CA2222717C - Spiral or wave strip perforating system - Google Patents
Spiral or wave strip perforating system Download PDFInfo
- Publication number
- CA2222717C CA2222717C CA002222717A CA2222717A CA2222717C CA 2222717 C CA2222717 C CA 2222717C CA 002222717 A CA002222717 A CA 002222717A CA 2222717 A CA2222717 A CA 2222717A CA 2222717 C CA2222717 C CA 2222717C
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- Prior art keywords
- strip
- well
- cap
- explosive
- invention defined
- Prior art date
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- Expired - Lifetime
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- 239000002360 explosive Substances 0.000 claims abstract description 41
- 239000002775 capsule Substances 0.000 claims abstract description 32
- 238000005474 detonation Methods 0.000 claims abstract description 14
- 238000013467 fragmentation Methods 0.000 claims abstract description 7
- 238000006062 fragmentation reaction Methods 0.000 claims abstract description 7
- 238000009987 spinning Methods 0.000 claims abstract description 5
- 238000003780 insertion Methods 0.000 abstract description 3
- 230000037431 insertion Effects 0.000 abstract description 3
- 230000015572 biosynthetic process Effects 0.000 description 5
- 238000005755 formation reaction Methods 0.000 description 5
- 239000000463 material Substances 0.000 description 5
- 238000010304 firing Methods 0.000 description 3
- 229910052500 inorganic mineral Inorganic materials 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 239000002184 metal Substances 0.000 description 2
- 238000003801 milling Methods 0.000 description 2
- 239000011707 mineral Substances 0.000 description 2
- 239000003208 petroleum Substances 0.000 description 2
- 230000000717 retained effect Effects 0.000 description 2
- 229910000788 1018 steel Inorganic materials 0.000 description 1
- 239000010963 304 stainless steel Substances 0.000 description 1
- 229910000589 SAE 304 stainless steel Inorganic materials 0.000 description 1
- 229910000831 Steel Inorganic materials 0.000 description 1
- 239000000969 carrier Substances 0.000 description 1
- 230000015556 catabolic process Effects 0.000 description 1
- 238000011109 contamination Methods 0.000 description 1
- 238000006731 degradation reaction Methods 0.000 description 1
- 239000012634 fragment Substances 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000010587 phase diagram Methods 0.000 description 1
- 239000010959 steel Substances 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
Classifications
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/11—Perforators; Permeators
- E21B43/116—Gun or shaped-charge perforators
- E21B43/117—Shaped-charge perforators
Landscapes
- Life Sciences & Earth Sciences (AREA)
- Engineering & Computer Science (AREA)
- Geology (AREA)
- Mining & Mineral Resources (AREA)
- Physics & Mathematics (AREA)
- Environmental & Geological Engineering (AREA)
- Fluid Mechanics (AREA)
- General Life Sciences & Earth Sciences (AREA)
- Geochemistry & Mineralogy (AREA)
- Drilling And Exploitation, And Mining Machines And Methods (AREA)
- Pressure Welding/Diffusion-Bonding (AREA)
- Portable Nailing Machines And Staplers (AREA)
Abstract
A perforating gun (33) having an elongated mounting strip (35) and a selecte d wave or non-linear, zig--zag form as seen in a plan view, with an outer surface diameter sized f or convenient insertion and removal from a well. The mounting strip (35) has a series of openings spaced in intervals for mounting capsule explosive charges (49) in a phased relationship between 0 and 360 degrees. T he cross-sectional area of the mounting strip (35) around each opening is selected to prevent fragmentation of the carrier upon detonation of the charges. The mounting strip (35) is preferably metallic with a select ed amplitude and wavelength. In each opening is an explosive charge (49) with a hollow cap (51) with a nose (53) for attachment to one of the openings. The cap (51) has an annular, interior thread with a thread run - out (61) of selected width. The explosive capsule (49) has a hollow body having an open end with exterior threads (59) and a width less than the width of the thread run-out (61) in the cap (51) to permit free spinning of the body in the cap (51) after thread makeup for convenient threading and connection with the detonating co rd (43).
Description
Description Spiral Or Wave Strip Perforating System Technical Field The present invention relates to through tubing perforation guns used to support explosive charges in a borehole to form perforations through which water, petroleum or minerals are produced.
