US2669431A - Earth drilling apparatus - Google Patents

Earth drilling apparatus Download PDF

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US2669431A
US2669431A US23053A US2305348A US2669431A US 2669431 A US2669431 A US 2669431A US 23053 A US23053 A US 23053A US 2305348 A US2305348 A US 2305348A US 2669431 A US2669431 A US 2669431A
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drill pipe
bell
water
drill
pipe
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US23053A
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John H Crowell
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CROWELL CONSULTING Co
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CROWELL CONSULTING Co
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    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B7/00Special methods or apparatus for drilling
    • E21B7/12Underwater drilling
    • E21B7/124Underwater drilling with underwater tool drive prime mover, e.g. portable drilling rigs for use on underwater floors

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  • This invention relates to drilling into earth formations at the bottom of a body of Water (for example, into the ocean bottom in coastal waters); and more particularly it is directed to drilling for seismic prospecting in such. formations.
  • the invention provides improved apparatus which may be sunk to the bottom of the body or water, and operated. from. the surface of the water to drill a hole in the underwater earth formation and then to detonate an. explosive at the bottom of the hole.
  • the seismic waves created by the explosion are transmitted through the earth formations and are recorded on shipboard instruments connected to geoph ones placed on the sea floor or sus ended from the ship in the usual manner incident to seismic prospecting;
  • the apparatus of the invention basically comprises a submergible bell which may be sunk to the bottom of the body of water, and a drill pipe extending through the bell and held upright thereby; together with means for rotating the drill pipe while submerged-to drill a hole in the ground at the bottom of the body of water, and
  • the invention provides effective apparatus for drilling a hole in earth formations in the bottom of the sea or other body of water, and for detonating an explosive at the bottom of a drill hole when it has been completed.
  • explosions for seismic prospecting may be produced under conditions giving as reliable and as easily interpreted recordings of seismic waves as can be produced on dry land; and at the same time the explosions are rendered substantially' harmless-to fish life.
  • the new apparatus comprises a submersible bell having a closed. buoyancy chamber in its upper portion and a broad, flat ballasted bottom which, when the bell is lowered to the sea floor; rests stably thereon.
  • Adrill pipe which is rotatable and vertically movable extends through the bell and. ishe'ld upright thereby.
  • An expendable drill pipe section and. bitare provided at the lower end of the drill pipe.
  • the upper end of the drill pipe, above the bell, is closed, and is provided with a swivel connection through which a In. the first place; an explosive detonated while-simply resting on the sea floor or suspended in the Water gives rise to only relatively feeble seismic waves through the underwater earth formations.
  • a motor for rotating the drill pipe when the bell is submerged also is provided.
  • the motor preferably is so arranged that it imparts notonly a turnin moment, but also adownward thrust to the drill pipe, to force the drill down during drilling operations.
  • the drill pipe accommodates a charge of explosive which is placed in position before the apparatus is submerged. Then, when the hole hasbeen drilled to the desired depth, this explosive is detonated at the expandable lower section of the drill pipe,
  • the upper end 'of the drill pipe normally is closed 'during drilling operations, so that the water introduced into the: pipe will flow down through the pipe to wash. the cuttings back up the hole outside the pipe- This closure, however,
  • the seismicwavesthereby produced are reis arranged so that it may be opened shortly before or at the time of the explosion, to prevent the back pressure developed in the drill pipe by the explosion from damaging the apparatus.
  • the apparatus While the apparatus is submerged, it is connected to a ship at the surface, from which the drilling operations are conducted, by hose lines and electric cables for operating the drilling motors, for supplying water under pressure to the drill pipe, and for detonating the explosive; and, it is also connected to the ship by a recovery cable or chain. After the explosive has been fired, the apparatus is raised to the surface, the expendable drill pipe section that was destroyed when the explosive was detonated is replaced, and a fresh charge of explosive is loaded in place. Any other operations necessary to ready the apparatus for drilling and firing a new hole are also performed, and the bell is then again submerged in a new location for repeating the procedure.
  • Fig.-1 is a vertical cross section through one form of underwater drilling apparatus shown in position for drilling;
  • Fig. 2 is a cross section similar to Fig. 1 through anotherform of underwater driling apparatus;
  • Fig. 3' is a view similar to Figs. 1 and 2 of still another modification of the new underwater drilling apparatus;
  • Fig. 4 is a cross section similar to Figs. 1 to 3 through yet another modification of the apparatus;'
  • Fig. 5 shows schematically the relation between the new underwater drilling apparatus and a ship from which drilling operations are conducted while drilling is in progress;
  • Fig. 6 shows how the new apparatus may be carried by the ship from one drilling location to another; and Fig. '7 is an enlarged view of the drill pipe recovery wedges shown in Fig. 1. 7
  • apparatus Referring first to the form of apparatus shown in Fig. '1, it comprises a submergible bell l having a closed buoyancy chamber H in its upper portion and abroad, fiat bottom [2.
  • a substantial load of. ballast l3. is provided to weight the bottom so that the bell will rest stably on the earth at the bottom of the body of water in which it is submerged.
  • A'sleeve l4 extends vertically through the bell, and a drill pipe l extends through this sleeve. The drill pipe is free to rotate and :to move axially in the sleeve, but-it is held I thereby in upright position when the bell is loweredtothe bottom of a body of water.
  • the lengthof the drill pipe should be substantially equalto the depth of hole it is desired to drill plus the height of the bell. Generally from 25.to 50 feet of drill pipe is sufficient for drilling a hole of adequate depth for seismic prospect- ;ing, without becoming unwieldy during use of the apparatus. .1
  • the drill pipe is rotated for drilling by hydraulic motors IE to which water under pressure is supplied from the surface through hoses 11.
  • the motors are arranged to drive a plurality of rollers i8 (advantageously faced with rubber) which are held in tight frictional contact with thedrill pipe l5 by the bearings in which they are mounted. When water under pressure is supplied to the motors l6, they cause rotation of the rollers l8'in the directions indicated by the arrowsfthereby rotating the drillpipe.
  • rollers l8 are mounted with their axes inclined at an acute angle to the axis of the drill pipe, rather than parallel thereto.
  • the direction of inclination with respect to the direction of rotation is such that when the rollers are turned, the force they exert on the drill pipe has a downward component as well as a tangential component. Thus a downward thrust is exerted on the drill pipe while it 'isbeing rotated during drilling operations.
  • the bell includes a fioodable compartment l9 between the closed buoyancy chamber H and the ballast l3.
  • Valved vent pipes 20 are connected to the top of this compartment, and ports 2! are provided near its bottom. permit air to be vented from the compartment 19 when it is desired to fiood it, and the ports 2
  • the weight of the bell, when the fiocdable compartment is filled with water, is substantially greater than the weight of the volume of water it displaces, but is about. equal to such weight when the fioodable compartment is filled with air.
  • the exhaust from the hydraulic motors is connected through pipes 22 with the interior of the fioodable compartment is.
  • This arrangement is such that when the bell is about to be submerged, the floodable compartment I9 is ventedby opening the vent pipe valve until the compartment is filled with water, and then closing it.
  • the water supplied to the hydraulic motors during drilling operations exhausts into the compartment i9, and escapes through the ports 2
  • compressed air is delivered through the hoses H to the motors l6,'and it fiows thence through the pipes 22 into the compartment i9, displacing the water therein and lightening the bell. It is'then comparatively easy to raise the bell to the surface by means of a recovery chain 23 permanently attached to it.
  • may be fitted with check valves which permit water to escape from the compartment during drilling, but which prevent water from flowing back in after the In such case special provision must be made for flooding the compartment when the vent pipe valve is opened.
  • a swivel plate 24 isscrew-threaded to the upper end of the drill pipe, and is swivelly con box 25.
  • Water, under the surface through a box' and therethrough nected to a water inlet pressure is supplied from hose 26 to the water inlet to the drill pipe. drill pipe and washes cuttings back up out of the hole during drilling operations. The water and the cuttings pass through, escape passages 21 in the ballast l3 to the surrounding water.
  • An expendable drill pipe section 28 is con-v V nected to the lower end of the drill pi'pe i5; A drill bit 29 is fastened to expendable section. "In the the expendable diameter secured thereto. A formed explosive charge 32 is mounted concentrically about the small diameter pipe section 31, V
  • the wires 34 may be taped tightly to the drill pipe before drilling operations begin, to protect them from damage during drilling; and for further protection, they may be received in a longitudinal groove 35' formed in the pipesection 30. For purposes of clarity, the wires are shown outside the groove 35 in Fig. 1.
