable or hydraulic linkage.
The foot pad (F1.13) has a central 2 axis pivot point (F1.14), with two control rod coupling points (Fl .l 5) displaced such that they are roughly twice as far apart as their common parallel offset from the pivot point; thereby ensuring a similar control sensitivity to forward / back tilting as left / right tilting. The pivot support shaft (Fl.l 6) can be lengthened telescopically on the craft to an appropriate position for the height of the user, and the control rods (Fl.l 7) lengthened or shortened to reflect this.
The control rods have ball and socket or 'rose joint' ends and link the pad coupling points to control horns (Fl.l 9) on a special common axis bar (F1.20). Tilting the pad alters the effective lengths of the rods thereby rotating the control horns. The mechanical mixing acts such that forward / back tilting causes common axis rotation and dive / climb reaction forces, while left / right tilting causes opposite axis rotation and right / left turn forces. To make the system as intuitive as possible, tilting by pressing with your left leg should cause a turn to the right and vice versa. To enable this apparent control reversal, either both the horns and coupling points need to be below their respective axes or the left horn has to control the right fin and vice versa. This is more desirable because it enables the fin to act from as low in the craft as possible (with the horn acting upwards). In any case the thrust vector control rods also require a left / right crossover.
The common axis bar is a tube within a tube such that the inner tube connects to the fin pivot with a universal joint on one side, and the outer to a U.J. on the other side. The control horn for the fin connected to the outer tube can then be directly attached to it, near it's outer end, while the control rod for the inner tube acts through a radial slot in the outer tube near it's inner end. For even gearing: the control hom should have the same leverage length as the parallel displacement of the control rod / pad coupling points from the pivot, the distance between the control horns should be roughly the same as the distance between the two pad coupling points and the neutral angles of the control horns should be roughly the same as the neutral angle of the foot pad.
The common axis bar is supported at either end with a 'pillow block' that integrates the push pull drive for the thrust vectoring nozzle. As the horn moves forward the nozzle control rod must move back. In this embodiment a spur gear effectively attaches to each control horn and an idler spur gear acts against it. The idler gear traps and in turn acts against an axially displaceable rack, such that moving the control horn outwards pushes the rack inwards. The end of the rack is attached to the end of the nozzle control rod with a further connecting rod permitting some angular displacement. This is to minimise any bend in the control rod and allow it to approach and act from it's natural angle.
The two nozzle control rods connect to the nozzle rim alternately left and right, 45 degrees from the vertical enabling the craft hull to readily integrate the mechanism. If the connection points were on the underside of the nozzle, idler gear direction reversal would not be necessary, but the nozzle push rod mechanism would be less conveniently located in the thin lower part of the thruster ducting.
The power system: This will be described with reference to Fig 2 which is a an assembled view of the system but without it's rear annular socket and Fig 3 which shows the nozzle and push rod detail with the upper section in the plane of the push rod and the lower section in the plane of the constraint pin.
The craft uses a brushless DC motor (F3.1) for it's reliability, efficiency and in particular ease of cooling the external stator through water contacting the motor housing. A basic servo amplifier is used to control the motor; in this embodiment in current mode such that the throttle acts like a car's to vary the power output (rather than the rpm). The throttle is hand operated and located on the winglet handle bars. To keep the amplifier compact and low cost the maximum current is kept at a manageable level by using quite a high bus voltage - in this case 120v. In this embodiment the motor can maintain a continuous 4 kW output at 3,000 rpm, and with higher short term peaks.
Power is provided by two removable 60v, 7Ah NiCad battery packs, each weighing about 12 kg. Together they will enable full power for about 12.5 minutes. A further 4.3 Ah is provided by a removable reserve. In practise full power is only used in short bursts, with an average power consumption of less than 1 kW; giving a total running time of about 80 mins (reserve included). The battery packs are removed for charging and can be immediately replaced with fully charged alternates. Because DC motors are small for their power output, the prop can be connected directly to the motor shaft resulting in a simple in line thruster pod which can be hermetically sealed and hence run fully submerged.
The propeller / thrust vectoring system is an original hybrid designed to offer the safety of a jet drive and efficiency of a propeller. It is fully integrated and recessed into the hull form enabling the craft to be safely 'beached'. Water flows readily into the prop cavity; thereby requiring little suction to prime the cavity after immersion. It also means that the prop can generate reverse thrust without near 180 degree flow vectoring (unlike a jet drive).
The prop as shown in Fig 4 is relatively large to efficiently provide a good thrust at low speeds, particularly beneficial for the higher drag submerged use. It extends from the motor pod in a slow progression of diameter and pitch, then curves round such that it's surface of revolution becomes spherical. This allows it to run within a conforming spherical thrust vectoring duct (F3.2) which in turn is retained in an annular socket (F3.3 and 3.4); keeping the system very compact. The relatively large diameter at the start of the prop core, slow radial growth and lack of a contaminant snaring blade tip reduce the risk of fouling around the shaft. The prop has an extending pitch (in this embodiment of about 60%) and a soft leading edge which together reduces the leading edge 'shock' and hence the risk of cavitation; especially on initial craft acceleration. It achieves this without compromising the high maximum exhaust velocity needed for fast running. With lower point stresses this style of prop may lend itself to moulding in engineering grade plastics.
The spherical duct extends into the thrust nozzle (F3.2 and F2.1) and can rotate about 2 axes within the annular socket. The third axis (about the plane of the socket) is constrained by two horizontally opposed inward facing pivot / slide pins (F3.5 and F2.2) retained in the socket and running in a longitudinal radial groove (F2.3) in the outside of the duct. The annular socket is comprised of two rings (F3.3 and 3.4) with internal truncated hemispherical surfaces which trap the spherical duct (and constraint pins (F3.5) between them. The inner ring is firmly retained against the craft with the outer ring releasable from the inner; permitting the duct to be extracted. The duct has two 90 degree displaced outward facing coupling points (F3.6 and F2.4) which connect to the control rods via two axis yolks as shown in Fig 5 (permitting the angular displacement caused by the ducts two axis rotation).
The duct coupling points are symmetrically arranged about the constraint pins and at 45 degrees from the vertical. As the control rods extend or retract they turn the duct within the annular socket about orthogonal tilt axes. In this embodiment common in / out action will tilt the nozzle up / down; opposed action will tilt the socket left / right. Any combination will mix into the combined 2 axis rotation.
