RU29997U1 - Detonator checker - Google Patents

Abstract

1. A detonating bomb containing an explosive charge containing TNT, in which two longitudinal channels are made, the inlet openings of which are connected by a recess, of which the first channel is made through and the second channel is a recess parallel to the first channel, placed in a cylindrical body covering the charge on the side surface and on the end side of the recess and having an opening in the end wall, corresponding in size and location to the recess, characterized in that the first channel is made inside the sides oh wall of the housing, and the second channel is made in the mass of charge. 2. A checker-detonator according to claim 1, characterized in that the second channel is made in the peripheral part of the charge so that at least one longitudinal generatrix of the second channel lies on the inner side surface of the housing. A checker-detonator according to claim 1 or 2, characterized in that a longitudinal slot is made in the outer wall of the housing, communicating the first channel along its entire length with the environment and adapted to introduce a waveguide into the first channel. A checker-detonator according to any one of claims 1 to 3, characterized in that the housing is additionally equipped with a charge fixing device in the housing. A checker-detonator according to any one of claims 1 to 4, characterized in that the housing is additionally equipped with a device for fixing the checkers in the hole. 6. A checker-detonator according to claim 4, characterized in that the charge fixing device in the housing contains at least one internal locking element made in the housing from the side of the open end of the charge and allowing reversible changes in the passage section of the internal cavity of the housing. The detonator checker according to claim 6, characterized

Description

Detonator checker

The utility model relates to the field of industrial explosive devices intended primarily for initiating drill-hole charges of industrial explosives.

At present, explosive-sensitive explosives (hereinafter - EXPLOSIVES) are used in boreholes, for example, varieties of ammonite, for example, rock ammonite in accordance with GOST 21985-76, grade 6ZhV ammonite in accordance with GOST 21984-76, which are initiated by the explosion of the capsule placed in them detonator. When less sensitive explosives are used in borehole charges, intermediate detonators containing ammonite are used to initiate them, for example, trained ammonium grade 6ЖВ according to TU 84-08628424-99. Given the limited financial capabilities of mining enterprises, with the mandatory safety requirement for drilling and blasting operations, inexpensive low-sensitivity explosives are used, for the initiation of which the ammonite capacity is insufficient.

Among those used to initiate bore-hole charges of detonators, for example, T-400G (OST 84-411-80), GTP-500 (TU 7611903-525-91), TGF850E (TU 84-08628424-692-97), the best in power, water resistance and versatility in relation to the means of initiation used with them is the PDP-300 detonator-bomb (TU 7276-002-07510000-99, RF certificate for utility model No. 13091, priority 10.26.1999) containing a molten charge of mixed explosive pentolite in a polymer shell . longitudinal channels, the inlets of which are connected by a recess, from

of which the first channel is made through, and the second channel is a recess parallel to the first channel and offset relative to it, and the housing covers the charge along the side surface and the end surface from the recess and has a hole in the end wall in size and location corresponding to the recess (certificate of the Russian Federation for Utility Model No. 13091), while for fixing the charge in the housing, the side surface of the housing has deviations from a cylindrical shape, for example, protrusions or depressions.

Such detonator drafts are successfully used in various mining and geological conditions, however, due to their large size and mass, they cannot be used as intermediate detonators for initiating drill holes. With small dimensions of the checker, the execution of channels with their location inside the charge mass and the fixation of the charge in the case with the help of structural elements protruding into the case leads to a significant decrease in the charge mass, that is, to a decrease in the efficiency of the detonator checker.

The purpose of creating a real utility model is to create a checkers with high initiating ability and small dimensions - a diameter of not more than the diameter of the drill - 40 mm and a weight of not more than 100-200 g.

When developing the technical solution of the proposed utility model, the task was to create a detonator checker, in which, for small overall dimensions, the main charge mass would be kept between the through channel for the waveguide, for example, a wire, a detonating cord, and a recess for accommodating the initiating means, which would ensure high charge sensitivity, as well as the most efficient use of body volume to accommodate the mass of explosives. In addition, the task was set to constructively ensure the fixation of the detonator-checker in the working position in the hole using

2 devices allowing to repeatedly dismantle a piece from a hole without

violation of its integrity and technical characteristics.

The problem was solved by creating a useful model of a checker detonator containing an explosive charge containing trotyl placed in a cylindrical body in which two longitudinal channels are made, the inlet openings of which are interconnected by a recess, of which the first channel is made through and the second channel is a recess, parallel to the first channel, and the housing covers the charge along the side surface and at the end from the side of the recess and has a hole in the end wall, corresponding in size and location to emke, characterized in that the first duct is formed within the side wall of the housing, and a second channel formed in the charge weight.

