US2307729A - Well explosive - Google Patents

Well explosive Download PDF

Info

Publication number
US2307729A
US2307729A US262531A US26253139A US2307729A US 2307729 A US2307729 A US 2307729A US 262531 A US262531 A US 262531A US 26253139 A US26253139 A US 26253139A US 2307729 A US2307729 A US 2307729A
Authority
US
United States
Prior art keywords
formation
projectile
explosive
bore hole
well
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US262531A
Inventor
Foster James Lewis
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to US262531A priority Critical patent/US2307729A/en
Priority to US467657A priority patent/US2408419A/en
Application granted granted Critical
Publication of US2307729A publication Critical patent/US2307729A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B43/00Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
    • E21B43/11Perforators; Permeators
    • E21B43/116Gun or shaped-charge perforators

Definitions

  • This invention relates to a method of placing an explosive projectile in a subterranean formation, and more particularly to the ring of these projectiles from a. well into a fluid-bearing for-l mation to increase therecovery of said fluid.
  • Fig, l is a fragmentary vertical section of an earth formation, showing the tool partly in elevation and partly in section, disposed in a well;
  • Fig. 2 ⁇ is a fragmentary horizontal section through the tool, on the line 2-2 of Fig. 1;
  • Fig. 3 is a longitudinal section through a form ci a projectile used in connection with the tool;
  • Fig. i is a similar View of a modified form ci projectile useclin the tool.
  • Fig. 5 is a diagrammatic view of a wiring diagram for sequentially firing a plurality of explosive charges Within the tool.
  • the numeral l represents the body of a tool which carries a plurality of radially disposed explosive chambers or cannons 2 which are preferably spaced along the length of the tool, preferably being turned in different radial directions relative thereto.
  • These cannons have removable barrels 3 which may be taken out of the tool i, being removably placed in sockets t in the tool I.
  • the removable barrels 3 are held in place in recess 1 by bolts t and within the outer end of this barrel is disposedthe threaded bushing 8 which engages shear ring II and causes the ring to seat upon gasket 5 ⁇ This prevents the moisture from entering the powder chamber 9.
  • This threaded bushing forms an extension of cannon barrel 2 and is removed each time a new projectile is inserted.
  • an explosive charg'e 9 is placed in each of the cannon bores 2 behind an explosive projectile I0 or l0' therein, upon which projectile an expansive shear ring II has been iitted, is slipped into an annular recess I2 in the cannon bore 2.
  • a percussion cap I3 is fitted into an opening Ii in the cannon barrel 3, longitudinally of the tool, so that iiring pin I5 will detonate the cap i3 and the adjacent explosive charge i) upon the striking of the firing pin I5 by the hammer I6.
  • the hammer I6 is operated by an electro-magnetic coil or solenoid il when electrical energy is supplied thereto.
  • the entire solenoid mechanism is contained in a casing I8 and may be inserted into or removed from the tool through the recess t therein.
  • a source of electrical energy such as a battery 2U is connected with circuit 2
  • a switch arm 22 rests on contact plate 23 (Fig. 2) which closes the circuit to the coil Il and actuates the hammer I6 by the force exerted in magnetic coil Il.
  • a pointed end 2t of the hammer which pointed end 2li is made of fiber or other insulating material and 'which normally holds the switch arm 22 retracted, is withdrawn and permits switch arm 22 to be moved into the position shown in dotted lines and the solenoid Il is deenergized, releasing the hammer i6, and upon the return of the hammer It under pressure of spring 26 bearing thereagainst, the pointed end 23 will push the switch point oli contact plate 23 against contact 23', to dotted line position as indicated at 22" (Fig. 2).
  • A an explosive projectile is shot into the stratum for a short distance and the force of the explosive is used to blow the formation toward the well.
  • A an explosive projectile is shot into the stratum for a short distance and the force of the explosive is used to blow the formation toward the well.
  • a formation which has become sealed with paraffin, asphalt, mud or other foreign material that renders the formation non-productive of oil may be removed by placing a projectile a. short distance beyond the wall of the bore hole and detonating it so that this foreign substance will be loosened, and may be cleaned from the well.
  • a new porous surface is thus produced which has a larger exposed area, thereby giving the Well greater productivity.
  • the amount of explosive 3 in chamber 2 is increased so as to drive the projectile a greater distance into the stratum than shown at A.