Many constraint and coupling permutations are possible. The constraint need only have one engaging protrusion; where it has two their common pivot axis must intersect the focal point of the spherical parts. It can be outward facing (retained in the duct, groove in the socket) as well as inward facing as in this embodiment. In all cases: rotation in the plane of the socket is constrained, the two coupling points should be around 90 degrees radially displaced from each other and to achieve control symmetry they should in turn be symmetrical about the constraint(s). The duct nozzle features an array of inward bearing stator blades (F3.7 and F2.5). They serve both to unwind the props exhaust vortex thereby reducing the crafts axial torque reaction and to enhance the effect of the nozzle in vectoring the flow. As they bear inwards with a backwards rake they are unlikely to foul as there is no axial shaft around which things can tangle. The breathing system:
In the preferred embodiment the breathing system is simple and passive, utilising air reserved in the cushions (and / or other bladders) as a third lung. The energy that powers the system comes directly from the work done by the craft in getting submerged. If such a system holds around 30 litres of air it will serve the user with a few minutes of careful use; more than adequate for his duck dive needs.
As the air is depleted the buoyancy of the craft reduces, making it possible to stay submerged at lower speeds. This can also be used as a trim feature in conjunction with a stop valve to reduce the craft's submerged displacement as a trade off against lung volume.
The cushions (F1.5) can be either a complete bag with an internal open cell foam core or can utilise the adjacent upper craft shell as the lower surface, with a flexible upper skin only. This design variation has the advantage of effectively sealing the cushion to the craft such that it is not able to float away from the craft when submerged. To effect this, an air tight seal has to be made between the flexible skin and the craft. As the seal can be releasable, it can be occasionally removed to clean the foam core.
The foam core has a coefficient of restitution sufficient to lift the user a little and fill out the spaces around him when the craft is surfaced. The single opening acts as a damper to enhance the apparent cushion hardness when subjected to shock loads. Such air has to be evacuated through the snorkel system.
The snorkel is of a style which closes the air channel automatically when submerged and opens again on surfacing, even if subjected to a low back pressure. It connects both to the 'lung' and breathing tube. The mouthpiece of the breathing tube incorporates a one way valve so as to exhaust stale air out of the system. When on the surface, the user can breath through the snorkel at the same time as the lung is re-inflating. When submerged, the snorkel shuts off and the user begins to breath the air from the lung. As the reserve depletes, ambient pressure differential between the slightly lower lung and the user becomes insufficient to further collapse the foam lung core, requiring suction assist from the user. This serves as a useful intuitive indicator of the amount of remaining air, leaving time to reach the surface. Also lung pressure compared to ambient pressure can be processed to enable a digital air volume indication.
The safety systems:
The craft is capable of deep dives and fast climbs which would be a serious hazard to the user. However because of it's intrinsic buoyancy it requires a high power output to stay submerged; any loss of power would result in immediate surfacing. The craft is therefore fitted with a depth limiter that cuts off the power above a safe pressure. This will be set to less than 2 Bar leaving a maximum dive depth of less than 10m. A potentially more sensitive system would be processor controlled and relate dive duration to depth. Because nitrogen narcosis (the bends) requires many breaths to super saturate the bodies fluids, fast deep dives can be less hazardous than prolonged shallow ones (in both cases with quick assent).
As previously explained, the preferred breathing system requires increasing suction as reserves deplete and is therefore safe and intuitive. In any event because of depth limits worst case surfacing will still only take a few seconds.
Power reserves are shown by a bar graph comprised of LED's located along the trailing edge of the foot well cowling, along with a main or reserve indicator. Present drain rate (or time remaining at present rate) could optionally also be displayed. Other possible locations for instrumentation include in the users peripheral vision around the rim of the headrest / helmet.
While one hand controls the proportional throttle, the other can select between forward / stop / reverse with a 3 position tilt switch. Reserve power is separately enabled with a switch not prone to accidental setting. The battery packs connect with watertight couplings and are separately enabled when their integrity has been confirmed by electronically checking for power leakage. Any subsequent leakage automatically switches them back off.
The cell packs include one way pressure relief valves which permit the venting of gases (particularly during charging).
In ideal conditions the craft could have a range of 30 km, so the inclusion of a compartment within the body shell which can house safety equipment (flares, radio, compass etc.) is helpful.
Claims:
1. A personal water craft for use with a person lying lengthwise of the craft to plane on or submerge below the surface of a mass of water at will, the craft comprising a hull for receiving a person thereon, the hull including a low curvature planning underside, a plurality of independent control means, each operable by the legs or arms of the said person, respectively, for controlling the direction and use of the craft, the pwer means for driving the craft on or through the water. 2. A craft as in 1. where the rear mounted propulsive thrust is vectored in two axes such as to compliment the reaction vector of the forward hydroplanes for enhanced control effect, by virtue of direct mechanical or hydraulic coupling between the vectoring nozzle and hydroplanes. 3. A marine propulsion system where thrust vectoring occurs when a substantially spherical duct with exhaust nozzle, otherwise retained in an annular socket, tracks with two degrees of freedom around a propeller, the propeller having a conforming spherical surface of revolution to maintain a small clearance to the duct and the constrained third axis being normal to the plane of the socket. 4. A system as in 3. where two control coupling points for push / pull action or 3 or more control coupling points for pull / release action are located on the outer side of the duct, each connected through a two axis linkage to the control effect mechanism.
5. A system as in 4. where the control effect mechanism is a push / pull rod linking the thrust vectoring with forward controls.
6. A system as in 3. where the exhaust nozzle features inward facing stator blades which act to unwind the exhaust vortex and control flow direction.
7. A marine propeller which has a large starting core diameter from which the blades extend progressively in diameter moving along the axis, as also the core diameter reduces. Similarly the blade pitch lengthens by a minimum of 50% as the diameter increases. The propellers length is sufficient to accommodate at least 270 degrees of blade spiral. The trailing edge of the blades undercut the tips and blend back into the reducing hub.
8. A propeller as in 7. where the surface of revolution turns into a sphere able to be deployed in a thrust vectoring system as in 3.
9. A craft as in 1. where the feet act against a two axis tilt pad and where two push / pull couplings or 3 or more pull / release couplings on the pad are offset from the pivot point such that they are effected by both forward / back tilting of the pad and left / right tilting of the pad; such couplings then directly effecting the axial rotation of the forward hydroplanes such that forward / back tilting effects both hydroplanes in mirror image and left / right tilting effects both hydroplanes in opposites.
