AU740692B2 - Nautical balance system - Google Patents

Description

(*y 2 nd Copy

AUSTRALIA

Patents Act 1990 STANDARD PATENT

K..

IN THE COMPLETE SPECIFICATION

OF

MARIO TALASIMOV FOR A NAUTICAL BALANCE SYSTEM The following statement is a full description of this invention, including the best method of performing it known to me: NAUTICAL BALANCE SYSTEM BACKGROUND OF THE INVENTION 1. FIELD OF THE INVENTION The present invention relates to a balance system for installation on small sailboats which improves the ability of a helmsman to counter the heeling force of the wind on the sails.

More particularly, the system enables the helmsman to easily use his weight to limit the heel of the sailboat.

DESCRIPTION OF THE RELATED ART 15 It has long been recognized that the position of the weight of the crew is critical to the performance of small sailboats.

For sailboats that are double or single handed, the position of the weight of the helmsman is also important. On such small boats, the weight of the crew and helmsman is the major force used to counter the heeling force of the wind on the sails.

Thus, devices that assist the helmsman or crew in shifting and maintaining body weight near or beyond the sides of the boat enable the boat to be sailed upright and efficiently level.

One such a device is disclosed in the U.S. Patent No.

2,238,464 issued April 15, 1941, to W.G. Fletcher. Fletcher discloses a convertible sailing vessel including a swinging arm.

The swinging arm is pivotally supported by a main frame at a single location. The arm permits a crew member, but not the helmsman, to use body weight to balance the vessel.

U.S. Patent No. 4,539,926, issued September 10, 1985, to J.

Boffer, discloses a sailboat having an outrigger which is supported solely by a sleeve which encircles the foot of the mast. The helmsman is supported on a seat on the outrigger. A relatively high cut sail is attached to the mast to allow the helmsman to pass under the sail when tacking.

U.S. Patent No. 4,852,507, issued August i, 1989, to R.C.

Ryon et al., discloses a sail craft including a semicircular seat, foot rail and back stop used by a helmsman in maneuvering his body as a counterweight.

U.S. Patent No. 4,936,236, issued June 26, 1990, to F.W.

15 Sinden, discloses a moment balancing rig for a sailboat. The rotatable rig includes a boom for supporting the helmsman. The

*O.

.*boom is attached to a mast that is in turn attached to the hull of the boat.

U.S. Patent No. 4,986,202, issued January 22, 1991, to P.

Mourgne et al. and British Patent Application No. 2195297 published April 7, 1988, show a fixed transverse rail extending between lateral hulls of a trimaran. A seat slides along the rail to permit crew members to counterbalance the boat.

French Application No. 79 11824 discloses a catamaran including a saddle permitting a helmsman seated in the saddle to balance the boat by pivoting the saddle. The saddle is mounted on a short arm that requires insignificant support.

None of the above inventions and patents, taken either singularly or in combination, is seen to describe the instant invention as claimed. Thus, a nautical balance system solving the concerns encountered when attempting to counterbalance the heel of a small saiboat is desired.

SUMMARY OF THE INVENTION When sailing a small sailboat, particularly upwind, it is desirable for a helmsman to hike his body weight as far as possible beyond the windward rail to counter the heeling force of the wind on the sails. The present nautical balance system is a device that assists the helmsman in moving his body weight to counteract this heeling force. The system also assists the helmsman in maintaining his body weight beyond the windward rail for extended periods of time as the boat is sailed upwind.

The nautical balance system includes an outrigger that supports the helmsman. The outrigger pivots about a bearing on the centerline of the boat. The outrigger is supported by the pivot bearing and by a semicircular rail assembly fastened to the deck of the sailboat. The outrigger is slidably supported by the rail assembly as the outrigger pivots about the bearing.

Rollers are included to promote the movement of the outrigger along the rail.

The additional support of the rail assembly limits the force borne by the pivot bearing and the deck supporting the bearing.

The outrigger includes a seat for the helmsman. When seated on the outrigger the helmsman is able to stabilize himself and the outrigger by placing his feet on the rail assembly. The helmsman also controls the angular position of the outrigger with his feet placed on the rail assembly. To ensure that the helmsman can manipulate and stabilize himself the outrigger rides along a rail that is raised above the deck. The rail also extends beyond the limit of rotation of the outrigger so that the helmsman may always put both feet on the rail while straddling the outrigger. The seat is adjustable along the :.*".outrigger to fit the length of the helmsman's legs.

The pivot bearing is located in a position independent of 15 the location of the mast thereby allowing the weight of the helmsman to be located at the optimal position for performance *e.

of the sailboat. A pivot bearing located aft of the mast also permits the helmsman to swing behind the boom when tacking.

This permits the boom to be positioned relatively lower on the mast and, therefore, the sail to be larger and more efficient.

Accordingly, it is a principal object of the invention to provide a nautical balance system on a sailboat to assist a helmsman using his body weight to counterbalance the heeling force of the wind on the sails.

