RU215353U1 - Borehole charge - Google Patents

Abstract

The borehole charge belongs to the field of exploration geophysics, namely to drilling and blast seismic exploration, and can be used for blasting in mines that are not dangerous for gas or dust, as well as for geophysical work. A borehole charge in a polymer casing for industrial blasting comprises a casing with a bottom and a cover made with a hole for the possibility of installing the bottom part of the charge casing when the charges are connected into a garland by locking elements made in the form of an annular collar on the outer side of the bottom part of the casing and a counter annular grooves on the inside of the lid opening, respectively. The body contains a composite explosive material, in which a socket is made for a detonator cap, in which the lower part of the explosive material of the charge is made of plastite energy-saturated brisant substances and is pressed directly into the body, and the upper part of the explosive material of the charge, in which, on the side of the cover, a socket is made for detonator cap, made in the form of a pressed piece of energy-saturated blasting substances. EFFECT: ensuring non-failure operation with high energy of charge explosion. 3 ill.

Description

The utility model relates to the field of exploration geophysics, namely to drilling and blast seismic exploration, and can be used for blasting in mines that are not dangerous for gas or dust, as well as for geophysical work.

A borehole charge is known for excitation of seismic vibrations, consisting of an explosive material poured into a polymer shell having internal and external locking devices at the edges, in which transverse relief protrusions-ridges are made on the outer surface of the cylindrical part of the polymer shell, the outer diameter of which does not exceed diameter of the outer (enclosing) locking device. (RF patent for utility model RU 123133 U1, 20.12.2012, Mkl F42B 1/00).

The disadvantages of this technical solution is the structural complexity of the locks, the lack of reliability of the connection with the mutual reversal of the elements connected in a garland, the low detonation velocity due to the low density of the explosive material poured into the polymer shell.

The closest to the proposed technical solution is a borehole charge in a polymer case for industrial blasting, containing a body with a bottom and a cover made with a hole to allow the bottom part of the charge body to be installed when the charges are connected into a garland by locking elements made in the form of an annular shoulder on the outer side of the bottom part of the body and the reciprocal annular groove on the inside of the cover opening, respectively, in the body there is a composite explosive material in which a socket for the detonator cap is made, (Patent US 4000696 A, 04.01.1977, Mki F42B3 / 02; F42B3 / 24).

For use in the field, the closing plug is removed, the liquid second explosive component is poured into the cartridge, and the plug is reinserted to form a watertight sliding seal with the cartridge. When several cartridges are connected to each other to form an explosive chain, the nose end of one cartridge moves the plug of the adjacent forward cartridge inward to compensate for the settling of the explosive composition and to maintain the seal of the closure plug.

The disadvantage of this technical solution is the probability of failure during blasting in mines, as well as during geophysical work.

The technical problem solved by the proposal is to increase the reliability of the charge.

To solve this technical problem, a downhole charge in a polymer case for industrial blasting is proposed, containing a body with a bottom and a cover made with a hole for the possibility of installing the bottom part of the charge body when connecting the charges into a garland by locking elements made in the form of an annular collar on the outer side of the bottom part of the housing and the reciprocal annular groove on the inner side of the opening of the cover, respectively, in the housing there is a composite explosive material in which a socket is made for a detonator cap, in which the lower part of the explosive material of the charge is made of plastite energy-saturated brisant substances and is pressed directly into the housing , and the upper part of the explosive material of the charge, in which a nest for a detonator cap is made on the side of the cover, is made in the form of a pressed checker of energy-saturated brisant substances.

No other technical solutions of a similar purpose with a similar set of essential features were found by the applicant during a search in the scientific and technical literature and patent documentation. The proposed charge borehole in a polymer case for industrial blasting can be made from known materials on known equipment and used in drilling and blasting seismic. Therefore, the applicant believes that the proposal for this application meets the criteria for patentability of the utility model "novelty" and "industrial applicability".

The essence of the proposal is illustrated by a non-exclusive example of the implementation of the proposed borehole charge.

In FIG. 1 shows the cross-section of the borehole charge, in Figs 2 and 3 - elements of the interlock connection. The drawings indicate: body 1 with a bottom and a cover 2, the elements of the locking connection are made in the form of an annular shoulder 3 and a reciprocal annular groove 4, the upper part of the charge 5, in which the socket for the detonator cap is made, is made in the form of a pressed checker of energy-saturated brisant substances (for example, TNT, Tetryl). The lower part 6 is made of plastic energy-saturated brisant substances (for example, PVB5, PVB7) and is pressed directly into the housing 1.

The borehole charge is used as follows:

When connecting the charges into a garland, the bottom of the case 1 of one charge is inserted into the hole in the cover 2 of another charge until the annular shoulder 3 and the reciprocal annular groove 4 are aligned (the annular shoulder 3 and the reciprocal annular groove 4 can be placed as shown in the drawing or swapped). The connection of charges can be provided by their translational or translational-rotational approach. With the mutual rotation of the connected charges after assembly, the separation of the charges does not occur. The execution of the upper part 5 of the charge, in which a socket is made for the detonator cap in the form of a pressed checker of energy-saturated brisant substances (TNT, Tetryl) and the lower part 6 of the charge, made of plastite energy-saturated brisant substances (PVV5, PVV7) and pressed directly into the body, provides non-failure operation of the charge, high detonation velocity and increased explosion energy.

The applicant has manufactured and successfully tested prototypes of the proposed downhole charge.

Claims (1)

Borehole charge in a polymer body for industrial blasting, containing a body with a bottom and a cover made with a hole for the possibility of installing the bottom part of the charge body when the charges are connected into a garland by locking elements made in the form of an annular collar on the outer side of the bottom part of the body and a counter an annular groove on the inner side of the cover opening, respectively, in the body there is a composite explosive material in which a socket for a detonator cap is made, characterized in that the lower part of the explosive material of the charge is made of plastite energy-saturated brisant substances and is pressed directly into the body, and the upper part explosive material of the charge, in which a nest for a detonator cap is made on the side of the cover, is made in the form of a pressed block of energy-saturated brisant substances.

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