10. A craft as in 1. where left and right pivoting pedals each operate separate hydroplanes such the hydroplanes rotate in the same direction as the pedals.
11. A craft as in 9. or 10. where hydroplane rotation is coupled to the thrust vectoring as in 2.
12. A craft as in 9. or 10. where the separate hydroplane pivot axes are translated by universal or flexural joints to a common axis and where respective torsion members from each hydroplane coupling can rotate about each other, and that an extension from the inner torsion member can protrude through a radial clearance on the outer without preventing limited independent rotation of either; such that control attachments to both the extension and the outer torsion member can each cause the rotation of the opposite (not adjacent) hydroplane.
13. A craft as in 12. where the control attachments incorporate a means to effect push pull actions in further thrust vectoring control rods.
14. A craft as in 1. where rear two axis hydroplanes are controlled directly by arm location and hand holds and with two axis pivots located adjacent to the users shoulder and with the constrained axis being substantially normal to the plane of the water.
15. A craft as in 14. where the pivot point is behind the users shoulder and the two pivot axes are substantially orthogonal and offset from the craft axis. 16. A craft as in 14. except instead of a two axis pivot, the axes are distributed as two single axis pivots, arranged to emulate first shoulder and then elbow.
17. A craft as in 2. except that the rear hydroplanes directly connect to the thrust vectoring (instead of the forward hydroplanes) in synchronous such that they both generate complimentary reaction forces.
18. A craft as in 1. where the nose form consists of two vertically displaced prows with a concave linking scallop and an upper recess incorporating seat, back and head rest, substantially able to support the reclined form of the user.
19. An underwater breathing system where an air tight cushion or bladder can be used as a reserve of air, said reserve having at least one expandable side and containing an elastomeric open cell foam core able to expand it against a small load; the internal volume being connected both to a fresh air source which automatically closes on water immersion and a one way flow means of air delivery to the user. 20. A system as in 1 where the bladder is expanded by air pressure, mechanical or other elastomeric means.
21. A craft as in 1. where a substantially spherical visor can be deployed from a fixed head rest rotating into position from a pivot axis behind the users neck, said pivot holding firmly against inward loading, but permitting outward dislocation beyond a modest force threshold.
22. A principally personal powered water craft with a low curvature underside planning hull form for above surface use and above to submerge below the water and otherwise achieve operational control utilising foot control of two independent signal axis forward mounted hydroplanes and independent arm control of two, single or more axis rear mounted hydroplanes. APPENDIX 3 (Pages 57 - 71)
Multi Axis Marine Propulsion System
Background:
There is a growing need for submersible craft which are able to move in any direction. An example is a class of craft known as a ROV (Remotely Operated Vehicle); particularly employed as a camera and manipulator platform, but also performing many specialist mining and exploration tasks. These craft use a number of ducted propeller units acting in various directions to permit multi axis thrust.
This approach has several limitations. True 6 axis control from fixed thrusters requires a minimum of 6 thrust vectors in a generally inconvenient arrangement. Thrusters not aligned such that they can assist in the current craft movement cause drag. Having to combine various thrust vectors is inefficient compared with a single properly aligned vector. Any rotating shaft has a seal issue. Props can ingest weeds etc. and foul; or grating covers can become clogged. Ducted props tend to move a small volume of water quickly, rather than a large volume slowly; they are thus more suited to high speed low drag motion rather than generating low speed lifting power. Without complex additional pitch control, props optimised for force will be limited in velocity and vice versa. Rotational inertia in the prop and motor limit the rate at which direction can be reversed. Props cause turbulence which can disturb a silt bed or offer an unwelcome acoustic footprint. Recently there has been a resurgence of interest in a propulsion system known as a Voight Schneider drive. This was first developed in Germany in the 1930's for use on tug boats. It is able to generate thrust in a two axis vector; but is difficult to seal, has limited efficiency and is prone to fouling. Summary of the invention:
This invention proposes to replace propeller based thrusters with an arrangement of powered fins. Three different concepts are described.
In the first the fins describe a conical (or fructoconical) surface as they orbit around a central drive axis. Thrust is generated by turning the fins on their own axis such that they act as blades with a variable pitch angle; and timed to focus the thrust in a particular vector. Each fin can thereby generate variable thrust in two axes with a sinusoidal swim action. Various arrangements and drive methods are proposed. Four of such fin units arranged in a cross can provide synchronous six degrees of motion with balanced thrust reaction forces. The minimum arrangement for 6 axis control is 3 fins arranged as a "Y" in a common plane.
In the second the fins are permitted to oscillate more freely around a pivot point with separate power of each of the two tilt axes and fin rotation. In the third a particular solution to fin propulsion is proposed which minimises the cyclical accelerations as the fins oscillate about their own axes. Propulsion with fins can be up to around 80% efficient, compared to 50% for a good propeller thruster. An oscillating fin can have an elastomeric joint cover over it's pivot point rather than needing a rotating seal; as such it is taking a lesson from nature where there isn't a single example of a continuously rotating shaft. A minimum of 50% and a maximum of 100% of available thrust can be applied to any vector or rotation. A long fin can move a large water mass slowly, providing good lift leverage; it does so without compromising it's ability to propel the craft quickly by adjusting fin pitch control. Fins resting in the move plane cause minimal drag. A non rotating fin cannot foul. Turbulence is minimised and acoustic patterns can be avoided. Fins have less inertia and can change their motion and hence thrust vector very quickly; this makes them very responsive and enables the tight positional control needed in closed loop robotic applications. Description:
Fig 1 shows the functional schematic of the Voight Schneider drive. As the blades rotate (shown as a progression of plan views) they are caused to tilt first one way and then the other. Overall the blade rotates at the same rate as the boss.
Several new drive concepts are particularly proposed by this invention.
In the first the fin describes a conical surface by moving it's tip in a continuous largely circular pattern, achieving thrust vector control by the timing of the fin's rotation about it's own axis as shown in Fig 2. Note that the fin now oscillates about a fixed reference rather than rotating with the boss.
This particularly lends itself to a mechanical arrangement where most of the work is done by the conical movement of the fin axis and a swashplate like system acts to effect the rotation about the fin axis. Two servo controls can then be employed both to rotate this reference plane to change the thrust angle and to change the fin pitch oscillation extent about the fin axis to vary the thrust. Reaction forces resulting from moving the fins are balanced by synchronising the 4 fin actions into diagonally opposite contra-rotating pairs where the fin placement largely describes an X.
