RU2723107C1 - Explosive cartridge, a method of making said cartridge and a device for filling the cartridge with an explosive substance and forming a cavity for inputting a detonating cap - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: invention relates to production of cartridges of safety explosive substances. Method of producing explosive cartridge with tight detonating cap entry device consists in sealing one of ends of flexible tubular shell from polymer material and putting it on hollow tubular element with funnel-shaped expansion with location of the sealed end of the tubular shell on the side opposite to the location of the funnel-shaped expansion. Then, tubular part is introduced into cavity of sleeving element with placement of rod-like element of last element in cavity of this tubular part and an open end of the flexible tubular shell is pulled along the outer surface of the hollow tubular element towards the funnel-shaped expansion until the sealed end of the tubular shell is placed on the end of the rod-like element of the sleeving element. Then, through funnel-shaped expansion, industrial explosive is filled into cavity between walls of flexible tubular shell with gradual withdrawal of tubular element with funnel-shaped expansion from cavity of this shell as it is filled with industrial explosive until complete withdrawal of this element from sleeving element. After that, open end of flexible tubular shell is connected to its sealed end, shell filled with industrial explosive is removed and detonating cap is inserted into its inner channel.EFFECT: invention allows improving operating reliability of the cartridge.3 cl, 9 dwg

Description

The invention relates to the production of cartridges of industrial explosives (BB) for blasting. In particular, we are talking about intermediate detonators of charges of industrial explosives, which in the framework of the present invention in accordance with the design are referred to as "cartridge charge" or "cartridge explosive" or "cartridge".

Currently used industrial explosives (granular, emulsion, water-gel) purposefully (for safety reasons in the manufacture, storage, transportation and use) create insensitive to the initial impulse primary means of initiation (detonator caps, detonating cords) - which corresponds to class 1, subclass 1.5 of compatibility group “D” (classification according to GOST 19433-88).

To initiate detonation in the charges of such explosives, intermediate detonators are used: charges of small mass (usually not more than 1 kg), which are sensitive to the above primary means of initiation of explosives (class 1.1.D), placed in a shell to preserve the shape of such a charge, equipped with devices for input and fastening of primary means of initiation (hollow sockets for placement of detonator caps in them, channels for placement of a detonating cord in them).

Thus, the mass of the intermediate detonator (sensitive to primary means of initiation) is less than 1% of the mass of the initiated main charge of an industrial explosive (not sensitive to primary means of initiation), which significantly reduces risks and increases safety in the manufacture, storage, transportation and use of explosives.

Known capsule-sensitive explosive compositions used to fill the shells of intermediate charge detonators of non-capsule-sensitive industrial explosives. As a rule, it is pressed trotyl, or compositions based on molten trotyl with the addition of powders of individual explosives (RDX, PETN, etc.) to increase sensitivity to primary means of initiation (since molten TNT is not sensitive to primary means of initiation). Intermediate detonators made from the indicated TNT, RDX, and TEN must be stored and transported with increased safety measures, with a significant restriction on the carrying capacity of the vehicles carrying them. This leads to a significant increase in the cost of such intermediate detonators at the place of use.

In this regard, the urgent task of manufacturing intermediate detonators from non-explosive components directly at the application site is to minimize the risks associated with the transportation and storage of explosives sensitive to primary means of initiation.

Thus, an explosive cartridge is known (which is an intermediate detonator) with a sealed detonator-capsule input device, which is a tubular shell made of a polymer material with sealed ends, inside which an emulsion or water-gel industrial explosive is placed, as well as a detonator, a tubular shell made flexible, while from one sealed end in the body of the tubular shell, a recess elongated along the shell of an elongated shape is formed to accommodate the detonator capsule, formed by pressing the end of the tubular shell inside this shell (RU 2591868, F42B 3/087, F42D 1/08, publ. 07.20.2016 .).

From the same source, a device is known for manufacturing an explosive cartridge with a sealed detonator capsule input device, which is a glass-shaped element with a wall height of not more than the length of the cartridge, at least one through hole is made in its bottom and a tubular rod is fixed, directed to the side the open end of this glass-like element and made not less than the length of the detonator capsule.

