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Publication numberUS2548463 A
Publication typeGrant
Publication dateApr 10, 1951
Filing dateDec 13, 1947
Priority dateDec 13, 1947
Publication numberUS 2548463 A, US 2548463A, US-A-2548463, US2548463 A, US2548463A
InventorsBlood Robert H
Original AssigneeStandard Oil Dev Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Thermal shock drilling bit
US 2548463 A
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Description  (OCR text may contain errors)

April '10, 1951 R. H. BLOOD THERMAL. SHOCK DRILLING BIT 3 6 A. 8 4 5 Y Z,

Filed Deo. 13, 1947 2 Sheets-Sheet l 2 mmm OXYGEN Qobert H. Ealooc u nventcr April 10, 1951 R. H. BLOOD THERMAL sHocx DRILLING BIT 2 Sheets-Sheet 2 Filed Dec. 13, 1947 Nl H l Qoberb H4 Pglooc Bru/enter' Patented Apr. 10, 1951 THERMAL SHOCK DRILLING BIT Robert H. Blood, Tulsa, Okla., assignor to Standard Oil Development Company, a corporation of Delaware l d Application December 13, 1947, Serial No. 791,553

(Cl. Z55-61) 3 Claims.

1 This invention relates to improved means and method for drilling through hard formations. It

particularly relates to the provision of a drilling mechanism designed to alternately heat and cool hard formations in oil drilling operations so as to cause fracture of the hard formations.

In accordance with the present invention heating and cooling means are spaced around thehead of a drilling device designed to alternately subject formations in contact with the rotating drilling device to veryrhigh and reasonably low temperatures as the device is rotated. In particular itis proposed to maintain an oxyacetelene flame' in one nozzle or a group of nozzles while a cooling meduim such as drilling mud is forced through another nozzle or group of nozzles positioned on the drilling device. As this device is rotated, formations in contact with the drill are periodically heated and cooled. This cooling and heating is operative to fracture hard formations.

At the present time in conventional oil drilling operations the expense of the procedure is greatly increased by the necessity for drilling through extremely hard formations. Conventionally it is necessary to employ specially constructed drilling tools having extremely hard cutting edges in order to out through hard formations. The drilling rate attainable may be extremely slow and it is necessary to frequently replace the drilling tool. It is the purpose of the proposed invention to overcome these disadvantages of the conventional drilling processes for hard formations by providing a means for fracturing the rock by subjecting the rock to the application of rapid temperature differentials. By this means the rapid expansion and contraction caused by the applied temperature differential results in the fracture of particles of the rock. A conventional drilling device may then be used to remove the fractured rock.

It is a further object of my invention to increase the rate at which a hard formation may be drilled.

It is a further object of my invention toincrease the life of conventional tools employed for drilling hard formations.

Further objects' and advantages of my invention will be more fully understood from the following detailed description in connection with the accompanying drawings in which:

Figure l diagrammatically shows partially in section a complete embodiment of my invention;

Figure 2 shows in cross-section the construction of a swivel which may be employed to permit rotation of the drilling device;

Figure 3 shows an end view of the head of the drilling device; and,

Figure 4 shows a section of the drilling device through two adjacent nozzles of Figure 3.

Referring now to Figure l, the numeral I designates a hole drilled in the earth. This hole may have been partially drilled by conventional drill- ,2 y ing methods to such a depth that hard formations 2 are encountered. At this stage of the drilling operations the embodiment of my invention illustrated in Figure 1 may be employed. l

This consists of a drilling device 3 positioned at the bottom of the drill string 4. The drill string comprises 3 pipes, that is, pipes 5, 6 and l, positioned one within another providing passageways 8, 9, and It. Through these passageways or chambers the necessary combustible gases and the necessary cooling fluid are conducted to the drilling device 3. Conventional rotating means designated by the rectangles II and I2 are employed to rotate the drilling string. These means conventionally comprise a power driven rotating table which drives a gear xed to the drilling string. As the means for driving or rotating the drilling stem is no part of my present invention,