  • a second coil 35 mounted in the bell also surrounds the drill pipe l5. This second coil is connected to the ship from which operations are conducted by wires 31.
  • the two" coils 33 and 35" are inductively coupled by the steel drill pipe 15. Consequently, when a heavy surge of current is passed through the coil 35 in the bell, a current is-induced in the lower coil 33, thereby setting off the explosive.
  • the surge of current passed through the upper coil 38 comes, of course, from a battery or generator to which the wires 31 are connected on board theship.
  • a back: pressure wave of considrable magnitudes is developed within the drill pipe.
  • the swivel plate 23 normally rotates with the drill pipe IE, but as seen as the ears 38 engage with the lugs 39, it is no longer free to do so. Continued rotation of the drill pipe by the motor-driven rollers It. therefore. causes the drill pipe to be unscrewed from the swivel plate. The swivel plate and inlet b02125 fastened thereto fall off to the side, thus opening the upper end of the drill pipe.
  • opening the upper end of the drill pipe 35 in this manner occurs as soon as the drill hole has been bottomed, and before the explosive charge is detonated.
  • the pressure of the water fed through the hose 26 decreases. This pressure decrease can be noted on board the operations ship, and provides a clear indication that the hole has been completed. Thereupon the supply of water to the motors it can be discontinued and the explosive charge can be detonated.
  • the back pressure wave developed by the explosive inside the pipe passes harmlessly through it, once its upper end has been opened.
  • the explosion destroys the lower expendable section 28 of the drill pipe. Consequently, when the bell is brought to the surface after the explosive has been fired, the remnants of the damaged expendable lower section are removed from the drill pipe and a new-expendable lower section is fastened in place to prepare the apparatus for the next shot.
  • the pipe section- 30 at the upper end of. the expendable section is made long enough so that the drill pipe above it is not damaged.
  • the swivel plate 24 and the water inlet box 25 hang from the end of the hose 26 when the bell is brought-to the surface after firing the explosive. It is easily retrieved and screwed back on to the drill pipe for the next drilling operation;
  • a series of wedges 40 are secured about the fee riphery of the drill pipe by links llv towedge blocks 42 fastened to the bottomof the bell. These wedges are shown on an enlarged scale in Fig; 7'.
  • the pipe-gripping faces of the wedges" are provided teeth-s3- pitched like screw threads at an angle tothe axis of the: drill: pipe.
  • the form oi apparatus shown in Fig. 2 is gen. erally' the same as that shown in Fig. l, but with modifications the construction of the hell. it.- self and in the construction of the water inlet box.
  • the bell lt shown in Fig. 2 has a buoyancy chamber it in its upper portion and abroad, flat bottom 4%.
  • a sufficientload of ballast 48 is providedin the lower portion of the bell to impart to it a total weight somewhat greaterthan the weight of the volume of water it displaces,- so: that it will rest stably on the ground at the bottom of the water in which it is submerged.
  • a length or" drill pipe 49 passes through a vertical sleeve 5!] in the bell and is held upright thereby.
  • the drill pipe is rotated during drilling operations by hydraulic motors '5l driving rollers 52, which bear tightly against the drill pipe, all generally in the same manner as in the apparatus shown in Fig. 1.
  • the motors are mounted in the bell in a motor compartment 53.
  • the bell 45 is not provided with a fioodable compartment between the buoyancy chamber 46 and the ballast 48. Consequently, the exhaust from the motors discharges directly into the motor compartment 53, and therefrom is exhausted to the surrounding water through ports 5.
  • Firingof the explosive 55 is accomplished by inducing a detonating current in a coil 5? surrounding the drill pipejust above the expendable lower section 56.
  • this detonating current is induced by passing a heavy current from the ship at the surface ofthe water through wires 58 connected'to a coil 59 mounted on the bell.
  • Thefiring, arrangement thus is similar to what has been described above in connection with Fig. 1, excepting' only that the coil 59 surrounds the entire bell rather than just the drill pipe.
  • the two cells are inductively coupled,-however,"by the steel drill pipe and the steel of the bell.
  • Water to" facilitate drilling is supplied to the interi'orof the drill pipe 69 through a hose '50 connected to a water inlet box ti, which inturn is fastened to a swivel plate 62 attached to the upper end of the drill pipe.
  • the swivel plate 62' is not intended to be unscrewed from the drill pipe when the drill hole has been bottomed. Instead, to relieve the back pressure wave created in the drill pipe whenthe explosive is fired, a blow-out plate 63 ismounted in the top of the water inlet box. This plate is simply pressed tightly into an apex-.
  • the inlet box cover 64 for receiving it in the inlet box cover 64. It is held in place frictionally, like the top on a paint can, with sufiicient tightness to withstand the pressure of the water forced through the inlet box during drilling, but not tightly enough to withstand a substantially greater pressure created in the pipe when the explosive is detonated. Consequently, upon firing the explosive, the back pressure wave simply blows the plate 63 out of the aperture in which it is pressed, thus opening the upper end of the drill pipe and preventing damage to the apparatus.
  • thedrill pipe When the bell 45 is raised to the surface, after ahole has been drilled and fired, thedrill pipe is brought up with it because the swivel plate 62, being larger than the sleeve 50 in which the drill pipe is received, prevents the bell from being pulled away from the drill pipe.
  • the form of apparatus shown in Fig. 3 is essentially the same as shown in Fig. 2, except for modifications in the arrangement for firing the explosive when the drill hole has been completed, and some modification in the design of the water inlet box.
  • the bell 65, the drill pipe 66, and the hydraulic motors 61 by which the drill pipe is rotated are all about the same as shown in Fig. 2.
  • the expendable lower section 68 of the drill pipe is simply a short length of the pipe itself, to which a drill bit 69 is attached.
  • the explosive charge is carried in a recep tacle'll inside the drill pipe at its upper end.
  • the upper end of the drill pipe is provided with a head 12 which serves also as a swivel element.
  • the explosive receptacle H is tubular, with an inside diameter no larger than the inside diameterof the drill pipe. Its upper end is mounted in the head on a pivot pin 13, substantially on the axis of the drill piper Its lower end is connected by a link or flexible wire 14 to a push rod 15, which in turn is normally acted on by a compression spring E6 to hold the lower'end of the explosivereceptacle away from V axial alignment-with the drill pipe. By pushing in on the push rod, however, the lower end of the explosives receptacle .Ilmay be brought into axial alignment with the drill pipe 65.
  • a guide plate T1 of suitableshape is provided to insure properalignment of the explosives receptacle with the drill pipe when the push rod is pressed in to its full extent.
  • the guide plate H in the form of a strong permanent magnet, itcan also serve to hold a steel explosives receptacle in the proper alignment into which it guides it.
  • the head '52 is swivelly connected to a water inlet box i8. Flanges lilprevent axial movement of the inlet box with respect to the drill pipe, but permit free rotation of these parts relative to one another. Openings in the head adjacent the water inlet box provide for the flow of water between these two elements.
  • a supply of water to, facilitate drilling is delivered to the water inlet box through a hose 8
  • cam ring hasan inner surface 83 positioned to engage with the push rod 75, and force it inwardly as the head comesinto contact with the Thereby thelower end. of the explosives receptacle is brought into coaxial align-v of the explosives receptacle is open, however, so
  • the explosive isconnected by wires 85 to slip rings 86 mounted on the drill pipe head '12.
  • slip rings 86 mounted on the drill pipe head '12.
  • the slip rings 86 are in con tact with brushes 8'! connected by wires 88 to the ship from which operations are conducted, so that a detonating current can be delivered to the explosive charge by closing the circuit through the brushes and the explosive by means of a switch on board the ship.
  • the upper end of the drillpipe is closed dur: ing drilling operations by a blow-out closure plate 89 held in place at the top of the head 12 by spring clips 96.
  • the spring clips hold the closure plate in place tightly enough to withstand the pressure of the water supplied to the interior of the drill pipe during normal drilling operations; but they enable the plate to be blown off by the substantially greater force of the back pressure wave created in the pipe when the explosiveisfired.
  • V The apparatus shown in Fig. 4 is generally the same as that shown in Fig. 3, except that'diiferent means than thehydraulic motors 6] are pro vided for turning the drill pipe during drilling, and a somewhat different arrangement for firing the explosive is provided.
  • the drill pipe in upright position for drilling, and the drill pipe is provided with an expendable lower section 93 to which a bit 95 is attached substantially as 7 described above.
  • the upper end of the drill pipe is provided with a head 95 swivelly connected to a water inlet box 96.
  • the head 95 is an explosives resceptacle 91 of thesame type and arranged for operation similarly to that de scribed in connection with Fig. 3.
