DEM0019754MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: August 19, 1953. Advertised on January 12, 1956

GERMAN PATENT OFFICE

The invention relates to an explosive cartridge with a shaped charge for attaching Holes in the walls and casings of boreholes for the production of oil, water and gas, so that the fluid is collected from the surrounding formation in the boreholes can.

For this purpose, several explosive cartridges are attached to a carrier, which together in the Drill shaft exploded, causing holes in the pipes of the boreholes relatively small diameter arise through which the existing in the surrounding formation Fluid can penetrate into the tubes and is thus obtained. Through the destruction the housing in which the explosive charges are housed and the support bracket; up to now there has been an accumulation of junk for this purpose, which is often sufficient ^ the boreholes clogging or the inflow of fluid from the surrounding formation into the Manhole sensitive to disturb. Are the explosive cartridge assemblies on a heavy cylindrical Steel girder attached, which was pulled out of the shaft after the explosion is to be, the formed junk can accumulate between the carrier body and the shaft wall, so that it is in the shaft

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pipe gets stuck. The forces released by the detonation of the charges can be so great . be that the steel support body is damaged in such a way that it is no longer used or only one can still be used a few times. Since the steel beams are quite expensive, you can too frequent replacements make the blasting process uneconomical.

The invention overcomes these disadvantages. For this purpose she suggests that a shaped explosive charge be used, which is a very has great explosive power. Shaped explosive charges are known per se. Such a shaped explosive charge, whose conical cavity is lined with a thin metal layer is according to the invention ' in a hermetically sealed housing made of impermeable glass material of this type housed that the · conical cavity at a distance from .the one end wall of the housing stands, while the other end of the explosive charge on the opposite housing end wall is applied.

In the explosion, the glass cases are completely smashed, so that only a small amount of junk arises that does not interfere with operation. Formed by the explosion of the explosive charge very strong forces, which ensure the complete shattering of the glass case and a very size. Let number of holes arise in the drill pipe. The vitreous with the ones in it Hollow explosive charges can be attached to a destructible carrier or to a non-destructible carrier, which according to Carrying out the blast can be pulled out of the well, because this is not prevented by the corresponding small junk.

Explosive cartridges with containers made of glass are known. In the invention, however, a hollow explosive charge is used housed by an extraordinarily powerful detonation in such a glass container and uses the explosive cartridge to solve a specific task.

The invention is explained further with reference to the drawings.

Fig. Ι is a cross-sectional view of a drill set according to one embodiment of the Invention;

FIG. 2 is an external view of ^{the drill set rotated 90 °} from the position of FIG. 1, part of which has been broken away for clarity;

Fig. 3 is an exploded view of the main parts of the drill set;

Figures 4 and 5 together are a partially sectioned longitudinal side view of a group of Drill kits attached to an "open" type carrier;

Figure 6 is an end view of a portion of the carrier of Figures 4 and 5;

Fig. 7 is a partially sectioned view of part of a steel beam, from which it can be seen how the drill kits can be attached;

FIG. 8 is generally a partial elevational view showing how the supports of FIG Figures 4 and 7 can be combined to hold the drill sets according to the invention;

Fig. 9 is a longitudinal section of a drill set according to another embodiment of the invention;

Fig. 10 is a cross-sectional view of another embodiment of the drill kit of the present invention; '. '

Fig. 11 is a sectional view of another Embodiment of cargo liner;

Figure 12 is a top plan view, partially in section, of another embodiment of the present invention Drill set;

Figures 13 and 14 are front and rear views, respectively the embodiment, FIG. 12;

Fig. 15 is a partially sectioned longitudinal view the top of another form of support for holding the drill sets of Figure 12;

Fig. 16 is a partial longitudinal sectional view of the lower part of the carrier of Fig. 15, which is rotated with respect to the upper part of Fig. 15 to 90 ^0th