The first concept will be described with reference to a particular embodiment as shown in Fig 5. It is a low cost solution which does not require closed loop control as synchronisation occurs by direct mechanical coupling of all four fins.
A single motor acts through a reduction gearbox (F5.1) and bevel gears (F5.2) to cause the rotation of four orthogonal shafts in a common plane, with contra-rotating opposites.
Each drive shaft (F5.3) holds the fin axis (F5.4) at an angular offset, in this case 22.5 degrees. The fin can freely rotate about it's axis, being retained in suitable bearings. The rotating drive shaft causes the fin to describe a conical surface. A long lead multi start non-recirculating ballscrew (F5.5) is used such that varying the axial displacement of the nut part causes the fin to rotate about it's axis. The nut part (F5.6) is prevented from rotating by a bar running in a slot through it's body (F5.7). The slot is long enough to permit both tilt and axial displacement. The bar retains it's reference angle by virtue of a timing belt connecting it to a principally non rotating reference tube acting around the main drive shaft (F5.8). As the drive shaft rotates, the rotation of the nut is constrained by the timing belt causing motion like a planet orbiting a sun where each day is equal to each year. Without further action, the fin will not rotate about it's own axis as it describes the conical surface; the fin plane angle defining the thrust angle. The plane can be rotated by rotating the reference tube which acts through the timing belt to cause an offset about the nut (and hence fin) axis.
Constraining the fin can be achieved in two other ways. Instead of using a timing belt scheme, gears can be employed. In this embodiment idler gears act between the non rotating gear on the reference tube and the gear circumscribing the constraint bar such as to reverse its direction of rotation. Also rotation constraint can be achieved by including a pivot element and keyway between a ball on the fin shaft and a radially adjustable annular socket at the fins pivot point (or radially controlled gimbal). The radial control of the constraint reference becomes part of the thrust angle control.
The bar constraining the nut can be replaced by other means able to permit two axis tilt and axial displacement but constrain rotation, such as a gimbal (or constrained ball and socket) keyed to move in the nut axis but not around it.
The end of the nut features a ball which is retained in a cylindrical pocket in a swash plate system (F5.9). The pocket permits ball rotation about the nut axis, rotation in the plane described by the drive shaft and fin axis and some displacement along the pocket axis, but crucially not along the nut axis. The swash plate system consists of a means to displace a radially offset forcing element (F5.10) axially along the drive shaft. This forcing element is linked to a pivot acting about the reference tube (F5.11) such that displacing it causes the pivot to tilt. A bearing then acts in the tilt plane, in turn connected to the swash plate pocket (F5.9) such that it can rotate freely about the drive shaft but at the prescribed tilt angle. Without tilting the swash plate system, the drive shaft causes the ball at the end of the nut to describe a circular path. When tilted, this path becomes parabolic (as a section through a cone), forcing the nut to be displaced along the fin axis as it rides from peak to trough. This displacement of nut against screw shaft then forces the rotation of the fin about it's axis such that in each revolution of the drive shaft, the fin rotates first one way and then the other. Increasing the swash tilt extends the displacement and hence fin rotation. This has the effect of varying the fin's pitch oscillation angle and hence thrust in the water. The reference tube can be rotated by a rack acting against a spur gear around the tube (F5.13). The swash forcing element being connected to a pivot on the reference tube similarly rotates, however a further rack and pinion (F5.12) causing the axial displacement of the forcing element can be rotationally constrained by isolating it from the reference tube with a radial bearing. Two servos can then be readily connected to effect both the rotation of the reference tube (defining the thrust vector) and tilting of the swash plate (defining the thrust extent).
An elastomeric "boot' connects the fin to the crafts body shell (F5.14), such that it provides a hermetic pressure proof seal. In this embodiment, the boot must permit about 22.5 degrees of tilt and +- 135 degrees of rotation (+-
90 degrees of thrust angle, +- 45 degrees of radial oscillation). To assist in the progressive take up of the boot twist, the boot bearing part of the fin shaft can have an enveloping linear array of short tubular spacers or washers (F5.15). These can rotate with the boot, distributing the shear forces along the available length. A further layer of very soft elastomer can then also be employed between the washers and main boot skin, improving the averaging of shear forces.
Whereas the above mechanism features radial ball bearings to mitigate friction, a low cost variant could be readily produced from injection moulded thermoplastic parts with a suitably low coefficient of friction. Small 'model aircraft' type servos can be employed to effect the thrust vector control. The single motor has no seal issues and can be a low cost DC unit.
In the second embodiment the fin can pivot in a plane, rather than describing a conical surface. A direct means is then employed to effect the synchronised oscillatory rotation about the fin axis. A servo can then also rotate the pivot plane to alter the thrust angle and again adjusting fin pitch oscillation varies the thrust.
The fins need not be mechanically coupled, permitting their placement where most convenient for the craft. Rather than use multiple geared electric motors, a particularly suitable drive system is hydraulic. This lends itself to distributed high power densities operating at relatively low speeds. Also a hydraulic system will work fine at any ambient pressure, employing as it does pressure difference rather than net pressure to transmit it's power. This means that it is possible to design each fin unit as a hermetically sealed but not pressure proofed part, simplifying it's design and improving the performance of the boot (by fluid filling it). The motor that drives the pump could also be fluid filled to balance shaft seal pressure, or a magnetic 'through bulkhead' coupling could be employed - thereby leaving the motor (and control electronics) in a dry space. In all hydraulic applications it may be convenient to assemble a central pilot valve set providing the synchronised proportional control and then locating the high flow rate valves at the motor / cylinder location. This approach also avoids any need for electrical connections at the fin assemblies. Instead of radial motors to effect the necessary rotations, axial hydraulic cylinders can be employed acting as a push rod against a crank. A good compromise can be utilising one or more cylinders for powering the fin tilt (whether one or two axis) and radial motors for fin pitch adjustment (and thrust angle control in a single axis tilt system).
Each fin needs three motors. The main 'power' motor causes the basic planar oscillation of the fin about a pivot axis. Another motor rotates the pivot axis thereby effecting thrust angle control. The third motor rotates the fin about it's axis to create the sinusoidal swim action. Each axis needs closed loop positional control or a means to effect synchronisation between the fins to balance the reaction forces. A craft which utilises such a drive system is shown in Fig 6.
