US3443648A - Earth formation underreamer - Google Patents
Earth formation underreamer Download PDFInfo
- Publication number
- US3443648A US3443648A US667580A US3443648DA US3443648A US 3443648 A US3443648 A US 3443648A US 667580 A US667580 A US 667580A US 3443648D A US3443648D A US 3443648DA US 3443648 A US3443648 A US 3443648A
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- Prior art keywords
- underreamer
- hydraulic
- bore hole
- earth formation
- cutting
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- 238000005520 cutting process Methods 0.000 description 46
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- 239000003381 stabilizer Substances 0.000 description 18
- 238000005553 drilling Methods 0.000 description 16
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- 238000011068 loading method Methods 0.000 description 2
- 230000035939 shock Effects 0.000 description 2
- 230000000087 stabilizing effect Effects 0.000 description 2
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- 235000009470 Theobroma cacao Nutrition 0.000 description 1
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- 230000005611 electricity Effects 0.000 description 1
- 239000007789 gas Substances 0.000 description 1
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- 238000000034 method Methods 0.000 description 1
- 229910052757 nitrogen Inorganic materials 0.000 description 1
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- 239000012321 sodium triacetoxyborohydride Substances 0.000 description 1
- 230000006641 stabilisation Effects 0.000 description 1
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Images
Classifications
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B4/00—Drives for drilling, used in the borehole
- E21B4/20—Drives for drilling, used in the borehole combined with surface drive
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B10/00—Drill bits
- E21B10/26—Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers
- E21B10/32—Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers with expansible cutting tools
- E21B10/322—Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers with expansible cutting tools cutter shifted by fluid pressure
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B4/00—Drives for drilling, used in the borehole
- E21B4/16—Plural down-hole drives, e.g. for combined percussion and rotary drilling; Drives for multi-bit drilling units
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B4/00—Drives for drilling, used in the borehole
- E21B4/18—Anchoring or feeding in the borehole
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B44/00—Automatic control systems specially adapted for drilling operations, i.e. self-operating systems which function to carry out or modify a drilling operation without intervention of a human operator, e.g. computer-controlled drilling systems; Systems specially adapted for monitoring a plurality of drilling variables or conditions
- E21B44/005—Below-ground automatic control systems
Definitions
- the cutting components include one or more extensible cutting arms which are arranged to extend angularly outward from the drill pipe and to be operated rotatably by means of a hydraulic power system;
- Each cutting arm includes at least one self-powered c utter which is driven by a hydraulic motor which receives power from the central hydraulic system, and each cutting arm also includes a plurality of free wheeling cutters which cut by reason of the weight of the drilling system.
- This invention relates to earth formation drilling devices, and more particularly to drilling devices for bore holes. Still more particularly, this invention relates to drilling devices for enlarging bore holes which are known as underreamers in which the enlargement of the bore hole is accomplished by hydraulically driven cutters.
- Uneven cutting provides a rough operation, and the elasticity of the drill string coupled with the uneven cutting of the tool creates shock loading.
- the primary object of this invention is to provide an earth formation drilling device which will easily and efliciently produce a large diameter bore hole in an earth formation.
- Another object of this invention is to provide an earth nitd States Patent O m 3,443,648 Patented May 13, 1969 formation boring device which can be removably controlled to produce a large diameter bore hole.
- Still another object of this invention is to provide an earth formation boring device which can be inserted into a. bore hole in a retracted condition and which can be remotely controlled from the surface to produce an enlarged bore hole section.
- Still another object of this invention is to provide an earth formation boring device which is hydraulically driven to produce an enlarged bore hole section.
- Another object of this invention is to provide a rotary earth formation boring device which can be suspended down a bore hole on non-rotating suspension means and positioned appropriately to enlarge a desired section of the bore hole.
- FIGURE 1 is an elevational view of the bore hole underreamer of this invention showing the device in a retracted position upon entry into a bore hole.
- FIGURE 2 is a fragmentary elevational view of a bore hole underreamer according to this invention in position in a bore hole as it is when beginning operation to enlarge the bore hole.
- FIGURE 3 is an elevational view of a bore hole underreamer according to this invention showing the device after it has enlarged a section of a bore hole.
- FIGURE 4 is a cross-sectional view of a cutting arm of a bore hole underreamer according to this invention.
- FIGURE 5 is a schematic circuit diagram of the electric control circuit of a bore hole underreamer according to this invention.
- the bore hole underreamer of this invention comprises a hydraulically driven cutter arm rotatably positioned on a supporting member such as a drill pipe retained in position by conventional drill pipe supporting devices.
- the underreaming device is retractable to a compact condition for easy insertion into the bore hole.
- stabilizing means are actuated by a hydraulic component incorporated as a part of the underreamer.
- the stabilizing means is actuated to bear firmly against the side of the bore hole to hold the drill pipe or other suspending means in a non-rotative condition while the cutting arm rotates to cut into the earth formation adjacent the bore hole.