From the same source there is a known method of manufacturing an explosive cartridge with a sealed detonator-capsule input device, which consists in sealing one of the ends of a tubular shell of polymer material, filling its cavity from the open end with an emulsion or water-gel industrial explosive, followed by sealing the open end, and then the detonator capsule is fixed, a flexible polymeric material is used for the tubular shell, and before filling the cavity of the tubular shell of flexible material, the nozzle of the metering device is introduced into this shell from the side of the open end and the shell is placed on the side of its sealed end in a glass-shaped element with abutment of this end into a tubular rod fixed to the bottom of this element, and then the cavity of the tubular shell is filled with an emulsion or water-gel industrial explosive, during which the wall of the tubular shell of the tubular piece is grasped eye for the formation of a recess pulled into the cavity of the shell for subsequent placement in it of the detonator capsule.

This decision was made as a prototype for the declared objects.

A feature of the manufacture of this cartridge is that the shell filled with an industrial explosive with a plugged end (end) is lowered into a glass (which is a device), at the bottom of which a rod with a length equal to the length of the detonator capsule is mounted. Under the weight of the explosive, the shell is pressed into the inside of the glass, is mounted on the end of the rod and sinking in the direction of the bottom of the glass, squeezes the recess due to the fact that it forces the mass of explosives inside the shell. The disadvantage of this technical method of manufacturing a channel for a detonator capsule is that at the moment the rod is pressed into the shell, the walls of the latter experience pressure from the explosive inside the shell and pressure from the rod stretching the shell. As a result, a breakthrough of the shell at the point of contact with the rod end is possible. In addition, the channel for the detonator capsule is made equal to the length of this detonator. After its installation, the mass of explosives is redistributed inside the shell, often leading to partial or complete extrusion of this detonator capsule from the recess. It is assumed that after installation in the recess, the detonator capsule should be jammed with pressure from the wall forming this channel. But, we must not forget that as an explosive, an emulsion or water-gel industrial explosive is used, with a sufficiently small internal friction. Such explosives are of the type "water in oil" and have a sufficiently high fluidity. Therefore, in the shell, the equilibrium state of such an explosive is determined by the equality of pressures outside the shell. After the shell is removed from the device, the explosive begins to move inside the shell towards a balanced state, which is determined by the movement of the explosive mass down the shell, just in the direction of the recess. When the explosive mass is displaced, the pressure from the walls is redistributed to the wall of the recess and the end part of this recess, as a result of which the channel begins to shorten. This causes squeezing the detonator capsule out of the recess.

In this regard, such cartridges as intermediate detonators operating from their own detonator have insufficient operational reliability in terms of maintaining the volumetric shape as a whole and the channel shape for its own detonator.

The present invention is aimed at achieving a technical result, which consists in increasing the operational reliability of the cartridge by maintaining the external shape of the filled explosive shell and the channel formed in it.

The specified technical result for the device is achieved by the fact that in the cartridge of an explosive with a sealed input device of the detonator capsule, which is a tubular shell of flexible polymer material with sealed ends, inside which an industrial explosive is placed, as well as a detonator capsule, with one of a sealed end in the body of the tubular shell, a recess elongated along the shell of an oblong shape is formed to accommodate the detonator capsule, formed by pressing the end part of the tubular shell inside this shell, an elongated recess is made along the entire length of the tubular shell to place the detonator capsule at a distance from the open end of this recess while the blind end of the indented end of the tubular shell forming a recess for accommodating the detonator capsule is connected to a sealed end of the shell located on the side of the blind end of the pressed tubular shell.

The specified technical result is achieved in that the device for filling the cartridge with explosive and forming a cavity for introducing the detonator capsule containing a glass-shaped element with a wall height not exceeding the length of the cartridge, in the bottom of which a rod-shaped element is fixed, directed towards the open end of this glass-shaped element and made longer than the height of the glass-like element, it is provided with a hollow tubular element with a funnel-shaped extension at one end, used to put on it a muffled cartridge from one end of the tubular shell with a muffled end placed on the other end of this hollow tubular element, while this hollow tubular element is placed tubular part in a glass-like element with the location of the rod-shaped element of the latter inside for the tubular part for drawing the tubular shell along the outer surface of the hollow tubular element towards the funnel-shaped expansion and filling of the shell industrial explosive.