  • Wires 98 however, connect a detonator 99in the explosive with a firing coil it, rather than with slip rings as described in connection with Fig. 3.
  • I06 is mounted on :the head 95 and rotates with the drill pipe.
  • a second coiliti mounted .on the water inlet box 96 is electrically connected by wires [02 'to the ship from which operations are conducted.
  • the two coils are inductively coupled by virtue of being in close proximity to one another, and by means of the steel of the water inlet box and the head. Consequently in connection with Figs. 1 and 2. but here the The coil' acce e;
  • Water is delivered to the interior of the head 55 at the upper endof the drill ,pipe through a hose H13 connected to a pipe lM which .in turn is rigidly connected to the water inlet box 96.
  • Projecting laterally from the head 95 are two or more jet pipes I55 ,p1ovided at their .outer ends with nozzles having apertures N36.
  • the nozzles and nozzle apertures are direct-ed substantially tangentially to the circle described by the outer .ends of the jet pipes 105 when the drill pipe rotates, and also they are directed somewhat upwardly.
  • .A deflector plate Hi1 substantially in the .form of a truncated cone is mounted in the head 95 of the drill pipe about at the point where the jet pipes Hi5 communicate with the interior thereof (the deflector pi-ate is formed with a slot to permit the explosives receptacle 9'! to occupy the position shown in the drawing). Consequently, a part of the water supplied under pressure to the interior of the head is deflected out through the pipes I85 and escapes as jets through the :nozzle apertures i116 into the surrounding water in which the apparatus is submerged. The reaction of these jets imparts a rotating force to the drill pipe, thereby turning it for drilling operations. Since the jets are directed slightly upwardly, as well as tangentially, the reaction to the escaping jets also imparts a downward thrust to the drill pipe, causing the bit 94 to dig into the ground at the bottom of the drill hole.
  • That portion of the water entering the head .95 which is not deflected through the jet pipes passes down through the drill pipe 92 during water inlet box while the drill pipe is rotating.
  • the danger ofentangling the hose and wires with the drill pipe can be further reduced by making the mast hollow and by passing the hose, with wires taped thereto, through the mast about to its center, substantially as shown. lhen only a length of hose and wires about equal to half the depth of the hole to be drilled need be exposed in the open water to the danger of entanglement.
  • Fig. 5 shows a ship H0 anchored at the surface of a body of water in which a hell i l I of the character above described is submerged.
  • the ship is connected with the bell by hose lines I I2 through which water is supplied to the hydraulic or jet motors for turning the drill pipe, and to the drill pipe for washing cuttings from the hole. Wires taped to the hose lines also connect the ship with the bell for the purpose of detonating the explosive when the drill hole has been hottomed.
  • a recovery chain or cable H3 extends between the bell and the ship, so that the hell can be raised to the surface after-the explosive has been fired.
  • the ship or a companion ship This may carry whatever apparatus is necessary .for detecting and recording seismic waves provided in the underwater earth formations when the explosive is fired, as is customary in seismic prospecting.
  • the bell l l .I is shown in Fig. 5 with the drill pipe H4 projecting up above it, as it does when drilling operations are ,just getting under way.
  • Fig. 6 shows how the bell l H may be carrie by the ship from one drilling location to another. 'When the bell is raised alongside the ship, as shown in Fig. 6, and while it is being moved, the damaged expendable section at the lower end of the drill pipe is replaced, the drill pipe is moved back up through the bell into position for commencing a new drill hole, a new charge of explosive is set in place and connected for firing, the upper end of the drill pipe is again closed (as by reattach ng the swivel plate 24 of Fig. l or by replacing the blow-out cap of Figs. 2 to 4) and thebell otherwise .is readied for drilling and .fir'ing a new hole.
  • Apparatus for drilling into earth formations at the bottom of a body of water comprising a bell having a closed buoyancy chamber in its upper portion and a ballasted lower portion, a vertical drill pipe extending through and held upright by said bell, said drill pipe being rotatably and vertically movable relative to the bell, a drill bit on the lower end of said pipe, a water inlet box swivelly connected to the drill pipe at its upper end, a hose connected to said inlet box for delivering a stream of water to the interior of the drill pipe, a motor for rotating the drill pipe when the bell is submerged to the bottom of the body of water, a vertical mast extending upwardly from the bell, and a projection extending laterally from the inlet box into engagement with the mast, whereby accidental rotation of the inlet box with the drill pipe and danger of entanglement of the hose with the drill pipe is prevented.
  • a submergible bell .a completely submergible drill pipe extending completely through said bell and arranged to be held upright thereby, said drill pipe projecting beyond the top and bottom surfaces of the bell and being rotatable and vertically movable relative to the bell
  • a jet motor for rotating the drill pipe comprising a jet pipe secured to and extending laterally from the drill pipe at a point above the bell, said jet pipe communicating with the interior of the drill pipe and being provided at its outer end with a nozzle directed substantially tangentially to the circle described by the outer end of the jet pipe during rotation of the drill pipe, and means for delivering a stream of water under pressure through said jet pipe comprising a water inlet box swivelly connected .to the drill pipe at its upper end and a hose connected to said water inlet box for delivering a stream of water to the interior of the drill pipe.
  • a subniergible bell a completely submergible drill pipe extending completely through said bell and arranged to be lieldupright thereby, said drill pipe projecting beyond the top and bottom surfaces of the bell and being rotatable and verticallyniovable relative to the bell, and a jet moi. tor for rotating the drill pipe and imparting a downward thrust thereto comprising a jet pipe secured to and extending laterally from the drill pipe at a point above the bell, said jet pipe communicating at its inner end with the interior of the drill pipe being provided at its outer end with a nozzle directed both slightly upwardly and 4.
  • a submergible bell a drill pipe extending .through said bell and arranged to be held upright thereby, said drill pipe being rotatable and vertically movable relative to the bell, a head secured to the upper end of the drill pipe above the bell, a water inlet box swivelly connected to said head and communicating therewith, a plurality of jet pipes extending laterally from said;
  • each of said jet pipes be ing provided with a nozzle directed slightly upwardly and substantially tangentially to the circle described by the outer end of the jet pipes during rotation of the drill pipe, whereby water admitted under pressure to the water inlet box flows into the head and escapes in part through the jet pipes, imparting a rotating force ,and'downward thrust to the drill pipe, and in part through the drill pipe, facilitating drilling operations.
  • a submergible bell In seismic prospecting apparatus of the character described, a submergible bell, a com- .pletely submergible drill pipe extending comj pletely through the bell and arranged to be held upright thereby, an expendable drill pipe section and bit at the lower end of said drill pipe, a water inlet box swivelly connected to the upper end of the drill pipe, a motor for rotating the drill pipe when the bell is submerged to the bottom of a body of water, thereby to drill a hole in the earth formation at the bottom of said body of.
  • said detonating means comprising a first coil mounted on the water inlet box, a second coil rotatable with the drill pipe relative to said first coil, said coils being in close proximity to each other and inductively coupled, wires connecting said second coil to a detonator in the explosive charge, and means for passing an electric current through said first coil, whereupona detonating current is induced in said second coil.
  • a submergible bell having a closed buoyancy chamber in its upper portion and a ballasted lower portion, a drill pipe sleeve extending vertically completely through the bell and opening at both its ends to the outer surface of the bell, a drill pipe extending completely through the drill pipe sleeve and arranged to be held upright thereby, an expendable drill pipe section and bit at the lower end of said drill pipe,
  • an explosives receptacle mounted at the upper end of the drill pipe above the bell, means for normally holding a charge of explosive in said explosives receptacle, a cam operated push rod for moving the charge of explosive from engagement with said holding means into coaxial align ment with the drill pipe, and means for trans-- I ferring the charge of explosive from said receptacle through the drill pipe to the expendable section at the lower end thereof.
  • a submergible'bell In seismic prospecting apparatus of the character described, a submergible'bell, a idrill pipe extending through the bell and arranged to be held upright thereby, an expendable drill descend relative to the bell, and a cam at the.
  • top of the bell positioned to engage with the push rod to actuate movement of the receptable into coaxial alignment with the drill pipe when the upper end of the drill pipe has descended to the top of the bell.
  • a drill pipe having an expendable lower section, a head secured to the upper end of the drill pipe and communicating therewith, a hose connected to said head and communicating with a source of water under pressure for introducing water under pressure into said head, means for normally holding a charge of explosive in said head but away from position to enter the drill pipe, and a cam operated push rod for moving said explosives charge from engagement with said holding means within the head into the drill pipe while water under pressure is being supplied to the head, whereby the water forces theexplosives charge through the drill pipe to the expendable lower section thereof.