- Hydraulic means on the device both controls the positioning of the extensible cutting arm and drives a hydraulic motor position on the cutting arm. Operation of this hydraulic motor drives a cutter attached thereto which in turn causes rotation of the cutting arm by contact with the earth formation and also brings about additional cutting by means of contact with the earth formation of a plurality of free-wheeling cutters positioned on the cutting arm.
- Crusher means positioned beneath the cutting arm is also hydraulically driven and reduces in size particles chipped from the earth formation. Material passing through the crusher means is caught by collection means positioned thereunder and caused to circulate to the surface by fluid passing down the bore hole.
- the hydraulic means positioned down the bore hole as a part of an underreaming device is controlled from the surface by an electric circuit.
- a suitable device for circulating fluid down the bore hole to flush out particles removed from the earth formation is also controlled by the electric circuit means and they consist of conventional pumps for either a gas such as air or nitrogen, or a liquid such as water or oil.
- FIGURE 1 shows a bore hole underreamer 10, generally, which is mounted on a section of drill pipe 12 to which additional sections of drill pipe may be added, and which may be suspended in any well known form of conventional traveling block 14, which may be supported by well known means as by cables 16 and held in position on traveling block 14 by means of a conventional bushing.
- the entire apparatus including the underreamer, drill pipe, and suspension cables may be mounted in the usual form of drilling rig 20 which provides that the structure for positioning the underreamer down the bore hole and removing the underreamer by the addition or removal of additional drill pipe sections as necessary.
- the usual drilling rig includes floor 22 having a central opening 24 therein which is aligned with bore hole 26.
- Bore hole 26 has already been drilled to the prescribed depth by independent conventional drilling means preferably using the same drilling rig 20 as employed in the suspension of the underreamer of this invention.
- bore hole 26 may be an enlarged diameter bore such as 48-inch hole with the underreamer of this invention designed to enlarge this bore hole to a diameter of 28 feet.
- smaller bore holes may be enlarged to larger diameters.
- FIGURES 1 through 3 it is seen that the underreamer of this invention is positioned on modified drill pipe section 12 which is secured bearably at its upper end to a rotary terminal block 28 which receives electric wires 30 from the surface and by rotating connections within block 28 conducts electric current from wires 30 to wires 32 which pass the motive current to an electric pump and electric motor within hydraulic component 34.
- the electric motor and pump are not shown since these are simply of conventional design.
- Hydraulic component 34 includes an accumulator of hydraulic reservoir for the hydraulic fluid circulating through the system to hydraulic cylinders and motors hereinafter described.
- drill pipe section 13 which may be a conventional section of drill pipe, a variable amount of weight may be positioned such as removable weights 36 which rest on a base plate 38. By this means the underreaming force may be varied as desired.
- an upper stabilizer 40 which includes a housing section 42 having therein conventional bearings abutting pipe section 13, and an extensible hydraulic cylinder secured pivotally to housing 42 and having each side of a. piston therein connected to hydraulic lines from hydraulic component 34 as described in FIGURE 5.
- Hydraulic cylinder 44 is in turn pivotally connected to frame 46 on which is mounted rollers 48. Then, actuation of hydraulic cylinder 44 in one direction will force rollers 48 into firm contact with the wall of bore hole 26 to stabilize the underreamer during operation.
- a similar stabilizer 50 is mounted bearably near the lower end of the underreamer on a housing 52 with a hydraulic cylinder 54 pivotally attached to housing 52 and pivotally attached to frame 56.
- Frame 56 also has rollers 58 therein which can be put into contact with the walls of the bore hole.
- actuation of hydraulic cylinders 44 and 54 can extend rollers 48 and 58 against the wall of the bore hole to a chosen degree so that the cutting components of the underreamer can be properly guided to provide a clean, true underreaming operation.
- Housing 42 is made to be lockable into position on bushings 60 of rotary terminal block 28.
- Bushing 60 is held non-rotatably while terminal block28 is intended to rotate with modified drill pipe section 12 which serves as a frame for the underreamer.
- Hydraulic connections 4 between cylinder 44 and hydraulic component 34 are made through conventional hydraulic rotary seals operating between bushing 60 and terminal block 28.
- lower housing 52 is made to be lockable within bushing 62 at the lower end of drill pipe 12 in a manner to permit housing 52 to be held non-rotatively while drill pipe 12 rotates.
- Similar hydraulic seals are provided within bushing 62 to permit hydraulic fluid capacity component 34 to hydraulic cylinders 54.
- hydraulic cylinders 44 and 54 include solenoid valves as shown schematically in FIGURE 5 to control the flow of hydraulic fluid from the surface as desired for actuation of the upper and lower stabilizers.
- Each cutting arm includes an adjustable brace 64 pivotally mounted to a housing 66 mounted on drill pipe section 12 with the other end of housing 66 pivotally mounted to a supporting arm 68 which in turn is pivotally mounted at its lower end to a housing 70 secured to drill pipe section 12. Positioning of the cutter arms is provided by the operation of a hydraulic cylinder 72 mounted pivotally between housing 66 and housing 74. Hydraulic cylinder 72 includes a piston therein which has its opposite faces adaptable to be contacted by hydraulic fluid passing through lines 76 and 78 from hydraulic component 34.