no details are given. The drilling device 3 consists of an outer casing I 'I which may have 4 nozzles I3, It, l5, and I6, extending from the casing. As illustrated in the drawing, Vtwo of these nozzles, I4 and I6, are'connected to the chamber of the pipestring through which drilling mud flows. Two other nozzles, I3 and I5, are connected to the chambers through which the combustible gases such as oxygen and acetylene are conducted. Thus one set of nozzles provides a source lof intense localized heat while the other set of nozzles provides a localized cooling effect. By virtue of rotation of the drilling string thev drilling device 3 is caused to rotate, successively subjecting a particular portion of rock which is 'below the drilling Ydevice to the alternate action of the hot and cold nozzles. A conventional drilling bit I8 may be positioned on the casing of the drilling device, extending somewhat below they nozzles to aid in the removal of fractured rock. This drilling bit may comprise the usual type of drag bit or fish tail bit. As stated oxygen, acetylene, and drilling mud are separately conveyed through the chambers of the drilling string. Oxygen may be conducted through the chamber I0 while acetylene may be conducted through the annular space 9 While drilling mud may be conducted throughthe outer annular space 8. Alternatively, the oxygen and .acetylene may be conducted through a common passage but this procedure is not desirable since the presence of the combined oxygen Yand acetylene streams throughout the length of the drilling stem would constitute a severe safety hazard. lDrilling mud is introduced to the annular space 8 by means of the inlet line 2l! pumped by a suitable pump. Oxygen and acetylene may conveniently be added to the spaces 9 and Ill from standard gas tanks ZI and 22. In order to permit the upper part of the assembly consisting of the line through which the mud and gases are introduced to be stationary, conventional swivels are employed. The swivels are diagrammatically illustrated in 3 Figure 1 by the packed joints 23, 24 and 25. Figure 2 shows, in cross-section detail a suitable construction for these swivels. As illustrated in Figure 2, the stationary line 20 may be connected to the rotating line I by means of the swivel con! struction illustrated. An outwardly extending collar 25 is provided on the line 28 so as to support a thrust bearing 26 resting on the uppermost portion of the thrust collar 25. Bearing against the upper part of the thrust collar 25 is a circular supporting means 2'I providing internal threads 23 for the support of the lower drill pipe '1. The drill pipe 'I is screwed into the supporting member 21 so as to tightly compress packing 29 compressed between the outer surface of the line 20 and the inner surface of the line l. By this means a fluid tight seal is provided between the A lines 'I and 2D while at the same time rotation of the line 'I with respect to the line 2li is possible. Similar construction may be employed for the other swivels.

Referring now to Figurec a section of the embodiment of Figure i taken substantially through the line 4-4 of Figure 3 is illustrated. The nozzle I4 is one of the nozzles adapted to eject a iiow of drilling mud towards the formation directly below the drilling device. The drilling mud, or other cooling iluid, ilows through the string of pipe in the annular space 8 and is pumped through the nozzle I4. The nozzle I adjacently positioned on the drilling device, is adapted to burn the oxygen and acetylene conducted to the nozzle through the passages 9 and IU. It is preferable to conduct the oxygen through the innermost passage l0 while conducting the acetylene through the outer passage 9 combining the flow of gases at the tip of the nozzle l5. As it is not desired to continue the burning of the acetylene during periods when the device is not in operative position, a special igniting means is included in the nozzle adapted to ignite the acetylene when desired. A high resistance wire I3 is fixed across the tip of the nozzle I5. An insulated conductor 30 connects one side of the heating wire I3 to a nxed contact 3I of a switch 32. The other side of the heating wire I3 is connected to a bimetallic strip 33 which is constructed to serve as a second switch. When the bimetallic strip 33 is cool, the strip contacts the extending lug 34 while the strip when hot, will bend away from this lug. A battery 35 is connected so that one pole is connected to the metal structure of which the lug 34 is a part, while the other pole is connected to the switch 32. Suitable insulating means 31 are employed to properly insulate the electrical circuit. The switch 32 consists of a vane-like make and break member which is normally maintained in the open position by means of the spring 3S. When it is desired to start the operation of the drilling device, a now of oxygen and acetylene is initiated through the passages 9 and I0. IThis ow is operative to act upon the vane-like switch 32 closing the switch. At this point in the operation the bimetallic strip 33 will also be in the closed position, the device being relatively cool. Consequently the battery circuit will be completed through the resistance wire I3 which will heat sufficiently to ignite the oxygen-acetylene stream. On ignition of the acetylene, the nozzle I 4 will of course become hot. This heat will be effective in causing the bimetallic strip to change shape suiciently to open the electrical circuit through the wire I3. The heat will cause the bimetallic strip to bend away from the contact 34 discontinuing the flow of current through the heating wire. The wire I 3 used to ignite the acetylene may consist of any suitable high resistance electrical wire. The battery 35 employed to supply current to the wire may also consist of any suitable voltage source. It may be desirable to employ an induction coil in connection with the battery to supply higher voltages to the resistance Wlle.