  • Apparatus for drilling into earth formations at the bottom of a body of water comprising a self-stabilized drill pipe support structure
  • said drill pipe support structure comprising a broad base member adapted to contact and be supported by the earth floor at the bottom of the body of water, a permanent ballast section positioned directly above and adjacent said base member, a closed buoyancy chamber positioned above said ballast section, and a drill pipe supporting sleeve extending vertically through said buoyancy chamber substantially coterminus therewith, a vertical drill pipe rotatably and vettically movably mounted in the sleeve of the aforesaid drill pipe support structure and extending completely through said sleeve and the ballast section of the drill pipe support structure, a drill bit at the lower end of said vertical drill pipe, a drill drive motor connected to said drill pipe exteriorly of said buoyancy chamber adapted to rotate and to advance the drill pipe ratus may be lowered from above the surface of the body of Water to its operative drilling posi tion on the floor of said body of water, said drill pipe support-structure resting stably of its own weight in upright position on the earth floor tion.
  • Apparatus according to claim 9 having a water inlet box swivelly connected to the drill pipe at its upper end, and a hose connected to said water inlet box for delivering a stream of Water to the interior of the drill pipe.
  • Apparatus for seismic prospecting of earth formations at the bottom of a body of water comprising a self-stabilized drill pipe support structure, said drill pipe support structure comprising a broad base member adapted to contact and be supported by the earth floor at the bottom of the body of Water, a permanent ballast section positioned directly above and adjacent said base member, a closed buoyancy chamber positioned above said ballast section, and a drill pipe supporting sleeve extending vertically through said buoyancy chamber substantially coterminus therewith, a vertical dril1 pipe rotatably and vertically movably mounted in the sleeve of the aforesaid drill pipe support structure and extending completely through said sleeve and the ballast section of the drill pipe support structure, an expendable drill pipe section and drill bit at the lower end of said vertical drill pipe, an explosive charge mounted on said drill pipe, means for detonating the explosive charge at the expendable drill pipe section, a drill drive motor connected to said drill pipe exteriorly of said buoyancy chamber to rotate and to advance
  • Apparatus according to claim 11 having a water inlet box swivelly connected to the drill pipe at the upper end, and a hose connected to said water inlet box for delivering a stream of Water to the interior of the drill pipe.
  • Apparatus according to claim 12 in which the water inlet box is provided at its upper end with a water escape opening, an operable closure plate disposed in position to close said water escape opening, and fastener means securing said closure plate in place, said fastener means resisting movement of said closure plate with sufficient force to prevent escape through said water escape opening of Water delivered to the interior of the drill pipe during drilling operations and with insufiicient force to prevent escape of water through said water escape opening upon detonation of the explosive charge.

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  • Earth Drilling (AREA)

Description

1954 J. H. CROWELL I 2,669,431
EARTH DRILLING APPARATUS Filed April 24, 1948 5 Sheets-Sheet 2 dim M ATTORNEYS Feb. 16, 1954 J. HJCROWELL EARTH DRILLING APPARATUS I Filed April 24, 1948 5 SheetS- S heet :s
lil I r FIG. .3
INVENTOR (2229 b. C'rawel/ ATTORNEYS 1954 J. H. CROWELL 2,669,431
EARTH DRILLING APPARATUS Filed April 24, 1948 S'SheetS-Sheef 4 IINVENTOR 125)) K (rave/l M V WW4 ATTORNEYS Febilfi, 1954 c ow L 2,669,431
EARTH DRILLING APPARATUS Filed April 24, 1948 5 Sheets-Sheet 5 INVENTOR 4721' b. Crawel/ ATTORNEYS Patented F eb. 16, 1954 EARTH DRIELIN G APPARATUS John H. Orowell, Houston, Tera, assignor to (Jrowell Consulting Company, Houston, Tom, a
copartnership Application April 24, 194s, Serial No. 23,053
is claims. (01-. 255-43) This invention relates to drilling into earth formations at the bottom of a body of Water (for example, into the ocean bottom in coastal waters); and more particularly it is directed to drilling for seismic prospecting in such. formations. The invention provides improved apparatus which may be sunk to the bottom of the body or water, and operated. from. the surface of the water to drill a hole in the underwater earth formation and then to detonate an. explosive at the bottom of the hole. The seismic waves created by the explosion are transmitted through the earth formations and are recorded on shipboard instruments connected to geoph ones placed on the sea floor or sus ended from the ship in the usual manner incident to seismic prospecting;
The apparatus of the invention basically comprises a submergible bell which may be sunk to the bottom of the body of water, and a drill pipe extending through the bell and held upright thereby; together with means for rotating the drill pipe while submerged-to drill a hole in the ground at the bottom of the body of water, and
means for firing an explosive at the bottom of the hole after it has been drilled.
.In seismic prospecting on land it is customary to drill a hole twenty to fifty or so feet deep with portable drilling apparatus, and then to detonate a small explosive charge at the bottom of the hole after the drill has been withdrawn. This method is not adaptable to seismic prospecting in underwater formations, because it is not practical to load an underwater drill hole with an explosive charge after withdrawal of the drill. According- 1-y, the method heretofore used for seismic prospecting in coastal waters has involved simply dropping a charge of explosive to the bottom of the water, or suspending it in the water and detonating it. While it is possible to obtain. some worthwhile information regarding underwater earth formations in this manner, the method. is subject to two serious defects.
diflicult task of recording and interpretingthe Waves even more difficult.
In the second place, explosive charges detonated on the sea floor or suspended in the Water s in coastal waters often kill many fish. There is frequent conflict between geophysicists seeking authority to detonate explosive charges in coastal waters for seismic prospecting purposes, and fishermen seeking to prevent such explosions in order to protect marine life. There have been occasions when governmental authority has forbidden the detonation of explosives on the floor of the sea in coastal waters because of the harmful efi'ect' on fish life.
The invention provides effective apparatus for drilling a hole in earth formations in the bottom of the sea or other body of water, and for detonating an explosive at the bottom of a drill hole when it has been completed. By use of this new apparatus, explosions for seismic prospecting may be produced under conditions giving as reliable and as easily interpreted recordings of seismic waves as can be produced on dry land; and at the same time the explosions are rendered substantially' harmless-to fish life.
The new apparatus comprises a submersible bell having a closed. buoyancy chamber in its upper portion and a broad, flat ballasted bottom which, when the bell is lowered to the sea floor; rests stably thereon. Adrill pipe which is rotatable and vertically movable extends through the bell and. ishe'ld upright thereby. An expendable drill pipe section and. bitare provided at the lower end of the drill pipe. The upper end of the drill pipe, above the bell, is closed, and is provided with a swivel connection through which a In. the first place; an explosive detonated while-simply resting on the sea floor or suspended in the Water gives rise to only relatively feeble seismic waves through the underwater earth formations. Such waves often are too weak to be clearly recorded or accurately interpreted. Waves from such explosions that are reflected from the surface of the water and from the sea I floor itself, moreover, interfere with the seismic waves traversing the formations whose character is to be ascertained, thus makingan; already stream of water may be passed to wash cuttings out of the drill hole. A motor for rotating the drill pipe when the bell is submerged also is provided.- The motor preferably is so arranged that it imparts notonly a turnin moment, but also adownward thrust to the drill pipe, to force the drill down during drilling operations. The drill pipe accommodates a charge of explosive which is placed in position before the apparatus is submerged. Then, when the hole hasbeen drilled to the desired depth, this explosive is detonated at the expandable lower section of the drill pipe,
corded inthe usual manner.
The upper end 'of the drill pipe normally is closed 'during drilling operations, so that the water introduced into the: pipe will flow down through the pipe to wash. the cuttings back up the hole outside the pipe- This closure, however,
and the seismicwavesthereby produced are reis arranged so that it may be opened shortly before or at the time of the explosion, to prevent the back pressure developed in the drill pipe by the explosion from damaging the apparatus.
While the apparatus is submerged, it is connected to a ship at the surface, from which the drilling operations are conducted, by hose lines and electric cables for operating the drilling motors, for supplying water under pressure to the drill pipe, and for detonating the explosive; and, it is also connected to the ship by a recovery cable or chain. After the explosive has been fired, the apparatus is raised to the surface, the expendable drill pipe section that was destroyed when the explosive was detonated is replaced, and a fresh charge of explosive is loaded in place. Any other operations necessary to ready the apparatus for drilling and firing a new hole are also performed, and the bell is then again submerged in a new location for repeating the procedure.
