RU2333452C2 - Intermediate detonator - Google Patents

Abstract

FIELD: explosive works.

SUBSTANCE: invention is related to facilities of initiation of charges of industrial explosives. Intermediate detonator contains cylindrical casing that is arranged with tailpiece, cover that is provided with seat for detonating cap and is installed with the possibility of fixation at the casing end, which is opposite to tailpiece, and explosive charge that is installed in casing. Internal surface of casing is conjugated with internal surface of tailpiece along with conical surface. Casing tailpiece is arranged with open end and equipped with diaphragm that is bent inside casing and that divides tailpiece into two parts. Cover is made with thickened walls in the field of its fixation at the casing and transfer to seat. There are two longitudinal bulges on seat internal surface for fixation of detonating cap with displacement in respect to seat central axis and provision of detonating cap contact with seat surface. Charge of explosive is made of loose explosive material and is installed in casing between cover and diaphragm with density that is more than the apparent density by 1-25%.

EFFECT: increase of receptivity to initiation facilities, reliability of intermediate detonator initiation and efficiency of its initiating action.

7 cl, 2 dwg, 1 ex

Description

The invention relates to means for initiating explosive charges (BB), and in particular to intermediate detonators designed to initiate borehole and other charges of industrial explosives in mining, in wells of any water cut and in explosive cavities of small transverse size - holes.

In industrial conditions, intermediate detonators in the form of checkers and cartridges of various designs and from various types of explosives are mainly used to initiate explosive charges in explosive cavities.

A known design of an intermediate detonator (according to the patent US 3955504 A, 05/11/1976, F42B 3/02), comprising a housing with channels for accommodating a detonator capsule and a detonating cord, made of two identical hemispheres fastened to each other, and an explosive charge placed in the housing substances. 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. Such placement of the detonator capsule allows to increase its efficiency and reliability of initiating the main explosive charge through the walls of the nest. The housing may be made of plastic, and the explosive charge may be made of solid or liquid explosive.

Known design of the checker-detonator (patent RU 2213929 C1, 02/20/2002, F42B 1/04), intended for use as an intermediate detonator for industrial blasting in bore holes. The detonator checker includes a housing in which a charge of a free-flowing explosive, for example, phlegmatized RDX, is placed in a sealed polymer case 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 and along the generatrices of the cylindrical part and ending with ledges in the upper part of the cylindrical container for placement of a detonating cord or a non-electric detonator with a shock wave tube or an electric detonator in it.

A well-known cartridge-action movie (according to the USSR AS SU 1763857 A1, 09/23/1992, F42B 3/10), designed to initiate charges of industrial explosives during the passage of mine workings drilling and blasting. The action cartridge contains a cartridge with an alluvial explosive with a detonator capsule placed therein using a hemispherical sleeve oriented by a cumulative recess inside the cartridge, means for securing the detonator capsule in the cartridge case and latches for attaching the cartridge to the explosive cartridge. In order to increase the reliability of fastening the sleeve on the cartridge by increasing the thickness of the explosive explosive danger zone, the latches are made in the form of triangular spikes and are located at an angle to the longitudinal axis of the cartridge other than 90 °.

Also, an intermediate detonator is known (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, acting as a slot for the detonator capsule and sealed with the explosive lid ( PETN, tetryl, pentolite, hexogen). For the manufacture of the housing, it is proposed to use metal, such as copper, aluminum, etc. The cover is made of flexible or plastic material - polyethylene, polypropylene, polyvinyl chloride, etc. On the inner surface of the nest, two or three longitudinal protrusions are performed to fix the detonator capsule.

The closest analogue of the claimed invention is the design of an intermediate detonator (according to the application WO 96/11374 A1, 04/18/1996, F42C 19/08, F42B 3/24), containing a cylindrical body made with a shank of a smaller diameter, a cover made with a socket under the capsule - a detonator having longitudinal protrusions on the inner surface for fixing the detonator capsule, and located with the possibility of fixing on the opposite end of the housing, and an explosive charge placed in the housing. A shank is provided for fastening additional equipment in the form of a divider recharged into an explosive hole. For the manufacture of the body can be used various materials - paper, cardboard, plastic, etc. An explosive charge can be formed from a plastic composition like PRIMEX or a solid cast composition like ANZOMEX or PETN / wax, or a composition containing an inorganic oxidizing salt and a liquid matrix.