  • This projectile may be so constructed as shown in Fig. Il, that it will be blown into bits, each of the fragments cutting a channel in the stratum, and in this manner a passage is formed for some distance out into the stratum with a basin at the outer end, and passages radiating from said basin, thus opening up producing stratum, or permitting 'chemicals to be introduced into certain types of formations where they will work with greater rapidity and edectiveness than if introduced into the immediate bore hole of the well.
  • IZCwo types of projectiles are shown in Figs. 3 and 4, respectively.
  • the type shown in Fig. 3 has a round nose 23 which is fitted with a firing pin 23 which strikes percussion cap 33. This ignites a fuse 3l which may be varied in length to delay the firing of the explosive charge 32 until the projectile has. traveled the desired distance into the stratum.
  • the interior of the projectile is accessible for loading as by forming it in sections screw-threaded together at 33.
  • the nose 23 is crushed upon striking a formation of sufiicient hardness and this drives pin 23 against percussion cap 33.
  • a short fuse is shown to indicate the placing of the explosive charge only a short distance from the bore hole.
  • the shear ring Ii retains the projectile within the cannon barrel until the greater part of the explosive charge is burned. In this manner the full eectiveness of the charge is obtained upon the shearing of expansive shear ring Il.
  • the form of projectile as shown in Fig. 4 is preferably made of cast metal, in two parts also screw-threaded vtogether at 33', and has annular and longitudinal grooves 33 and 3ft respectively, disposed within the chamber 32 which is designed to carry the explosive charge.
  • This form is shown with a sharp nose and pointed firing pin 33, which may be advantageous in penetrating hard types of formation.
  • the pointed firing pin 33 is in position to strike percussion cap 33 upon impact with a substantially nonyielding formation.
  • a shear pin 33 is provided which will shear when the projectile is driven into a hard formation. Upon the detonation of cap 33 a powder train All will be ignited.
  • This powder train together with the speed with which the powder burns, will be computed, so as to permit the projectile to travel the desired distance into the formation before detonating the explosive contained in the chamber 33.
  • 'Ihis type of projectile will form a long passage with a basin at the end thereof and radiating passages outward therefrom, in the formation.
  • the tool may also be used to obtain samples of formation in the proximity of the detonated projectile, as the force of the explosion of the projectile I3 or i3' will force a portion of the formation into a cannon barrel, as indicated at t3, which portion may be removed from the well for analysis.
  • the lower end of the tool is preferably tapered to a point to facilitate its insertion into, as well as its removal from the well after the explosion of the projectiles when the explosions would have forced a quantity of the formation into the bore hole.
  • a process of treating a well having a surrounding lluid-bearing earth formation comprislng firing a projectile into said surrounding fluid bearing earth formation, and subsequently exploding the projectile in said formation.
  • a process of treating a well having .a bore hole with a surrounding fluid-bearing earth formation comprising ring a projectile from within said bore hole laterally at an angle to the axis thereof into said formation, subsequently exploding the projectile in said formation forming one or more passageways from the point of detonation into the bore hole, and flowing the uid from said formation through said one or more passage- Ways into the bore hole.
  • a process of obtaining a sample from a well bore hole having a surrounding iiuid bearing earth formation comprising introducing into the bore hole a gun having a recess in the periphery thereof w th said recess immediately adjacent the surrounding wall of the bore hole, discharging an explosive shell from said recess into the formation beside the bore hole, therefore detonating said explosive shell in the formation while holding the open side of said recess adjacent the point of detonation forcing a sample of the formation into the recess, and lifting said sample out of the bore hole.
  • a process of obtaining a sample from a well bore hole having a surrounding fluid bearing earth formation comprising introducing into the bore hole a gun having a recess in the periphery thereof with said recess immediately adjacent the surrounding Wall of the bore hole, discharging an explosive shell from said recess into the formation beside the bore hole, therefore detonating said explosive shell in the formation while holding the open side of said recess adjacent the point of detonation forcing a sample of the formation into the recess. and lifting said gun out of the bore hole and removing the sample therefrom JAMES LEWIS FOSTER.