The specified technical result for the method is achieved in that the method of manufacturing an explosive cartridge with a sealed detonator-capsule input device, which consists in sealing one of the ends of a flexible tubular shell of polymeric material and putting it on a hollow tubular element with a funnel-shaped extension with a sealed arrangement the end of the tubular shell from the side opposite to the location of the funnel-shaped expansion, then the tubular part is introduced into the cavity of the cup-shaped element with the placement of the rod-shaped element of the latter in the cavity of this tubular part and the open end of the flexible tubular shell is pulled along the outer surface of the hollow tubular element towards the funnel-shaped expansion to the moment of the location of the sealed end of the tubular shell at the end of the rod-shaped element of the glass-like element, and then industrial explosives are poured or poured through the funnel-shaped extension the substance into the cavity between the walls of the flexible tubular shell with the gradual pulling of the tubular element with a funnel-shaped expansion from the cavity of this shell as it is filled with industrial explosive until the element is completely withdrawn from the glass-like element, after which the open end of the flexible tubular shell is connected to its sealed end and a shell filled with an industrial explosive is removed and a detonator capsule is inserted into its inner channel.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present invention is illustrated by a specific example of execution, which, however, is not the only possible, but clearly demonstrates the possibility of achieving the desired technical result.

In FIG. 1 shows a General view of the cartridge assembly with a detonator capsule;

FIG. 2 is the same as in FIG. 1 shows how a detonator capsule is inserted into a shell with explosives;

FIG. 3 - jamming of the detonator capsule after filling the explosive shell;

FIG. 4 - the appearance of the tubular shell;

FIG. 5 - the first element of the device for shaping the tubular shell;

FIG. 6 - the second element of the device for shaping the tubular shell;

FIG. 7 - placement of a tubular shell on the first element of the device before giving the shell a three-dimensional shape;

FIG. 8 - the introduction of the first element of the device with the shell in the second element of the device;

FIG. 9 - organization of the volumetric shape of the tubular shell in the device before filling the explosives in this shell.

According to the present invention, a novel design of an explosive cartridge with a sealed detonator capsule input device is contemplated. This cartridge can be considered as an intermediate detonator (PD) for explosive charges that are not susceptible to primary means of initiation, and, therefore, requiring the use of PD to initiate detonation.

A sealed device for introducing a detonator capsule allows not to violate the integrity of the cartridge shell when a detonator capsule is inserted into it. This is especially important when the explosive is not allowed to come into contact with the rock due to a possible chemical reaction between them (for example, sulfide-containing rocks can undergo a chemical reaction with industrial explosives containing ammonium nitrate. The reaction occurs with the release of heat, which leads to heating explosive charge and emergency explosion of such a charge up to fatal injury to personnel engaged in blasting).

The explosive cartridge (Fig. 1-3) with a sealed input device of the detonator capsule 1 is a tubular shell 2 of flexible polymeric material, for example, of polyamide (a segment of the polymer sleeve 3, Fig. 4, plugged at one end 4 by, for example , ligation with a thread or twine of the walls of this end, the other end 5 open). An industrial explosive is placed inside the flexible shell 6. At the same time, a recess 7 (recess) is formed along the oblong-shaped shell from the one sealed end in the body of the tubular shell to accommodate the detonator capsule 1. This recess (recess) is formed by pressing the end of the tubular shell into this shell in the direction along its length.

The design feature of this cartridge is that the oblong recess 7 is made along the entire length of the tubular shell, that is, to its muffled end 4, and the detonator capsule 1 is placed at a distance from the open end of this recess. In addition, it is important that the deaf end of the depressed end part of the tubular shell forming a recess for accommodating the detonator capsule is connected to a sealed (drowned) end of the shell located on the side of this blind end of the pressed tubular shell. In fact, as will be seen later in the description of the method of manufacturing a cartridge, the wall of the shell at the open end is tied with thread or twine, or by overlaying a wire clip with a blanked end of the pressed part of the shell.

The detonator capsule 1 or a device, other in design or function, for initiating the detonation of explosives from a flame-retardant cord or from another source is introduced into the cavity of an elongated recess shape after the shell is filled with an industrial explosive. Since the filling of the shell is carried out on a special device on which this recess is also formed, after removing the filled shell, the recess retains its cylindrical shape along the entire length of the shell - the cartridge. This is enough to insert a detonator capsule (Fig. 2), which, as a rule, and most manufactured by the industry, has a cylindrical shape. When carrying, transporting and storing in boxes, the shell deforms (due to external loads) and partially passes - the recess is blocked by the wall forming this recess, as shown in FIG. 3. The wall of the shell compresses the detonator capsule and fixes it from falling out under any conditions and at any spatial position of the cartridge, as an intermediate detonator.

