RU2628115C1 - Detonation wave formation device - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: device includes a two-layer inert matrix with detonation wiring in form of filled explosive materials (EM) of channel network, the upper layer of which includes common detonation wiring input area, and the lower layer comprises end sections disposed in through holes, provided in this layer. The upper layer includes areas, located along surface layer and areas disposed in through holes, provided therein, and the lower matrix layer also includes detonation wiring areas, located along its surface. The EM sublayer abuts the lower matrix layer and contacts the EM surface of detonation wiring end sections. Lower layer through holes are built with interval l chosen experimentally.

EFFECT: invention allows to increase simultaneous activation of the device with improved production manufacturability.

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Description

The invention relates to the field of blasting and can be used in the development of devices for the formation of a blast wave of a given shape in explosive charges (BB).

The task to which the invention is directed is to ensure the synchronization of the occurrence of a detonation front in an explosive charge being detonated by simultaneously (with minimal time difference) detonation using a multipoint initiating device while maintaining the dimensions or minimizing them.

From the prior art, devices are known for generating a detonation wave in an explosive charge, aimed at solving this problem. For example, a device is known according to patent US 3430563 (F42B 3/02, publ. 04.03.1969), which contains a flexible inert elastomer plate having the shape of a matrix and detonation wiring in the form of a flat sheet of flexible explosive, pressed into the matrix in such a way that it forms a lattice BB, consisting of coplanar strips of rectangular section with a common beginning for all strips. A sheet of flexible explosive, including a point common to all strips, is located in the thickness of an elastomer plate between its surfaces. The explosive strips have the same length, width and height, and a section forming a protrusion located at right angles to the surface of the elastomer plate departs from the end of each of them. The end of this portion of the strip is flush with the surface of the plate. The result is a series of end sections of the detonation wiring, spaced evenly along one of the surfaces of the flexible inert elastomer plate. When a detonation pulse is applied to a point common to the entire lattice, the explosive charge detonates simultaneously in a large number of points at which it emerges from the elastomer on the plate surface.

To obtain a synchronous detonation front in a detonated explosive charge, a uniform arrangement of the detonation wiring outputs on the surface of the detonated charge and equal lengths of the coplanar explosive strips are necessary, in addition, it is necessary to fulfill the conditions for ensuring the stability of operation of the end sections. It should be noted that these conditions cannot be satisfied when using this design, which means that there is a difference in time, up to the failure of the operation of individual elements.

Another device is known from the prior art by which a detonation wave is generated in the explosive charge, aimed at solving the above problem and partially eliminating the disadvantages of the previous analogue (patent RU 2135935, published on 08.27.1999). The known device includes a charge of explosives, means of initiation, detonation wiring, made in an inert matrix. The detonation wiring is a system of detonation channels of rectangular cross section with a common entrance, sections located along the matrix surface, and several outputs (end sections). To increase the synchronization of the detonation front, it is necessary to comply with the condition of equal transmission times of the detonation pulse to the surface of the charge in order to minimize the difference in the arrival times of detonation pulses to the outputs of the detonation wiring — end sections located at an angle to the matrix surface.

However, despite the fact that the detonation wiring, unlike the analogue discussed above, is laid in the channels of the matrix, the disadvantage of this analogue is that it is difficult to reconcile the uniform distribution of the outputs of the detonation wiring and the uniformity of its channels, but even when this is achieved, the synchronous detonation front in the detonated charge BB may not be formed.

Known for another device for generating a detonation wave (RU 2542804, F42B 3/10, 02/27/2013), containing two matrices of inert material with a network of detonation channels, consisting of sections located along the surface of the matrices and sections located in through holes. Channels of different matrices are activated from different initial initiation points, while the configuration of the network of matrix channels is made similar. One of the sections of the detonation channel network of the first matrix, located in one of its through holes, serves to activate the initial point of initiation of the second matrix, and the through holes of the second matrix depart from the holes for the end sections of the channels of the first matrix and are connected to each other in pairs, forming channels initiation along the surface of the matrix adjacent to the surface of the detonated explosive charge. When the initial initiation points of the channels of both matrices are undermined, detonation propagates along the networks of channels and holes of the first and second matrices and enters the initiation channels from different sides. Collision of detonation waves in the initiation channels creates local zones of increased pressure sufficient to initiate detonation in the adjacent main explosive charge, providing initiation of inputs of initiating channels close to simultaneous. EFFECT: increased reliability of operation.