- a solenoid valve is included within hydraulic component 34 to control the flow of fluid to and from cylinders 72 so that the cutting arms may be positioned as desired.
- the construction of each cutting arm is more clearly shown in FIGURE 4.
- FIGURE 3 is shown the hydraulic connections from hydraulic component 34 to each hydraulic motor 80 of each cutting arm.
- One such hydraulic line 82 supplies fluid to each motor and another line 84 serves as a return line to an accumulator within hydraulic component 34, such as is represented by accumulator 86 shown in FIGURE 5.
- Motors 80 drive an internal shaft which is connected to driven cutters 88 which cause rotation of the cutter arms by their contact with their surface of the earth formation. The speed of rotation of course is controllable by the flow of hydraulic fluid into the hydraulic motor 80 which flow can be controlled from the surface.
- the rate of drilling is also adjustable by the addition or removal of weights 36.
- Rotation of the cutting arms by operation of motors 80 cause rotation of free-wheeling cutters 90 which rotate freely and bearably around an axle housing which contains the axle driving cutters 88.
- Attached to the lower end of drill pipe section 12 is a crusher frame 92 which supports a free-wheeling crusher roller 94 which rotates freely on an axle 96 mounted within frame 92.
- At least two crusher rollers 94 are mounted on frame 92.
- Frame 92 is held non-rotatably by being secured to housing 52. Cuttings broken loose from the earth formation fall toward rollers 94 and are crushed between rollers 94 and a revolving crusher plate 98 which is attached to and revolves with drill pipe 12.
- FIGURE 4 discloses a portion of one of the cutting arms of this underreamer and how the hydraulic motor 80 is connected through a transmission to a drive shaft 106 which is in turn coupled to driven cutter 88.
- Each cutting arm may include more than one driven cutter with each to be driven by its own hydraulic motor.
- each cutting arm may include a suitable number of freewheeling cutters 90, depending upon the length of the cutting arm, weight of the underreamer, earth material to be encountered, and other factors.
- Each cutting arm is pivotally secured to brace 64 by connection of support blocks 108.
- Support block 108 is secured to a cutter arm housing 110 upon which is mounted hydraulic motor 80 at one end, a transmission assembly 112 sealably mounted within housing 110, drive shaft 106, and driven cutter 88 at the other end of housing 110.
- Hydraulic motor 80 is preferably engaged with transmission 112 by means of a flexible coupling 114 of conventional design, transmission 112 is further engaged with drive shaft 106 by a similar flexible coupling 116, and drive shaft 106 preferably engages driven cutter 88 through another flexible coupling 118.
- Free-wheeling cutters 90 are mounted on housing 110 by means of conventional bearings 120.
- driven cutter 88 is bearably mounted on housing 110 to bearings 121.
- FIGURE 5 describes schematically the electrical circuit controlling the operation of this underreamer and the hydraulic components which provide the actuating force for the underreamer.
- a surface control station 122 includes the usual switches to actuate the solenoid valves of each hydraulic component to permit the flow of hydraulic fluid into or from each component as desired to provide the motive force.
- Current through line 124 actuates valve 126
- line 128 actuates valve 130
- line 132 actuates valve 134
- line 136 actuates valves 138 on the cutter arms
- line 140 provides electric power to drive the electric motor in hydraulic component 34.
- the underreamer of this invention is lowered into bore hole 26 in a compacted condition as in FIGURE 1 by means of a usual drilling rig.
- the proper switches on the surface control station 122 are actuated to start the pump in the hydraulic component 134 and to open the hydraulic valves in top stabilizer 40 and bottom stabilizer 50 so that hydraulic fluid flows into cylinders 44 and 54 to force rollers 48 and 58 against the walls of the bore hole.
- closing of a switch on a surface control station 122 to permit current to flow through line 128 will actuate solenoid valve 130 to permit hydraulic fluid to flow from hydraulic component 34 to arm positioner 72 which will cause the cutting arms of the underreamer to bear against the adjacent earth formation during the cutting operation.
- a switch on the surface control station is closed to permit solenoid valves 138 to open so that hydraulic motors will be rotated by hydraulic fluid flowing into them, and these motors Will in turn transmit their rotative energy through the transmission system and drive shaft 106 to driven cutters 88 as they bear against the earth formation.
- the weight imposed upon the underreamer and the rotation of driven cutters 88 cause all the free-wheeling cutters 90 to rotate and remove particles from the earth formation.
- the traction created between drilling cutters 88 and the earth formation causes rotation of the entire underreamer from rotary block 28 downward, except for stabilizers 40 and 50 and crusher frame 92 as described above, so that the torque developed during the drilling operation is utilized by this underreamer in performing the drilling operation rather than subjecting the entire drill string to excessive torque and vibration by rotation of the drill string from the surface.
- Drilling may proceed With the cutting arms extended to any angle less than their full extension, or the underreamer may be maintained in position in the bore hole until the cutting ar-ms have been extended to their full extension as shown in FIGURE 3.