Description

J. L. FOSTER WELL EXPLOSIVE Jam. 5, 943.
Filed March 17, 1969 INVENTOR.
w w F .M W L J ATTORNEY.
tente iam 5, iid
.lames Lewis lFoster, Wichita lF'alls, Tex. Application rch 17, 1939, Serial No. 262,531 (Cl. 1412-21) 6 Claims.
This invention relates to a method of placing an explosive projectile in a subterranean formation, and more particularly to the ring of these projectiles from a. weil into a fluid-bearing for-l mation to increase therecovery of said fluid.
By placing a small amount of the explosive at various points in the .earth formation and detohating this explosive, more advantageous results may be obtained than by placing a large amount of explosive within the bore hole and detonating it there.
Heretofore, it has been common practice to lower large charges of high explosives into a, well and to detonate these charges by mechanical or time-clock means. These charges, which consist of from ten quarts to ve hundred quarts of pure nitroglycerin, are dangerous to the workmen handling them, dangerous to the public safety, since they must be moved over the public highways, and often do extensive damage to the well casing and equipment. The reason that these charges must be so large is that they depend entirely on concussion and reverberation to achieve the desired result of loosening and removing that part of the formation immediately adjacent the bore hole. wherein theyare approximately axially disposed at the time oi the detonation.
While the drawing shows apparatus for practicing the invention, it is to be understood that the invention relates to the more advantageous placing of explosives contained in projectiles at a point in the earths stratum removed from the bore hole. so that the portion oi the stratum lying between thepoint of explosion land the bore hole will be driven toward the bore hole by the force of the explosion. It is obvious that varied results, such as blasting down a portion of the wall of the well, driving gathering holes with basins at the outer ends thereof, providing entries for formation solvents, providing enlarged sections in the bore hole for the anchoring of cement bridges, and other similar functions may be produced by varying the forces of the explosives involved in the process and by varying the types of projectiles used. These variations of the basic process are to be considered within the scope of the invention herein disclosed. Y
The accompanying drawing shows a preferred and novel form of apparatus used in carrying out this process, in which:
Fig, l is a fragmentary vertical section of an earth formation, showing the tool partly in elevation and partly in section, disposed in a well;
Fig. 2` is a fragmentary horizontal section through the tool, on the line 2-2 of Fig. 1;
Fig. 3 is a longitudinal section through a form ci a projectile used in connection with the tool;
Fig. i is a similar View of a modified form ci projectile useclin the tool; and
Fig. 5 is a diagrammatic view of a wiring diagram for sequentially firing a plurality of explosive charges Within the tool.
With more particular reference to the drawing, the numeral l represents the body of a tool which carries a plurality of radially disposed explosive chambers or cannons 2 which are preferably spaced along the length of the tool, preferably being turned in different radial directions relative thereto. These cannons have removable barrels 3 which may be taken out of the tool i, being removably placed in sockets t in the tool I. The removable barrels 3 are held in place in recess 1 by bolts t and within the outer end of this barrel is disposedthe threaded bushing 8 which engages shear ring II and causes the ring to seat upon gasket 5` This prevents the moisture from entering the powder chamber 9. This threaded bushing forms an extension of cannon barrel 2 and is removed each time a new projectile is inserted.
Before inserting the tool into a well, an explosive charg'e 9 is placed in each of the cannon bores 2 behind an explosive projectile I0 or l0' therein, upon which projectile an expansive shear ring II has been iitted, is slipped into an annular recess I2 in the cannon bore 2.