In addition, the checker-detonator, according to the technical solution of the utility model, can be made in such a way that at least one longitudinal generatrix of the second channel lies on the inner side surface of the housing.

In addition, the checker-detonator, according to the technical solution of the utility model, may have a longitudinal slot in the outer wall of the housing communicating the first channel along its entire length with the environment and adapted for introducing the waveguide into the first channel.

In addition, according to the technical solution of the utility model, in the checker, the housing is additionally equipped with a charge fixing device in the housing.

Moreover, according to the technical solution of the utility model, the charge fixing device in the housing may contain at least one internal locking element made in the housing from the side of the open end of the housing and providing the possibility of reversible change in the passage section

3 It is advisable that, according to the technical solution of the utility model,

the internal fixing elements of the charge fixing device in the housing were elastically deformable protrusions on the inner surface of the housing.

In addition, according to the technical solution of the utility model, in the checker, the housing is additionally equipped with a device for fixing the checkers in the hole.

At the same time, it is advisable that, according to the technical solution of the utility model, the device for fixing the checkers in the hole contains at least three external fixing elements placed uniformly around the circumference on the outer surface of the casing and ensuring the centering of the checkers in the working position in the hole.

In this case, it is desirable that the locking elements were made with the possibility of reversibly changing the diameter of the outer dimension of the checker.

In this case, it is advisable that, according to the technical solution of the utility model, the external fixing elements are elastically deformable protrusions on the outer surface of the housing.

In addition, according to the technical solution of the utility model, fixing the checkers in the hole and fixing the charge in the checker case can be performed using at least three fixing elements uniformly spaced around the circumference in the form of elastically deformable mustaches on the end surface of the side wall of the case, made curved in length so that in the part located at the open end of the charge, the mustache protrudes into the body to allow reversible changes in the bore

4 body parts to allow reversible diameter changes

the outer dimension of the detonator checker when placed in a hole.

Moreover, according to the technical solution of the utility model, the housing can be made of a polymer material.

In this case, according to the technical solution of the utility model, the housing can be made of polyethylene.

Moreover, according to the technical solution of the utility model, the charge can be made of explosives containing TNT and RDX in the following ratio of components, wt.%:

TNT - 50

RDX - the rest

In addition, according to the technical solution of the utility model, the charge can be made of explosives containing TNT and pentaerythritol tetranitrate (TEN) in the following ratio of components, wt.%:

TNT - 50

TEN- rest

In addition, according to the technical solution of the utility model, the charge can be made of TNT.

The technical solution of the utility model is explained in the following examples of the implementation of the detonator drafts and the accompanying drawings, on which:

FIG. 1 illustrates the implementation of a detonator-checker, in which the first channel is located inside the side wall of the housing, and the second channel is located on the periphery of the charge and its longitudinal generatrix lies on the inner side surface of the housing;

5

FIG. 3 illustrates the implementation of a detonator-checker, in which the first channel is placed inside the side wall of the housing, and the second channel is placed inside the charge mass;

Fig. 4 is a view of the checker of Fig. 3 from the side of the recess.

In FIG. 1.2 shows a detonator bomb having a cylindrical body 1, made, for example, according to the technical solution of a utility model, made of polyethylene, in which, for example, by pouring, charge 2 of an explosive, for example a mixed explosive containing trotyl, is placed, for example, TNT with RDX or TNT with TEN, or consisting of TNT.

Inside the side wall 3 of the housing 1 is made the first through channel 4, for example, cylindrical, to accommodate a waveguide, for example, a wire, a detonating cord having an inlet 5.

In charge 2, the second channel 6 is made in the form of a recess, for example, a cylindrical one, for accommodating a detonator capsule having an inlet 7. Inlet 5 of the first channel 4 and inlet 7 of the second channel 6 are interconnected by a recess 8. The housing 1 has an end wall 9 with a hole 10 corresponding to the recess 8.

At the detonator checker shown in FIG. 1, 2, the longitudinal generatrix 11 of the second channel 6 lies on the inner surface of the housing 1. According to the technical solution of the utility model, the channel 6 can be made so that its two longitudinal generators can lie on the inner surface of the housing 1, that is, the channel 6 can have the shape of the truncated cylinder, due to the need to place the maximum possible mass of charge in the housing when using small detonator capsules. evenly spaced around, for example, at least three

external fixing element 13, made, for example, according to the technical solution of the utility model, in the form of protrusions on the outer surface 12 of the side wall 3, elastically deformable when the detonator checker is placed in the cylindrical bore of the hole, providing centering of the detonator checker in the borehole and prevents spontaneous loss Checkers - detonator from a hole. Obviously, the number and location of the locking elements, as well as their design, as well as the design of the device, may be different.