Since the shell of the cartridge takes a complex concave shape, which must be filled with an industrial explosive, a specially designed device is used to create a cavity for introducing the detonator capsule and filling the cartridge with explosive (Figs. 5 and 6). This device allows the manufacture of cartridges directly at the place of blasting, which eliminates the dependence of the technological process of blasting on the need to provide a warehouse for storage of industrial manufactured explosive cartridges.

This device contains two assembly units: a glass-like element 8 and a hollow tubular element 9 with a funnel-shaped extension 10 (in fact, a funnel with an elongated tubular nose of constant diameter).

The glass-like element (Fig. 5) is a pipe 11 with a flat bottom 12 and with a wall height of not more than the length of the cartridge. A rod-shaped element or rod 13 is fixed in the bottom of this element, directed towards the open end of this glass-like element and made longer than the height of the glass-like element. The second assembly unit, a hollow tubular element 9 with a funnel-shaped extension 10, is used to put on it a tubular shell of a cartridge muffled from one end 4 (one end of the sleeve) with a muffled end placed on the other end of this hollow tubular element. This element of the device is used to obtain a recess of a given shape in cross section and a length equal to the length of the cartridge. It is also used to fill the shell with an industrial explosive without disturbing the geometry of the recess. The first part of the device is used to ensure the length of the shell in the cartridge and its external shape when filling this explosive. In the assembled state, the hollow tubular element 9 is placed by the tubular part in a cup-shaped element 8 with the latter being positioned inside for the tubular part to extend the tubular shell along the outer surface of the hollow tubular element toward the funnel-shaped expansion and backfill the shell with an industrial explosive. Both parts are preferably made of metal in order to obtain filled explosive shells with the same overall dimensions. Execution is possible, for example, from polymeric materials, but when choosing such a material, it is necessary to take into account the range of external temperatures at which the manufacture of cartridges is possible and to exclude the possibility of the appearance of charges of static electricity.

A method of manufacturing an explosive cartridge with a sealed detonator capsule input device is based on the application of the device described above and consists of the following steps:

- use a polyamide film in the form of an industrially finished sleeve, cut a piece of sleeve of a given length and seal one of the ends 4 (Fig. 4) to obtain a workpiece, which is a flexible tubular shell for the cartridge. Polyamide film - a transparent film or painted by adding dyes to the desired color, obtained from melts or solutions of polyamides by extrusion or irrigation. It is wear-resistant, well resists fracture, is stable in alkalis, solvents, oils, has excellent physical, chemical and electrical characteristics, resistance to radiation, solvents, temperature extremes (temperature range of application: from -270 to + 260 ° С);

- this preform is put on a hollow tubular element 9 with a funnel-shaped extension 10 with the location of the sealed end 4 of the tubular shell from the side opposite to the location of the funnel-shaped extension, as shown in FIG. 7;

- then the tubular part of this tubular element 9 is introduced into the cavity of the glass-shaped element 8 (Fig. 8) with the placement of the rod 13 of the latter in the cavity of this tubular part and the open end of the flexible tubular shell is pulled along the outer surface of the hollow tubular element towards the funnel-shaped extension 10 to the location a sealed end 4 of the tubular shell at the end of the rod of the glass-like element (Fig. 9). During this operation, the part of the shell located around the rod 13 forms a recess for the detonator capsule, the shape of which is determined by the shape of the rod. The part of the shell that extends along the wall of the glass-like element is the outer part of the shell of the cartridge (Fig. 9);

- then, through the funnel-shaped extension 10, the industrial explosive is poured (or poured) into the cavity between the walls of the flexible tubular shell with a gradual extension of the tubular element 9 with the funnel-shaped expansion from the cavity of this shell as it is filled with an industrial explosive until this element is completely withdrawn from the glass-like element. As the shell fills, its volumetric swelling takes place, the shell begins to rely on the wall of the glass-like element 8, the bottom of the latter and on the rod 13. This shape is maintained until the explosive is completely filled into the shell;

- after filling in a dosage portion of an industrial explosive, the open end 5 of the flexible tubular shell is connected (clipped, bandaged) with its previously sealed end 4 and a connected end 14 of the shell is obtained;

- at the final stage, a shell filled with an industrial explosive is removed and a detonator capsule 1 is inserted into its internal channel (recess) (Figs. 1 and 2).