Background Art This invention is an improvement to prior art phased, through tubing, perforating systems in that it allows for widely varied phasing (i.e., orientation of multiple directional charges at various angles) while allowing for retrieval of the carrier. Prior art phased capsule perforating systems may be generally classified into three categories: (1) the phased frangible base strip (US 4,951,744); (2) the retrievable base strip with frangible retaining means (US 5,095,999); and (3) the phased expendable link (US 5,241,891).
The disadvantages of the first category (illustrated in Figure 1 of the drawings) is that the shattered pieces of the base strip are not retrieved from the well leaving a substantial amount of debris. As a result, one cannot determine if all the charges detonated properly. Also, since the base strip shatters after firing the gun, the strip must be brittle and thereby could break when it is not desirable (e.g. upon conveying in the well).
The disadvantage of the second category (illustrated in Figure 2 of the drawings) is that the base strip is composed of a heavy gauge steel bar that limits possible = phasing (normally + 45 degrees, -45 degrees) and that distorts (when the shaped charges are fired) to make retrieval difficult. Also, since only a relatively weak
Background Art This invention is an improvement to prior art phased, through tubing, perforating systems in that it allows for widely varied phasing (i.e., orientation of multiple directional charges at various angles) while allowing for retrieval of the carrier. Prior art phased capsule perforating systems may be generally classified into three categories: (1) the phased frangible base strip (US 4,951,744); (2) the retrievable base strip with frangible retaining means (US 5,095,999); and (3) the phased expendable link (US 5,241,891).
The disadvantages of the first category (illustrated in Figure 1 of the drawings) is that the shattered pieces of the base strip are not retrieved from the well leaving a substantial amount of debris. As a result, one cannot determine if all the charges detonated properly. Also, since the base strip shatters after firing the gun, the strip must be brittle and thereby could break when it is not desirable (e.g. upon conveying in the well).
The disadvantage of the second category (illustrated in Figure 2 of the drawings) is that the base strip is composed of a heavy gauge steel bar that limits possible = phasing (normally + 45 degrees, -45 degrees) and that distorts (when the shaped charges are fired) to make retrieval difficult. Also, since only a relatively weak
2 PCTIUS96/07556 breakable clip retains the capsule charge to the base strip, it may break when it is undesirable (e.g. upon conveying into the well) . The advantage of this system is that it permits some simple phasing (two rows at +/- 45 degrees typically), and the strip is rugged and retrievable.
The disadvantages of the third category (illustrated in Figure 3 of the drawings) are that more debris is left in the well and that the system is weak (the pins and links often break when they hit obstructions in the tubing), resulting in use only for simple perforating operations. The main advantage of the third category is that very flexible phasing is possible. This high degree of phasing of the capsules is significant to well productivity in many formation types.
Co-pending application PCT/US95/15230 discloses a perforating gun carrier with a slotted configuration and interior dimensions to enable capsule orientation at selected phases between 0 and 360 degrees. The carrier has a frangible seam that fractures upon detonation to form two retrievable strips, each supported by the conveyance sub for retrieval. The seam is a narrow bridge, formed by slotting the carrier partially, with a cross-sectional area that shatters upon detonation of the shaped charges. The remaining cross-sectional area and strength of each strip is sufficient to assure retrieval after detonation. The strips are preferably nonplanar, arcuate or a segment of a circle in cross section. When the capsule charges are arrayed around many phases, by attaching both front and rear portions of the capsule charges to the nonfrangible regions of the carrier, detonating cords are used for detonation.
Disclosure of Invention The general object of the invention is to provide a gun for well perforating that overcomes the various
The disadvantages of the third category (illustrated in Figure 3 of the drawings) are that more debris is left in the well and that the system is weak (the pins and links often break when they hit obstructions in the tubing), resulting in use only for simple perforating operations. The main advantage of the third category is that very flexible phasing is possible. This high degree of phasing of the capsules is significant to well productivity in many formation types.
Co-pending application PCT/US95/15230 discloses a perforating gun carrier with a slotted configuration and interior dimensions to enable capsule orientation at selected phases between 0 and 360 degrees. The carrier has a frangible seam that fractures upon detonation to form two retrievable strips, each supported by the conveyance sub for retrieval. The seam is a narrow bridge, formed by slotting the carrier partially, with a cross-sectional area that shatters upon detonation of the shaped charges. The remaining cross-sectional area and strength of each strip is sufficient to assure retrieval after detonation. The strips are preferably nonplanar, arcuate or a segment of a circle in cross section. When the capsule charges are arrayed around many phases, by attaching both front and rear portions of the capsule charges to the nonfrangible regions of the carrier, detonating cords are used for detonation.
