GB2394762A

GB2394762A - Shaped charge perforating system

Info

Publication number: GB2394762A
Application number: GB0329741A
Authority: GB
Inventors: Philip Kneisl; Lawrence A Behrmann; Brenden M Grove
Original assignee: Schlumberger Holdings Ltd
Current assignee: Schlumberger Holdings Ltd
Priority date: 2001-05-31
Filing date: 2002-05-31
Publication date: 2004-05-05
Anticipated expiration: 2022-05-31
Also published as: GB2394763B; GB2394763A; GB2394762B; GB0329787D0; GB0329741D0

Abstract

A system for perforating well casings comprises shaped charges carried by a perforating gun, each charge having a case 10 and a jacket 24 by which it is retained in a loading tube 22. The case 10 and/or the jacket 24 are either (a) made from a combustible material eg plastic or energetic material so as to produce no debris when the charge is detonated or (b) are very thin-walled and made of a material, eg copper, glass or ceramics, that gives rise to small fragments of debris. The loading tube 22 may be made from cardboard.

Description

GB 2394762 A continuation (74) Agent and/or Address for Service: Sensa

Gamma House, Enterprise Road, Chilworth Science Park, SOUTHAMPTON, Hampshire, S016 7NS, United Kingdom

22. 1463D2

DEBRIS FREE PERFORATING SYSTEM

FIELD OF THE INVENTION

The subject matter of the present invention relates to a debris free perforating system. More specifically, the subject matter of the present invention relates to reducing the amount of debris generated during perforating with shaped charges.

BACKGROUND OF THE INVENTION

In drilling operations, the drilled hole is often lined with a casing to prevent the earth from filling the hole. In order for the surrounding fluid to enter the drilled hole, the well casing must be perforated. Such operation is typically performed by a perforating gun loaded with one or more shaped charges.

Conventional perforating guns produce significant debris upon detonation of the shaped charges. The generated debris can enter the well fluid and become entrained in the well fluid. As the debris is carried by the well fluid, it can complicate down stream processing of the well fluids by clogging filters and jamming pumps, for example.

Extensive research on hollow carrier perforating guns indicates that the majority of gun debris is generated by the shaped charge cases. In fact, roughly 80% of all gun debris is attributed to the charge cases. The remaining debris is attributed to the charge case jackets and the loading tubes.

There exists, therefore, a need for a debris free perforating system that reduces or eliminates the debris generated upon detonation of the shaped charges.

SUMMARY

According to the invention, a debris free perforating system comprises a shaped charge having a jacket made from a combustible material, and a case made from a combustible material.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure I is a cross-sectional view of a typical shaped charge, loading tube, and perforating gun.

Figure 2 is a perspective view of a typical shaped charge and loading tube.

Figure 3 is a perspective view of a loading tube being inserted into a perforating gun. Figure 4 illustrates an embodiment of the debris free perforating system in which the shaped charge does not have a case.

Figure 5 illustrates a cross-sectional view of an embodiment of the debris free perforating system having a solid loading tube.

Figure 6 illustrates an embodiment of the debris free perforating system in which the jacket and/or case is made from a plastic or energetic material.

Figures 7a and 7b illustrate an embodiment of the debris free perforating system in which the loading tube is a combustible cardboard tube.

Figure 7c is a sketch of an embodiment of the debris free perforating system in which the loading tube is a reinforced plastic tube or rod.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Figure I provides an illustration of a typical shaped charge, indicated generally as 1, used for perforating a well casing. Typical shaped charges for use in perforating guns are discussed in U.S. Pat. No. 4,724, 767 to Aseltine issued Feb. 16, 1988; U.S. Pat. No. 5,413,048 to Werner et al. issued May 9, 1995; U.S. Pat. No. 4,669,384 to Chawla et al. issued Jun. 2, 1987; and again in U S. Pat. No. 5,597,974 to Voreck, Jr. et al. issued Jan. 28, 1997. The shaped charge 1 includes a case 10, a main body of explosive material 12, which in the past has been, for example, RDX, 1,3,5,7-tetranitro octahydro-1,3,5,7-

tetrazocine (HMX), 2,6-bis (Picrylamino)-3,5-dinitropyridine (PYX), or 2, 2',4,4',6-

hexanitrostilbene (HNS) packed against the inner wall of the case 10, a primer 13 disposed adjacent the main body of explosive 12 that is adapted to detonate the main body of explosive 12 when the primer 13 is detonated, and a liner 14 lining the primer 13 and the main body of explosive material 12. The liner 14 acts to maintain the shape of the explosive to assure proper propagation of the detonation. A detonating cord 20 contacts the case 10 of the shaped charge 1 at a point nearest the apex of the liner 14 of the charge. When a detonation wave propagates within the detonating cord 20, the detonation wave will detonate the primer 13. When the primer 13 is detonated, the detonation of the primer 13 will further detonate the main body of explosive 12 of the charge 1. In response to the detonation of the main body of explosive 12, the liner 14 will form a jet that will propagate along a longitudinal axis of the shaped charge 1. The jet will perforate a formation penetrated by the wellbore.