The used sleeve polymer film can be made not only of polyamide (this is the preferred embodiment), but also of other types of polymers that can be selected from a number of cartridges corresponding to the temperature range of use, the strength of the film itself and its inertness to the explosive components used. Regardless of the type or type of flexible film used, it is important that the shell filled with an industrial explosive does not lose its bulk shape due to the presence of an internal channel of a rather large length. Any flexible film does not hold bulk. Volumetric form - is the result of the application of distributed pressure or load to the walls of the film shell. In the framework of the present invention, such a distributed pressure exerts an industrial explosive loaded into the cavity of the shell. While the shell is in the device, the position of its walls, both external and internal, is the result of the equilibrium state of the explosive pressure and the reference pressure from the metal elements of the device. But it is worth taking out the shell from the device, filled with, for example, a gel industrial explosive, then the external pressure on the walls of the shell disappears, and the pressure from this gel explosive begins to deform the walls of the inner channel — the recesses. This is directly related to the viscosity of industrial explosives. In any case, due to the fact that the end of the shell forming the recess is connected with the muffled end of the outer part of the shell, this recess does not change in length, only the passage section changes. But this is not an obstacle to pushing the detonator capsule into this flattened channel.

However, it is desirable that this channel does not change the flow area under pressure from an industrial explosive. For this, it is necessary that the viscosity of industrial explosives be sufficiently high (increased internal friction). In this case, after filling the shell with such an explosive, the cartridge will retain the shape given to it by the device for a long time. It is known that high viscosity have such compositions that relate to gel-paste. Such explosives can be poured into the shell or pressed into the shell. You can also use various kinds of retaining the shape of the Central channel of the sleeve.

At present, explosive compounds of the dynamon type are known, which are a finely divided mixture of ammonium nitrate and fuel (oil product, sawdust, peat, etc.). These compounds are sensitive to primary means of initiation, but have a low initiating ability - insufficient for their use as an intermediate detonator of industrial explosives of class I.5.D.

Explosives are known containing granular ammonium nitrate, an oil product and aluminum powder. These compounds are powerful enough, but not capsule sensitive (belong to class 1.5.D).

Combining the advantages of the explosive compositions described above, an explosive composition is proposed consisting of finely ground components: 90-95% ammonium nitrate, 1.5-2.0% liquid fuel (for example: diesel fuel, or mineral oil, or polymethylsiloxane liquid, or polyethylsiloxane liquid) and 5-10% of aluminum powder (aluminum powder, preferably, grades "PAP-1" or "PAP-2").

It was experimentally established that the specified explosive composition is sensitive to primary means of initiation, and its charge, placed in a polyethylene shell with a diameter of 40 mm and a length of 200 mm and initiated from a detonator capsule, causes stable detonation of the AN-FO charge (mechanical mixture of 94% granular ammonium nitrate and 6% diesel fuel) placed in a cardboard shell with a diameter of 240 mm. To compare the initiating ability of the proposed composition, comparative tests were carried out: initiating identical charges of ANFO with the PT-P300 pentolite block and the charge described above. Moreover, it was experimentally established that the measured detonation velocities developed by the indicated ANFO composition are identical both when using the pentolite block and the charge of the proposed composition.

It was also experimentally established that the proposed explosive composition, placed in plastic shells with a diameter of 28 mm and 50 mm, initiated by a detonator capsule, develops a detonation speed of 4800 and 5100 m / s, respectively, the detonation is transmitted between the ends of these charges is transmitted at a distance of 15 and 30 mm respectively (table 1).

At the same time, this explosive composition created for the cartridge according to the present invention relates to highly viscous compositions with increased internal friction. This allows, on the one hand, to fill the shell of the cartridge when it is in the device, and on the other hand, the shell filled with this explosive after it has been removed from the device does not lose its volume shape for a long time, in particular, the cross section of the recess does not change . This makes it possible to produce shells with explosives in place and leave them for short-term storage without introducing detonator caps into recesses. The latter are inserted into the cartridge immediately before its use as an intermediate detonator in the main charge (immediately before laying the main charge in the well).