Disclosure of Invention The general object of the invention is to provide a gun for well perforating that overcomes the various
- 3 -disadvantages of the prior art devices with a carrier that produces perforations in a wide degree of patterns, including a 360 degree phase relationship, that does not fragment and that is therefore removable from the well.
This object is achieved also with a perforating gun having an elongated mounting having a spiral or selected wave, or non-linear, zig-zag form as seen in a plan view, with an outer surface diameter sized for convenient insertion and removal from a well. The mounting strip has a series of openings spaced in intervals for mounting capsule explosive charges in a phased relationship between 0 and 360 degrees. The cross-sectional area of the mounting strip around each opening is selected to prevent fragmentation of the carrier upon detonation of the charges. The mounting strip is preferably metallic with a selected amplitude and wave length.
In each opening is an explosive capsule with a hollow cap with a nose for attachment to one of the openings. The cap has an annular, interior thread with a thread run-out of selected width. The explosive capsule has a hollow body having an open end with exterior threads and a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread makeup for convenient threading and connection with the detonating cord.
Certain exemplary embodiments may provide a perforation gun for carrying a plurality of explosives connecting by a detonating cord to perforate a section of a well in a selected pattern, comprising: an elongated, spiraled strip having an outer diameter sized for convenient entry and removal from a well; a series of openings spaced in internals along a length of the spiraled strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well; the cross-sectional - 3a -area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges; whereby the spiraled strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and the spiraled strip retrieved from the well.
The above as well as additional objects, features, and advantages of the invention will become apparent in the following detailed description.
Description of the Drawings The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself however, as well as a preferred mode of use, further objects and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in
This object is achieved also with a perforating gun having an elongated mounting having a spiral or selected wave, or non-linear, zig-zag form as seen in a plan view, with an outer surface diameter sized for convenient insertion and removal from a well. The mounting strip has a series of openings spaced in intervals for mounting capsule explosive charges in a phased relationship between 0 and 360 degrees. The cross-sectional area of the mounting strip around each opening is selected to prevent fragmentation of the carrier upon detonation of the charges. The mounting strip is preferably metallic with a selected amplitude and wave length.
In each opening is an explosive capsule with a hollow cap with a nose for attachment to one of the openings. The cap has an annular, interior thread with a thread run-out of selected width. The explosive capsule has a hollow body having an open end with exterior threads and a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread makeup for convenient threading and connection with the detonating cord.
Certain exemplary embodiments may provide a perforation gun for carrying a plurality of explosives connecting by a detonating cord to perforate a section of a well in a selected pattern, comprising: an elongated, spiraled strip having an outer diameter sized for convenient entry and removal from a well; a series of openings spaced in internals along a length of the spiraled strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well; the cross-sectional - 3a -area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges; whereby the spiraled strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and the spiraled strip retrieved from the well.
The above as well as additional objects, features, and advantages of the invention will become apparent in the following detailed description.
Description of the Drawings The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself however, as well as a preferred mode of use, further objects and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in
- 4 -conjunction with the accompanying drawings, wherein:
Figure 1 illustrates a prior perforating gun of the type that utilizes a frangible base strip;
Figure 2 is a prior art perforating gun of the type utilizing a retrievable base strip with frangible retaining means;
Figure 3 is a prior art perforating gun having multi phased expendable links;
Figure 4 illustrates the preferred embodiment of the present invention in a frontal view;
Figure 5 is a side elevational view of the Figure 4 embodiment;
Figure 6 is a view of the Figure 4 embodiment shown from the top within a casing to be perforated to illustrate the shaped charge orientations and perforations in the casing and geological formation;
Figure 7 is a phase diagram showing the phase relationship of the capsule charges in the Figure 4 embodiment;
Figure 8 is a fragmentary, enlarged view of the carrier of the Figure 4embodiment to illustrate the mounting means and strip configuration;
Figure 8-A is a cross-sectional view as seen looking along the corresponding lines and arrows of Figure 8;
Figure 9 illustrates one capsule charge of the type used in the preferred embodiment of Figure 4;
Figure 9-A is an enlarged, fragmentary view taken from Figure 9; and Figure 10 is a plan or frontal elevational view of an alternative embodiment of the mounting means shown in the plane of the paper.