First, FIGS. 1 to 3 will be described. A drill set P according to one embodiment of the invention is shown. It "consists of a housing 10 made of glass material. The housing 10 has a generally frustoconical shape. The term" glass material "is intended to encompass not only glass of the common and known type, but also various ceramic materials which, when baked or fired The housing 10 has a bore 11 also of generally frusto-conical shape, open at its wider end and closed at its narrower end by an end wall 12. The end wall 12 is somewhat concave In two directions at right angles to one another, it has a slight curvature, as can be seen from Figures 1 and in particular 2. A pair of spaced projections 13 is cast on the outside of the end wall 12. They form a recess 14 which extends transversely to the center of the The recess 14 has an inwardly curved bottom 15 which also has a convex curvature along the longitudinal axis hse of the recess. The A-wall of the housing 10 has an externally thickened portion 16 and an annular flange 17 for reinforcing the container. It forms shoulders for holding the housing in place in suitable supports, as will be described below. The inclination of the bore 11 is preferably somewhat reduced at its front part 18.

The dome-shaped cover 19, also made of glass material, has a generally hemispherical cavity 20. It closes the open end of the Housing 10 from. Its annular end edge 21 is of fairly the same thickness as the adjacent one End of the casing. This creates an annular inner shoulder 22, which extends inwardly into Direction to the housing axis extends. It is also

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An outer ring flange 23 is provided on the cover in order to reinforce the edge of the cover all around. As shown, a plurality of spaced apart, outwardly extending projections 24 on be cast on the front end of the cover. The touching edges of the housing 10 and the lid 1.9 are preferably flat in order to obtain a very tight seal between the two parts. They can be sealed together by a thin layer of any suitable solid, waterproof Adhesive 25 connected, which serves to effectively seal the connection and the lid hold on to the housing at the high pressures the kit may be subjected to during operation.

One material from which the container 10 and the lid 19 can be made is a glass material with a very high crushing strength. But their unique quality is that when they do Vibrations at a certain frequency

ao, they are completely thrown into crystalline powder as opposed to the relatively large irregular ones Pieces into which ordinary types of glass break, will be dissolved. The dissolution frequency of the respective type of glass can be according to the temperature control conditions. The detonation of an explosive is usually a wave or vibration phenomenon. The frequency of the vibration depends on the nature of the individual explosives.

As a result, it is possible to set the frequency of dissolution of the glass to the frequency of the relevant Adapt explosive, which is located in the glass housing, so that the housing is always will dissolve to the desired fine powder upon detonation of the charge. This ensures that relatively large particles of debris are not present in the shaft. In general however, most glass and ceramic materials will turn out to be a relatively fine state dissolve at the oscillation frequencies of the shock waves, as they are caused by the explosive charges of the subsequently considered species can be generated.

An intermediate layer 26, preferably made of rigid, synthetic, plastic material generally a truncated cone shape so that it fits exactly into the bore 11 of the housing. The The inner end of the intermediate layer 26 has an end wall 27 in which an axial opening 28 is provided is. The intermediate layer 26 has a straight or cylindrical front end part 29, which in FIG ends the same plane with the front end of the housing 10 so that it is in contact with the Shoulder 22 of the lid is when it is placed on the end of the housing. Since part 18 of the Housing is inclined to the axis of the drill bit, while the front end portion 29 of the insert straight or is cylindrical, there is a small air gap 30 between these parts, which is the radial Explosive forces reduced from this end of the drill set to the adjacent parts of the girders or, absorbed in which the drill set is mounted. This helps the narrow ventilation gap 30, the neighboring To protect parts of the carrier against damage caused by the explosion of the cargo. this is especially important when the drill kits are housed in solid metal supports that again should be used.

The interior of the intermediate layer 26 is filled with a charge of a suitable explosive 31, which spreads through opening 28 into contact with the inner surface of end wall 12 can. The portion 32 of the explosive which lies within the opening 28 and is in Spreading contact with the end wall 12 may be more sensitive than the main part of the charge, to serve as an amplifier for this. Part 32 can be another explosive. But he can also be the same explosive as that of the main part of the cargo, but will then be different tightly packed to increase its sensitivity to that of the bulk of the cargo.