-Several modifications of the new apparatus, embodying the features briefly mentioned above and other features as well, are shown in the: accompanying drawings, wherein Fig.-1 is a vertical cross section through one form of underwater drilling apparatus shown in position for drilling;
Fig. 2 is a cross section similar to Fig. 1 through anotherform of underwater driling apparatus; Fig. 3'is a view similar to Figs. 1 and 2 of still another modification of the new underwater drilling apparatus;
Fig. 4 is a cross section similar to Figs. 1 to 3 through yet another modification of the apparatus;'
Fig. 5 shows schematically the relation between the new underwater drilling apparatus and a ship from which drilling operations are conducted while drilling is in progress;
Fig. 6 shows how the new apparatus may be carried by the ship from one drilling location to another; and Fig. '7 is an enlarged view of the drill pipe recovery wedges shown in Fig. 1. 7
Referring first to the form of apparatus shown in Fig. '1, it comprises a submergible bell l having a closed buoyancy chamber H in its upper portion and abroad, fiat bottom [2. A substantial load of. ballast l3.is provided to weight the bottom so that the bell will rest stably on the earth at the bottom of the body of water in which it is submerged. A'sleeve l4 extends vertically through the bell, and a drill pipe l extends through this sleeve. The drill pipe is free to rotate and :to move axially in the sleeve, but-it is held I thereby in upright position when the bell is loweredtothe bottom of a body of water. The lengthof the drill pipe should be substantially equalto the depth of hole it is desired to drill plus the height of the bell. Generally from 25.to 50 feet of drill pipe is sufficient for drilling a hole of adequate depth for seismic prospect- ;ing, without becoming unwieldy during use of the apparatus. .1 The drill pipe is rotated for drilling by hydraulic motors IE to which water under pressure is supplied from the surface through hoses 11. The motors are arranged to drive a plurality of rollers i8 (advantageously faced with rubber) which are held in tight frictional contact with thedrill pipe l5 by the bearings in which they are mounted. When water under pressure is supplied to the motors l6, they cause rotation of the rollers l8'in the directions indicated by the arrowsfthereby rotating the drillpipe. The
I provide for the water has been displaced by air.
rollers l8 are mounted with their axes inclined at an acute angle to the axis of the drill pipe, rather than parallel thereto. The direction of inclination with respect to the direction of rotation is such that when the rollers are turned, the force they exert on the drill pipe has a downward component as well as a tangential component. Thus a downward thrust is exerted on the drill pipe while it 'isbeing rotated during drilling operations.
The bell includes a fioodable compartment l9 between the closed buoyancy chamber H and the ballast l3. Valved vent pipes 20 are connected to the top of this compartment, and ports 2! are provided near its bottom. permit air to be vented from the compartment 19 when it is desired to fiood it, and the ports 2| flow of water into and from the compartment. The weight of the bell, when the fiocdable compartment is filled with water, is substantially greater than the weight of the volume of water it displaces, but is about. equal to such weight when the fioodable compartment is filled with air. The exhaust from the hydraulic motors is connected through pipes 22 with the interior of the fioodable compartment is. This arrangement is such that when the bell is about to be submerged, the floodable compartment I9 is ventedby opening the vent pipe valve until the compartment is filled with water, and then closing it. The water supplied to the hydraulic motors during drilling operations exhausts into the compartment i9, and escapes through the ports 2|. When at the conclusion of drilling operations it is desired to raise the bell, compressed air is delivered through the hoses H to the motors l6,'and it fiows thence through the pipes 22 into the compartment i9, displacing the water therein and lightening the bell. It is'then comparatively easy to raise the bell to the surface by means of a recovery chain 23 permanently attached to it. The exhaust ports 2| may be fitted with check valves which permit water to escape from the compartment during drilling, but which prevent water from flowing back in after the In such case special provision must be made for flooding the compartment when the vent pipe valve is opened.
A swivel plate 24 isscrew-threaded to the upper end of the drill pipe, and is swivelly con box 25. Water, under the surface through a box' and therethrough nected to a water inlet pressure is supplied from hose 26 to the water inlet to the drill pipe. drill pipe and washes cuttings back up out of the hole during drilling operations. The water and the cuttings pass through, escape passages 21 in the ballast l3 to the surrounding water.
An expendable drill pipe section 28 is con-v V nected to the lower end of the drill pi'pe i5; A drill bit 29 is fastened to expendable section. "In the the expendable diameter secured thereto. A formed explosive charge 32 is mounted concentrically about the small diameter pipe section 31, V
time by inducing an electriccurrent .in .a coil,3 3
surrounding the drill pipe l5 just above the expendable lower section 28. This coil is connected by wires 34 to a detonator imbedded in the The vent pipes This water travels through the the lower end'o'fjthis V "apparatus of Fig? 1', 7 lower section comprises'aipipe section 30 of the same outside diameter as the drill pipe, and a lower pipe section3l of smaller.
cylindrically explosive charge. The wires 34 may be taped tightly to the drill pipe before drilling operations begin, to protect them from damage during drilling; and for further protection, they may be received in a longitudinal groove 35' formed in the pipesection 30. For purposes of clarity, the wires are shown outside the groove 35 in Fig. 1.
In order to induce a detonating current in the coil 33, a second coil 35 mounted in the bell also surrounds the drill pipe l5. This second coil is connected to the ship from which operations are conducted by wires 31. The two" coils 33 and 35" are inductively coupled by the steel drill pipe 15. Consequently, when a heavy surge of current is passed through the coil 35 in the bell, a current is-induced in the lower coil 33, thereby setting off the explosive. The surge of current passed through the upper coil 38 comes, of course, from a battery or generator to which the wires 31 are connected on board theship.
When theexplosive is detonated, a back: pressure wave of considrable magnitudes" is developed within the drill pipe. To prevent this pressure wave from damaging the equipment, provision is made for opening the normally closed upper end of the drill pipe. In the formof apparatus shown in Fig. 1, this is accomplished by the provision of cars 38 projecting laterally from the swivel plate 24. The ears are arranged to engage with lugs 3d fastened to the top of the bell lil when the drill pipe has descended far enough through the bell to bring the swivel plate to the level of the top of the bell. This, of course, occurs when the drill hole has been driven to the maximum depth possible with the length of drill pipe used. The swivel plate 23 normally rotates with the drill pipe IE, but as seen as the ears 38 engage with the lugs 39, it is no longer free to do so. Continued rotation of the drill pipe by the motor-driven rollers It. therefore. causes the drill pipe to be unscrewed from the swivel plate. The swivel plate and inlet b02125 fastened thereto fall off to the side, thus opening the upper end of the drill pipe.
It is apparent that opening the upper end of the drill pipe 35 in this manner occurs as soon as the drill hole has been bottomed, and before the explosive charge is detonated. As soon as the swivel plate 2 3 is unscrewed from the drill pipe, the pressure of the water fed through the hose 26 decreases. This pressure decrease can be noted on board the operations ship, and provides a clear indication that the hole has been completed. Thereupon the supply of water to the motors it can be discontinued and the explosive charge can be detonated. The back pressure wave developed by the explosive inside the pipe passes harmlessly through it, once its upper end has been opened.
The explosion, of course, destroys the lower expendable section 28 of the drill pipe. Consequently, when the bell is brought to the surface after the explosive has been fired, the remnants of the damaged expendable lower section are removed from the drill pipe and a new-expendable lower section is fastened in place to prepare the apparatus for the next shot. The pipe section- 30 at the upper end of. the expendable section is made long enough so that the drill pipe above it is not damaged. The swivel plate 24 and the water inlet box 25 hang from the end of the hose 26 when the bell is brought-to the surface after firing the explosive. It is easily retrieved and screwed back on to the drill pipe for the next drilling operation;
To insure retrieving the drill pipe it when the bell Hi is raised to thesurface (the grip of the: driving rollers f8 may notalwaysbe suiiicient-l. a series of wedges 40 are secured about the fee riphery of the drill pipe by links llv towedge blocks 42 fastened to the bottomof the bell. These wedges are shown on an enlarged scale in Fig; 7'. When the bell is raised to the surface, the wedges 45 are drawn tightly between the drill? pipe and the wedge blocks 4?, and by their trio-- tiona-l grip on the drill pipe cause it to be: raised with the bell. The pipe-gripping faces of the wedges" are provided teeth-s3- pitched like screw threads at an angle tothe axis of the: drill: pipe. When the drill-pipe is being rotated during drilling operations, these teeth cause the wedges to be raised enough to permit the turning. pipe to pass down through. the bell; but when rotation of the drill pipe ceases and thebell is raised, they grip the pipe tightly.