Description of the Invention Referring initially to Figures 1-3 of the drawings, which illustrate three prior art perforating guns, the perforating gun 11 of Figure 1 utilizes a frangible base
Figure 1 illustrates a prior perforating gun of the type that utilizes a frangible base strip;
Figure 2 is a prior art perforating gun of the type utilizing a retrievable base strip with frangible retaining means;
Figure 3 is a prior art perforating gun having multi phased expendable links;
Figure 4 illustrates the preferred embodiment of the present invention in a frontal view;
Figure 5 is a side elevational view of the Figure 4 embodiment;
Figure 6 is a view of the Figure 4 embodiment shown from the top within a casing to be perforated to illustrate the shaped charge orientations and perforations in the casing and geological formation;
Figure 7 is a phase diagram showing the phase relationship of the capsule charges in the Figure 4 embodiment;
Figure 8 is a fragmentary, enlarged view of the carrier of the Figure 4embodiment to illustrate the mounting means and strip configuration;
Figure 8-A is a cross-sectional view as seen looking along the corresponding lines and arrows of Figure 8;
Figure 9 illustrates one capsule charge of the type used in the preferred embodiment of Figure 4;
Figure 9-A is an enlarged, fragmentary view taken from Figure 9; and Figure 10 is a plan or frontal elevational view of an alternative embodiment of the mounting means shown in the plane of the paper.
Description of the Invention Referring initially to Figures 1-3 of the drawings, which illustrate three prior art perforating guns, the perforating gun 11 of Figure 1 utilizes a frangible base
- 5 -strip 13 having plural surfaces 15, 17 upon which are mounted a plurality of capsule charges 19 oriented at different angles or phases to perforate a well in more than one direction. The base strip 13 is constructed of a material as explained in the specification of U.S.
Patent No. 4,951,744 to shatter into a multitude of very small pieces in response to detonation of the capsule charges, allowing the resulting debris from the base strip to fall ideally below the perforating zone, to prevent obstruction of the flow of oil or gas from the perforated well. The material of the base strip 13 is strong enough to avoid breakage during impact with an obstruction when travelling downward in the borehole.
A retrievable base strip that will not shatter when the charges detonate, and that may be retrieved from the well, is disclosed in U.S. Patent 5,095,999. Here, the charges are retained on the base strip by support rings that will shatter into a multitude of pieces, allowing the charges to fall to the bottom of the well. This configuration of perforating gun is illustrated in Figure 2 of the drawings and is taken from U.S. Patent 5,095,999. A nonfrangible strip 21 is retrievable from the well after detonation of the capsule charges 23 upon ignition of the detonating cord 25. The capsule charges 23 are retained on the base strip 21 by a plurality of support rings 26 that shatter upon detonation of the capsule charges.
Another prior art perforating gun is shown in U.S.
Patent No. 5,241,891 and in Figure 3, wherein the explosive charges 27 are mounted on link carriers 29, and are detonated by ignition of the detonating cord 31.
This configuration of perforating gun occupies a small diameter similar to prior art guns in the well while enabling multi-phase orientation of the charges and retrieval from a well.
Referring now to Figure 4 of the drawings and the
Patent No. 4,951,744 to shatter into a multitude of very small pieces in response to detonation of the capsule charges, allowing the resulting debris from the base strip to fall ideally below the perforating zone, to prevent obstruction of the flow of oil or gas from the perforated well. The material of the base strip 13 is strong enough to avoid breakage during impact with an obstruction when travelling downward in the borehole.
A retrievable base strip that will not shatter when the charges detonate, and that may be retrieved from the well, is disclosed in U.S. Patent 5,095,999. Here, the charges are retained on the base strip by support rings that will shatter into a multitude of pieces, allowing the charges to fall to the bottom of the well. This configuration of perforating gun is illustrated in Figure 2 of the drawings and is taken from U.S. Patent 5,095,999. A nonfrangible strip 21 is retrievable from the well after detonation of the capsule charges 23 upon ignition of the detonating cord 25. The capsule charges 23 are retained on the base strip 21 by a plurality of support rings 26 that shatter upon detonation of the capsule charges.
Another prior art perforating gun is shown in U.S.
Patent No. 5,241,891 and in Figure 3, wherein the explosive charges 27 are mounted on link carriers 29, and are detonated by ignition of the detonating cord 31.
This configuration of perforating gun occupies a small diameter similar to prior art guns in the well while enabling multi-phase orientation of the charges and retrieval from a well.
Referring now to Figure 4 of the drawings and the
- 6 -preferred embodiment of the present invention, the numeral 33 designates a perforating gun for well perforating having an elongated, spiraled mounting strip 35 having an outer diameter sized for convenient insertion and removal from a well that contains geological formations that are to be perforated to enhance the production of petroleum or other minerals.