The explosive 31 and the amplifier 32 are highly explosive materials, e.g. B. pentaerythritol granitrate (PETN), tetryl, pentolite (50% PETN and 50% TNT), trinitrotoluene (TNT), amatol, cyclonite, tetrytol (6o ° / .o tetryl and 40% TNT) and other known detonating chemicals.

The end of the explosive directed towards the open end of the insert has an outwardly opening, generally conical cavity 33, the apex of which is preferably rounded at 34 and lies on the longitudinal axis of the drill set. A conical lining 35 with a complementary shape to that of the cavity 33, the apex part of which is rounded in addition to the shape of the apex 34 of the cavity, sits in the cavity and is thus pressed against its wall. The apex angle of the cavity 33 (and the liner 35) is usually from 40 ⁰ to about ioo ° depending on the nature of the desired nozzle. The liner 35 is usually made of thin metal, preferably copper, with a thickness that depends on the dimensions and nature of the explosive and the desired nozzle properties. The thickness of the liner is usually about 0.5 to 3.5 mm for the various sizes of drill bits. They may be uniform over the entire liner, or at the apex it has a slightly thinner portion of the liner, which is slightly thicker down, as 10 and 11 shown at 35 _e in Fig.. The tapered shape of the liner is particularly effective in ensuring complete destruction of the liner and better nozzle formation, which results in greater penetrating effectiveness and better hollow formation. The length of the liner is so dimensioned that when it is tightly inserted into the cavity 33, its outer end lies in the same plane as the outer ends of the intermediate layer 26 and housing 10 and is thus also in contact with the shoulder 22 when the lid 19 is placed on the end of the housing. The cavity 20 in the cover 19 forms the so-called "standing apart" space, which is the front continuation of the

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Depicts cavity at the end of the charge in which a convergence of the explosive gases in Nozzles or narrow jets formed by the shape of the cavity 33 and the liner 35 can take place without interference from external materials.

The drill set is assembled in any suitable and convenient manner. Using an intermediate layer 26 can usually contain the required amount of explosive plastic or powder form are brought into the intermediate layer and pressed firmly by using the liner 35 as a press ram. Through this the cavity 33 is formed and the lining is inserted at the same time. The amplifier explosive 32 can be attached separately to the front of the main part of the explosive, or he can be part of the main part itself. This part is pressed together to form a slightly different tightness than the rest of the charge, to give it a different level of detonation sensitivity admit. The intermediate layer, which now contains the explosive, and with the lining 35 is provided can be plugged into the housing as a unit. A film of poetic Adhesive 25 is then applied to the mating ends of housing 10 and lid 19. the The lid is placed on the end of the housing and held there until the glue is either air dried or application of heat or the like, depending on the nature of the particular one used Adhesive is firm. Other known methods of hermetically sealing the housing can be used.

The intermediate layer 26 can also be omitted. In this case, the explosive charge is initially in the to cast the desired shape and to bring it directly into the housing according to FIG.

If the drill set constructed in the manner described above is put together as explained, so it is completely tight and can withstand external pressures of more than 454 kg, so that it is in a borehole at any desired depth and in fluids at very high depths hydrostatic pressures can be immersed without damage before it takes effect is brought. The construction described allows the perfect composition of the Drilling sets at a suitable assembly point, their handling and shipping too widely distributed Places of use without danger and in the condition that they are attached to any carrier that is to be used at the particular location of use. Since the If the drill set is hermetically sealed, it can be used for long periods without risk of deterioration of the explosive.

To detonate the drill kit, a strip of flexible fuse 36, e.g. B.

the well-known "Prima Cord" through the recess

14 and in close contact with the ground

15 of the drill set held. The one from the ignition The detonating force generated by the cord 36 becomes a booster explosive through the end wall 12 of the drill bit 32 and then transferred to the main explosive charge 31. The detonating force is thereby applied to the longitudinal axis of the drill set and at its rear end. the Fuse usually has a solid waterproof cover so that it can keep any liquid out of it is exposed in the shaft, without influencing its ignition properties offers resistance. As a result of described construction, which makes the drill set a completely self-supporting or rigid and is sealed structure, and by the arrangement of the outer recess 14 at the end of the housing the fuse can be placed outside. This makes the final attachment in the Simplified manhole. Also, multiple drill sets can be easily accessed at any one Brackets are attached, which is of extremely simple construction, since it is only necessary any to provide an appropriate support shape, whereby the drill sets are kept in the desired spacing or directional arrangement, and because it is not necessary is agile to protect the outside of the drill kits or the fuse against liquid. the Detonating cord is then drawn through and over the support frame in a convenient manner, when going from one drill set to another.