Improved efficiency can be achieved if the fin oscillation was effected by a two tilt axes system, with a third radial axis for the fin pitch control. In this embodiment thrust vectoring occurs by establishing the best possible thrust plane (like a joystick being able to oscillate anywhere within the confines of it's limiting bumper). The thrust plane can then not only rotate (as in the previous embodiment) but can also be set at a tilt offset.
A further advantage occurs as the thrust angle can in effect continuously rotate because two tilt axes do not introduce any twist into the protective cover. In the previous embodiment the thrust angle is confined within twist limits resulting in a possible situation where the angle needs to be 'unwound'
180 degrees before further rotation can be achieved.
In all cases it is necessary to synchronise the fin action to balance the reaction forces. Where not directly mechanically or fluidically coupled, synchronisation can occur by explicit positional encoding and suitable data processing. Relative fin thrust can then be controlled both by fin pitch oscillation rate and tilt extent.
Other arrangements are possible where multiple fins notionally share a common axis point. In one such case as shown in Fig 7 two fins are connected to a rotatable boss, in such a way that the fins can also be independently rotated about their own axis. Such units are able to generate 3 axis thrust vectors, x,y and torque in the boss axis; acting functionally like two independent fins. They are powered by a common high power motor rotating the boss and have smaller motors or other limited angle actuators controlling each fin axis. A further style of fin propulsion has a different swim drive concept.
Instead of the fins acting in a sinusoidal way, they act more directly as paddles as shown in concept in Fig 3 and in use on a craft in Fig 8. The charm of this variant is the ability to mechanically drive the fin axis from the boss rotation at constant angular velocity; thereby permitting the system to be run at high speeds (rather than where the fins have to accelerate back and forwards as they oscillate).
The arrangement lends itself to multiple blades to balance reaction forces; apart from torque which is balanced by multiple units.
The secret of the ability to generate thrust with constant rotation in the blade axis is that the blades rotate at half the speed of the boss - in the same direction. If they otherwise rotate with the boss, then relative to the boss they are rotated backwards at half the boss speed.
The result is a situation that when thrusting downwards, at the top of their orbit their orientation is such as to ingest the water, down one side they are then acting like a paddle with the blade face on to it's movement vector, at the bottom of their orbit they act such as to expel the water, and on the upward return they are substantially edge on to their movement vector (causing minimum drag). The composite effect is an efficient 'underwater paddle wheel' with minimal vortex turbulence and efficient compounding of the overall thrust vector.
Three or some greater odd number is appropriate as a blade number, serving to reduce thrust and torque ripple.
Such drives effect thrust extent by the speed at which they are driven.
They thus require their own individual motors (or variable gearboxes). Because torque cannot be separately controlled to thrust (unlike fins with oscillating axes) they can only be two axis. All the blades are mechanically coupled and cannot normally be independently varied.
Changing the thrust vector occurs as the reference to the blade rotation is advanced or retarded. This is accomplished by enabling a servo control to rotate the otherwise static reference gear around which the gears effecting the blade axes orbit. Synchronisity at 1 : 2 rotation speeds is then re-established, but now with the thrust at a new vector. The change only effects rotation about the blade axes (not a change in speed of the boss) and can thus be accomplished quite quickly. Because this embodiment is 2 axis only, there is no intrinsic need to arrange the blades such that they describe a cone. They can be arranged with parallel axes, separated by a larger boss diameter.
A suitable method is shown in Fig 9. It features a hollow drive shaft
(F9.1) on the power motor, directly or via reduction gearing rotating the blade mounting boss (F9.2). A shaft (F9.3) connects the vectoring servo through the hollow drive shaft to a gear at the centre of an upper gear set (F9.4).
Intermediate gears (F9.5) held by the boss then orbit this reference gear. The blades also have individual gears (F9.6) each driven from the intermediate gears. The use of intermediate gears has the effect of reversing the direction of rotation. The reference gear must have half the tooth number of the blade gear, such that the rotation speed of the blade gear becomes half that of the boss.
When the servo (F9.7) rotates the reference gear, it can now be seen to have the effect of advancing or retarding the blade rotation, without otherwise effecting their orbit. Another method employs belt rather than gear coupling. This has the advantage of not requiring intermediate gears to reverse the rotation, as belt drives do this anyway.
The different swim methods need not be mutually exclusive. For example a 2 fin module with independent fin axis control could be run in the 1 : 2 synchronous mode if the axis servos are able to rotate continuously as a motor.
Also as shown in Fig 4, A system with independent fin control can cause overall water ingestion by reversing part of the tilt direction. Where the fins are otherwise describing a cone, this results in exhaust thrusting out of the open cone end principally along it's axis. This effect can be employed to increase thrust in that vector.
Any of the embodiments using two or more fins or blades rotating from a common boss can benefit from a hoop which connects the fin tips such that the fins or blades can still rotate about their own axes (as shown in Fig 7 and
Fig 8). This has the benefit of stabilising the fins against bending moments, and also acts as a guard to mitigate the effect of a fin striking an obstruction.
Control System: A solution to the requirement of 6 axis control from a number of fins will be described with particular reference to a craft with 4 opposing fins rotating at a common speed.
In order to smoothly vary the fin thrust vectors in response to a six axis movement command, a vector summation strategy needs to be employed. With reference to Fig 10 the fins can be considered as split into two pairs. Fin
1 and Fin 3 are capable of generating thrust in the xz plane (y normal) and Fin
2 and Fin 4 generate thrust in the yz plane (x normal). All 4 fins combine to generate thrust in the xy plane (z normal). Each fin is capable of creating a thrust vector of variable magnitude at any angle within it's plane. Given a six axis thrust vector with a Cartesian component of C and a rotational component of R the thrust vectors of each of the four fins (F1...F4) can be calculated as follows:
Flx = 1/2 Cx + 1/2 Ra F3X - 1/2 Cx - 1/2 Ra Fly = 0 F3y = 0 Fl; 1/4 Cz + 1/4 Re F3Z = 1/4 Cz - 1/4 Re
F2X = 0 F4X = 0
F2y = 1/2 Cy + 1/2 Rb F4y = 1/2 Cy - 1/2 Rb F2Z = 1/4 Cz + 1/4 Re F4Z = 1/4 Cz - 1/4 Re
Such that C = F1+F2+F3+F4, and R = (F1-F3) + (F2-F4) The units of C and R represent the maximum manoeuvring speed and are determined experimentally. The guidance system knows it has to live within these limits.