- the diameter of the enlarged section of the bore hole may be chosen between the limits of the cutting arm extension.
- FIGURES l, 2, and 3 describe cutting arms which have four driven cutters on each arm and eight free-wheeling cutters on each arm.
- the number of driven cutters and free-wheeling cutters may be varied as described de pending upon such factors as the desired diameter of the enlarged section, a depth at which the drilling proceeds, the weight imposed upon the underreamer, and the environment in which the underreamer is used. Cuttings removed from the walls of the bore hole fall to the bottom of the enlarged opening and impinge upon the crusher plate 98 which rotates simultaneously with the cutting arms.
- Crusher rollers 94 are held in nonrotative position in relationship to the axis of drill pipe section 12 by reason of attachment to the housing of bottom stabilizer 50, but these crusher rollers rotate freely on crusher axle 60 which supports them in crusher frame 92.
- the particles falling upon crusher plate 98 are reduced in size by the cooperation of plate 98 and roller 94, after which the reduced particles fall through openings 100 in plate 98 to land in collection basin 102 from which they are propelled upward through drill pipe section 12 and drill pipe sections 13 by fluid pumped down the bore hole.
- FIGURE 5 also describes schematically an emergency hydraulic system that, when energized from the surface, will position all components for removal of the underreamer from the bore hole.
- Surface emergency station 142 includes a suitable source of the electricity to operate an electric motor and hydraulic pump included in the station, which system may be automatic or manual, to pump hydraulic fluid through line 144 simultaneously to top stabilizer 44, bottom stabilizer 54, and arm positioner 72, to cause arm positioner 72 to move to its retracted position and to release stabilizers 44 and 54 from their forceable contact with the wall of the bore hole so that the underreamer may be withdrawn from the bore hole in the event of any emergency such as the failure of the down hole hydraulic system.
- An earth formation underreamer comprising:
- hydraulic power means positionable on said supporting body
- a cutter arm rotatively positionable on said supporting body, said cutter arm adaptable to be driven by and positioned axially and radially on said supporting body by said hydraulic power means, crusher means rotatively positionable on said supporting body below said cutter arm and adaptable to be driven by said hydraulic power means, said crusher means adaptable to reduce in size material dislodged from said earth formation by said cutter,
- said stabilizer means is actuated by said hydraulic power means.
- said supporting body is a pipe section.
- said crusher means is actuated by said hydraulic power means.
- said hydraulic power means comprises an electrically driven pump, a reservoir of hydraulic fluid communicable with said pump, and fluid lines connecting said pump to said stabilizer, said cutter arm, said crusher means, and said collection means.
- said cutter arm includes a swivel mounting on said supporting pipe, a supporting arm swivelably attached to said supporting pipe, a stiffening arm swivelably attached to said supporting pipe and to said supporting arm, an axle housing secured to said supporting arm, a driven cutter rotatively claim 8, wherein:
- said stabilizer means includes an upper stabilizer member and a lower stabilizer member, each of said stabilizer members having a supporting frame mounted on said axle housing, a hydraulic motor mounted on said supporting pipe, a pair of extendmounted on said axle housing adjacent said swivel able members attached to said frame, and a roller mounting, transmission assembly operatively conmember on each of said extensible members adaptnected to said motor, a drive axle having one end able to contact said bore hole wall, said extensible meshing with said transmission assembly and a member operable by said hydraulic means.
- second end driving said driven cutter, and a free wheeling cutter mounted bearably on said axle References Cited housing. 7.
- said crusher means comprises a crusher roller swivel- 1841021 1/1932 slmmqns 17517 ably mounted on said supporting pipe adjacent the 7/1932 Grimvlne 175 267 X lower end thereof and a crusher plate mounted be- 28O9015 10/1957 Phipps 175 267 neath said crusher roller and driven rotatively by said hydraulic means to cooperate with said crusher roller in reducing said material in size.
- said crusher means comprises a crusher roller swivel- 1841021 1/1932 slmmqns 17517 ably mounted on said supporting pipe adjacent the 7/1932 Grimvlne 175 267 X lower end thereof and a crusher plate mounted be- 28O9015 10/1957 Phipps 175 267 neath said crusher roller and driven rotatively by said hydraulic means to cooperate with said crusher roller in reducing said material in size.