Since the fuse 36 will be attached to the outside of the drill kits, it is important that the thickness of the End wall 12 is kept within suitable limits which allow effective transmission of ignition from the fuse to the end of the explosive charge. The thickness for glass materials here species described will usually be between approximately one inch and one inch for the various Sizes of the drill kits used for manholes.

FIGS. 4, 5 and 6 show the one support form, which is used to hold a number of drill sets and to sink them in a well can be. In this embodiment the carrier consists of a pair of narrow, flat metal strips 40, in particular made of a metal, which under the detonation forces of the explosive charges is shattered into relatively small pieces and dissolved. Various aluminum and Magnesium alloys with the desired crushing properties are available for this. the Strips are attached to the longitudinally spaced points by suitable fastening means 41, z. B. rivets or screws, fastened together. The intermediate sections of the strips are spread apart to form circular sleeves 42. In each such sleeve one of the Drill sets inserted, as can be seen in particular from FIG. The flange 17 of the drill kit is used as a stop so that the drill set cannot slide all the way through the sleeve. Every drill set is used in any suitable manner, e.g. B. held by a wire 43, which the housing on flange 17 and then wrapped around strips 40 above and below the sleeve.

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A strip of detonating cord 36 is then passed along the carrier. It is placed one after the other in the recesses 14 of the individual drilling units attached to the carrier. The portion of the fuse which lies in the indentations is held in place by wrapping a friction tape 44 lengthwise around each drill set as shown in FIG. The band 44 also encompasses the exterior of the sleeve, which additionally holds the drill sets in place. Any suitable and convenient means can be used to hold the drill sets in place on the carrier. The lower end of the fuse is enclosed in a suitable container 45. The detonating cord goes through a screw cap 46 for the container and ends in a knot 3O ₁₂ lying perpendicular to the cord, which is embedded in a suitable, water-repellent lubricant 47 or a similar plastic compound which is insoluble in the liquids contained in the Shaft or well may be present. The lubricant seals the free end of the fuse against the ingress of such liquids. The container can be attached to the carrier in any convenient manner. A weight 48 is attached to the lower end of the beam, as shown, to provide sufficient weight to pull the beam so that the beam can be easily submerged through the fluids that may be present in the wellbore or well.

The upper end of the carrier is connected to an ignition head 49. It consists of the lower one Piece 50 with the internal screw thread 51 and an upper piece 52 with a projection 53 with External screw thread. Both parts can be screwed together. The lower piece 50 has to the top extending slots 54 on its opposite. lying sides in which the upper ends of the Strips 40 are placed and fastened there by screws 55. The bottom of the screw socket 51 is cut out to form a container 56 which is connected to an axial passage 57. The passage 57 extends to the open end of the lower piece 50. The upper end of the detonating cord 36 is passed through the passage 57. There is a knot 58 perpendicular to the cord formed to hold the string in the container 56.

The upper piece 52 has an axial bore 59 which at the lower end of the projection 53 to Receiving the upper end of a tubular capsule 60 with a bore 61 is enlarged, the is closed at its lower end. The bore 61 protrudes from the projection 53 so that, when screwed into the screw socket 51, the closed lower end of the capsule 60 in in firm contact with knot 48 at the end of the fuse. The lower 'end of the screw socket 51 and the container 56 are with a suitable, water-repellent lubricant 62.