The thrust angle and pitch rates for each fin can be calculated from each fins required thrust vector. The required pitch rate to achieve a given thrust can again be determined experimentally and implemented as a look up table. If the craft has a high speed through the water relative to it's fin rate, the pitch can be optimised to the true incidence vector of the oncoming water
(reducing pitch as speed increases). This is like a variable pitch propeller where pitch is lengthened for high water speeds; the object being to maintain an optimum work rate without increasing the rpm - or in this case flap rate. All the above thrust vector control can occur at a constant flap rate; however controlling the flap rate can avoid needless 'running on the spot' power consumption. If the guidance system has little requirement for craft movement in the current time period, then the flap rate can be minimised. Equally if the craft has to work hard (through load, drag or acceleration) the flap rate can be maximised for the available motor power. Control of flap rate can also be employed to reduce / increase the crafts command responsiveness; if for example conditions dictate a stealthy approach, or alternately high speed manoeuvring or variable load compensation is required.
This control system works best in the context of a computer controlled guidance system providing craft movement and positional feedback, such that the control loop can be closed. The user need merely establish the required final position or movement vector and the craft will then manage it's own implementation by setting the appropriate flap rate and individual fin thrust vectors. This is particularly useful as drag from the umbilical or prevailing current conditions can then be automatically compensated for.
In the mechanically synchronised embodiment all fins must flap at the same rate and to the same angular extent. This can result in some reaction force imbalance where for example a fin is not required to produce a thrust vector; because that fin will generate a higher reaction force that a fin pitching through an angle.
Where the system permits individual control of the extent of the flap angle (as in the hydraulic embodiments), a more complete balancing of the reaction forces is possible.
Where fins are connected in pairs to a common rotating boss, the same control concept applies; now requiring at least two, 2 fin modules. From a control perspective the fins can be considered independent.
The arrangement differs in vector summation when three, 2 axis modules are employed (like the constant angular blade rotation design).
Torque is not balanced with an equal and opposite symmetry as in a 4 fin system, but by adjusting the overall direction thrust of each module to create a torque about their common axis point.

Claims

Claims:
1. A submarine propulsion system utilising 4 fins, each able to oscillate about individual pivot points with variable control of fin pitch and angle.
2. A system as in Claim 1 where fin pitch is varied such that the fin plane describes a substantially sinusoidal path through the water when the craft is in forward motion.
3. A system as in Claim 2 where the fins are arranged such that their thrust vectors can act over at least 2 substantially orthogonal planes.
4. A system as in Claim 3 where the fins act as two opposite pairs such that each pair balances radial reaction forces and the two pairs balance Cartesian reaction forces.
5. A system as in Claim 4 where fin movement describes a cone rather than a planar oscillation such that variable thrust vectoring occurs through the timing of the fin pitch as the fin axis describes the conical surface.
6. A system as in Claim 5 where fin pitch timing is effected by a pivoting swash plate able to act through a screw form to translate variable fin axis displacement into pitch variation about the fin axis.
7. A system as in Claim 5 where the fin is prevented from rotating about it's axis without additional cause by a timing belt referenced to a non rotating member or by gears acting through an idler gear again referenced to a non rotating member or by a feature extending from or into the pivot focus which prevents rotation in the fin axis while still permitting two axis tilt.
8. A system as in Claim 4 where the fins are oscillated by hydraulic or electrical power, with additional rotary axes before the oscillation to change thrust angle and after the oscillation to change thrust pitch.
9. A system as in Claim 4 where the fins are able to tilt in two powered axes with an additional axis to change thrust pitch.
10. A system as in Claim 8 and Claim 9 where servo control of a hydraulic embodiment is implemented with a pilot master radial axis driving the power stage slave such that the slave always tracks the position of the master being suitably mechanically coupled.
1 1. A system as in any of the preceding claims where total Cartesian thrust is the sum of the individual fin members and total rotational thrust is the sum of the difference of opposite fin pairs.
12. A system as in any of the preceding claims where an even number of fins greater than 4 are employed such that both Cartesian and rotational reaction forces are balanced.
13. A system as in any of the preceding claims where an elastomeric protective cover about the fin pivot point isolates the fin powering mechanism from the surrounding water while permitting fin tilt and pitch rotation without any sliding seal parts.
14. A system as in Claim 13 where shear stresses caused by the axial rotation of the fin pivot cover are distributed evenly over the available length by a number of cylindrical elements able to individually rotate about the fin axis.
15. A system as in Claim 13 where the fin pivot protective cover is backed up with a very soft elastomer better able to further distribute shear stresses evenly.
16. A system as in Claim 13 where the fin pivot protective cover is filled with a non compressible fluid to prevent the cover pressing against the fin shaft when under external ambient pressure.
17. A 2 axis marine propulsion system where one or more fins are rotationally held in a boss and connected such that as the boss rotates, the fins rotate at half the boss rotation speed - at a common direction with a common reference.
18. A system as in Claim 17 where the fin axes are coupled to a rotational reference by gear or belt such that boss rotation with respect to the reference causes the complimentary rotation of the fins about their axes.
19. A system as in Claim 18 where a drive motor, pulley or gear otherwise rotating the boss has a hollow axis enabling the rotational reference to be connected to a radial servo behind it, such that the servo can advance or retard the reference; thereby changing the drive thrust vector without effecting the boss rotation.
20. A multi axis marine propulsion system substantially as in Claims 1 to 5 where the fins are arranged as two pairs, each pair rotationally connected to a common boss, such that the boss rotation causes the fin sweep; but each fin has independent control of rotation about it's own axis.
21. A system as in Claim 20 where the two fin axes are coupled such they react in an equal and opposite way, being now controlled from a single servo.
22. A system as in Claim 21 where a mechanical coupling system directly causes the fins axial oscillation, with a servo now only employed to change the reference position.
23. A system as in Claim 17 and Claim 20 where the ends of the fins are rotationally connected to a hoop, such that they may still rotate about their own axis while the hoop rotates with the boss.
24. A 6 axis submarine propulsion system utilizing 4 fins, each able to oscillate about individual pivot points with variable control of fin pitch and angle.
Claims:
1. A 2 axis marine propulsion system where one or more fins are rotationally held in a boss such that the fin axis is displaced from the boss axis; and connected such that as the boss rotates, the fins rotate at half the boss rotation speed in a common direction.