In a typical shaped charge 1, the case 10 greatly contributes to the penetration performance of the shaped charge 1. The case 10 (typically steel or similar) provides substantial inertial confinement, thereby enhancing the proportion of explosive

energy transferred to the collapsing liner 14, and hence the penetrating jet.

Several shaped charges 1 may be spatially arranged in a pattern (a spiral pattern, for example) in a device called a perforating gun. The shaped charges 1 are ballistically connected via the detonating cord 20 or some other means. In general, perforating guns are either capsule guns, which are essentially a metallic strip or similar device onto which the shaped charges 1 are attached, or hollow carrier guns as shown in Figures 1-3.

For a typical hollow carrier gun, one or more shaped charges 1 are housed within a loading tube 22 for transport. The loading tube 22 can house the shaped charges 1 at desired orientations, or in a linear fashion. A jacket 24 is used to both secure the shaped charges 1 to the loading tube 22 and to maintain the orientation of the shaped charges 1. Once the loading tube 22 is ready for delivery downhole, a perforating gun 30 is used to carry the loading tube 22 and housed shaped charges 1.

Conventionally, as shown in Figs. 2 and 3, the shaped charges 1 and jackets 24 are inserted into the loading tube 22 until the jackets 24 shoulder against the loading tube shoulders 23. Once all of the shaped charges I are secured, the loading tube 22 is inserted into the interior of the perforating gun 30. The gun 30 then transports the shaped charges 1 downhole to the desired depth of perforation.

Figure 4 illustrates one embodiment of the debris free perforating system in which the shaped charge 1 does not have a case. Because, as discussed above, a typical shaped charge relies in part on its metal case to aid in perforating the well casing, it is desirable to use an explosive 12 that compensates for the elimination of the case. In one embodiment of the present invention, the caseless shaped charge 1 shown in Fig. 4 contains a larger amount of explosive 12. For example, the caseless shaped charge I may contain 2 to 3 times the explosive 12 as similarly sized metallic cased charges to obtain equivalent penetration performance. In another embodiment of the caseless shaped charge 1 shown in Figure 4, the explosive 12 comprises a densified explosive 12 that possesses the beneficial confinement properties usually afforded by the case. The densified explosive 12 is formulated to not expand as quickly, therefore increasing the duration of its primary pulse. The densified explosive 12 delivers more of its energy to the liner 14 during the primary pulse, and therefore relies less on subsequent sustained impulse.

In one embodiment, the explosive 12 is densified by blending it with some inert heavy materials such as powdered metals. The inserted powdered metals can include tungsten, iron, copper, and lead, for example. The resulting blend provides more mass at

the detonation front, which delays expansion due to the explosive cloud mass, and hence increases primary impulse detonation.

In a typical shaped charge, the case and liner maintain the shape and the integrity of the explosives. As discussed above, in the embodiment of the debris free perforating system shown in Fig. 4, the shaped charge 1 does not have a case. During transport, the liner 14 acting alone is generally unable to maintain the shape of the explosive 12. Thus, alternative methods of maintaining the integrity of the explosive 12 must be incorporated.

One method of maintaining the integrity of the explosive 12 in the caseless shaped charge 1 is to use a solid loading tube 36, as shown in cross-section in Fig. 5. Hollow cavities 38 formed in the solid loading tube 36 provide housings and support for the shaped charges 1. Suitable materials for the solid loading tube 36 include low density plastic materials, Styrofoam_ or paper, for example. Typically, the detonation of the shaped charge 1 will incinerate the solid loading tube 36.

Referring back to Fig. 4, yet another method of maintaining the integrity of the explosive 12 in a caseless charge 1 is to use a suitable binder that will not melt or slump when exposed to the desired operating temperature. For lower temperature applications (generally below 250 OF (121 C)), suitable binders can be thermoplastics such as Viton_, Kel-F800, THV, Polyethylene, Nylon, or PVC, for example. Other suitable binders include any polymeric material having a service temperature meeting or exceeding the desired operating temperature of the application.

