RU2629297C1 - Intermediate detonator - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: intermediate detonator comprises a cylindrical body formed in one with a primer cap well having at least one longitudinal protrusion on the inner surface for fixing the primer cap on one end side, and a latch that is detachably disposed on the opposite to the primer cap well open side. The charge of the explosive is made of a slurry explosive and pressed to a density of 20-35% above the srurried. The cylindrical body is formed with one or more grooves on the end side where the primer cap well is located. The latch is made with one or more clamps under for the shock-wave tube. The latch is made with a liner having a diameter of 0.6-0.7 of the latch outer diameter and a length of 1-1.25 of the latch outer diameter, disposed along the latch axis and having in section an annular or star-shaped shape of three or more plates. Cylindrical body with primer cap well is made composite.

EFFECT: invention makes it possible to increase the reliability and efficiency of initiation, to increase the convenience and safety of handling it.

5 cl, 5 dwg

Description

The invention relates to means for initiating charges of industrial explosives (BB), and in particular to intermediate detonators designed to initiate boreholes, boreholes and other charges of industrial explosives using non-electric means of initiation, electric detonators of various types in dry and flooded boreholes and wells in open and underground mining operations.

Known design of the checker-detonator (patent RU 2213929 C1, 02/20/2002, F42B 1/04), intended for use as an intermediate detonator for initiating industrial explosives. The detonator bomb includes a housing in which a charge of a free-flowing explosive, for example, phlegmatized RDX, is placed in a sealed polymer housing in the form of a cylindrical container with a wall thickness of 0.2-0.8 mm and a cap with thread for connection with a cylindrical container. A groove is made on the surface of the cylindrical container, located diametrically in the bottom part along the generatrices of the cylindrical part and ending with ledges in the upper part of the cylindrical container, for placement of initiation means in it. The disadvantage of this design is the difficulty in manufacturing and the difficulty in pressing loose explosives in a thin-walled polymer case.

Known intermediate detonator (according to the patent US 3451341 A, 06/24/1969, F42B 3/10), consisting of an open from one end of the housing placed on this end of the lid, which serves as a slot for the detonator capsule, and sealed with a lid of bulk explosive. For the manufacture of the housing, it is proposed to use metal, such as copper, aluminum, etc. The cover is made of a plastic material - polyethylene, polypropylene, etc. On the inner surface of the nest, two or three longitudinal protrusions are performed to fix the detonator capsule. The disadvantage of this design is the difficulty in manufacturing and the difficulty in pressing loose explosives due to the presence of the capsule socket in the lid.

The closest analogue of the claimed invention is the design of the intermediate detonator (patent RU 2333452 C2, 09.28.2006, F42B 3/00), which is selected as a prototype and contains a cylindrical body made with a shank, a cover made with a socket for the detonator capsule and located with the possibility of fixing on the opposite to the shank end of the body, and an explosive charge placed in the body. The inner surface of the housing is associated with the inner surface of the shank on a conical surface. On the inner surface of the nest, two longitudinal protrusions are made for fixing the detonator capsule with an offset relative to the central axis of the nest and ensuring contact of the detonator capsule with the surface of the nest. The explosive charge is made of bulk explosive and placed in the housing between the cover and the diaphragm with a density of 1-25% higher than bulk. The disadvantage of this design is the difficulty in pressing the bulk explosive, since when closing the lid with the capsule socket of the case, with the bulk explosive sprinkled into it, only the redistribution of the explosive occurs, and excess material is squeezed out of the housing.

The technical result of the invention is to increase the reliability and efficiency of initiating industrial explosives, increasing safety when handling an intermediate detonator by changing its design and manufacturing technology.

The technical result is achieved by the fact that in the intermediate detonator containing a cylindrical body, made in one with a socket for the detonator capsule, having on the inner surface of at least one longitudinal protrusion for fixing the detonator capsule, on one end side and a lid that can be fixed , on the opposite side from the nest under the detonator capsule, an explosive charge is placed, and the explosive charge is made of loose explosive and pressed to a raft 20–35% higher than bulk.

The cover of the intermediate detonator can be made with one or more clamps for the shock wave tube, which (which) serves as a convenience when charging the hole (well) with an intermediate detonator and to protect the shock wave tube from friction against the walls of the hole.