A percussion cap I3 is fitted into an opening Ii in the cannon barrel 3, longitudinally of the tool, so that iiring pin I5 will detonate the cap i3 and the adjacent explosive charge i) upon the striking of the firing pin I5 by the hammer I6. The hammer I6 is operated by an electro-magnetic coil or solenoid il when electrical energy is supplied thereto. The entire solenoid mechanism is contained in a casing I8 and may be inserted into or removed from the tool through the recess t therein. A single wire, with grounded return circuit, is shown and a relay switch is connected within this wired circuit 2| and has connection with the solenoid which is next to be operated so that the projectiles may be sequentially red from cannon bores 2 by closing and opening a switch I9 in said circuit (Fig; 5) which switch is located at the surface or at the mouth of the well. Upon closing the switch i9, a source of electrical energy, such as a battery 2U is connected with circuit 2| leading to the solenoids II'I, which are in parallel with the circuit through secondary switchesl Y A switch arm 22 rests on contact plate 23 (Fig. 2) which closes the circuit to the coil Il and actuates the hammer I6 by the force exerted in magnetic coil Il. As the hammer I6 is moved to strike ring pin I5 (Fig. 1), a pointed end 2t of the hammer, which pointed end 2li is made of fiber or other insulating material and 'which normally holds the switch arm 22 retracted, is withdrawn and permits switch arm 22 to be moved into the position shown in dotted lines and the solenoid Il is deenergized, releasing the hammer i6, and upon the return of the hammer It under pressure of spring 26 bearing thereagainst, the pointed end 23 will push the switch point oli contact plate 23 against contact 23', to dotted line position as indicated at 22" (Fig. 2). By this movement of the switch arm 22, the rst solenoid is entirely disconnected from the circuit and remains de-energized until the tool is removed and the mechanism reset when a new charge is inserted. A plugged opening 21 is provided through the wall of the tool l for the inscrtion of an instrument against switch arm 22 for resetting the same, as shown in Fig. 2.
When the switch arm 22 moves to the dotted line position 22" and engages contact 23 after firing the first charge, this closes the circuit 2l to the next succeeding solenoid Il which is then ready to be fired by again closing switch i3, as described. This operation is repeated until all of the charges have been fired. A wire 2l is shown schematically in Fig. l for clearness; however, it is to be understood that the tool I is to be drilled both longitudinally and transversely to accommodate the Wire to the respective solenoids, designated a, b and c in Fig. 5. This wire is shown leading onward from solenoid c, as any number of discharge units may be used. When the tool is cross-drilled, the holes will be plugged in the usual manner.
Several types of penetration are desirable, particularly for oil wells two of which are shown. One type is indicated at A, where an explosive projectile is shot into the stratum for a short distance and the force of the explosive is used to blow the formation toward the well. In this manner, a formation which has become sealed with paraffin, asphalt, mud or other foreign material that renders the formation non-productive of oil, may be removed by placing a projectile a. short distance beyond the wall of the bore hole and detonating it so that this foreign substance will be loosened, and may be cleaned from the well. A new porous surface is thus produced which has a larger exposed area, thereby giving the Well greater productivity.
Another form of shot which may be placed, that indicated by dotted outline at B. The amount of explosive 3 in chamber 2 is increased so as to drive the projectile a greater distance into the stratum than shown at A. This projectile may be so constructed as shown in Fig. Il, that it will be blown into bits, each of the fragments cutting a channel in the stratum, and in this manner a passage is formed for some distance out into the stratum with a basin at the outer end, and passages radiating from said basin, thus opening up producing stratum, or permitting 'chemicals to be introduced into certain types of formations where they will work with greater rapidity and edectiveness than if introduced into the immediate bore hole of the well.
IZCwo types of projectiles are shown in Figs. 3 and 4, respectively. The type shown in Fig. 3 has a round nose 23 which is fitted with a firing pin 23 which strikes percussion cap 33. This ignites a fuse 3l which may be varied in length to delay the firing of the explosive charge 32 until the projectile has. traveled the desired distance into the stratum. The interior of the projectile is accessible for loading as by forming it in sections screw-threaded together at 33. The nose 23 is crushed upon striking a formation of sufiicient hardness and this drives pin 23 against percussion cap 33. A short fuse is shown to indicate the placing of the explosive charge only a short distance from the bore hole. The shear ring Ii retains the projectile within the cannon barrel until the greater part of the explosive charge is burned. In this manner the full eectiveness of the charge is obtained upon the shearing of expansive shear ring Il.