For high temperature applications, thermosetting plastic binders can be used as the explosive binder. Typical thermosetting plastics do not have a melting point, but do decompose when exposed to high temperatures. In one embodiment of using a thermosetting plastic binder, the explosive 12 is of the castible type where the binder is in a liquid state during production. The explosive 12 is cast in a mold of the desired shape, and the binder reacts to form a crosslinked non-melting plastic. Suitable plastic systems for castible explosives include polyesters, polyurethanes, polyamides, polyimides, and epoxies, for example. In another embodiment of using a thermosetting plastic binder, the explosive 12 is of the pressed type.

Another embodiment of a suitable binder for the explosive 12 is a thermoplastic-

thermosetting polymer useful as a binder for pressed or extrudable explosive. In this embodiment, the thermoplastic-thermosetting binder comprises ElvamideTM 8061 or 8063 blended with a stoichiometric amount of an epoxy resin, such as Epon_ 828. The blend is then cured with a latent curing agent such as Dicyandiamide (DICY), for example. The

cured blend can then be coated on to the explosive 12 using the water slurry method.

Usually a 2 to 10 percent by weight coating is applied. When pressed at 212-250 F (100-

121 C), the binder cures to form a non-melting thermoses polymer stable to 400 F (204 C).

Alternatively, the explosive formulation can be pressed at room temperature and cured in an oven at elevated temperature.

Another embodiment of a thermoplastic-thermosetting binder for use in a pressed or extruded explosive is a fluoropolymer such as Dupont Viton_, 3M Fluorel (RTM) 2175, or Dyneon (RTM) THV, for example. These fluoropolymers can be formulated with RDX or HMX using the water slurry process. The resulting explosive molding powder is pressed to shape using standard explosive pressing technology. In their natural state, these materials are thermoplastics and will soften and slump at temperatures exceeding approximately 250 F (121 C). However, exposure to electron radiation (so called e-beams) causes the polymer to cross-link and cure by well known mechanisms. E-beam curing increases the glass transition temperature and melting points of these polymers. Even in instances where the e-

beam only cures the skin of the polymer, the skin is sufficiently toughened to prevent deformation of the caseless shaped charge I exposed to elevated temperatures.

Figure 6 illustrates another embodiment of the debris free perforating system in which the jacket 24 and/or case 10 is made of a plastic or energetic material to support the explosive 12 and attach the shaped charge 1 to the loading tube 22. The plastic or energetic material is combustible such that upon detonation of the shaped charge 1, the jacket 24 and/or case 10 does not leave any debris. Suitable plastics include Nylon, PEEK, Polyimide, Polysulfone, PVC, CPVC, Polyethylene, Torlon_, PVDF, Teflon_, CTFE, CTFE/E, Polyethylene, Phenolic, Polypropylene, or any other plastic or filled plastic possessing adequate thermal stability for use at the desired operating temperatures. In one embodiment, the jacket 24 is made of paper.

In this embodiment of the debris free perforating system, the shape of the explosive 12 is maintained by the case 10 and may be fabricated with a meltable binder such as wax, for example. The jacket 24 and/or case 10 is made as thin as possible to enhance its combustion by the explosive 12 contained in the shaped charge 1. Typical jacket 24 and/or case 10 thickness in this embodiment is between 0.010 and 0.060 inches (0.025 to 0.15cm).

To enhance the consumption of the jacket 24 and/or case 10, an oxidizer or oxidizer/powdered metal blend is added to the plastic or energetic material. Such oxidizers can be added during the forming process by direct addition to the melted polymer in the cast of a thermoplastic material. Alternatively the oxidizers can be added to the uncured

resins of a thermosetting system. Suitable oxidizers can be ammonium nitrate, potassium nitrate, sodium nitrate, strontium nitrate, barium nitrate, ammonium perchlorate, potassium perchlorate, sodium perchlorate, RDX, or HMX, for example. Suitable powdered metals can be aluminum, magnesium, boron or zirconium, for example.

Another embodiment of the debris free perforating system uses jackets 24 and/or cases 10 fabricated from very thin metal that generate small fragments upon detonation of the explosive 12. The small fragments can embed themselves in the wall of the perforating gun 30 so as to not be carried by the well fluids. In the case of the thin metal comprising copper, the metal case may expand like a balloon without fragmenting and actually paste itself to the inside of the perforating gun 30 in one piece.