The lid of the intermediate detonator can be made with a shank with a diameter equal to 0.6-0.7 of the outer diameter of the lid, and a length of 1-1.25 of the outer diameter of the lid located along the axis of the lid, and having in cross section a ring shape or a star shape of three or more plates used to install and hold the intermediate detonator in the charging hose during mechanized loading of industrial explosives.

The cylindrical body and the cover of the intermediate detonator can be made of polyethylene or other similar material.

A cylindrical housing with a socket for the detonator capsule can be made integral to simplify its production, while the housing can be made of paper, cardboard, polyethylene or other similar material.

As a powdered explosive, pentolite, hexogen, and others similar to them in properties and sensitivity of explosives can be used. The degree of compression of the explosive relative to the bulk density of the bulk material should be within 20-35% higher than the bulk, resulting in an increase in the speed of the detonation wave and the power of the initiating pulse. Pressing more than 35% with respect to the bulk density of the bulk material is difficult without a special tool, for example a metal clip, due to the insufficient strength of the housing with a socket for the detonator capsule, which complicates and increases the cost of manufacturing an intermediate detonator.

The fixing of the cover on the cylindrical body can be achieved by any of the known methods, for example, by means of the fixing protrusions on the cover and the body or by means of crushing ribs. The longitudinal protrusion (s) on the inner surface of the nest under the detonator capsule are designed to fix the detonator capsule and to ensure a tight fit of the detonator capsule to the surface of the nest, which ensures the reliability of the transfer of the explosive pulse from the detonator capsule to the explosive charge.

In the manufacture of an intermediate detonator, its geometrical dimensions are selected taking into account the conditions of use, while taking into account the sizes of holes, wells, detonator capsule and charging equipment, the necessary mass and density of explosives in the intermediate detonator, necessary to ensure reliable initiation of a stationary detonation wave in the charge of an industrial explosive.

The invention is illustrated in FIG. 1, 2, 3, 4, 5.

In FIG. 1 shows a longitudinal section of an intermediate detonator and a view from the side of the capsule socket, where: 1 - a cylindrical body; 2 - nest under the detonator capsule; 3 - protrusion (protrusions) under the detonator capsule; 4 - explosive charge; 5 - cover.

In FIG. 2 shows a longitudinal section of an intermediate detonator with a groove on the body, a retainer and a shank on the cover, a view from the side of the capsule socket and a view from the side of the cover, where: 1 is a cylindrical body; 2 - nest under the detonator capsule; 3 - protrusion (protrusions) under the detonator capsule; 4 - explosive charge; 5 - cover; 6 - groove; 7 - a clamp; 8 - shank.

In FIG. 3 shows a longitudinal section of an intermediate detonator with a composite body and a socket for the detonator capsule, where: 1 - a cylindrical body; 2 - nest under the detonator capsule; 3 - protrusion (protrusions) under the detonator capsule; 4 - explosive charge; 5 - cover.

The operation of the intermediate detonator is illustrated in FIG. 4, 5.

In Fig. 4 shows a longitudinal section of an intermediate detonator with a groove on the body, a retainer and a shank on the cover, complete with a detonator capsule, before loading into a hole (well), where: 1 - a cylindrical body; 2 - nest under the detonator capsule; 3 - protrusion (protrusions) under the detonator capsule; 4 - explosive charge; 5 - cover; 6 - groove; 7 - a clamp; 8 - shank; 9 - detonator capsule; 10 - shock wave tube; 11 - charging hose for mechanized loading of industrial explosives.

In FIG. 5 shows a longitudinal section of an intermediate detonator with a composite body and a socket for a detonator capsule, complete with a detonator capsule, before loading into a hole (well), where: 1 - a cylindrical body; 2 - nest under the detonator capsule; 3 - protrusion (protrusions) under the detonator capsule; 4 - explosive charge; 5 - cover; 9 - detonator capsule; 10 - shock wave tube; 11 - charging hose for mechanized loading of industrial explosives.

The operation of the intermediate detonator illustrated in FIG. 4: the intermediate detonator is held in the hand by the cylindrical body 1, the detonator capsule 9 complete with the shock wave tube 10 is installed in the socket 2 under the detonator capsule until it is fixed with the protrusion (s) 3, the shock wave tube 10 is installed in the groove 6 at the end of the cylindrical body 1, is located on top of the cylindrical body 1 and is fixed by the latch 7 of the cover 5, then the intermediate detonator with the shank 8 on the cover 5 is inserted into the charging hose 11, and the shock wave tube 10 is located on top of the charging hose 11, after of this, the intermediate detonator is recharged with a charging hose to the stop in the bottom of the hole (well) and mechanized loading of the hole (well) is performed. The shock wave tube receives the initiating pulse from the source and transfers it to the detonator capsule, which initiates the intermediate detonator, and it, in turn, initiates the hole (borehole) charge of the industrial explosive, which completes the operation of the intermediate detonator.