The spiral strip 35 is manufactured by utilizing the capabilities of a multiple axis laser milling machine on drawn-over-mandrel (DOM) tubing. The laser mill must have at least the X-axis and rotational capabilities in order to slit the spiral strip. Four (4) strips are manufactured from each full round tube started. The tube is left partially connected until all spiral slits are made over the length of the tube. The partial connection points are later broken apart to yield four (4) separate strips. The threaded holes on the strip are then completed on conventional machine centers.
The perforating gun 33 -has at its upper end a connector 37 for mounting on a conveyance sub (not shown) to raise or lower and position the gun at the selected elevation in the well adjacent to the geological formation to be perforated. The strip 35 is connected to a lower end of connector 47 with a plurality of fasteners 39 that may be socket head set screws or the equivalent.
Secured to the connector 37 is an electrical means 41 (see Fig. 5) adapted to supply electrical energy to a detonating cord 43.
The exterior surface of the strip 35 is cylindrical about a longitudinal axis (not shown) and is formed of a selected metal that forms a helical band with a pitch in a range of 12 to 24 inches. As shown in_the cross-sectional view of Figure 8A, a suitable thickness t for the strip is 0.125 inches and the circumferential width W 1.25 inches. At the lower end of the strip is connected a strap 45 to which may be secured a second WO 96l38652 PCT/US96107556
The spiral strip 35 is manufactured by utilizing the capabilities of a multiple axis laser milling machine on drawn-over-mandrel (DOM) tubing. The laser mill must have at least the X-axis and rotational capabilities in order to slit the spiral strip. Four (4) strips are manufactured from each full round tube started. The tube is left partially connected until all spiral slits are made over the length of the tube. The partial connection points are later broken apart to yield four (4) separate strips. The threaded holes on the strip are then completed on conventional machine centers.
The perforating gun 33 -has at its upper end a connector 37 for mounting on a conveyance sub (not shown) to raise or lower and position the gun at the selected elevation in the well adjacent to the geological formation to be perforated. The strip 35 is connected to a lower end of connector 47 with a plurality of fasteners 39 that may be socket head set screws or the equivalent.
Secured to the connector 37 is an electrical means 41 (see Fig. 5) adapted to supply electrical energy to a detonating cord 43.
The exterior surface of the strip 35 is cylindrical about a longitudinal axis (not shown) and is formed of a selected metal that forms a helical band with a pitch in a range of 12 to 24 inches. As shown in_the cross-sectional view of Figure 8A, a suitable thickness t for the strip is 0.125 inches and the circumferential width W 1.25 inches. At the lower end of the strip is connected a strap 45 to which may be secured a second WO 96l38652 PCT/US96107556
- 7 -spiraled strip 47. There are a series of openings in the spiraled strip 35 to serve as mounts for a plurality of explosive capsules 49. These openings are spaced in intervals along the length of the spiral strip so that they are arranged in a phase relationship to correspond with the selected perforation pattern in the well.
As shown in Figure 9, each of the explosive capsules 49 has a cap 51 having a threaded nose 53 that engages the threads 55 of the strip 35. The cross-sectional area of the strip around or adjacent each opening is selected to prevent fragmentation of the strip 35 upon detonation of the charge, taking into account the strength of the material used to form the strip, which in the preferred embodiment is a strong, ductile and flexible material such as 1018 steel or 304 stainless steel. The cap 51 is hollow with an interior cavity 57 to receive an explosive charge and terminate in an angular interior thread 59 having a thread runout 61, as may be better seen in the enlarged, fragmentary view of Figure 9A.
The thread runout 61 is wider than the threads 63 that are formed on the exterior of the open end of a hollow body 64 that partially contains the previously described explosive charge. The open end of the hollow body also has a seal 65 in an annular groove 67 to prevent contamination and degradation of the explosive charge. The opposite end of the hollow body 63 has a slot 69 to receive the detonating cord 43 shown in Figures 4 and 5, which is adjacent a heat-sensitive firing pin 71 that will detonate the explosive inside the capsule. A slot 73 receives a retainer clip 75 (see Fig.