. filled, the when the projection 53 into the screw socket S ι is screwed in tightly around the knot 58 and into the passage 57 around the fuse 36 being pressed around. The lubricant forms a plastic seal for the top of the fuse. It prevents the entry of liquid into the interior of the ignition head. So he protects that free end of the fuse against damage by a liquid. At the same time the transmits Due to its plastic properties, lubricant exerts external pressure on the knotted end of the fuse. As a result, its tightness is increased in accordance with the size of the external pressure. Ever The greater the tightness of the explosive that forms the core of the fuse, the greater it is the speed of their detonation. As a result, the plastic seal described type for the end of the fuse the ignition effect of the cord with increasing external pressures increases the entry of external fluids while at the same time acting as an effective, flexible seal prevented in the ignition head.

An electric initiator percussion cap 63 of suitable and convenient type, which is to be ignited, extends into the bore 61 of the capsule 60. A small pill 64 of suitable amplification explosive can be inserted into the bottom of the bore 61 below the primer 63, thereby increasing the strength of the initiator ignition, which will go transmitted from the percussion cap 63 to the node 58 at the end of the fuse is increased. The upper end of the bore 59 is widened and provided at 65 with an internal screw thread for receiving a screw pin 66 which is connected to a cable 67. The cable 67 is used to sink the drill set group into a shaft or well. An electrical conductor 68 is enclosed in the cable 67. It is connected to an electrical contact device 69 in the usual manner. It is located at the lower end of the screw pin 66 and is connected to the primer 63 in the usual manner by a pair of electrical conductors.

A number of upwardly and outwardly extending, flexible fingers 71, of which only one shown can be arranged on the outside of the firing head around it for the purpose of the drill set assembly in a known manner to hold in position in a borehole.

The drill set group, which, as shown in particular in FIGS. 4, 5 and 6, is assembled, is sunk into a borehole on the cable 67 in the desired position at which the wall of the shaft or well is to be drilled. Ignition current is fed to the primer cap 63 via the conductor 68. It comes into effect and thereby also the fuse 36. The detonation wave travels along the fuse and will bring the explosive charges of the drill sets P into effect one after the other. Of course, the detonation wave travels at such a rapid rate that, for all practical purposes, all of the drill sets detonate essentially simultaneously. Each drilling set generates an extraordinarily fine-powdered gas jet, which is directed against the shaft or well wall in order to create the desired perforations there.

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keep. As mentioned earlier, it affects the frequency of the detonation wave that is generated in each drill set becomes, the complete dissolution of the glass material housing in fine powder, while the strip 40th of the carrier is equally perfect be smashed into small pieces. No so-called junk will be sufficient Amount present that the perforations or the borehole are clogged. The junk can easily be washed away from the well or manhole if so desired. the The ignition head is normally not damaged and can be pulled out of the shaft or well to replace the initiator element and attach it to a new carrier, which holds a new group of drill sets.

Fig. 7 shows an arrangement in which the drill sets P 'are attached to another carrier. It consists of a cylindrical piece of steel 75 in which a number of recesses 76 are provided for receiving the drill sets. An axial bore jj ¹ extends through the piece of steel and is in communication with the successive recesses 76. The upper end of the steel piece 75 has a recess 78 with an internal screw thread for receiving the projection 53 of the upper piece 52 of an ignition head 49. When. Assembling the device is the fuse 36, which has a knot 58 at its upper end, down through the hole JJ. pulled so that it reaches the individual recesses 76 one after the other. When the drill set is inserted into its recess 76, it is rotated so that its groove 14 coincides with the part of the detonating cord which passes through the recess 76. The cord lies tightly in the groove of the drill set when it is fully inserted into its recess 76. '. The drill set is held in place by a wire 79, for example. It is stretched transversely around the outer end of the cover 19 of the drill set between the projections 24. The opposite ends of the wire 79 extend through side openings 80 on the opposite

Φ5 lying sides of the front end of the recess 76. They extend around the outside of the steel body and are folded over at the edges of the outer ends of the openings 80, whereby the drill set is retained in its recess 76, as shown. The protrusion 53 includes the initiator primer 63 and its associated parts, as in the previously described embodiment. The bottom of the recess 78 is filled with lubricant 62 which seals and protects the end of the detonating cord and the upper end of the passage JJ in the same manner and for the same purpose as was already stated in the previous embodiment. From the described