The form oi apparatus shown in Fig. 2 is gen. erally' the same as that shown in Fig. l, but with modifications the construction of the hell. it.- self and in the construction of the water inlet box. The bell lt shown in Fig. 2 has a buoyancy chamber it in its upper portion and abroad, flat bottom 4%. A sufficientload of ballast 48 is providedin the lower portion of the bell to impart to it a total weight somewhat greaterthan the weight of the volume of water it displaces,- so: that it will rest stably on the ground at the bottom of the water in which it is submerged. A length or" drill pipe 49 passes through a vertical sleeve 5!] in the bell and is held upright thereby. The drill pipe is rotated during drilling operations by hydraulic motors '5l driving rollers 52, which bear tightly against the drill pipe, all generally in the same manner as in the apparatus shown in Fig. 1. The motors are mounted in the bell in a motor compartment 53. The bell 45 is not provided with a fioodable compartment between the buoyancy chamber 46 and the ballast 48. Consequently, the exhaust from the motors discharges directly into the motor compartment 53, and therefrom is exhausted to the surrounding water through ports 5.
,An explosive charge 55 is carried on an expend ablel'ower drill-pipe=section 56 similarly tothe corresponding expendable lower section 28 of the apparatus shown in Fig. l. Firingof the explosive 55 is accomplished by inducing a detonating current in a coil 5? surrounding the drill pipejust above the expendable lower section 56. In the apparatus of Fig-2, this detonating current is induced by passing a heavy current from the ship at the surface ofthe water through wires 58 connected'to a coil 59 mounted on the bell. Thefiring, arrangement thus is similar to what has been described above in connection with Fig. 1, excepting' only that the coil 59 surrounds the entire bell rather than just the drill pipe. The two cells are inductively coupled,-however,"by the steel drill pipe and the steel of the bell.
Water to" facilitate drilling is supplied to the interi'orof the drill pipe 69 through a hose '50 connected to a water inlet box ti, which inturn is fastened to a swivel plate 62 attached to the upper end of the drill pipe. Unlike the apparatus shown in Fig. 1, the swivel plate 62' is not intended to be unscrewed from the drill pipe when the drill hole has been bottomed. Instead, to relieve the back pressure wave created in the drill pipe whenthe explosive is fired, a blow-out plate 63 ismounted in the top of the water inlet box. This plate is simply pressed tightly into an apex-.
top of the bell.
ture for receiving it in the inlet box cover 64. it is held in place frictionally, like the top on a paint can, with sufiicient tightness to withstand the pressure of the water forced through the inlet box during drilling, but not tightly enough to withstand a substantially greater pressure created in the pipe when the explosive is detonated. Consequently, upon firing the explosive, the back pressure wave simply blows the plate 63 out of the aperture in which it is pressed, thus opening the upper end of the drill pipe and preventing damage to the apparatus.
When the bell 45 is raised to the surface, after ahole has been drilled and fired, thedrill pipe is brought up with it because the swivel plate 62, being larger than the sleeve 50 in which the drill pipe is received, prevents the bell from being pulled away from the drill pipe.
The form of apparatus shown in Fig. 3 is essentially the same as shown in Fig. 2, except for modifications in the arrangement for firing the explosive when the drill hole has been completed, and some modification in the design of the water inlet box. Here the bell 65, the drill pipe 66, and the hydraulic motors 61 by which the drill pipe is rotated are all about the same as shown in Fig. 2. However, the expendable lower section 68 of the drill pipe is simply a short length of the pipe itself, to which a drill bit 69 is attached. The explosive charge is carried in a recep tacle'll inside the drill pipe at its upper end. For this purpose, the upper end of the drill pipe is provided with a head 12 which serves also as a swivel element. The explosive receptacle H is tubular, with an inside diameter no larger than the inside diameterof the drill pipe. Its upper end is mounted in the head on a pivot pin 13, substantially on the axis of the drill piper Its lower end is connected by a link or flexible wire 14 to a push rod 15, which in turn is normally acted on by a compression spring E6 to hold the lower'end of the explosivereceptacle away from V axial alignment-with the drill pipe. By pushing in on the push rod, however, the lower end of the explosives receptacle .Ilmay be brought into axial alignment with the drill pipe 65. A guide plate T1 of suitableshape is provided to insure properalignment of the explosives receptacle with the drill pipe when the push rod is pressed in to its full extent. By making the guide plate H in the form of a strong permanent magnet, itcan also serve to hold a steel explosives receptacle in the proper alignment into which it guides it. 7 I V The head '52 is swivelly connected to a water inlet box i8. Flanges lilprevent axial movement of the inlet box with respect to the drill pipe, but permit free rotation of these parts relative to one another. Openings in the head adjacent the water inlet box provide for the flow of water between these two elements. A supply of water to, facilitate drilling is delivered to the water inlet box through a hose 8|, and normally it flows through the openings 80 and thence di-'- rectly down the drill pipe, washing cuttingsback out of the hole. a
.When the hole has been drilled to the full depth permitted by the length of drill pipe used, its head 12 comes in contactwith the top of the bell, where a cam ring 32 is mounted. The
cam ring hasan inner surface 83 positioned to engage with the push rod 75, and force it inwardly as the head comesinto contact with the Thereby thelower end. of the explosives receptacle is brought into coaxial align-v of the explosives receptacle is open, however, so
that as soon as the lower end of the explosives receptacle moves into coaxial alignment with the drill pipe, the pressure of the, water delivered throughthe hose 8| acts on the upper surface of explosive charge 10 in the receptacle and forces it, like a piston, down through the drill pipe to the expendable lower section 68. .With the explosive now more or less plugging the'drill pipe, an increase in the pressure of the water delivered through the hose 8| will be indicated on pressure gauges connected with the pump on the ship from which the water is supplied, pro-I viding thereby an indication that the drill hole has been bottomed and that the explosive charge is in position to be fired. V i
The explosive isconnected by wires 85 to slip rings 86 mounted on the drill pipe head '12. When th explosive charge is first placed in the recep tacle H, these wires are coiled so as to pay out freely when the explosive is forced to the bottom of the drill pipe. The slip rings 86 are in con tact with brushes 8'! connected by wires 88 to the ship from which operations are conducted, so that a detonating current can be delivered to the explosive charge by closing the circuit through the brushes and the explosive by means of a switch on board the ship.
The upper end of the drillpipe is closed dur: ing drilling operations by a blow-out closure plate 89 held in place at the top of the head 12 by spring clips 96. The spring clips hold the closure plate in place tightly enough to withstand the pressure of the water supplied to the interior of the drill pipe during normal drilling operations; but they enable the plate to be blown off by the substantially greater force of the back pressure wave created in the pipe when the explosiveisfired. V The apparatus shown in Fig. 4 is generally the same as that shown in Fig. 3, except that'diiferent means than thehydraulic motors 6] are pro vided for turning the drill pipe during drilling, and a somewhat different arrangement for firing the explosive is provided.
The bell 9! of Fig. 4 supports a drill pi es:
in upright position for drilling, and the drill pipe is provided with an expendable lower section 93 to which a bit 95 is attached substantially as 7 described above. The upper end of the drill pipe is provided with a head 95 swivelly connected to a water inlet box 96. 'Inside the head 95 is an explosives resceptacle 91 of thesame type and arranged for operation similarly to that de scribed in connection with Fig. 3. Wires 98 however, connect a detonator 99in the explosive with a firing coil it, rather than with slip rings as described in connection with Fig. 3. I06 is mounted on :the head 95 and rotates with the drill pipe. A second coiliti mounted .on the water inlet box 96 is electrically connected by wires [02 'to the ship from which operations are conducted. The two coils are inductively coupled by virtue of being in close proximity to one another, and by means of the steel of the water inlet box and the head. Consequently in connection with Figs. 1 and 2. but here the The coil' acce e;
.two coils are in close proximity and are closely coupled inductively, so that they operate more ein'ciently.
Water is delivered to the interior of the head 55 at the upper endof the drill ,pipe through a hose H13 connected to a pipe lM which .in turn is rigidly connected to the water inlet box 96. Projecting laterally from the head 95 are two or more jet pipes I55 ,p1ovided at their .outer ends with nozzles having apertures N36. The nozzles and nozzle apertures are direct-ed substantially tangentially to the circle described by the outer .ends of the jet pipes 105 when the drill pipe rotates, and also they are directed somewhat upwardly. .A deflector plate Hi1 substantially in the .form of a truncated cone is mounted in the head 95 of the drill pipe about at the point where the jet pipes Hi5 communicate with the interior thereof (the deflector pi-ate is formed with a slot to permit the explosives receptacle 9'! to occupy the position shown in the drawing). Consequently, a part of the water supplied under pressure to the interior of the head is deflected out through the pipes I85 and escapes as jets through the :nozzle apertures i116 into the surrounding water in which the apparatus is submerged. The reaction of these jets imparts a rotating force to the drill pipe, thereby turning it for drilling operations. Since the jets are directed slightly upwardly, as well as tangentially, the reaction to the escaping jets also imparts a downward thrust to the drill pipe, causing the bit 94 to dig into the ground at the bottom of the drill hole.