Description
y 3, 1969 c. E. HOWARD 3,443,648
EARTH FORMAT I ON UNDERREAMER Filed Sept. 13, 1967 Sheet of 4 INVENTOR. CLARENCE E. HOWARD ATTORNEYS EARTH FORMAT I 0N UNDERREAMER Filed Sept. 13, 1967 Sheet 3 of 4 INVENTOR. CLARENCE E. HOWARD Aka/W ATTORNEYS c. E. HOWARD EARTH FORMATION UNDERREAMER May 13, 1969 Sheet Filed Sept. 13. 1967 INVENTOR. CLARENCE E. HOWARD ATTORNEYS y 1969 o. E. HOWARD 3,443,648
I EARTH FORMAT I 0N UNDERREAMER BOTTOM STAB/L lZER Filed Sept. 13, 1967 Sheet 4 of4 SURFACE /42 EMERGENCY 2%; STAT/ON I l 44 "l' /24 I26 1 fL:: I
I I l I 28 I44 TOP STAB/LIZER 1 l l 130 72 l l ELECTRICAL I i POWER CABLE i I l ARM POSITIONER L 54 I 1 I34 l I I CUTTER ARM 8 INVENTOR. CLARENCE E. HOWARD BY/Q/EW ATTORNEYS 3,443,648 EARTH FORMATION UNDERREAMER Clarence E. Howard, Cocoa Beach, Fla., assignor to Fenix & Scisson, Inc., Tulsa, Okla., a corporation of Oklahoma Filed Sept. 13, 1967, Ser. No. 667,580 Int. Cl. E21b 1/06, 3/08, 5/00 US. Cl. 175-103 9 Claims ABSTRACT OF THE DISCLOSURE An underreamer is lowered down a bore hole in an inoperative condition, and upon reaching the desired depth, the apparatus is directed by means of surface controls to begin the operation of enlarging the bore hole. The cutting components may be suspended in the bore hole on a conventional drill pipe with all operating components, except an electric control circuit, positioned at the end of the drill pipe. The cutting components include one or more extensible cutting arms which are arranged to extend angularly outward from the drill pipe and to be operated rotatably by means of a hydraulic power system; Each cutting arm includes at least one self-powered c utter which is driven by a hydraulic motor which receives power from the central hydraulic system, and each cutting arm also includes a plurality of free wheeling cutters which cut by reason of the weight of the drilling system. The drill pipe section upon which the cutting arms are mounted in held in position by stabilizers above and below the cutters. Cuttings fall to a crusher and collector positioned below the cutters and are circulated up through the drill pipe by fluid being pumped into the bore hole.
BACKGROUND OF THE INVENTION This invention relates to earth formation drilling devices, and more particularly to drilling devices for bore holes. Still more particularly, this invention relates to drilling devices for enlarging bore holes which are known as underreamers in which the enlargement of the bore hole is accomplished by hydraulically driven cutters.
It has been known for many years that small diameter drill holes may be provided with enlarged sections, known as bell holes by the operation of expandable drill bits or other cutting tools suspended on the end of a drill pipe. Such expandable drill bits when rotated from the surface may provide an enlarged section of two to three feet in diameter. However, rotary underreamers operated from a rotating drill string have serious practical limitations. Some of these are enumerated below:
As the diameter of the enlarged section increases, the torque on the drill string increases. Very shortly the torque exceeds the ability of drill string to rotate the cutting member.
As the diameter of the enlarged section increases, the necessary strength of the cutting arms cannot be built into the arms or body of the tool.
Uneven cutting provides a rough operation, and the elasticity of the drill string coupled with the uneven cutting of the tool creates shock loading.
And, unless a tool is adequately stabilized, the cut section will be uneven and the desired smoothness and the diameter of the chamber wall will not be obtained. Improper stabilization leads to rough operations, shock loadings and broken tools.
Therefore, the primary object of this invention is to provide an earth formation drilling device which will easily and efliciently produce a large diameter bore hole in an earth formation.
Another object of this invention is to provide an earth nitd States Patent O m 3,443,648 Patented May 13, 1969 formation boring device which can be removably controlled to produce a large diameter bore hole.
Still another object of this invention is to provide an earth formation boring device which can be inserted into a. bore hole in a retracted condition and which can be remotely controlled from the surface to produce an enlarged bore hole section.
Still another object of this invention is to provide an earth formation boring device which is hydraulically driven to produce an enlarged bore hole section.
Another object of this invention is to provide a rotary earth formation boring device which can be suspended down a bore hole on non-rotating suspension means and positioned appropriately to enlarge a desired section of the bore hole.
Further objects and advantages of the invention will become apparent from the following description and claims, and from the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is an elevational view of the bore hole underreamer of this invention showing the device in a retracted position upon entry into a bore hole.
FIGURE 2 is a fragmentary elevational view of a bore hole underreamer according to this invention in position in a bore hole as it is when beginning operation to enlarge the bore hole.
FIGURE 3 is an elevational view of a bore hole underreamer according to this invention showing the device after it has enlarged a section of a bore hole.
FIGURE 4 is a cross-sectional view of a cutting arm of a bore hole underreamer according to this invention.