The form of projectile as shown in Fig. 4 is preferably made of cast metal, in two parts also screw-threaded vtogether at 33', and has annular and longitudinal grooves 33 and 3ft respectively, disposed within the chamber 32 which is designed to carry the explosive charge. This form is shown with a sharp nose and pointed firing pin 33, which may be advantageous in penetrating hard types of formation. The pointed firing pin 33 is in position to strike percussion cap 33 upon impact with a substantially nonyielding formation. To prevent the ring pin 33 from striking percussion cap 33 too readily, a shear pin 33 is provided which will shear when the projectile is driven into a hard formation. Upon the detonation of cap 33 a powder train All will be ignited. The length of this powder train, together with the speed with which the powder burns, will be computed, so as to permit the projectile to travel the desired distance into the formation before detonating the explosive contained in the chamber 33. 'Ihis type of projectile will form a long passage with a basin at the end thereof and radiating passages outward therefrom, in the formation.
The tool may be lowered into the well by any suitable means such as pipe 32 or a cable. If used on a drill stem, it can be screwed together in such manner that the direction of the cannon barrels can be determined, as by matching index marks i3 as the joints are screwed together. In this manner the direction in which the projectile is fired may be determined from the surface.
The tool may also be used to obtain samples of formation in the proximity of the detonated projectile, as the force of the explosion of the projectile I3 or i3' will force a portion of the formation into a cannon barrel, as indicated at t3, which portion may be removed from the well for analysis.
On reloading the device, a new gasket t and a new shear ring ll as well as a new projectile, will be required, as the projectile will shear these each time the cannon is detonated.
The lower end of the tool is preferably tapered to a point to facilitate its insertion into, as well as its removal from the well after the explosion of the projectiles when the explosions would have forced a quantity of the formation into the bore hole.
I claim:
1. The herein described method of treating oil wells which consists ln firing a projectile into the surrounding formation, and subsequently exploding the projectile in said formation.
2. A process of treating a well having a surrounding lluid-bearing earth formation, comprislng firing a projectile into said surrounding fluid bearing earth formation, and subsequently exploding the projectile in said formation.
asoma@ 3. A process of treating a well having a hore` hole with a surrounding Huid-bearing earth i'or- -mation, comprising flring a projectile from within said bore hole laterally at an angle to the axis thereof into said formation, and subsequently exploding theprojectile in said formation.
4. A process of treating a well having .a bore hole with a surrounding fluid-bearing earth formation, comprising ring a projectile from within said bore hole laterally at an angle to the axis thereof into said formation, subsequently exploding the projectile in said formation forming one or more passageways from the point of detonation into the bore hole, and flowing the uid from said formation through said one or more passage- Ways into the bore hole.
5. A process of obtaining a sample from a well bore hole having a surrounding iiuid bearing earth formation, comprising introducing into the bore hole a gun having a recess in the periphery thereof w th said recess immediately adjacent the surrounding wall of the bore hole, discharging an explosive shell from said recess into the formation beside the bore hole, therefore detonating said explosive shell in the formation while holding the open side of said recess adjacent the point of detonation forcing a sample of the formation into the recess, and lifting said sample out of the bore hole.
6. A process of obtaining a sample from a well bore hole having a surrounding fluid bearing earth formation, comprising introducing into the bore hole a gun having a recess in the periphery thereof with said recess immediately adjacent the surrounding Wall of the bore hole, discharging an explosive shell from said recess into the formation beside the bore hole, therefore detonating said explosive shell in the formation while holding the open side of said recess adjacent the point of detonation forcing a sample of the formation into the recess. and lifting said gun out of the bore hole and removing the sample therefrom JAMES LEWIS FOSTER.
US262531A 1939-03-17 1939-03-17 Well explosive Expired - Lifetime US2307729A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
US262531A US2307729A (en) 1939-03-17 1939-03-17 Well explosive
US467657A US2408419A (en) 1939-03-17 1942-12-02 Well explosive device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US262531A US2307729A (en) 1939-03-17 1939-03-17 Well explosive