2. A system as in Claim 1 where the fin axes are coupled to a rotational reference by gear or belt such that boss rotation with respect to the reference causes the complimentary rotation of the fins about their axes. 3. A system as in Claim 2 where a drive motor, pulley or gear otherwise rotating the boss has a hollow axis enabling the rotational reference to be accessed behind it, and such that the rotational reference can then be rotated to change the thrust vector.
4. A system as in Claim 2 where the rotational reference has a drive tube which allows the boss to be driven by a drive shaft running through it, and such that the rotational reference can then be rotated to change the thrust vector.
5. A system as in Claim 2 where the fins are connected at their end by a disc or a ring such that they are still able to rotate independently about their own axes.
6. A system as in Claim 2 where the fins terminate in orthogonal end discs which are countersunk with clearance into the boss.
7. A system as in Claim 2 where water trapped between the underside of the boss and the craft is caused to rotate and be centrifugally ejected by virtue of protruding features on the boss, in the manner of a centrifugal pump.
8. A system as in any of the preceding claims where three or more of such marine drive units are arranged such that the planes in which their drive vectors act are substantially symetrically uncommon thereby able to generate combined force or torque in all six degrees of freedom.
9. A 6 axis submarine propulsion system utilizing 4 fins, each able to oscillate about individual pivot points with variable control of fin pitch and angle.
10. A system as in Claim 9 where fin pitch is varied such that the fin plane describes a substantially sinusoidal path through the water when the craft is in forward motion.
11. A system as in Claim 10 where the fins are arranged such that their thrust vectors can act over at least 2 substantially orthogonal planes.
12. A system as in Claim 11 where the fins act as two opposite pairs such that each pair balances radial reaction forces and the two pairs balance
Cartesian reaction forces.
13. A system as in Claim 12 where fin movement describes a cone rather than a planar oscillation such that variable thrust vectoring occurs through the timing of the fin pitch as the fin axis describes the conical surface. 14. A system as in Claim 13 where fin pitch timing is effected by a pivoting swash plate able to act through a screw form to translate variable displacement along the fin axis into pitch variation about the fin axis.
15. A system as in Claim 13 where fin rotation is constrained by a timing belt referenced to a non rotating pulley or by gears acting through an idler gear referenced to a non rotating gear or by a feature extending from or into the pivot focus which prevents rotation in the fin axis while still permitting two axis tilt.
16. A system as in Claim 12 where the fins are oscillated by hydraulic or electrical power, with additional rotary axes before the oscillation to change thrust angle and after the oscillation to change thrust pitch.
17. A system as in Claim 12 where the fins are able to tilt in two powered axes with an additional axis to change thrust pitch.
18. A system as in Claim 16 and Claim 17 where servo control of a hydraulic embodiment is implemented with a pilot master radial axis driving the power stage slave such that the slave always tracks the position of the master being suitably mechanically coupled.
19. A system as in Claim 12 where total Cartesian thrust is the sum of the individual fin members and total rotational thrust is the sum of the difference of opposite fin pairs.
20. A system as in Claim 19 where an even number of fins greater than 4 are employed such that both Cartesian and rotational reaction forces are balanced.
21. A system as in any of the preceding claims where an elastomeric protective cover about the fin pivot point isolates the fin powering mechanism from the surrounding water while permitting fin tilt and pitch rotation without any sliding seal parts.
22. A system as in Claim 21 where shear stresses caused by the axial rotation of the fin pivot cover are distributed evenly over the available length by a number of cylindrical elements able to individually rotate about the fin axis.
23. A system as in Claim 21 where the fin pivot protective cover is backed up with a very soft elastomer better able to further distribute shear stresses evenly. 24. A system as in Claim 21 where the fin pivot protective cover is filled with a non compressible fluid to prevent the cover pressing against the fin shaft when under external ambient pressure.
25. A multi axis marine propulsion system substantially as in Claims 9 to 13 where the fins are arranged as two pairs, each pair rotationally connected to a common boss, such that the boss rotation causes the fin sweep; but each fin has independent control of rotation about it's own axis.
26. A system as in Claim 25 where the two fin axes are coupled such they react in an equal and opposite way, being now controlled from a single servo.
27. A system as in Claim 25 where a mechanical coupling system directly causes the fins axial oscillation, with a servo now only employed to change the reference position.
28. A principally personal powered water craft with a low curvature underside planning hull form for above surface use and able to submerge below the water and otherwise achieve operational control utilizing foot control of two independent single axis forward mounted hydroplanes and independent arm control of two, single or more axis rear mounted hydroplanes.
29. A craft as in Claim 28. where the rear mounted propulsive thrust is vectored in two tilt axes such as to compliment the reaction vector of the forward hydroplanes for enhanced control effect, by virtue of direct mechanical or hydraulic coupling between the vectoring nozzle and hydroplanes.
30. A marine propulsion system where thrust vectoring occurs when a substantially spherical duct with exhaust nozzle, otherwise retained in an annular socket, tracks with two degrees of freedom around a propeller, the propeller having a conforming spherical surface of revolution to maintain a small clearance to the duct and the constrained third axis being normal to the plane of the socket.
31. A system as in Claim 30 where two control coupling points for push / pull action or 3 or more control coupling points for pull / release action are located on the outer side of the duct, each connected through a two axis linkage to the control effect mechanism.
32. A system as in Claim 30 where the control effect mechanism is a push / pull rod linking the thrust vectoring with forward controls.
33. A system as in Claim 30 where the exhaust nozzle features inward facing stator blades which act to unwind the exhaust vortex and control flow direction.
34. A marine propeller which has a large starting core diameter from which the blades extend progressively in diameter moving along the axis, as also the core diameter reduces. Similarly the blade pitch lengthens by a minimum of 50% as the diameter increases. The propellers length is sufficient to accommodate at least 270 degrees of blade spiral. The trailing edge of the blades undercut the tips and blend back into the reducing hub.
35. A propeller as in Claim 34 where the surface of revolution turns into a sphere able to be deployed in a thrust vectoring system as in 3.
36. A craft as in Claim 28 where the feet act against a two axis tilt pad and where two push / pull couplings or 3 or more pull / release couplings on the pad are offset from the pivot point such that they are effected by both forward / back tilting of the pad and left / right tilting of the pad; such couplings then directly effecting the axial rotation of the forward hydroplanes such that forward / back tilting effects both hydroplanes in mirror image and left / right tilting effects both hydroplanes in opposites.