Common disadvantages of all known intermediate detonators is the lack of reliability of the initiation of primary means of initiation associated with the peculiarities of the placement of sockets for initiating means in the design of the intermediate detonator.

An object of the invention is the creation of an intermediate detonator with increased safety and reliability when used, especially in explosive cavities of small diameter - holes, as well as allowing mechanized loading of industrial explosives by pneumatic transport or to supply industrial explosives of the emulsion type through a pipeline.

The technical result of the invention is to increase the reliability and safety of the intermediate detonator by improving its susceptibility to the means of initiation and the effectiveness of its initiating action.

The technical result is achieved in that in the intermediate detonator containing a cylindrical body made with a shank, a cover made with a socket for the detonator capsule having longitudinal protrusions on the inner surface for fixing the detonator capsule and located with the possibility of fixing on the end opposite to the shank case, and the explosive charge placed in the case, the shank is made with a diameter equal to 0.5-0.9 of the diameter of the case, while the inner surface of the case is associated with the inner surface by the surface of the shank along a conical surface having an angle relative to the central axis of the body less than the angle of internal friction of the explosive charge, the body shank is made with an open end and is equipped with a diaphragm concave into the body equal to 20-95% of the thickness of the walls of the body, and dividing the shank into two parts, the cover is made with thickened walls in the area of fixing it on the housing and the transition to the socket, while on the inner surface of the socket there are two longitudinal protrusions for fixing the detonator capsule with offset relative to the central axis of the nest and ensuring contact of the detonator capsule with the surface of the nest, and the explosive charge is made of granular explosive and is placed in the housing between the cover and the diaphragm with a density 1-25% higher than the bulk.

In the open end of the shank, a divider with a stop element in the area of contact with the diaphragm can be placed, and a star-shaped divider made of three or more plates, or a divider made in the form of a plate located along the central axis of the housing, or a spiral divider can be used. In addition, it is possible to perform a shank with perforation in the form of holes or longitudinal slots, and the lid may be provided with elastic elements of the detonator in the hole, made with the possibility of fixing the means of initiation.

As a powdered explosive, mixed explosives based on ammonium nitrate (for example, ammonite), including with the addition of dispersed aluminum, as well as powerful blasting explosive RDX and PETN, phlegmatized by the introduction of paraffins (mixtures A-IX-I, A- IX-II) or TNT at a low, not more than 20%, content of the latter (a mixture of pentolite and TG).

The degree of compaction of explosives with respect to the bulk density of bulk material should be in the range of 1-25%. Compaction of less than 1% can lead to the appearance of voids in the charge during additional compaction as a result of shaking during transportation of the intermediate detonator to the place of use, which significantly reduces its susceptibility to the means of initiation and the reliability of initiation of charges of industrial explosives, and compaction of more than 25% will necessitate the application of significant efforts when introducing cover elements into the explosive massif, which increases the fire hazard and, accordingly, complicates the manufacturing technology.

The fixing of the cover on the housing can be achieved by any of the known methods, for example, by means of a locking groove at the open neck of the housing, by means of a thread or by means of crushing ribs.

The longitudinal protrusions on the inner surface of the socket are designed to fix the detonator capsule, while the angle between them is less than 180 ° (α <80 °). The location of the detonator capsule with an offset relative to the central axis of the nest while ensuring a tight fit of the detonator capsule to the surface of the nest can improve the reliability of the transfer of the explosive pulse from the detonator capsule to the explosive charge. Longitudinal protrusions can be made both rigid and elastic flexible.