So order results that when using the sealed, self-supporting or rigid Drill sets according to the invention ensure careful machining of the steel body and precise tolerances in the recesses 76 are not necessary. This reduces the cost of manufacturing one-piece carrier of the type described significantly reduced. They can also do so many times to be used. ,

Fig. 8 shows yet another carrier arrangement in which the piece of steel carrier of FIG a freely accessible or open carrier of FIGS. 4, 5 and 6 can be connected. The connection between these two types of support is done by a screw projection 81, which is screwed into the screw sleeve 51. The lower end of the portion of the fuse 36, which passes through the steel body 75 ,. has a transverse knot 82 that connects to knot 58 at the upper end of the line part. that can be squeezed out from the lower Carrier extends into the screw sleeve 52. The nodes in contact are in the previous one described manner soaked with lubricant. The detonation wave passes through the part of the Detonation cord in steel body 75 and then over 85 touching nodes 82 and 58 to drill kits in the lower beam. All drill sets in both carriers thus arrive one after the other and in the essential at the same time to the effect.

It will be understood that many other arrangements and carrier configurations can be used to to hold the drill sets according to the invention.

Fig. 9 shows a somewhat modified form of the drill set. The conical angle of the conical part 20 _{e of} the intermediate layer 26 is slightly larger than that of the inner part of the bore 11, so that there is an air gap 85 between these two parts. This modified type of drill set can in particular be attached to one-piece support arms according to FIG. 7, since it has been shown that the air gaps 85 and 30 reduce the radial forces of the explosive charge. The air gaps appear to absorb the impacts, greatly reducing the possibility of damage to the walls of the recesses in the one-piece beam. As a result, the useful life of this type of carrier is significantly increased.

Fig. 10 shows an embodiment of the drill set to which we have already referred. The intermediate layer 26 is missing. This embodiment is particularly suitable when using relatively large explosive charges. The part 3i _(I the explosive is cast in the desired, generally frustoconical shape before use. At its apex is a recess 31 $, for receiving a corresponding shape 'of a booster explosive 32. The housing _ft present. Io _ß is somewhat shorter than the explosive part 3i _ß , so that the hollowed end of the explosive part 3i _{i (} protrudes a corresponding amount from the open end of the housing. The cap ig _u is proportionally longer, so that it surrounds the protruding end of the explosive part. It has an ent - 125th speaking recess for an inner shoulder 22 _fl ,

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against which the hollowed end of the explosive part and the inserted lining 35 rest when the cap ig _{a is} brought into position over the end of the charge. The shoulder 22 _a is correspondingly removed from the closed outer end of the cap in order to get the desired inner distance within the cap io, _a .

The radial dimensions of the explosive part 3i _a are slightly smaller in length than the bore of the housing io _fl and the recess in the cap ig _a , so that an annular air space 85 ,, is obtained over the entire length of the explosive part. As already mentioned, the ring-shaped air space 85 'serves to dampen the lateral forces which radiate from the explosive which is coming into effect. A suitable spacer 86 is located around the explosive part 3i _fi so that it is held concentrically in the housing. The spacer 86 can be made of any material, e.g. B. consist of a band of plastic material. Usually more glue 25 is used to hold the cap to the housing, the excess then runs into the interior of the housing around the explosive part 3i _(r

Fig. 11 shows the already mentioned tapered design Lining construction. The wall thickness is reduced in the direction of the apex. The tapered liner construction can be used in any of the various previously described embodiments of. Drill sets are used. The degree of rejuvenation can for the different thicknesses and sizes of the liner and for the different Substances are changed from which the lining is made. In general, the Reduction in wall thickness at the apex of the liner approximately 10 to 75% of the thickness of the liner at their base.

Figures 12, 13 and 14 show another form of drill kit. Consists of one piece with th ^e case 10 of the laterally extending flange 90. It extends around the sides and the rear end of the housing in the center plane of Bohrsatzes around. There are holes 91 in the flange 90 on opposite sides of the housing 10 and a hole 92 in the rear of the flange on the outside of the end wall 12 of the housing. The hole 92 has the task, like the recess 14 in the previously described embodiments,

d. that is, it is intended to receive the fuse 36. The shape of the drill set and the arrangement of the The explosives in the drill set are otherwise exactly the same as in the previously described versions.