FIGURE 5 is a schematic circuit diagram of the electric control circuit of a bore hole underreamer according to this invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS The bore hole underreamer of this invention comprises a hydraulically driven cutter arm rotatably positioned on a supporting member such as a drill pipe retained in position by conventional drill pipe supporting devices. The underreaming device is retractable to a compact condition for easy insertion into the bore hole. At the chosen depth in the bore hole stabilizing means are actuated by a hydraulic component incorporated as a part of the underreamer. The stabilizing means is actuated to bear firmly against the side of the bore hole to hold the drill pipe or other suspending means in a non-rotative condition while the cutting arm rotates to cut into the earth formation adjacent the bore hole. Hydraulic means on the device both controls the positioning of the extensible cutting arm and drives a hydraulic motor position on the cutting arm. Operation of this hydraulic motor drives a cutter attached thereto which in turn causes rotation of the cutting arm by contact with the earth formation and also brings about additional cutting by means of contact with the earth formation of a plurality of free-wheeling cutters positioned on the cutting arm. Crusher means positioned beneath the cutting arm is also hydraulically driven and reduces in size particles chipped from the earth formation. Material passing through the crusher means is caught by collection means positioned thereunder and caused to circulate to the surface by fluid passing down the bore hole. The hydraulic means positioned down the bore hole as a part of an underreaming device is controlled from the surface by an electric circuit. Thus, all the major operating components of the underreamer are positioned at one location in the bore hole and only the electric control circuit is at the surface. A suitable device for circulating fluid down the bore hole to flush out particles removed from the earth formation is also controlled by the electric circuit means and they consist of conventional pumps for either a gas such as air or nitrogen, or a liquid such as water or oil.
Referring now to the drawings in detail, FIGURE 1 shows a bore hole underreamer 10, generally, which is mounted on a section of drill pipe 12 to which additional sections of drill pipe may be added, and which may be suspended in any well known form of conventional traveling block 14, which may be supported by well known means as by cables 16 and held in position on traveling block 14 by means of a conventional bushing. The entire apparatus including the underreamer, drill pipe, and suspension cables may be mounted in the usual form of drilling rig 20 which provides that the structure for positioning the underreamer down the bore hole and removing the underreamer by the addition or removal of additional drill pipe sections as necessary. The usual drilling rig includes floor 22 having a central opening 24 therein which is aligned with bore hole 26. Bore hole 26 has already been drilled to the prescribed depth by independent conventional drilling means preferably using the same drilling rig 20 as employed in the suspension of the underreamer of this invention. As a typical example of the use to be made of this underreamer, bore hole 26 may be an enlarged diameter bore such as 48-inch hole with the underreamer of this invention designed to enlarge this bore hole to a diameter of 28 feet. Of course, it is contemplated that smaller bore holes may be enlarged to larger diameters.
In FIGURES 1 through 3 it is seen that the underreamer of this invention is positioned on modified drill pipe section 12 which is secured bearably at its upper end to a rotary terminal block 28 which receives electric wires 30 from the surface and by rotating connections within block 28 conducts electric current from wires 30 to wires 32 which pass the motive current to an electric pump and electric motor within hydraulic component 34. The electric motor and pump are not shown since these are simply of conventional design. Hydraulic component 34 includes an accumulator of hydraulic reservoir for the hydraulic fluid circulating through the system to hydraulic cylinders and motors hereinafter described. Thus, by this arrangement, only a single section of drill pipe is being rotated during the underreaming operation rather than the entire drill string which is the usual procedure. On drill pipe section 13 which may be a conventional section of drill pipe, a variable amount of weight may be positioned such as removable weights 36 which rest on a base plate 38. By this means the underreaming force may be varied as desired. Also on drill pipe section 13 is bearably positioned an upper stabilizer 40 which includes a housing section 42 having therein conventional bearings abutting pipe section 13, and an extensible hydraulic cylinder secured pivotally to housing 42 and having each side of a. piston therein connected to hydraulic lines from hydraulic component 34 as described in FIGURE 5. Hydraulic cylinder 44 is in turn pivotally connected to frame 46 on which is mounted rollers 48. Then, actuation of hydraulic cylinder 44 in one direction will force rollers 48 into firm contact with the wall of bore hole 26 to stabilize the underreamer during operation. A similar stabilizer 50 is mounted bearably near the lower end of the underreamer on a housing 52 with a hydraulic cylinder 54 pivotally attached to housing 52 and pivotally attached to frame 56. Frame 56 also has rollers 58 therein which can be put into contact with the walls of the bore hole. Thus, actuation of hydraulic cylinders 44 and 54 can extend rollers 48 and 58 against the wall of the bore hole to a chosen degree so that the cutting components of the underreamer can be properly guided to provide a clean, true underreaming operation.