Similarly, another embodiment of the debris free perforating system uses jackets 24 and/or cases 10 fabricated from thin, low-mass glass and ceramic materials. The fragments generated during detonation would be in the form of fine particulates that will not compromise the integrity of the flow of the well fluids.

Figures 7a and 7b illustrate another embodiment of the debris free perforating system in which the loading tube 22 is a combustible cardboard tube. Figure 7a illustrates a spiral wrap cardboard tube and Fig. 7b illustrates a convoluted cardboard tube. To ensure incineration in an oxygen deficient environment, the loading tube 22 may be coated with an oxidizer filled paint 40. One embodiment of a suitable coating is a polyester or polystyrene thermosetting resin filled with an oxidizer such as ammonium nitrate, potassium nitrate, sodium nitrate, strontium nitrate, barium nitrate, ammonium perchlorate, potassium perchlorate, RDX, or HMX, for example. Additional energy can be supplied by incorporating powder metals such as aluminum, magnesium, boron, or zirconium.

Another embodiment of the debris free perforating system is illustrated in Fig. 7c.

In this embodiment, the loading tube 22 is a thin-walled plastic tube or rod made of one of the previously mentioned engineering plastics formulated with reinforcing fibers 42 (such as glass, carbon, or Kevlar_) and a suitable oxidizer such as ammonium nitrate, potassium nitrate, sodium nitrate, strontium nitrate, barium nitrate, ammonium perchlorate, potassium perchlorate, sodium perchlorate, RDX, or HMX. Additional energy can be supplied by incorporating powder metals such as aluminum, magnesium, boron, or zirconium.

Example

The following example details the results of debris tests run on two embodiments of the present invention. The "caseless" shaped charges used in the tests were very thin (0.060 inches (0.15cm) thick) 8 gram plastic combustible eases. The results are compared

to test results for a conventional steel-cased charge of equal size.

Test I. In the first test, five (5) of the above-described "caseless" shaped charges were carried in a 1-foot (0.30m) gun. The charges were loaded into a Styrofoam_ loading tube without the use of a jacket. The charges were detonated and the debris was collected. The amount of debris collected was approximately 2.1 grams of debris per charge. Most of the debris was actually liner powder that did not jet and therefore remained in the gun. It was estimated that the non-liner debris remaining in the gun was less than 1 gram per charge.

For reference, the conventional steel-shaped cased charge yielded approximately 240 grams per charge.

Test II. In the second test, four (4) of the above-described "caseless" shaped charges were carried in a 1-foot gun. The charges were loaded into a cardboard loading tube without the use of a jacket. The charges were detonated and the debris was collected. The amount of debris collected was approximately 6.3 grams of debris per charge. The debris was a combination of liner powder and small (approx. 'ail") cardboard pieces. Again, for reference, the conventional steel-shaped cased charge yielded approximately 240 grams per charge. The above discussed data is provided in tabular form in Table 1 below.

TABLE [Conventional Shaped Charge v. "Caseless" Shaped Charge Conventional "Caseless" Charges in "Caseless" Charges in Steel- Cased Styrofoam Loading Cardboard Loading Charges Tube Tube Grams of Debris 240 2.1 6.3 Per Charge The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the scope of the invention, and all such are to be intended to be included within the scope of the following claims.

Claims

1. A debris free perforating system, comprising: a shaped charge having a jacket made from a combustible material; and a case made from a combustible material.

2. The debris free perforating system of claim 1, wherein the combustible material is plastic.

3. The debris free perforating system of claim 2, wherein the plastic is selected from Nylon, PEEK, Polyimide, Polysulfone, PVC, CPVC, Polyethylene, Torlon_, PVDF, Teflon_, CTFE, CTFE/E, Polyethylene, Phenolic, and Polypropylene.

4. The debris free perforating system of claim 1, wherein the combustible material is an energetic material.

5. The debris free perforating system of claim 1, wherein the jacket comprises paper.

6. The debris free perforating system of claim 1, wherein the combustible material further contains or is coated with an oxidizer

7. The debris free perforating system of claim 6, wherein the oxidizer is selected from ammonium nitrate, potassium nitrate, sodium nitrate, strontium nitrate, barium nitrate, ammonium perchlorate, potassium perchlorate, sodium perchlorate, RDX, and HMX.

8. The debris free perforating system of claim 1, wherein the jacket and case are made from thin material.

9. The debris free perforating system of claim 8, wherein the thin material is copper.

10. The debris free perforating system of claim 8, wherein the thin material is glass.

11. The debris free perforating system of claim 8, wherein the thin material is ceramic material.