That portion of the water entering the head .95 which is not deflected through the jet pipes passes down through the drill pipe 92 during water inlet box while the drill pipe is rotating. I
The danger ofentangling the hose and wires with the drill pipe can be further reduced by making the mast hollow and by passing the hose, with wires taped thereto, through the mast about to its center, substantially as shown. lhen only a length of hose and wires about equal to half the depth of the hole to be drilled need be exposed in the open water to the danger of entanglement.
The way in which the new apparatus is used is shown schematically in Figs. 5 and 6. Fig. 5 shows a ship H0 anchored at the surface of a body of water in which a hell i l I of the character above described is submerged. The ship is connected with the bell by hose lines I I2 through which water is supplied to the hydraulic or jet motors for turning the drill pipe, and to the drill pipe for washing cuttings from the hole. Wires taped to the hose lines also connect the ship with the bell for the purpose of detonating the explosive when the drill hole has been hottomed. A recovery chain or cable H3 extends between the bell and the ship, so that the hell can be raised to the surface after-the explosive has been fired. The ship or a companion ship This may carry whatever apparatus is necessary .for detecting and recording seismic waves provided in the underwater earth formations when the explosive is fired, as is customary in seismic prospecting. "The bell l l .I is shown in Fig. 5 with the drill pipe H4 projecting up above it, as it does when drilling operations are ,just getting under way.
Fig. 6 shows how the bell l H may be carrie by the ship from one drilling location to another. 'When the bell is raised alongside the ship, as shown in Fig. 6, and while it is being moved, the damaged expendable section at the lower end of the drill pipe is replaced, the drill pipe is moved back up through the bell into position for commencing a new drill hole, a new charge of explosive is set in place and connected for firing, the upper end of the drill pipe is again closed (as by reattach ng the swivel plate 24 of Fig. l or by replacing the blow-out cap of Figs. 2 to 4) and thebell otherwise .is readied for drilling and .fir'ing a new hole.
The various modifications oi the new apparatus shown in the drawings and described above are only illustrative of the invention. The various features of the invention may be combined in other ways than those specifically shown.
I claim:
1. Apparatus for drilling into earth formations at the bottom of a body of water comprising a bell having a closed buoyancy chamber in its upper portion and a ballasted lower portion, a vertical drill pipe extending through and held upright by said bell, said drill pipe being rotatably and vertically movable relative to the bell, a drill bit on the lower end of said pipe, a water inlet box swivelly connected to the drill pipe at its upper end, a hose connected to said inlet box for delivering a stream of water to the interior of the drill pipe, a motor for rotating the drill pipe when the bell is submerged to the bottom of the body of water, a vertical mast extending upwardly from the bell, and a projection extending laterally from the inlet box into engagement with the mast, whereby accidental rotation of the inlet box with the drill pipe and danger of entanglement of the hose with the drill pipe is prevented.
2. In apparatus ofthe character described, a submergible bell, .a completely submergible drill pipe extending completely through said bell and arranged to be held upright thereby, said drill pipe projecting beyond the top and bottom surfaces of the bell and being rotatable and vertically movable relative to the bell, and .a jet motor for rotating the drill pipe comprising a jet pipe secured to and extending laterally from the drill pipe at a point above the bell, said jet pipe communicating with the interior of the drill pipe and being provided at its outer end with a nozzle directed substantially tangentially to the circle described by the outer end of the jet pipe during rotation of the drill pipe, and means for delivering a stream of water under pressure through said jet pipe comprising a water inlet box swivelly connected .to the drill pipe at its upper end and a hose connected to said water inlet box for delivering a stream of water to the interior of the drill pipe.
3. In apparatus of the character described, a subniergible bell, a completely submergible drill pipe extending completely through said bell and arranged to be lieldupright thereby, said drill pipe projecting beyond the top and bottom surfaces of the bell and being rotatable and verticallyniovable relative to the bell, and a jet moi. tor for rotating the drill pipe and imparting a downward thrust thereto comprising a jet pipe secured to and extending laterally from the drill pipe at a point above the bell, said jet pipe communicating at its inner end with the interior of the drill pipe being provided at its outer end with a nozzle directed both slightly upwardly and 4. In drilling apparatus of the character described, a submergible bell, a drill pipe extending .through said bell and arranged to be held upright thereby, said drill pipe being rotatable and vertically movable relative to the bell, a head secured to the upper end of the drill pipe above the bell, a water inlet box swivelly connected to said head and communicating therewith, a plurality of jet pipes extending laterally from said;
head, the outer end of each of said jet pipes be ing provided with a nozzle directed slightly upwardly and substantially tangentially to the circle described by the outer end of the jet pipes during rotation of the drill pipe, whereby water admitted under pressure to the water inlet box flows into the head and escapes in part through the jet pipes, imparting a rotating force ,and'downward thrust to the drill pipe, and in part through the drill pipe, facilitating drilling operations.
.5. In seismic prospecting apparatus of the character described, a submergible bell, a com- .pletely submergible drill pipe extending comj pletely through the bell and arranged to be held upright thereby, an expendable drill pipe section and bit at the lower end of said drill pipe, a water inlet box swivelly connected to the upper end of the drill pipe, a motor for rotating the drill pipe when the bell is submerged to the bottom of a body of water, thereby to drill a hole in the earth formation at the bottom of said body of. water, and means for detonating an explosive .charge at the expendable drill pipe section when the hole has attained desired depth, said detonating means comprising a first coil mounted on the water inlet box, a second coil rotatable with the drill pipe relative to said first coil, said coils being in close proximity to each other and inductively coupled, wires connecting said second coil to a detonator in the explosive charge, and means for passing an electric current through said first coil, whereupona detonating current is induced in said second coil.
6. In seismic prospecting apparatus of the character described, a submergible bell having a closed buoyancy chamber in its upper portion and a ballasted lower portion, a drill pipe sleeve extending vertically completely through the bell and opening at both its ends to the outer surface of the bell, a drill pipe extending completely through the drill pipe sleeve and arranged to be held upright thereby, an expendable drill pipe section and bit at the lower end of said drill pipe,
an explosives receptacle mounted at the upper end of the drill pipe above the bell, means for normally holding a charge of explosive in said explosives receptacle, a cam operated push rod for moving the charge of explosive from engagement with said holding means into coaxial align ment with the drill pipe, and means for trans-- I ferring the charge of explosive from said receptacle through the drill pipe to the expendable section at the lower end thereof.
'7. In seismic prospecting apparatus of the character described, a submergible'bell, a idrill pipe extending through the bell and arranged to be held upright thereby, an expendable drill descend relative to the bell, and a cam at the.
top of the bell positioned to engage with the push rod to actuate movement of the receptable into coaxial alignment with the drill pipe when the upper end of the drill pipe has descended to the top of the bell.
8. In seismic prospecting apparatus of the character described, a drill pipe having an expendable lower section, a head secured to the upper end of the drill pipe and communicating therewith, a hose connected to said head and communicating with a source of water under pressure for introducing water under pressure into said head, means for normally holding a charge of explosive in said head but away from position to enter the drill pipe, and a cam operated push rod for moving said explosives charge from engagement with said holding means within the head into the drill pipe while water under pressure is being supplied to the head, whereby the water forces theexplosives charge through the drill pipe to the expendable lower section thereof. I
9. Apparatus for drilling into earth formations at the bottom of a body of water comprising a self-stabilized drill pipe support structure,
. said drill pipe support structure comprising a broad base member adapted to contact and be supported by the earth floor at the bottom of the body of water, a permanent ballast section positioned directly above and adjacent said base member, a closed buoyancy chamber positioned above said ballast section, and a drill pipe supporting sleeve extending vertically through said buoyancy chamber substantially coterminus therewith, a vertical drill pipe rotatably and vettically movably mounted in the sleeve of the aforesaid drill pipe support structure and extending completely through said sleeve and the ballast section of the drill pipe support structure, a drill bit at the lower end of said vertical drill pipe, a drill drive motor connected to said drill pipe exteriorly of said buoyancy chamber adapted to rotate and to advance the drill pipe ratus may be lowered from above the surface of the body of Water to its operative drilling posi tion on the floor of said body of water, said drill pipe support-structure resting stably of its own weight in upright position on the earth floor tion.
of said body of water when in said operative posi- 10. Apparatus according to claim 9 having a water inlet box swivelly connected to the drill pipe at its upper end, and a hose connected to said water inlet box for delivering a stream of Water to the interior of the drill pipe.