Publications (1)

Publication Number Publication Date
US2307729A true US2307729A (en) 1943-01-05

Family

ID=22997893

Family Applications (1)

Application Number Title Priority Date Filing Date
US262531A Expired - Lifetime US2307729A (en) 1939-03-17 1939-03-17 Well explosive

Country Status (1)

Country Link
US (1) US2307729A (en)

Cited By (23)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2544573A (en) * 1946-01-29 1951-03-06 Stanolind Oil & Gas Co Method and means for drilling
US2591319A (en) * 1946-09-23 1952-04-01 Mccullough Tool Company Casing perforating gun
US2591807A (en) * 1947-08-23 1952-04-08 Haskell M Greene Oil well cementing
US2717760A (en) * 1947-11-08 1955-09-13 Clyde E Bannister Apparatus for taking a sample of an earth formation
US2749841A (en) * 1950-08-31 1956-06-12 Edward N Jones Hydraulic acting jet gun for perforating well casings
US2761385A (en) * 1951-01-30 1956-09-04 Schlumberger Prospection Devices for controlling the firing of charges of powder or explosives from a distance
US2788461A (en) * 1952-11-28 1957-04-09 Ici Ltd Method of firing explosive charges and apparatus therefor
US2814991A (en) * 1952-05-21 1957-12-03 Ici Ltd Art of delay electric shot-firing of blasting explosive charges and appliances suitable for use in delay electric shot-firing circuits
US2821136A (en) * 1951-04-05 1958-01-28 P G A C Dev Co Firing system for jet type perforating gun
US2871784A (en) * 1951-07-05 1959-02-03 Schlumberger Well Surv Corp Firing system for electrically detonated borehole equipment
US2879972A (en) * 1957-12-06 1959-03-31 Dresser Ind Sidewall sampler
US2884836A (en) * 1953-12-14 1959-05-05 Jersey Prod Res Co Gun perforators for wells
US2919646A (en) * 1953-05-26 1960-01-05 Foster James Lewis Well explosive devices
US2946283A (en) * 1955-09-02 1960-07-26 Borg Warner Method and apparatus for perforating wellbores and casings
US3029732A (en) * 1959-05-18 1962-04-17 Haskell M Greene Perforation and cleaning of wells
US3034579A (en) * 1959-07-20 1962-05-15 Phillips Petroleum Co Process for igniting and producing carbonaceous strata
US3043379A (en) * 1957-10-01 1962-07-10 Lane Wells Co Formation sampler
US3072054A (en) * 1958-05-20 1963-01-08 Gun Products Co Oil well shooting projectile and method
US3190372A (en) * 1962-03-05 1965-06-22 Sun Oil Co Methods and apparatus for drilling bore holes
DE1207890B (en) * 1961-06-02 1965-12-23 Peute Chemie G M B H & Co K G Method for producing a sealing veil in the ground
DE1210747B (en) * 1962-05-29 1966-02-10 Montage Technik Anstalt F Method and device for making holes in the ground
US5853224A (en) * 1997-01-22 1998-12-29 Vastar Resources, Inc. Method for completing a well in a coal formation
US6024171A (en) * 1998-03-12 2000-02-15 Vastar Resources, Inc. Method for stimulating a wellbore penetrating a solid carbonaceous subterranean formation