One or more cutting arms are mounted on drill pipe section 12, but preferably for heavy duty work and for balancing of the torque developed, at least two cutting arms should be employed. Each cutting arm includes an adjustable brace 64 pivotally mounted to a housing 66 mounted on drill pipe section 12 with the other end of housing 66 pivotally mounted to a supporting arm 68 which in turn is pivotally mounted at its lower end to a housing 70 secured to drill pipe section 12. Positioning of the cutter arms is provided by the operation of a hydraulic cylinder 72 mounted pivotally between housing 66 and housing 74. Hydraulic cylinder 72 includes a piston therein which has its opposite faces adaptable to be contacted by hydraulic fluid passing through lines 76 and 78 from hydraulic component 34. A solenoid valve is included within hydraulic component 34 to control the flow of fluid to and from cylinders 72 so that the cutting arms may be positioned as desired. The construction of each cutting arm is more clearly shown in FIGURE 4. However, in FIGURE 3 is shown the hydraulic connections from hydraulic component 34 to each hydraulic motor 80 of each cutting arm. One such hydraulic line 82 supplies fluid to each motor and another line 84 serves as a return line to an accumulator within hydraulic component 34, such as is represented by accumulator 86 shown in FIGURE 5. Motors 80 drive an internal shaft which is connected to driven cutters 88 which cause rotation of the cutter arms by their contact with their surface of the earth formation. The speed of rotation of course is controllable by the flow of hydraulic fluid into the hydraulic motor 80 which flow can be controlled from the surface. The rate of drilling is also adjustable by the addition or removal of weights 36. Rotation of the cutting arms by operation of motors 80 cause rotation of free-wheeling cutters 90 which rotate freely and bearably around an axle housing which contains the axle driving cutters 88. Attached to the lower end of drill pipe section 12 is a crusher frame 92 which supports a free-wheeling crusher roller 94 which rotates freely on an axle 96 mounted within frame 92. At least two crusher rollers 94 are mounted on frame 92. Frame 92 is held non-rotatably by being secured to housing 52. Cuttings broken loose from the earth formation fall toward rollers 94 and are crushed between rollers 94 and a revolving crusher plate 98 which is attached to and revolves with drill pipe 12. As cuttings are crushed between rollers 94 and plate 98 the reduced particles fall through fine openings 100 in plate 98 and are caught in a collection basin 102 secured to non-rotating crusher frame 92. For removal of fine cuttings, water, air, or other fluid is passed downward through the bore hole 26 and the fine cuttings are washed upwardly through the open center 104 of drill pipe 12 eventually to reach the surface.
FIGURE 4 discloses a portion of one of the cutting arms of this underreamer and how the hydraulic motor 80 is connected through a transmission to a drive shaft 106 which is in turn coupled to driven cutter 88. Each cutting arm may include more than one driven cutter with each to be driven by its own hydraulic motor. Also, each cutting arm may include a suitable number of freewheeling cutters 90, depending upon the length of the cutting arm, weight of the underreamer, earth material to be encountered, and other factors. Each cutting arm is pivotally secured to brace 64 by connection of support blocks 108. Support block 108 is secured to a cutter arm housing 110 upon which is mounted hydraulic motor 80 at one end, a transmission assembly 112 sealably mounted within housing 110, drive shaft 106, and driven cutter 88 at the other end of housing 110. Hydraulic motor 80 is preferably engaged with transmission 112 by means of a flexible coupling 114 of conventional design, transmission 112 is further engaged with drive shaft 106 by a similar flexible coupling 116, and drive shaft 106 preferably engages driven cutter 88 through another flexible coupling 118. Free-wheeling cutters 90 are mounted on housing 110 by means of conventional bearings 120. Also, driven cutter 88 is bearably mounted on housing 110 to bearings 121.
FIGURE 5 describes schematically the electrical circuit controlling the operation of this underreamer and the hydraulic components which provide the actuating force for the underreamer. A surface control station 122 includes the usual switches to actuate the solenoid valves of each hydraulic component to permit the flow of hydraulic fluid into or from each component as desired to provide the motive force. Current through line 124 actuates valve 126, line 128 actuates valve 130, line 132 actuates valve 134, line 136 actuates valves 138 on the cutter arms, and line 140 provides electric power to drive the electric motor in hydraulic component 34.
In operation, the underreamer of this invention is lowered into bore hole 26 in a compacted condition as in FIGURE 1 by means of a usual drilling rig. Upon reaching the desired depth, the proper switches on the surface control station 122 are actuated to start the pump in the hydraulic component 134 and to open the hydraulic valves in top stabilizer 40 and bottom stabilizer 50 so that hydraulic fluid flows into cylinders 44 and 54 to force rollers 48 and 58 against the walls of the bore hole. Then, closing of a switch on a surface control station 122 to permit current to flow through line 128 will actuate solenoid valve 130 to permit hydraulic fluid to flow from hydraulic component 34 to arm positioner 72 which will cause the cutting arms of the underreamer to bear against the adjacent earth formation during the cutting operation. At the same time, a switch on the surface control station is closed to permit solenoid valves 138 to open so that hydraulic motors will be rotated by hydraulic fluid flowing into them, and these motors Will in turn transmit their rotative energy through the transmission system and drive shaft 106 to driven cutters 88 as they bear against the earth formation. The weight imposed upon the underreamer and the rotation of driven cutters 88 cause all the free-wheeling cutters 90 to rotate and remove particles from the earth formation. Also, the traction created between drilling cutters 88 and the earth formation causes rotation of the entire underreamer from rotary block 28 downward, except for stabilizers 40 and 50 and crusher frame 92 as described above, so that the torque developed during the drilling operation is utilized by this underreamer in performing the drilling operation rather than subjecting the entire drill string to excessive torque and vibration by rotation of the drill string from the surface. Drilling may proceed With the cutting arms extended to any angle less than their full extension, or the underreamer may be maintained in position in the bore hole until the cutting ar-ms have been extended to their full extension as shown in FIGURE 3. Thus, the diameter of the enlarged section of the bore hole may be chosen between the limits of the cutting arm extension. When the cutting arms have been extended to a desired diameter, the underreamer may be lowered in the bore hole so that the enlarged Section of the bore hole may be lengthened as shown in FIGURE 3. FIGURES l, 2, and 3 describe cutting arms which have four driven cutters on each arm and eight free-wheeling cutters on each arm. Of course, the number of driven cutters and free-wheeling cutters may be varied as described de pending upon such factors as the desired diameter of the enlarged section, a depth at which the drilling proceeds, the weight imposed upon the underreamer, and the environment in which the underreamer is used. Cuttings removed from the walls of the bore hole fall to the bottom of the enlarged opening and impinge upon the crusher plate 98 which rotates simultaneously with the cutting arms. Crusher rollers 94 are held in nonrotative position in relationship to the axis of drill pipe section 12 by reason of attachment to the housing of bottom stabilizer 50, but these crusher rollers rotate freely on crusher axle 60 which supports them in crusher frame 92. The particles falling upon crusher plate 98 are reduced in size by the cooperation of plate 98 and roller 94, after which the reduced particles fall through openings 100 in plate 98 to land in collection basin 102 from which they are propelled upward through drill pipe section 12 and drill pipe sections 13 by fluid pumped down the bore hole.