The end of the shank free from explosives protects the diaphragm from external influences during storage and transportation of the intermediate detonator, and also reduces the thickness of the diaphragm and, accordingly, increases the intensity of the explosive pulse in the axial direction. The presence of a shank in the design of the intermediate detonator allows it to be placed in the charging hose with a fixed position, while it is possible to place the intermediate detonator with the detonator capsule installed in it until it stops at the bottom of the hole without the risk of distortions and pinching. The shank acts as a concentrator and distributor of explosive streams charged into the hole pneumatically. To increase this effect, perforations in the form of holes or longitudinal slots can be made in the walls of the shank. For the same purpose, a divider with a stop element in the area of contact with the diaphragm, made in the form of a plate located along the central axis of the housing, can be placed in the open end of the shank. A star-shaped divider made of three or more plates, a spiral divider can also be used. The presence of a divider causes a redistribution of the flow of explosives charged into the borehole, additional destruction of the explosive granules, and also ensures the twisting (turbulization) of gaseous products during the explosion. Another function of the divider is to ensure, if necessary, to further maintain the diaphragm in a concave position, which is especially important when, in order to increase and / or concentrate the energy of the explosion in the axial direction, the diaphragm is made especially thin and / or strongly concave in the form of a cumulative funnel. On the outer surface of the lid, located outside the housing, elastic elements can be placed to fix the position of the intermediate detonator in the hole, made with the possibility of fixing the means of initiation. Elastic elements can be made in the form of plates or petals.

In the manufacture of the intermediate detonator, its geometrical dimensions are selected taking into account the conditions of use, while taking into account the dimensions of the borehole, detonator capsule and charging hose, the necessary mass and density of explosives in the explosive charge, necessary to ensure the reliability of detonation transfer from the intermediate detonator to the charge of an industrial explosive in the hole.

- The outer diameter of the shank is selected according to the diameter of the charging hose. However, according to the invention, the diameter of the shank should be 0.5-0.9 of the diameter of the body to ensure the reliability of the initiation of a charge of industrial explosives such an intermediate detonator. The specified lower limit is due to the possibility of destruction of the design of the intermediate detonator during installation and a sharp decrease in the initiating ability. The specified upper limit is due to the need to create a diameter difference between the shank and the housing for mounting the charging equipment while ensuring the safety of manufacturing an intermediate detonator, in particular when pressing the explosive charge.

- The mass and density of the explosive in the finished intermediate detonator, as well as the thickness of the diaphragm, are selected from the condition of the reliability of the initiation of the explosion in the explosive charge in the hole. It was experimentally established that the thickness of the diaphragm should be 20-95% of the wall thickness of the body, which, together with the choice of a certain diameter of the body and, accordingly, of the shank, ensures the reliability of the initiation of industrial explosives by an intermediate detonator.

- The bulk density of the explosive may change with a change in the type of powdered explosive used. However, the explosive charge density, as was noted, should be 1-25% higher than the bulk density of the explosive.

- The conjugation of the inner surfaces of the housing and the shank on a conical surface having an angle relative to the central axis of the housing less than the angle of internal friction of the explosive is due to the uniform distribution of the explosive at the interface, which will increase the degree of compression of the explosive in the shank and the diaphragm and improve the efficiency of the initiating action of the detonator.

The invention is illustrated in FIGS. 1 and 2.

Figure 1 shows a longitudinal section of an intermediate detonator.

Figure 2 shows a cross section of an intermediate detonator.

In figure 1 and 2, the positions indicated:

1 - housing;

2 - shank of the housing;

3 - the inner surface of the housing in the area of its interface with the inner surface of the shank;

4 - explosive charge;

5 - cover;

6 - nest for detonator capsule;

7 - longitudinal protrusions on the inner surface of the socket for fixing the location of the detonator capsule;

8 - aperture.

9 - detonator capsule.

An example of the manufacture of an intermediate detonator.

An intermediate detonator is made of the following geometric dimensions - case diameter 28 mm, shaft diameter 17 mm, body length together with shaft 150, socket wall thickness 1.5 mm. As an explosive charge, pentolite with a TNT content of 10% and a weight of a sample of 30 g are used. The explosive density in the charge is 0.8 g / cm ³ .

The housing is placed in a ferrule-matrix, a cover with a slot for the detonator capsule is put on a mandrel punch, which eliminates undesirable and / or uncontrolled deformations in the housing and cover elements. The diaphragm can be made in the form of a separate element, which is introduced into the shank of the housing by pre-indentation with a force directed along the central axis. The explosive is poured into the casing to the state of bulk density with or without tapping, not higher than the upper cut of the open end of the casing, while the deflection of the diaphragm is directed outside the casing. A housing filled with explosives is inserted into the holder and closed with a lid mounted on the punch, while the socket is inserted into the explosives array, the lid mount fixes it on the housing, and the diaphragm clicks from the position bent out of the case into the position bent inward.