In the detonator block (Fig. 1,2), a charge fixing device 2 is made in the housing 1, which is an elastically deformable protrusion on the inner surface 14 of the side 3 of the wall of the housing 1 near the open end 15 of the charge 2.

In the detonator block shown in Fig.3,4, the second channel 6 is made in the mass of charge 2, and the first channel 4 is connected to the environment by a slot 16, adapted for introducing through it into the first channel 4 of the waveguide, for example, a detonating cord.

In the checker-detonator (Fig. 3, 4), an embodiment of the joint device for fixing the charge in the case and the device for fixing the checker in the hole using, for example, three elastically deformable mustache bent 17 along the length 17, one part 18 protruding inside the body 1 and providing reversible changing the area of the bore of the inner cavity of the housing 1 at the open end 15 of the charge 2 for fixing the charge 2 in the housing 1, and the other part 19 protruding outward for the diameter of the housing and providing a reversible change in the diameter of the dimension of the checkers.

7 detonator checkers when installed in a hole, thereby ensuring centering

checkers in the hole and maintaining the mustache in a tense state, preventing the spontaneous loss of the checker from the hole.

The structural design of the detonator-checker according to the technical solution of the utility model ensures charge integrity, eliminates the mechanical damage of the checker, reduces the sensitivity of the checker to external mechanical and thermal influences, as well as to the initiation of a shock wave or friction, which ensures increased safety of working with it in operating conditions. This design solution allows for small overall dimensions - up to 40 mm and a small charge mass - 100-200 g to vary the effectiveness of the checker by using charges of different sensitivity and power.

Above have been described examples of the execution of the detonator drafts according to the technical solution of the utility model. Those skilled in the field of explosive devices, it should be obvious that in the above structures can be made changes and improvements that do not go beyond the scope of the utility model and the claims of the utility model, for example, changes in the design of devices for fixing the charge and fixing the checkers in the hole.

Detonator checkers according to the technical solution of the utility model can be manufactured using widely known technologies, various explosives, effective and safe in operation.

8 к о Formula of utility model 1. A detonator-cup containing an explosive charge containing TNT, in which two longitudinal channels are made, the inlet openings of which are connected by a recess, of which the first channel is made through and the second channel is a recess parallel to the first a channel placed in a cylindrical body, covering the charge along the side surface and at the end from the side of the recess and having a hole in the end wall, corresponding in size and location to the recess, characterized in that the first the channel is made inside the side wall of the housing, and the second channel is made in the mass of charge. 2. The detonator cup according to claim 1, characterized in that the second channel is made in the peripheral part of the charge in such a way that at least one longitudinal generatrix of the second channel lies on the inner side surface of the housing. 3. The detonator-cup according to claim 1 or 2, characterized in that a longitudinal slot is made in the outer wall of the pus, communicating the first channel along the entire length with the narrowing medium and adapted for introducing the waveguide into the first channel. 4. Checker-detonator according to any one of claims 1 to 3, characterized in that the housing is additionally equipped with a charge fixing device in the housing. 5. Checker-detonator according to any one of claims 1 to 4, characterized in that the housing is additionally equipped with a device for fixing the checkers in the hole. 6. The detonator cup according to claim 4, characterized in that the charge fixing device in the housing contains at least one internal locking element made in the housing from the side of the open end of the charge and allowing reversible change in the passage section of the internal cavity of the housing.

7. Checker-detonator according to claim 6, characterized in that the internal fixing

the elements of the charge fixing device in the housing are made in the form of elastically deformable protrusions on the inner surface of the housing.

8. Checker-detonator according to any one of paragraphs.5-7, characterized in that the device for fixing the checkers in the hole contains at least three external locking elements placed uniformly around the circumference on the outer surface of the housing and providing centering of the checkers in the working position in the hole.

9. Checker-detonator according to claim 8, characterized in that the external locking elements are configured to reversibly change the diameter of the outer dimension of the checker.

10. The detonator cup according to claim 9, characterized in that the external locking elements are made in the form of elastically deformable protrusions on the outer surface of the housing.