In the operation of my invention, conventional drilling rates may be employed. In general the drill will be rotated between 60 to 400 revolutions per minute. For drilling through particularly hard formations it is preferred that the drilling rate be about 60 to 120 revolutions per minute. In any event, a drilling rate may be maintained which is somewhat greater than that attainable using conventional hard formation drills.

As described, my invention comprises the method and apparatus for subjecting a hard for mation to rapid changes in temperature. It is apparent many modifications may be made of the embodiment particularly illustrated and described. .For example, any suitable gas other than acetylene may be employed. Again any desired arrangement of nozzles or passageways may be used. Consequently it is desired that the appended claims be given a broad interpretation commensurate with the prior art.

Having now fully described my invention, I claim:

1. Apparatus for the drilling of hard formations comprising a rotatable ,elongate casing provided with a plurality of separate passageways at least one of which is adapted to conduct cooling iiuid to the lower end of said casing and others of which are adapted to conduct combustible gases and combustion supporting gases to the lower end of said casing, a plurality of nozzles afxed adjacent the lower portion of said casing and extending in a generally downward direction therefrom, said nozzles being arranged in circumferential relation about the lower end of said casing, alternate nozzles communicating with the passageway adapted to conduct cooling iluid and the remaining nozzles communicating with the passageways adapted to conduct combustible gases and combustion supporting gases, and a metallic bit aflixed to the bottom of said casing and extending below said nozzles.

2. Apparatus dened by claim 1 wherein each of Said nozzles communicating with said passageways for combustible gas and combustion supporting gas comprises an outer tubing communicating with one of said passageways and an inner tubing terminating short of the outer tubing and communicating with another of said passageways.

3. Apparatus defined by claim 2 wherein elec trical means for igniting combustible gases is disposed within each of said nozzles adjacent said inner tubing.

ROBERT H. BLOOD.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Burch Aug. 24, 1943