Is is a further object of the invention to provide a nautical balance system having an outrigger supported at multiple points for holding a helmsman over the windward rail of a sailboat with minimal stress transmitted to the deck.

Another object of the invention is to provide a rail by which the helmsman can steady himself and manipulate the position of the outrigger with his feet on the rail.

Still a further object of the invention is to provide a seat for the helmsman which swings aft of a low boom when the boat is tacked.

It is an object of the invention to provide improved elements and arrangements thereof in a nautical balance system for the purposes described which is inexpensive, dependable and fully effective in accomplishing its intended purposes.

These and other objects of the presente invention wil become readily apparent upon further review of the following O specification and drawings.

15 BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side view of a sailboat including the present nautical balance system.

Figure 2 is a plan view of the sailboat shown in Figure 1.

Figure 3 is an enlarged, partial side view of the present nautical balance system.

Figure 4 is a perspective view of the present nautical balance system.

Figure 5 is a diagrammatic view representing the forces on the present nautical balance system.

Figure 6 is a diagrammatic view representing the forces on a sailboat including the present nautical balance system.

Figure 7 is a diagrammatic view representing the righting forces on a sailboat using the presente nautical balance system.

Similar reference characters denote corresponding features consistently throughout the attached drawings.

S 10 DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The present nautical balance system 10 installed on a small sailboat is shown in Figures 1 and 2. The main structural assembly of the sailboat includes a hull 12 and a deck 14. A 15 keel or centerboard 16 and a rudder 18 are attached to the Sunderwater surface of hull 12. On the longitudinal center line of the hull 12 and deck 14 is a mast 20 that supports a boom 22 and a sail 24.

The nautical balance system 10 as shown in Figure 4 includes an outrigger 26, a pivot bearing 28, and a rail assembly Outrigger 26 is oriented primarily parallel to deck 14 and thus perpendicular to mast 20. Outrigger 26 includes a pivot end 32 and an outboard end 34. Pivot end 32 is pivotally supported by pivot bearing 28. Rail assembly 30 slidably supports outrigger 26 at a point between pivot end 32 and outboard end 34.

As shown in Figure 4, pivot bearing 28 includes a sleeve 36.

Sleeve 36 extends perpendicularly from deck 14 on the longitudinal centerline of hull 12 and deck 14. Pivot end 32 of outrigger 26 includes a perpendicular tube 38 that fits within sleeve 36. Tube 38 is free to rotate within sleeve 36 and outrigger 26 may therefore swing or rotate about pivot bearing 28.

Proximate outboard end 34 of outrigger 26 is seat 40. Seat provides means for supporting a weight, specifically the body weight of the helmsman, outboard of deck 14. Seat 40 is movably attached on outrigger 26 with bracket 42.

Rail assembly 30 is fastened to deck 14 and further supports outrigger 26. Rail assembly 30 is essentially semicircular in shape to support outrigger 26 as it rotates or swings about pivot bearing 28. The semicircular shape has a constant radius of curvature but does not necessarily extend through precisely one half of a circle. Rail assembly 30 has an upper support rail 44 and a lower connection rail 46. Upper support rail 44 is supported above deck 14 by a plurality of generally vertical rail supports 48. Rail supports 48 are connected to lower connection rail 46, wich is in turn fastened to deck 14. In the preferred embodiment upper rail 44 is supported about 4-5 inches above the deck and rail assembly 30 has a radius of about 1 foot 3- inches.

It is upper rail 44 that comes in contact with and directly supports outrigger 26. Therefore, it is the upper rail 44 that must have a constant radius of curvature and must be centered about pivot bearing 28 such that a single point along outrigger 26 contacts rail assembly 30 as outrigger swings or rotates about pivot bearing 28. As can be seen in Figure 2, lower connection rail 46 need not be precisely semicircular, but may include flattened sections 50. To provide the most effective support it is important that upper rail 44 have a large diameter. A diameter larger than the beam of the boat can be supported by lower rail 46 with flattened sections 50 that extend along the sides of deck 14.

As shown in Figure 3, outrigger 26 includes an upper roller 52 disposed above upper rail 44 to assist the outrigger 26 in sliding along upper rail 44. Outrigger 26 also includes a lower roller 54 disposed below upper rail 44. Lower roller 54 steadies outrigger 26 by ensuring that outrigger 26 is kept in continuous contact with rail assembly 30 during any motion of the sailboat that tends to raise outrigger 26. To permit both upper roller 52 and lower roller 54 to slide unobstructed along upper rail 44, rail supports 48 are attached to the inside edge of upper rail 44.

Rail assembly 30 also includes stops 56 to limit the rotation or swing of outrigger 26. Stops 56 extend above upper rail 44 to engage outrigger 26 upon reaching the point of maximum rotation. In the preferred embodiment, stops 56 are positioned to stop outrigger 26 when it has rotated 900 from the centerline of hull 12 and deck 14. The outrigger 26 in a position 900 from the centerline produces the maximun heel resisting moment by holding the weight of the helmsman the maximum distance from the center of the hull. Rail assembly 30 extends beyond stops 56 to provide a resting surface for the helmsman's foot when the outrigger 26 engages stop 56. Thus rail assembly 30 is not precisely a semicircle but extends through an arc greater than 1800, with stops 56 disposed a substantial distance from the ends of upper rail 44.