Fig. 15 shows a form of a so-called open support frame, which is therefore freely accessible. He can be used to attach a number of drill kits as shown in FIG. The support frame consists of a pair of cylinder rods 93. The rods 93 are inserted through the holes 91 of the drill sets of FIG. 12 inserted. This number of drill sets can be fitted onto the rods 93 one after the other as desired. The individual drill sets are spaced apart on the rods with the help of the tubular spacer sleeves 94. The spacer sleeves 94 can be any Length, depending on the distance you want between the individual drill sets. It the drill sets can alternate, as shown, in opposite directions, or they can all lie in the same direction or be arranged in a different grouping type. The lower ends of the rods 93 are connected to a nosepiece 95. The top ends are connected to a head 96 which is generally the lower piece 50 of the firing head shown in FIG is equivalent to. The detonating cord 36 passes through the head 96. You will then get through one after the other the holes 92 of the individual drill sets, and their lower end is in the nosepiece 95 in. either attached in a suitable manner. With this support structure, if the drill sets to There is an explosion, the housing completely shattered. But the support frame with the bars 93, the spacer sleeves 94, the nose piece 95 and the head 96 are retained and can be used as a whole pulled out of the shaft or well. - ■

Numerous other forms of support can be used for securing the various embodiments the drill kits as shown and explained can be used. The porters can from be of the so-called open type, d. i.e., they are freely accessible. The carriers can also be of so-called be of a fixed nature, d. that is, the beams are made from a single solid piece. In the latter case the carrier can consist of a solid metal. It can be made from a cementitious block of stone or consist of ceramic material or glass material. In this case, the wearer is completely through the detonation of the drill sets shattered. . There can be various changes and deviations on the details of the invention may be made within the scope of the following Claims lie and do not deviate from the spirit of the invention.

Claims (6)

PATENT CLAIMS: i. Explosive cartridge with a hollow charge for making holes in the walls and housings of wells for the promotion of oil, water and gas, whereby the fluid from the surrounding formation is collected in the well, characterized in that the explosive hollow charge (3 ^τ > 3 Ο » whose conical cavity (33) is covered by a thin metal layer (35), is housed in a hermetically sealed housing (10, 10 ") made of impermeable glass material in such a way that the conical cavity of the load is at a distance from one end wall of the housing, while the other end of the explosive charge rests against the opposite end wall of the housing. 509 628/325 M 19754 IVaJ 78 e 2. explosive cartridge with a shaped charge according to claim i, characterized in that the wall thickness' of the metal lining (35 _a ) decreases from its base to its apex (Fig. Ii). 3. explosive cartridge with a shaped charge according to claim i, characterized in that the Shaped explosive charge a booster explosive part (32) at its end opposite the conical cavity (33). 4 .. explosive cartridge with a hollow charge according to claim 1, characterized in that the detonating cord (36) is attached to the point of the glass housing (10, io _(i ) which is opposite the conical cavity (33) and to the explosive reinforcement part (32) is present. 5. explosive cartridge with a hollow charge according to claim 1, characterized in that an intermediate _{layer (26, 26 a} ) made of rigid, plastic material between the glass housing (10, io _tt ) and .the hollow explosive charge (31, 31 ^) is inserted. 6. explosive cartridge with a hollow charge according to claim 1, characterized in that an annular air space (85, 85 _O ) between the glass housing (10, io _e ) and the intermediate layer (26, 20 _a ) made of rigid, plastic, material or the explosive shaped charge (31, 3I _n ) is located. Referred publications: U.S. Patent No. 1549,618; British Patent No. 16,536 of 1912; Swiss Patent No. 91 356; Engeneering and Mining Journal, May 1946, Vol. 147, No. S, pp. 58 to 63. For this purpose 2 sheets of drawings 509 628/325 1.56