A feature of the developed explosive composition for cartridges is that its manufacturing technology makes it possible to produce this explosive composition directly at the place of blasting. The following describes a simple algorithm for the manufacture of this explosive composition. The components are mixed in the following sequence:

- paste is prepared: the calculated amount of aluminum powder (grade PAP-1) and polymethylsiloxane liquid (grade PMS-5) are mixed in a ratio of 75% (powder) and 25% (PMS-5);

- granular ammonium nitrate (according to GOST 2-2013) in a cam (hammer) mill (or any other type) is grinded to a particle size of less than 100 microns, the cam mill at the outlet is equipped with a sieve that holds a large fraction sending it for completion;

- saltpeter powder and paste are loaded into a gravity-type mixer (without a mixing body - to prevent the mixture from getting into the bearing units and to prevent pinching of the product and its possible explosion) - such as a “drunk barrel” or “concrete mixer” (called the “blending drum” by the manufacturer) and they are mixed to homogeneity (the mixing time is established empirically based on the design features of the particular mixer used).

At the same time, nothing limits the use of other explosive formulations in the claimed cartridge, since the problem with changing the cross section of the recess in the filled explosive shell is closely related to the specific type of polymer film used. If the film belongs to the category of polyethylene, then this phenomenon can be quite pronounced. And if a polyamide film is used (which, having flexibility, is inextensible and at the same time has some rigidity), then the process of deformation of the recess can take quite a long time and depends on the storage conditions of the filled shells.

The present invention is industrially applicable and can be used for the safe carrying out of blasting operations, both in opencast mining and in underground workings and mines, which are dangerous due to the explosion of dust and gases.

Claims (3)

1. An explosive cartridge with a sealed detonator capsule input device, which is a tubular shell of flexible polymer material with sealed ends, inside which an industrial explosive is placed, as well as a detonator capsule, while an elongated tube is formed from one sealed end in the body of the tubular shell along the oblong-shaped shell, a recess for accommodating the detonator capsule formed by pressing the end part of the tubular shell inside this shell, characterized in that the oblong-shaped recess is made along the entire length of the tubular shell to place the detonator capsule at a distance from the open end of this recess, while the end face of the depressed end part of the tubular shell, forming a recess for accommodating the detonator capsule, is connected to a sealed end of the shell located on the side of this blind end of the pressed tubular shell. 2. A device for filling a cartridge with explosive and forming a cavity for introducing a detonator capsule containing a glass-like element with a wall height not exceeding the length of the cartridge, a rod-shaped element fixed to the open end of the glass-shaped element directed toward the open end of this glass-shaped element and made longer than the height of the glass-like element, characterized in that it is equipped with a hollow tubular element with a funnel-shaped extension at one end, used to put on a blanked from one end of the tubular shell of the cartridge with the placement of the blanked end from the other end of this hollow tubular element, while this hollow tubular element is placed tubular part in a glass-like element with the location of the rod-shaped element of the latter inside for the tubular part for pulling the tubular shell along the outer surface of the hollow tubular element towards the funnel-shaped expansion and filling the shell with an industrial explosive substance. 3. A method of manufacturing an explosive cartridge with a sealed detonator-capsule input device, which consists in sealing one of the ends of a flexible tubular shell of polymer material and putting it on a hollow tubular element with a funnel-shaped extension with the sealing end of the tubular shell on the opposite side the location of the funnel-shaped expansion, then the tubular part, this tubular element is introduced into the cavity of the cup-shaped element with the placement of the last rod-shaped element in the cavity of this tubular part and the open end of the flexible tubular shell is pulled along the outer surface of the hollow tubular element towards the funnel-shaped expansion until the sealed end of the tubular shell the end of the rod-shaped element of the glass-like element, and then, through the funnel-shaped expansion, the industrial explosive is poured or poured into the cavity between the walls of the flexible tubular shell with the gradual pulling of the tubular element with a funnel-shaped expansion from the cavity of this shell as it is filled with an industrial explosive until the element is completely withdrawn from the glass-like element, after which the open end of the flexible tubular shell is connected to its sealed end, the shell filled with the industrial explosive is removed and inserted into its internal channel is a detonator capsule.

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