11. Apparatus for seismic prospecting of earth formations at the bottom of a body of water comprising a self-stabilized drill pipe support structure, said drill pipe support structure comprising a broad base member adapted to contact and be supported by the earth floor at the bottom of the body of Water, a permanent ballast section positioned directly above and adjacent said base member, a closed buoyancy chamber positioned above said ballast section, and a drill pipe supporting sleeve extending vertically through said buoyancy chamber substantially coterminus therewith, a vertical dril1 pipe rotatably and vertically movably mounted in the sleeve of the aforesaid drill pipe support structure and extending completely through said sleeve and the ballast section of the drill pipe support structure, an expendable drill pipe section and drill bit at the lower end of said vertical drill pipe, an explosive charge mounted on said drill pipe, means for detonating the explosive charge at the expendable drill pipe section, a drill drive motor connected to said drill pipe exteriorly of said buoyancy chamber to rotate and to advance the drill pipe downwardly into said earth formation, power supply means connecting said drill drive motor to a source of power above the surface of the body of water, and a supporting element aifixed to the exterior of the buoyancy chamber of the drill pipe support structure whereby the apparatus may be lowered from above the surface of the body of water to rest stably of its own Weight in upright position on the earth floor of said body of water in position to drill a hole into the earth formation therebeneath and to 14 detonate said explosive charge adjacent the bottom of the drill hole.
12. Apparatus according to claim 11 having a water inlet box swivelly connected to the drill pipe at the upper end, and a hose connected to said water inlet box for delivering a stream of Water to the interior of the drill pipe.
13. Apparatus according to claim 12 in which the water inlet box is provided at its upper end with a water escape opening, an operable closure plate disposed in position to close said water escape opening, and fastener means securing said closure plate in place, said fastener means resisting movement of said closure plate with sufficient force to prevent escape through said water escape opening of Water delivered to the interior of the drill pipe during drilling operations and with insufiicient force to prevent escape of water through said water escape opening upon detonation of the explosive charge.
JOHN H. CROWELL.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,435,140 Rolland Nov. 7, 1922 2,001,529 Dorm'er May 14, 1935 2,058,287 Anderson Oct. 20, 1936 2,171,672 Plummer Sept. 5, 1939 2,187,871 Voorhees Jan. 23, 1940 2,283,200 Flude May 19, 1942 2,384,851 Reichert Sept. 18, 1945 2,503,516 Shrewsbury Apr. 11, 1950 2,512,783 Tucker June 27, 1950 FOREIGN PATENTS Number Country Date 160,865 Great Britain Apr. 7, 1921
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US2880966A (en) * 1957-01-14 1959-04-07 Jersey Prod Res Co Charge-planting motor-bit drill
US2890861A (en) * 1954-12-31 1959-06-16 Phillips Petroleum Co Underwater geophysical prospecting
US2929610A (en) * 1954-12-27 1960-03-22 Shell Oil Co Drilling
US2970646A (en) * 1958-01-30 1961-02-07 Jersey Prod Res Co Method for installing controls to and operating an underwater well
US2984308A (en) * 1956-09-04 1961-05-16 Shell Oil Co Underwater drilling guide
US3004602A (en) * 1956-11-05 1961-10-17 Richfield Oil Corp Underwater oil well completion
US3146836A (en) * 1959-12-16 1964-09-01 Consolidation Coal Co Mine drilling machine
US3204709A (en) * 1963-10-21 1965-09-07 Pacific Tugboat & Salvage Co Deep sea coring tower
US3247672A (en) * 1962-08-29 1966-04-26 Vincent C Johnson Underwater well head encasement structure
US3424253A (en) * 1956-12-03 1969-01-28 Chevron Res Method for drilling and working in offshore wells
US3554277A (en) * 1957-08-01 1971-01-12 Shell Oil Co Underwater wells
US3593808A (en) * 1969-01-07 1971-07-20 Arthur J Nelson Apparatus and method for drilling underwater
US3602320A (en) * 1968-10-16 1971-08-31 Amoco Prod Co Deep sea pile setting and coring vessel
US3603407A (en) * 1969-12-29 1971-09-07 Wallace Clark Well drilling apparatus
US3693717A (en) * 1970-10-22 1972-09-26 Gulf Research Development Co Reproducible shot hole
US3986569A (en) * 1973-12-21 1976-10-19 Atlas Copco Aktiebolag Drill string element handling apparatus
USRE30071E (en) * 1973-12-21 1979-08-14 Atlas Copco Aktiebolag Drill string element handling apparatus
US4190123A (en) * 1977-07-20 1980-02-26 John Roddy Rock drill bit loading device
US6622793B1 (en) * 1999-06-01 2003-09-23 Igor Igorevich Rylov Method for carrying out operations on petroleum and gas fields and deep-sea platform for realizing the same
EP2562346A1 (en) * 2011-08-23 2013-02-27 BAUER Maschinen GmbH Underwater drilling assembly and method for producing a borehole
US20130220700A1 (en) * 2011-08-23 2013-08-29 Bauer Maschinen Gmbh Underwater drilling arrangement and method for making a bore
US9487927B1 (en) 2014-01-13 2016-11-08 Michael Stebbins Impact tool

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GB160865A (en) * 1919-10-06 1921-04-07 James Forgie Improvements in and relating to submarine exploration
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US2929610A (en) * 1954-12-27 1960-03-22 Shell Oil Co Drilling
US2890861A (en) * 1954-12-31 1959-06-16 Phillips Petroleum Co Underwater geophysical prospecting
US2984308A (en) * 1956-09-04 1961-05-16 Shell Oil Co Underwater drilling guide
US3004602A (en) * 1956-11-05 1961-10-17 Richfield Oil Corp Underwater oil well completion
US3424253A (en) * 1956-12-03 1969-01-28 Chevron Res Method for drilling and working in offshore wells
US2880966A (en) * 1957-01-14 1959-04-07 Jersey Prod Res Co Charge-planting motor-bit drill
US3554277A (en) * 1957-08-01 1971-01-12 Shell Oil Co Underwater wells
US2970646A (en) * 1958-01-30 1961-02-07 Jersey Prod Res Co Method for installing controls to and operating an underwater well
US3146836A (en) * 1959-12-16 1964-09-01 Consolidation Coal Co Mine drilling machine
US3247672A (en) * 1962-08-29 1966-04-26 Vincent C Johnson Underwater well head encasement structure
US3204709A (en) * 1963-10-21 1965-09-07 Pacific Tugboat & Salvage Co Deep sea coring tower
US3602320A (en) * 1968-10-16 1971-08-31 Amoco Prod Co Deep sea pile setting and coring vessel
US3593808A (en) * 1969-01-07 1971-07-20 Arthur J Nelson Apparatus and method for drilling underwater
US3603407A (en) * 1969-12-29 1971-09-07 Wallace Clark Well drilling apparatus
US3693717A (en) * 1970-10-22 1972-09-26 Gulf Research Development Co Reproducible shot hole
US3986569A (en) * 1973-12-21 1976-10-19 Atlas Copco Aktiebolag Drill string element handling apparatus
USRE30071E (en) * 1973-12-21 1979-08-14 Atlas Copco Aktiebolag Drill string element handling apparatus
US4190123A (en) * 1977-07-20 1980-02-26 John Roddy Rock drill bit loading device
US6622793B1 (en) * 1999-06-01 2003-09-23 Igor Igorevich Rylov Method for carrying out operations on petroleum and gas fields and deep-sea platform for realizing the same
EP2562346A1 (en) * 2011-08-23 2013-02-27 BAUER Maschinen GmbH Underwater drilling assembly and method for producing a borehole
CN103089151A (en) * 2011-08-23 2013-05-08 包尔机械有限公司 Underwater drilling assembly and method for producing a borehole
US20130220700A1 (en) * 2011-08-23 2013-08-29 Bauer Maschinen Gmbh Underwater drilling arrangement and method for making a bore
US8720603B2 (en) * 2011-08-23 2014-05-13 Bauer Maschinen Gmbh Underwater drilling arrangement and method for making a bore
US9140068B2 (en) 2011-08-23 2015-09-22 Bauer Maschinen Gmbh Underwater drilling arrangement and method for making a bore
CN103089151B (en) * 2011-08-23 2016-06-22 包尔机械有限公司 For forming underwater drilling device and the method in hole
US9487927B1 (en) 2014-01-13 2016-11-08 Michael Stebbins Impact tool

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