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2077297 *Oct 1, 1934Apr 13, 1937Bernard Williams JamesAutomatic control and electric ignition for gas burners
US2111872 *Nov 6, 1933Mar 22, 1938Rea Walter CMethod of and apparatus for quarrying and shaping rock and stone
US2248737 *Oct 21, 1938Jul 8, 1941Bryant Heater CoPilot control
US2296686 *Jun 10, 1940Sep 22, 1942 Gas pilot and valve control
US2327496 *Dec 3, 1940Aug 24, 1943Linde Air Prod CoMethod of and apparatus for working mineral materials and the like
Referenced by
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US2628817 *Jan 24, 1950Feb 17, 1953Union Carbide & Carbon CorpRock piercing blowpipe
US2675993 *Mar 25, 1948Apr 20, 1954Union Carbide & Carbon CorpMethod and apparatus for thermally working minerals and mineral-like materials
US2675994 *Mar 25, 1948Apr 20, 1954Union Carbide & Carbon CorpThermal mineral piercing method and apparatus
US2776816 *Sep 17, 1953Jan 8, 1957Well Completions IncApparatus for and method of earth bore drilling
US2816735 *Jul 13, 1956Dec 17, 1957Rachel DalindaMethod and apparatus for drilling with dissociated gas
US2822148 *Feb 23, 1954Feb 4, 1958Murray Robert WElectric boring apparatus
US2939688 *Oct 5, 1955Jun 7, 1960Sinclair Oil & Gas CompanyOpening fissures in low-permeability strata
US2976941 *May 25, 1956Mar 28, 1961Fletcher Co H EMethod for thermal mineral piercing
US3042115 *Jun 3, 1954Jul 3, 1962Orpha B BrandonApparatus for forming and/or augmenting an energy wave
US3045766 *Aug 22, 1958Jul 24, 1962Union Carbide CorpSuspension type rotary piercing process and apparatus
US3093197 *Dec 9, 1958Jun 11, 1963Union Carbide CorpMethod and apparatus for thermally working minerals and mineral-like materials
US3115184 *Jan 4, 1960Dec 24, 1963Well Completions IncMethod and apparatus for severing casings and the like
US3152651 *Jan 15, 1962Oct 13, 1964Ross Sigmund LExcavating apparatus and method
US3212592 *Dec 13, 1963Oct 19, 1965Union Carbide CorpThermal mechanical mineral piercing
US3475055 *Jun 8, 1967Oct 28, 1969Mason & Hanger Silas Mason CoThermal tunneling apparatus and method
US3704914 *Nov 27, 1970Dec 5, 1972Fletcher Co H EMethod of fluid jet cutting for materials including rock and compositions containing rock aggregates
US3826537 *Feb 15, 1973Jul 30, 1974Copper Range CoMining and tunneling process involving alternated application of thermal and mechanical energy
US3881559 *Jul 10, 1974May 6, 1975Us NavyMethod for stress wave drilling
US3998281 *Nov 10, 1974Dec 21, 1976Salisbury Winfield WEarth boring method employing high powered laser and alternate fluid pulses
US4066138 *Dec 15, 1976Jan 3, 1978Salisbury Winfield WEarth boring apparatus employing high powered laser
US4073351 *Jun 10, 1976Feb 14, 1978Pei, Inc.Burners for flame jet drill
US4711310 *Nov 1, 1985Dec 8, 1987Luen Lam MFor a drilling machine
US8424617Aug 19, 2009Apr 23, 2013Foro Energy Inc.Methods and apparatus for delivering high power laser energy to a surface
US8511401Aug 19, 2009Aug 20, 2013Foro Energy, Inc.Method and apparatus for delivering high power laser energy over long distances
US8571368Jul 21, 2010Oct 29, 2013Foro Energy, Inc.Optical fiber configurations for transmission of laser energy over great distances
US8627901Oct 1, 2010Jan 14, 2014Foro Energy, Inc.Laser bottom hole assembly
US8636085Aug 19, 2009Jan 28, 2014Foro Energy, Inc.Methods and apparatus for removal and control of material in laser drilling of a borehole
US8662160Aug 16, 2011Mar 4, 2014Foro Energy Inc.Systems and conveyance structures for high power long distance laser transmission
US8684088Feb 24, 2011Apr 1, 2014Foro Energy, Inc.Shear laser module and method of retrofitting and use
US8701794Mar 13, 2013Apr 22, 2014Foro Energy, Inc.High power laser perforating tools and systems
US8720584Feb 24, 2011May 13, 2014Foro Energy, Inc.Laser assisted system for controlling deep water drilling emergency situations
US8757292Mar 13, 2013Jun 24, 2014Foro Energy, Inc.Methods for enhancing the efficiency of creating a borehole using high power laser systems
US8783360Feb 24, 2011Jul 22, 2014Foro Energy, Inc.Laser assisted riser disconnect and method of use
US8783361Feb 24, 2011Jul 22, 2014Foro Energy, Inc.Laser assisted blowout preventer and methods of use
EP0398405A1 *Apr 9, 1990Nov 22, 1990Schneider, FrancineDuel jet method
WO1990014200A1 *Apr 9, 1990Nov 17, 1990Durr IsabelleTwin-jet process
Classifications
U.S. Classification175/14, 431/202, 175/212, 116/22.00A, 175/15
International ClassificationE21B7/14
Cooperative ClassificationE21B7/14
European ClassificationE21B7/14