The operation of the intermediate detonator illustrated in FIG. 5: the intermediate detonator is held in the hand by the cylindrical body 1, the detonator capsule 9 complete with the shock wave tube 10 is installed in the socket 2 under the detonator capsule until it is fixed by the protrusion (s) 3; the shock wave tube 10 is located on top of the cylindrical body 1, then the intermediate detonator is inserted on top of the charging hose 11, and the shock wave tube 10 is located on top of the charge hose 11, after which the intermediate detonator is pushed by the charging hose until it stops at the bottom of the hole (well) and mechanized loading a hole (well). The shock wave tube receives the initiating pulse from the source and transfers it to the detonator capsule, which initiates the intermediate detonator, and it, in turn, initiates the hole (borehole) charge of the industrial explosive, which completes the operation of the intermediate detonator.

Examples of manufacturing an intermediate detonator.

At the Iskra NMZ JSC, intermediate detonators with a solid body and a socket for a detonator capsule were manufactured, as well as intermediate detonators with a composite case and a socket for a detonator capsule.

Intermediate detonators with a one-piece body and a socket for the detonator capsule were made in the following geometric dimensions - body diameter 23 mm, body length together with the cover and shank 180 mm, diameter of the shank of the cover 18 mm. Hexogen A-1X-1 GOST RV 1376-001-2006 with a bulk density of 0.82 g / cm ³ , which was pressed by a punch to a density of 0.99 g / cm ³ , which is 21% higher than the bulk density, was used as an explosive.

Intermediate detonators with a composite body and a socket for the detonator capsule were made in the following geometric dimensions - case diameter 18.5 mm, case length 135 mm. A pentolite of grade 90/10 TU 7511903-598-92 with a bulk density of 0.72 g / cm ³ , which was pressed by a punch to a density of 0.94 g / cm ³ , which is 30.6% higher than the bulk density, was used as an explosive.

The tests of the intermediate detonators were carried out at the testing ground of AO NMZ Iskra, the initiation of an intermediate detonator during tests was carried out from the CD of the non-electric initiation system ISKRA-S, AO NMZ Iskra. The explosive effectiveness was estimated by breaking through a steel plate. An intermediate detonator mounted vertically on the bottom of the lid or shank provides for through penetration of a 2 mm thick steel plate, which is sufficient for the effective operation of the intermediate detonator.

The proposed design of the intermediate detonator allows to increase the reliability and safety of the intermediate detonator by ensuring tightness and water tightness, to ensure that the explosives are pressed 20-35% higher than the bulk density, to prevent the formation of additional voids in the explosives during transportation, which increases the susceptibility to the means of initiation, the reliability of the initiation of the intermediate detonator , the effectiveness of its initiating action, and also increases the convenience of handling an intermediate detonator when it aryazhanii into the hole (the wellbore).

Claims (5)

1. An intermediate detonator comprising a cylindrical body, a lid and an explosive charge located in the housing, characterized in that on one end side of the cylindrical body there is a socket for a detonator capsule having at least one longitudinal protrusion on the inner surface for fixing the detonator capsule, and the lid is located with the possibility of fixing on the opposite side opposite the socket under the detonator capsule, the explosive charge being made of granular explosive and pressed to a density of 20-35% higher bulk. 2. An intermediate detonator according to claim 1, characterized in that the cylindrical body on the front side, where the socket for the detonator capsule is located, has one or more grooves. 3. An intermediate detonator according to claim 1, characterized in that the lid is made with one or more detents under the shock wave tube. 4. An intermediate detonator according to claim 1, characterized in that the lid is made with a protrusion of a diameter equal to 0.6-0.7 of the outer diameter of the lid and a length of 1-1.25 of the outer diameter of the lid located along the axis of the lid and having a cross section annular or star-shaped form of three or more plates. 5. An intermediate detonator according to claim 1, characterized in that the cylindrical body with a socket for the detonator capsule is made integral.

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