As shown in Figure 9, each of the explosive capsules 49 has a cap 51 having a threaded nose 53 that engages the threads 55 of the strip 35. The cross-sectional area of the strip around or adjacent each opening is selected to prevent fragmentation of the strip 35 upon detonation of the charge, taking into account the strength of the material used to form the strip, which in the preferred embodiment is a strong, ductile and flexible material such as 1018 steel or 304 stainless steel. The cap 51 is hollow with an interior cavity 57 to receive an explosive charge and terminate in an angular interior thread 59 having a thread runout 61, as may be better seen in the enlarged, fragmentary view of Figure 9A.
The thread runout 61 is wider than the threads 63 that are formed on the exterior of the open end of a hollow body 64 that partially contains the previously described explosive charge. The open end of the hollow body also has a seal 65 in an annular groove 67 to prevent contamination and degradation of the explosive charge. The opposite end of the hollow body 63 has a slot 69 to receive the detonating cord 43 shown in Figures 4 and 5, which is adjacent a heat-sensitive firing pin 71 that will detonate the explosive inside the capsule. A slot 73 receives a retainer clip 75 (see Fig.
8) of conventional configuration to secure the detonating cord in its position adjacent to firing pin 71.
Referring now to Figure 10 of the drawings (and an alternate embodiment of the present invention) the numeral 101 designates drawn-over-mandrel (DOM) tube shown in the plane of the paper (not a true plan or frontal elevational view) from which four (4) non-linear zig-zag mounting strips can be manufactured from each full round of tube with the use of a multiple axes laser milling machine. One such strip 103 is shown with a plurality of apertures 105 over its non-linear zig-zag length, having edges 107, 109 defined by slitting the tubing 101 with the laser mill. The laser mill must have rotational capabilities in order to slit the tubing 101 and form the non-linear zig-zag strip.
The tube is left partially connected until the non-linear zig-zag slits are made over the length of the tube. The partial connection points are later broken apart to yield four (4) separate non-linear zig-zag strips. The apertures 105 on the strip are then threaded and completed.
In the Figure 10 embodiment, the tube 101 is shown as if it were cut longitudinally and rolled into the plane of the paper, appearing to be a rectangle. The circumference is marked in degrees ill at the bottom of the tube. The degrees are used to define the edges 107, 109 of the strip 103 and their geometric shape. The dotted lines 113 are imaginary lines that are used in designing the shape of the strip 103 and do not appear physically on the tube. The strip 103 is described as being non-linear and in a zig-zag pattern.
Another way to define the strip 103 shape is with reference to wave forms. The strip 103 has a wave form comprised of a first triangular wave having a half wave length 11 and an amplitude al. This wave intersects and is continued by a second wave having a half wave length 12 and an amplitude aa. The waves can have a variety of forms such as triangular (as shown), square, rectangular or sinusoidal to provide some examples. The waves can be repeating or identical or may have differing lengths and amplitudes as shown.
The wave form is selected to provide the requisite
Referring now to Figure 10 of the drawings (and an alternate embodiment of the present invention) the numeral 101 designates drawn-over-mandrel (DOM) tube shown in the plane of the paper (not a true plan or frontal elevational view) from which four (4) non-linear zig-zag mounting strips can be manufactured from each full round of tube with the use of a multiple axes laser milling machine. One such strip 103 is shown with a plurality of apertures 105 over its non-linear zig-zag length, having edges 107, 109 defined by slitting the tubing 101 with the laser mill. The laser mill must have rotational capabilities in order to slit the tubing 101 and form the non-linear zig-zag strip.
The tube is left partially connected until the non-linear zig-zag slits are made over the length of the tube. The partial connection points are later broken apart to yield four (4) separate non-linear zig-zag strips. The apertures 105 on the strip are then threaded and completed.
In the Figure 10 embodiment, the tube 101 is shown as if it were cut longitudinally and rolled into the plane of the paper, appearing to be a rectangle. The circumference is marked in degrees ill at the bottom of the tube. The degrees are used to define the edges 107, 109 of the strip 103 and their geometric shape. The dotted lines 113 are imaginary lines that are used in designing the shape of the strip 103 and do not appear physically on the tube. The strip 103 is described as being non-linear and in a zig-zag pattern.
Another way to define the strip 103 shape is with reference to wave forms. The strip 103 has a wave form comprised of a first triangular wave having a half wave length 11 and an amplitude al. This wave intersects and is continued by a second wave having a half wave length 12 and an amplitude aa. The waves can have a variety of forms such as triangular (as shown), square, rectangular or sinusoidal to provide some examples. The waves can be repeating or identical or may have differing lengths and amplitudes as shown.