FIGURE 5 also describes schematically an emergency hydraulic system that, when energized from the surface, will position all components for removal of the underreamer from the bore hole. Surface emergency station 142 includes a suitable source of the electricity to operate an electric motor and hydraulic pump included in the station, which system may be automatic or manual, to pump hydraulic fluid through line 144 simultaneously to top stabilizer 44, bottom stabilizer 54, and arm positioner 72, to cause arm positioner 72 to move to its retracted position and to release stabilizers 44 and 54 from their forceable contact with the wall of the bore hole so that the underreamer may be withdrawn from the bore hole in the event of any emergency such as the failure of the down hole hydraulic system.
I claim:
1. An earth formation underreamer comprising:
a rotatable supporting body,
means to suspend said supporting bodyin a bore hole,
hydraulic power means positionable on said supporting body,
stabilizer means positioned on said supporting body adaptable to bear against the wall of said here hole,
a cutter arm rotatively positionable on said supporting body, said cutter arm adaptable to be driven by and positioned axially and radially on said supporting body by said hydraulic power means, crusher means rotatively positionable on said supporting body below said cutter arm and adaptable to be driven by said hydraulic power means, said crusher means adaptable to reduce in size material dislodged from said earth formation by said cutter,
collection means cooperating with said crusher means and said supporting body to collect and circulate to the surface said material passing through said crusher means, and
electric circuit means controllable from the surface of the ground to operate said hydraulic power means.
2. An earth formation underreamer as described in claim 1, wherein:
said stabilizer means is actuated by said hydraulic power means.
3. An earth formation underreamer as described in claim 2, wherein:
said supporting body is a pipe section.
4. An earth formation underreamer as described in claim 3, wherein:
said crusher means is actuated by said hydraulic power means.
5. An earth formation underreamer as described in claim 4, wherein:
said hydraulic power means comprises an electrically driven pump, a reservoir of hydraulic fluid communicable with said pump, and fluid lines connecting said pump to said stabilizer, said cutter arm, said crusher means, and said collection means. 6. An earth formation underreamer as described in claim 5, wherein:
said cutter arm includes a swivel mounting on said supporting pipe, a supporting arm swivelably attached to said supporting pipe, a stiffening arm swivelably attached to said supporting pipe and to said supporting arm, an axle housing secured to said supporting arm, a driven cutter rotatively claim 8, wherein:
said stabilizer means includes an upper stabilizer member and a lower stabilizer member, each of said stabilizer members having a supporting frame mounted on said axle housing, a hydraulic motor mounted on said supporting pipe, a pair of extendmounted on said axle housing adjacent said swivel able members attached to said frame, and a roller mounting, transmission assembly operatively conmember on each of said extensible members adaptnected to said motor, a drive axle having one end able to contact said bore hole wall, said extensible meshing with said transmission assembly and a member operable by said hydraulic means. second end driving said driven cutter, and a free wheeling cutter mounted bearably on said axle References Cited housing. 7. An earth formation underreamer as described in UNITED STATES PATENTS c1aim6wherein: 494,779 4/ 1893 Gardner l75--102 said crusher means comprises a crusher roller swivel- 1841021 1/1932 slmmqns 17517 ably mounted on said supporting pipe adjacent the 7/1932 Grimvlne 175 267 X lower end thereof and a crusher plate mounted be- 28O9015 10/1957 Phipps 175 267 neath said crusher roller and driven rotatively by said hydraulic means to cooperate with said crusher roller in reducing said material in size. 8. An earth formation underreamer as described in claim 7, wherein:
ERNEST R. PURSER, Primary Examiner.
US. Cl. X.R.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US66758067A | 1967-09-13 | 1967-09-13 |
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US667580A Expired - Lifetime US3443648A (en) | 1967-09-13 | 1967-09-13 | Earth formation underreamer |
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