37. A craft as in Claim 28 where left and right pivoting pedals each operate separate hydroplanes such the hydroplanes rotate in the same direction as the pedals.
38. A craft as in Claim 36 or Claim 37 where hydroplane rotation is coupled to the thrust vectoring as in 2.
39. A craft as in Claim 36 or 37 where the separate hydroplane pivot axes are translated by universal or flexural joints to a common axis and where respective torsion members from each hydroplane coupling can rotate about each other, and that an extension from the inner torsion member can protrude through a radial clearance on the outer without preventing limited independent rotation of either; such that control attachments to both the extension and the outer torsion member can each cause the rotation of the opposite (not adjacent) hydroplane.
40. A craft as in Claim 39 where the control attachments incorporate a means to effect push pull actions in further thrust vectoring control rods.
41. A craft as in Claim 28 where rear two axis hydroplanes are controlled directly by arm location and hand holds and with two axis pivots located adjacent to the users shoulder and with the constrained axis being substantially normal to the plane of the water.
42. A craft as in Claim 41 where the pivot point is behind the users shoulder and the two pivot axes are substantially orthogonal and offset from the craft axis.
43. A craft as in Claim 41 except instead of a two axis pivot, the axes are distributed as two single axis pivots, arranged to emulate first shoulder and then elbow.
44. A craft as in Claim 29 except that the rear hydroplanes directly connect to the thrust vectoring (instead of the forward hydroplanes) in synchronous such that they both generate complimentary reaction forces.
45. A craft as in Claim 28 where the nose form consists of two vertically displaced prows with a concave linking scallop and an upper recess incorporating seat, back and head rest, substantially able to support the reclined form of the user.
46. An underwater breathing system where an air tight cushion or bladder can be used as a reserve of air, said reserve having at least one expandable side and containing an elastomeric open cell foam core able to expand it against a small load; the internal volume being connected both to a fresh air source which automatically closes on water immersion and a one way flow means of air delivery to the user.
47. A system as in Claim 46 where the bladder is expanded by air pressure, mechanical or other elastomeric means.
48. A craft as in Claim 28 where a substantially spherical visor can be deployed from a fixed head rest rotating into position from a pivot axis behind the users neck, said pivot holding firmly against inward loading, but permitting outward dislocation beyond a modest force threshold.
49. A multi axis marine propulsion system, comprising one or more fins mounted for rotation on rotatable means, wherein a rotational axis of the or each fin is displaced laterally from the rotational axis of the rotational means, and wherein coupling therebetween is such as to rotate the fins at a reduced rotational speed of substantially one half the rotational speed of the rotational means.
50. A submersible craft for accommodating a single person, the craft comprising a hull having two interchangeable hemi ellipsoidal parts together defining a personal carrying space therein.
51. A small pressure lock comprising of a bell jar like internal form with a fructo conical flange which is slid into position over a conforming mounting tube leading to the outer opening with seal rings between the interface; and then retained by a collar bearing down around the flange such that once the collar is fixed, increasing pressure otherwise trying to blow out the bell jar like a piston also causes the bell jar to be compressed around its open annulus by the conical flange part so as to retain seal pressure to the mounting tube.
52. A marine specimen containment system comprising of two shells designed to clip together with a watertight seal that are deployed with their open side inward facing in a holding device, otherwise able to couple the two shells by bringing them together, and then release the now closed specimen container.
53. A hull for a personal submersible craft comprising of substantially two hemi ellipsoids, where entry is gained by opening the craft at the common tangent interface between them.
54. A personal water craft for use with a person lying lengthwise of the craft to plane on or submerge below the surface of a mass of water at will, the craft comprising a hull for receiving a person thereon, the hull including a low curvature planning underside, a plurality of independent control means, each operable by the legs or arms of the said person, respectively, for controlling the direction and use of the craft, and power means for driving the craft on or through the water.
55. A marine propulsion system where thrust vectoring occurs when a substantially spherical duct with exhaust nozzle, otherwise retained in an annular socket, tracks with two degrees of freedom around a propeller, the propeller having a conforming spherical surface of revolution to maintain a small clearance to the duct and the constrained third axis being normal to the plane of the socket.
56. A marine propeller which has a large starting core diameter from which the blades extend progressively in diameter moving along the axis, as also the core diameter reduces. Similarly the blade pitch lengthens by a minimum of 50% as the diameter increases. The propellers length is sufficient to accommodate at least 270 degrees of blade spiral. The trailing edge of the blades undercut the tips and blend back into the reducing hub.
57. A principally personal powered water craft with a low curvature underside planning hull form for above surface use and able to submerge below the water and otherwise achieve operational control utilising foot control of two independent single axis forward mounted hydroplanes and independent arm control of two. single or more axis rear mounted hydroplanes.
58. A submarine propulsion system utilising 4 fins, each able to oscillate about individual pivot points with variable control of fin pitch and angle.
59. A 2 axis marine propulsion system where one or more fins are rotationally held in a boss and connected such that as the boss rotates, the fins rotate at half the boss rotation speed - at a common direction with a common reference.
PCT/GB1999/002139 1998-07-03 1999-07-05 Multi axis marine propulsion system WO2000001575A2 (en)

Applications Claiming Priority (6)

Application Number Priority Date Filing Date Title
GB9814490.0 1998-07-03
GB9814489.2 1998-07-03
GBGB9814489.2A GB9814489D0 (en) 1998-07-03 1998-07-03 Personal submarine
GBGB9814490.0A GB9814490D0 (en) 1998-07-03 1998-07-03 Personal hybrid submersible craft
GB9814491.8 1998-07-03
GBGB9814491.8A GB9814491D0 (en) 1998-07-03 1998-07-03 Multi axis marine propulsion systems

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WO2000001575A2 true WO2000001575A2 (en) 2000-01-13
WO2000001575A3 WO2000001575A3 (en) 2000-03-09

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113382920A (en) * 2018-12-14 2021-09-10 Abb 有限公司 Propulsion unit for cycloidal ship and ship equipped with same
CN113382920B (en) * 2018-12-14 2024-04-16 Abb瑞士股份有限公司 Cycloidal marine propulsion unit and marine vessel equipped with same
US11999459B2 (en) 2018-12-14 2024-06-04 Abb Oy Cycloidal marine propulsion unit and a marine vessel equipped therewith

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