The wave form is selected to provide the requisite
- 9 -pattern of apertures 105 in which to mount shaped charge capsules and to maximize the number of strips 103 that may be cut from the tube 101. By cutting the strip 103 from the tube 101, the shaped charges, when mounted in apertures 105 are arranged in a segment of a cylinder (or arc of a circle in a range of preferably 90-120 degrees) to match the cy'lindrical shape of the wall in the well to be perforated. The apertures 105 are preferably spaced from one another in a range of 12 to 24 inches.
In the preferred example of Figure 10, the material is the same as that indicated for the spiral strip of Figure 4, with a thickness of 0.125 inches. The dimensions for a successful strip are:
1v W = 1.25 inches 11 = 6 inches 12 = 12 inches D = 3 inches d = 0.5 inches al = 45 degrees a2 = 45 degrees It should be apparent from the foregoing that an invention having significant advantages has been provided. The spiral strip 35 of Figure 4 can be configured to enable the orientation of explosive capsules in a wide variety of selected patterns, one of which is shown in Figure 6 in which the strip 35 is used to position the explosive capsule 49 and others like it to form perforation 77 through the metal casing 79 and into the geological formation 81. This pattern has a phase relationship as shown in Figure 7 wherein the perforation 77 is indicated by the corresponding point at zero degrees. Moreover, the configuration of the spiral strip, when constructed as indicated above, prevents it from fragmenting or major distortion that would prevent its retrieval from a wellbore after the explosive capsules are detonated. The spiral may be considered to
In the preferred example of Figure 10, the material is the same as that indicated for the spiral strip of Figure 4, with a thickness of 0.125 inches. The dimensions for a successful strip are:
1v W = 1.25 inches 11 = 6 inches 12 = 12 inches D = 3 inches d = 0.5 inches al = 45 degrees a2 = 45 degrees It should be apparent from the foregoing that an invention having significant advantages has been provided. The spiral strip 35 of Figure 4 can be configured to enable the orientation of explosive capsules in a wide variety of selected patterns, one of which is shown in Figure 6 in which the strip 35 is used to position the explosive capsule 49 and others like it to form perforation 77 through the metal casing 79 and into the geological formation 81. This pattern has a phase relationship as shown in Figure 7 wherein the perforation 77 is indicated by the corresponding point at zero degrees. Moreover, the configuration of the spiral strip, when constructed as indicated above, prevents it from fragmenting or major distortion that would prevent its retrieval from a wellbore after the explosive capsules are detonated. The spiral may be considered to
- 10 -be a three dimensional and continuous wave in a cylindrical boundary.
The non-linear or waved strip 103 of Figure 10 is an alternate way to achieve many of the advantages of the spiral strip of Figure 4. It is especially advantageous when the pattern perforations need not extend 360 degrees. Since plural strips can be formed of one tube 107, manufacturing efficiencies are obtained.
While we have shown our invention in only two of its forms, it is not so limited but is susceptible to various changes and modifications without departing from the spirit thereof.
A
The non-linear or waved strip 103 of Figure 10 is an alternate way to achieve many of the advantages of the spiral strip of Figure 4. It is especially advantageous when the pattern perforations need not extend 360 degrees. Since plural strips can be formed of one tube 107, manufacturing efficiencies are obtained.
While we have shown our invention in only two of its forms, it is not so limited but is susceptible to various changes and modifications without departing from the spirit thereof.
A
Claims (17)
1. A perforating gun for carrying a plurality of explosives connecting by a detonating cord to perforate a section of a well in a selected pattern, comprising:
an elongated, spiraled strip having an outer diameter sized for convenient entry and removal from a well;
a series of openings spaced in intervals along a length of the spiraled strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the spiraled strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and the spiraled strip retrieved from the well.
an elongated, spiraled strip having an outer diameter sized for convenient entry and removal from a well;
a series of openings spaced in intervals along a length of the spiraled strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the spiraled strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and the spiraled strip retrieved from the well.
2. The invention defined by claim 1 wherein the exterior surface of said spiraled strip is cylindrical about a longitudinal axis.
3. The invention defined by claim 2 wherein said spiraled strip is a metallic and helical band with a pitch in a range of 12 to 24 inches.