11. The detonator cup according to claim 4 or 5, characterized in that the housing comprises at least three fixing elements uniformly spaced around the circumference in the form of elastically deformable whiskers on the end surface of the side wall of the housing, made curved in length so that in the part located at the open end of the charge, the mustache protrudes inside the housing to allow reversible changes in the bore of the internal cavity of the housing after placing the charge in the housing and / or after placing the detonator-checker in the hole, and in Asti, remote from the open end of the charge, whiskers protrude beyond the dimensions of the cylindrical body portion to allow a reversible change in the outer diameter dimension checkers detonator.

13. Checker-detonator according to any one of paragraphs. 1-12, characterized in that the housing is made of polyethylene.

14. Checker-detonator according to any one of paragraphs. 1-13, characterized in that the charge is made of explosives containing TNT and RDX in the following ratio of components, wt.%:

TNT - 50 RDX - the rest

15. Checker-detonator according to any one of paragraphs. 1-13, characterized in that the charge is made of explosives containing trotyl and pentaerythritol tetranitrate (TEN) in the following ratio of components, wt.%:

TNT - 50

TEN- rest

16. Checker-detonator according to any one of paragraphs. 1-13, characterized in that the charge is made of TNT.

/ J

Fia /

Claims (16)

1. A detonating bomb containing an explosive charge containing TNT, in which two longitudinal channels are made, the inlet openings of which are connected by a recess, of which the first channel is made through and the second channel is a recess parallel to the first channel, placed in a cylindrical body covering the charge on the side surface and on the end side of the recess and having an opening in the end wall, corresponding in size and location to the recess, characterized in that the first channel is made inside the sides oh wall of the housing, and the second channel is made in the mass of charge. 2. Checker-detonator according to claim 1, characterized in that the second channel is made in the peripheral part of the charge so that at least one longitudinal generatrix of the second channel lies on the inner side surface of the housing. 3. Checker-detonator according to claim 1 or 2, characterized in that a longitudinal slot is made in the outer wall of the housing, communicating the first channel along its entire length with the environment and adapted for introducing the waveguide into the first channel. 4. Checker-detonator according to any one of claims 1 to 3, characterized in that the housing is additionally equipped with a charge fixing device in the housing. 5. Checker-detonator according to any one of claims 1 to 4, characterized in that the housing is additionally equipped with a device for fixing the checkers in the hole. 6. The detonator-checker according to claim 4, characterized in that the charge fixing device in the housing contains at least one internal fixing element made in the housing from the side of the open end of the charge and allowing reversible changes in the passage section of the internal cavity of the housing. 7. Checker-detonator according to claim 6, characterized in that the internal locking elements of the charge fixing device in the housing are made in the form of elastically deformable protrusions on the inner surface of the housing. 8. The checker-detonator according to any one of claims 5 to 7, characterized in that the device for fixing the checkers in the hole contains at least three external locking elements arranged uniformly around the circumference on the outer surface of the casing and providing centering of the checkers in the working position in the hole. 9. Checker-detonator according to claim 8, characterized in that the outer locking elements are configured to reversibly change the diameter of the outer dimension of the checker. 10. Checker-detonator according to claim 9, characterized in that the external locking elements are made in the form of elastically deformable protrusions on the outer surface of the housing. 11. Checker-detonator according to claim 4 or 5, characterized in that the housing contains at least three locking elements uniformly spaced around the circumference in the form of elastically deformable whiskers on the end surface of the side wall of the housing, made curved in length so that the part located at the open end of the charge, the mustache protrudes into the housing to allow reversible changes in the bore of the internal cavity of the housing after placing the charge in the housing and / or after placing the detonator-checker in the hole, and in parts remote from the open end of the charge, the mustache protrudes beyond the dimensions of the cylindrical part of the housing to enable reversible changes in the diameter of the outer dimension of the detonator-checker. 12. Checker-detonator according to any one of claims 1 to 11, characterized in that the housing is made of a polymeric material. 13. Checker-detonator according to any one of claims 1 to 12, characterized in that the housing is made of polyethylene. 14. Checker-detonator according to any one of claims 1 to 13, characterized in that the charge is made of explosives containing TNT and RDX in the following ratio, wt.%: TNT 50 RDX Rest 15. Checker-detonator according to any one of claims 1 to 13, characterized in that the charge is made of explosives containing TNT and pentaerythritol tetranitrate (TEN) in the following ratio, wt.%: TNT 50 TEN The rest 16. Checker-detonator according to any one of claims 1 to 13, characterized in that the charge is made of TNT.