Cited By (23)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2544573A (en) * 1946-01-29 1951-03-06 Stanolind Oil & Gas Co Method and means for drilling
US2591319A (en) * 1946-09-23 1952-04-01 Mccullough Tool Company Casing perforating gun
US2591807A (en) * 1947-08-23 1952-04-08 Haskell M Greene Oil well cementing
US2717760A (en) * 1947-11-08 1955-09-13 Clyde E Bannister Apparatus for taking a sample of an earth formation
US2749841A (en) * 1950-08-31 1956-06-12 Edward N Jones Hydraulic acting jet gun for perforating well casings
US2761385A (en) * 1951-01-30 1956-09-04 Schlumberger Prospection Devices for controlling the firing of charges of powder or explosives from a distance
US2821136A (en) * 1951-04-05 1958-01-28 P G A C Dev Co Firing system for jet type perforating gun
US2871784A (en) * 1951-07-05 1959-02-03 Schlumberger Well Surv Corp Firing system for electrically detonated borehole equipment
US2814991A (en) * 1952-05-21 1957-12-03 Ici Ltd Art of delay electric shot-firing of blasting explosive charges and appliances suitable for use in delay electric shot-firing circuits
US2788461A (en) * 1952-11-28 1957-04-09 Ici Ltd Method of firing explosive charges and apparatus therefor
US2919646A (en) * 1953-05-26 1960-01-05 Foster James Lewis Well explosive devices
US2884836A (en) * 1953-12-14 1959-05-05 Jersey Prod Res Co Gun perforators for wells
US2946283A (en) * 1955-09-02 1960-07-26 Borg Warner Method and apparatus for perforating wellbores and casings
US3043379A (en) * 1957-10-01 1962-07-10 Lane Wells Co Formation sampler
US2879972A (en) * 1957-12-06 1959-03-31 Dresser Ind Sidewall sampler
US3072054A (en) * 1958-05-20 1963-01-08 Gun Products Co Oil well shooting projectile and method
US3029732A (en) * 1959-05-18 1962-04-17 Haskell M Greene Perforation and cleaning of wells
US3034579A (en) * 1959-07-20 1962-05-15 Phillips Petroleum Co Process for igniting and producing carbonaceous strata
DE1207890B (en) * 1961-06-02 1965-12-23 Peute Chemie G M B H & Co K G Method for producing a sealing veil in the ground
US3190372A (en) * 1962-03-05 1965-06-22 Sun Oil Co Methods and apparatus for drilling bore holes
DE1210747B (en) * 1962-05-29 1966-02-10 Montage Technik Anstalt F Method and device for making holes in the ground
US5853224A (en) * 1997-01-22 1998-12-29 Vastar Resources, Inc. Method for completing a well in a coal formation
US6024171A (en) * 1998-03-12 2000-02-15 Vastar Resources, Inc. Method for stimulating a wellbore penetrating a solid carbonaceous subterranean formation

Similar Documents

Publication Publication Date Title
US2307729A (en) Well explosive
US2408419A (en) Well explosive device
EP3414424B1 (en) Detonation transfer system
US2544573A (en) Method and means for drilling
RU2081313C1 (en) Method and device for crushing hard rock and materials
US4329925A (en) Fracturing apparatus
CN1081720C (en) Dual redundant detonating system for oil well perforators
US2869825A (en) Earth boring
US11054233B2 (en) Hydraulic time delay actuated by the energetic output of a perforating gun
RU2254453C2 (en) Exploding device for forming horizontal underground hollows and method for performing exploding operations with use of said device
US3797576A (en) Method and apparatus for breaking up rocks containing liquid or gaseous hydrocarbons by means of explosives
US10597987B2 (en) System and method for perforating a formation
EP1534653B1 (en) Handheld tool for breaking up rock
US2925775A (en) Well casing perforator
US2843041A (en) Deep perforation of subsurface formations
US2446640A (en) Well perforator
US3620314A (en) Combination bullet-perforating gun and shaped charge perforator apparatus and method
US2140813A (en) Well casing perforator
US2919646A (en) Well explosive devices
US3611933A (en) Nuclear cavity configuration control
US2507230A (en) Weight controlled seismographic combustion deflection
Lekas et al. Initial evaluation of fracturing oil shale with propellants for in situ retorting, Phase 2
US3301185A (en) Well explosive devices
US5370055A (en) Three-phase hypervelocity projectile launcher
US3329219A (en) Selectively fired capsule type shaped charge perforation