4. The invention defined by claim 1 wherein said openings of the spiraled strip are threaded.
5. The invention defined by claim 4 including an explosive capsule charge which comprises:
a cap having a threaded nose for engagement with a threaded opening of said spiraled strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
a cap having a threaded nose for engagement with a threaded opening of said spiraled strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
6. A perforating gun for carrying a plurality of explosives connecting by a detonating cord to perforate a section of a well in a selected pattern, comprising:
an elongated, non-linear zig-zag strip having a generally tubular wall sized for convenient entry and removal from a well;
a series of openings spaced in intervals along a length of the non-linear zig-zag strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the non-linear zig-zag strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and retrieved from the well.
an elongated, non-linear zig-zag strip having a generally tubular wall sized for convenient entry and removal from a well;
a series of openings spaced in intervals along a length of the non-linear zig-zag strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the non-linear zig-zag strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and retrieved from the well.
7. The invention defined by claim 1 wherein the exterior surface of said non-linear zig-zag strip forms an arc of a circle about a longitudinal axis.
8. The invention defined by claim 2 wherein said arc is in a range of about 90 to 120 degrees.
9. The invention defined by claim 3 wherein said non-linear zig-zag strip is metallic and said openings spaced from one another in a range of 12 to 24 inches.
10. The invention defined by claim 1 wherein said openings of the non-linear zig-zag strip are threaded to receive shaped charge capsules.
11. The invention defined by claim 1 including an explosive capsule charge which comprises:
a cap having a threaded nose for engagement with a threaded opening of said non-linear zig-zag strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
a cap having a threaded nose for engagement with a threaded opening of said non-linear zig-zag strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
12. A perforating gun for carrying a plurality of explosives connecting by a detonating cord to perforate a section of a well in a selected pattern, comprising:
an elongated strip sized for convenient entry and removal from a well and in the form of a selected wave.
a series of openings spaced in intervals along a length of the strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and retrieved from the well.
an elongated strip sized for convenient entry and removal from a well and in the form of a selected wave.
a series of openings spaced in intervals along a length of the strip to serve as mounts for the explosives to be arranged in an angular phase relationship to correspond with said selected perforation pattern in the well;
the cross-sectional area of the strip around each opening being selected to prevent fragmentation of the carrier upon detonation of the charges;
whereby the strip is capable of being positioned in the well, the explosives detonated to create perforations in the selected pattern and retrieved from the well.
13. The invention defined by claim 7 wherein the exterior surface of said strip forms an arc of a circle about a longitudinal axis.
14. The invention defined by claim 8 wherein said arc is in a range of about 90 to 120 degrees.
15. The invention defined by claim 9 wherein said strip is metallic and said openings spaced from one another in a range of 12 to 24 inches.
16. The invention defined by claim 10 wherein said openings of the non-linear zig-zag strip are threaded.
17. The invention defined by claim 4 including an explosive capsule charge which comprises:
a cap having a threaded nose for engagement with a threaded opening of said non-linear zig-zag strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
a cap having a threaded nose for engagement with a threaded opening of said non-linear zig-zag strip;
the cap being hollow to contain explosive and terminating in an annular, interior thread with a thread run-out of selected width;
a hollow body to contain said explosive and having an open end with exterior threads having a width less than the width of the thread run-out in the cap to permit free spinning of the body in the cap after thread make-up;
a slot and retainer to receive a detonating cord on a closed end of the hollow body;
whereby the hollow body is capable of being freely spun to align said slot and retainer for convenient threading and connection of the detonating cord with the explosive capsule charge.
Applications Claiming Priority (5)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US626,392 | 1995-03-29 | ||
US459,509 | 1995-06-02 | ||
US08/459,509 US5638901A (en) | 1995-06-02 | 1995-06-02 | Spiral strip perforating system |
US08/626,392 US5662178A (en) | 1995-06-02 | 1996-03-29 | Wave strip perforating system |
PCT/US1996/007556 WO1996038652A1 (en) | 1995-06-02 | 1996-05-31 | Spiral or wave strip perforating system |
Publications (2)
Publication Number | Publication Date |
---|---|
CA2222717A1 CA2222717A1 (en) | 1996-12-05 |
CA2222717C true CA2222717C (en) | 2007-08-21 |
Family
ID=38434586
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA002222717A Expired - Lifetime CA2222717C (en) | 1995-03-29 | 1996-05-31 | Spiral or wave strip perforating system |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA2222717C (en) |
-
1996
- 1996-05-31 CA CA002222717A patent/CA2222717C/en not_active Expired - Lifetime
Also Published As
Publication number | Publication date |
---|---|
CA2222717A1 (en) | 1996-12-05 |
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MKEX | Expiry |
Effective date: 20160531 |