In use seat 40 is positioned such that the helmsman's legs comfortably reach rail assembly 30 when the helmsman is seated e1o 10 in seat 40. The helmsman sits in seat 40 and controls the sailboat from this position. Controls, such as the tiller and the sheets, are led to the helmsman seated in seat 40. The helmsman controls the rotation or swing of outrigger 26 with his S. feet placed on rail assembly 30. As the force of the wind heels the sailboat, the helmsman swings himself outboard on outrigger 26 thereby using his weight to counteract the heeling force.

CCC.

The outrigger 26 easily supports the weight of the helmsman as the helmsman moves his weight outboard to counter the heeling C. Sforce of the wind on the sails. The outrigger permits the helmsman to sail the boat from a steady secure position seated in seat 40 with his feet firmly placed on rail assembly 30. The helmsman can easily swing his weight inboard and outboard on outrigger 26 to maintain the most efficient sailing configuration. The helmsman weight is supported by outrigger 26 at all times permitting the helmsman to keep his weight outboard for extended periods of time.

Adjustably supporting the weight of the helmsman with nautical balance system 10 described above has a number of significant advantages. As shown in Figure 5, the use of rail assembly 30 to support outrigger 26 significantly reduces the forces transmitted to structural members of deck 14. Assuming a helmsman with a weight of 176 lbs (Wh) supported 2,7 ft (a) from rail assembly 30 and an upper rail with a radius of 1.3 ft The force F of pivot bearing 28 will can be calculated as follows: Wh(a)

F=

1761bs(2.7ft)

F=

1.3ft F=3651bs The force on rail assemby 30 at point B is: *oo F+Wh=3651bs+1761bs=5411bs This force is distributed around the deck by the rail assemby These loads can be easily supported by the structure of deck 14.

Without rail assemby 30 the deck under pivot bearing 28 must support the entire weight of outrigger 26 and the helmsman. Also the deck supporting the pivot must resist the moment of: Wh(a+b)=1761bs(2.7ft+l.3ft)=704ftlbs This moment cannot be resisted by most deck structures.

As shown in Figure 6 it is important that the pivot bearing 28 be located independently from mast 20. While sailing in a straight line, the position of the center of lateral resistance (CLR) of the hull in the water must correspond to the center effort (CE) of the wind on the sails. Due to the effect of the waves produced along the hull of a moving sailboat and the effect of the shape of the sails, the CE and CLR continuously change. To design a balanced boat, the center of the sail plan is typically placed forward of the static lateral center of the 10 underwater surface of the hull by 15 to 20 percent of the length of the load water line (LWL) as shown in Figure 6. Also, the center of gravity (CG) of the sailboat must correspond with the center of buoyancy (CB) of the hull to keep the trim and heel of the boat correct. For small sailboats the weight of the 15 helmsmam has a significant effect on the center of gravity.

Thus, the combined center of gravity (CCG) is the combination of the centers of gravity of the helmsman and the hull. Using the nautical balance system, the helmsman's weight is positioned to produce a CCG corresponding to the CB of the hull. Outrigger 26 does not pivot about the mast, because to do so would require the mast location to be dependent on the CCG rather than on the efficient placement of the CE. If CE is displaced, thereby destroying the relationship between the CE and the CLR, the rudder must be turned to keep the sailboat sailing in a straight line. This excessive rudder displacement causes unwanted excessive drag, wich slows the sailboat.

Another significant advantage of nautical balance system is the ability to use a low boom. As the sailboat is tacked 11 through the wind on a traditional small sailboat, the helmsman shifts his weight from one side of the sailboat to the other by ducking under the boom. The booms of traditional sailboats must therefore be located high enough to accommodate the helmsman.

With the nautical balance system 10 the helmsman does not duck under the boom 22, but rather swings behind boom 22 on seat This is possible, as shown in Figure i, since seat 40 is aft of the end of boom 22 when the boom and outrigger are both centered along the centerline. The advantage of a low boom is illustrated 10 in Figure 7. The sail 24 having a low boom 22 is shown in solid lines. A traditional sail 24' having a high boom 22' is shown in dashed lines. The center of effort CE of sail 24 is lower than would be the center of effort CE' of a traditional sail 24'. The traditional sail thus has a greater heeling moment arm Hm'. The heeling moment is countered by the displacement GZ of the center of gravity (CCG) from the center of buoyancy (CB) This displacement GZ or the weight of the helmsman must be increased if Hm is increased to Hm'. A lower boom thus allows a lighter helmsman to carry a larger sail while countering the heeling force of the wind on the sail.

It is to be understood that the present invention is not limited to the embodiment described above, but encompasses any and all embodiments within the scope of the following claims.