When assembling an intermediate detonator, an additional vibrational action on the explosive charge can be used to increase the degree of compaction and increase the degree of homogeneity of the seal.

Clicking the diaphragm from one position to another makes it possible to increase the degree of explosive compaction in the region of the shank, while this position of the diaphragm makes it possible to increase the initiating pulse in the direction of the central axis of the intermediate detonator.

Initiation of the intermediate detonator during the tests was carried out from the CD of the non-electric initiation system SINV-S of the Iskra Novosibirsk plant. The effectiveness of explosive action and initiating ability was evaluated in comparison with similar indicators for ammonite cartridges 6 LW with a diameter of 32 mm and a mass of 200 g.

The explosive effectiveness was estimated by breaking through a steel plate. An intermediate detonator mounted vertically on the bottom of the shank provides through penetration of a 2 mm thick plate, as well as an ammonite cartridge 6 LH.

The initiating ability of the intermediate detonator was evaluated by the reliability of the explosion in the charges of a granulated explosive like ASDT. ASDT samples were charged into a steel pipe with an inner diameter of 40 mm and a wall thickness of 4 mm by free filling with a shake (charge density 0.87 g / cm ³ ) or pneumatically to a density of 1.1-1.2 g / cm ³ . In all experiments, the ASDT charges were reliably blued and detonated completely.

The proposed design of the intermediate detonator allows you to:

- to increase the reliability and safety of an industrial detonator by ensuring tightness and water tightness,

- to ensure that the explosive seal is higher than the bulk density and to eliminate the formation of additional voids in the explosive during transportation

- to provide increased compaction of explosives in the region of the shank and the diaphragm, which in turn increases the concentration of energy of the explosive pulse in the direction of the open end of the shank and increases the reliability of the initiation of explosives in the hole,

- and also to simplify manufacturing technology by reducing and simplifying technological operations.

Claims (7)

1. An intermediate detonator comprising a cylindrical body made with a shank, a cover made with a socket for the detonator capsule having longitudinal projections on the inner surface for fixing the detonator capsule, and located with the possibility of fixation on the housing end opposite from the shank, and placed in the housing explosive charge, characterized in that the shank is made with a diameter equal to 0.5-0.9 of the diameter of the housing, the inner surface of the housing is paired with the inner surface of the shank a surface having an angle relative to the central axis of the housing less than the angle of internal friction of the explosive charge, while the tail of the shell is made with an open end and provided with a diaphragm concave into the shell of a thickness equal to 20-95% of the thickness of the walls of the shell, and dividing the shank into two parts, the cover is made with thickened walls in the area of fixing it on the housing and transition into the socket, while on the inner surface of the socket there are two longitudinal protrusions for fixing the detonator capsule with an offset relative to tral axis the slots and make contact with the detonator capsule socket surface, the explosive charge is made of a bulk explosive material placed in the housing and between the cover and the diaphragm at a density of 1-25% higher bulk. 2. The intermediate detonator according to claim 1, characterized in that in the open end of the shank there is a divider with a stop element in the area of contact with the diaphragm, made in the form of a plate located along the central axis of the housing. 3. The intermediate detonator according to claim 1, characterized in that in the open end of the shank there is a star-shaped divider with a stop element in the area of contact with the diaphragm, made of three or more plates. 4. The intermediate detonator according to claim 1, characterized in that in the open end of the shank there is a spiral divider with a stop element in the area of contact with the diaphragm. 5. The intermediate detonator according to claim 1, characterized in that the shank is made with perforation in the form of holes or longitudinal slots. 6. The intermediate detonator according to claim 1, characterized in that the lid is provided with elastic elements for fixing the position of the intermediate detonator in the hole, made with the possibility of fixing the initiation means. 7. The intermediate detonator according to claim 6, characterized in that the elastic elements are made in the form of plates or petals.

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