The disadvantage of this solution is that it is impossible to accurately ensure the formation of local zones of increased pressure in the middle of the initiating channel, which leads to asynchrony and the simultaneous response of the device.

There is another device for generating a detonation wave on a given geometric surface (patent US 3896731, 07.29.1975), selected as the closest analogue. The device comprises a multilayer matrix of inert material, the layers of which are located one above the other, and a detonation wiring located in the matrix in the form of a network of channels, including sections located along the surfaces of the layers and sections located at an angle to these surfaces. The upper layer of the matrix includes a common input section of the detonation wiring, from which depart areas along the surface of the layer, ending in sections located at an angle to the surface of the layer, placed in through holes. In a preferred embodiment, the upper layer of the matrix includes four end sections, the underlying one is sixteen, the next one is fifty-two, and the lowest layer of the matrix includes only sections located in through holes, which are aluminum caps with a pressed-in explosive. The detonation wiring sections of the lower matrix layer are the end sections of the entire detonation wiring and their number corresponds to the number of end sections of the previous layer. The detonation wiring is made of detonating cords, which are connected in a specific configuration using connecting parts, for example, end couplings. The device provides a simultaneous transmission of the detonation pulse from the starting point of initiation to the explosive, located in many through holes of the lower matrix.

A disadvantage of the closest analogue is that when a four-layer matrix is used, shock waves are formed as a result of the detonation wiring of the upper layer of the matrix, which can reach the surface of the explosive channels of the detonation wiring of the intermediate layers of the matrices simultaneously with the detonation signal arriving at them, which leads to the formation of gas-dynamic gaps between individual elements and undermined by the charge and can lead to failure of the passage of detonation signals through the channels of the intermediate layers ev matrix, in the end result this can lead to asynchronous operation of the device. In addition, the formation of a detonation wave on a certain geometric surface occurs through the wall of aluminum caps, into which the explosives are pressed in and which are installed in the through holes of the bottom layer of the matrix, resulting in a delay in the initiation of detonation under the projection of the cap, which leads to asynchronous operation of the device. It should also be noted that the implementation of detonation wiring of detonating cords leads to a complication of manufacture due to the use of a large number of connecting parts.

The technical result achieved by the claimed invention is to increase the synchronization response of the device while increasing the manufacturability.

The specified technical result is achieved due to the fact that in the device for the formation of a detonation wave, including a multilayer inert matrix with detonation wiring in the form of a network of channels filled with explosive (BB), the upper layer of which includes a common input section of the detonation wiring, and the bottom — end sections located in the through holes made in this layer, in addition, the upper layer includes sections located along the surface of the layer, and sections located in the through holes are made x in it, it is new that the bottom layer of the matrix includes detonation wiring sections located along its surface, while the lower layer of the matrix is adjacent to the explosive sublayer in contact with the surface of the explosive end sections of the detonation wiring, and through holes of the lower layer are made in steps l, which is selected from the following relation:

l≥2Δ _s + D + Δ _k , where

Δ _z is the thickness of the matrix layer under the detonation wiring section located along the layer surface;

D is the diameter of the through hole;

Δ _to - the width of the detonation wiring located along the surface of the matrix layer.

The implementation of the lower layer of the matrix with detonation wiring sections located along its surface, allows you to perform detonation wiring with many end sections, while using only two inert layers. In this case, when the channels of the detonation wiring of the upper matrix layer are triggered, shock waves are formed that reach the surface of the explosive channels of the detonation wiring of the lower matrix layer before the detonation signal arrives at them, which does not impede the passage of detonation signals through the channels of this matrix layer and leads to synchronization of the device operation.

The implementation of a sublayer of explosives adjacent to the lower layer of the matrix and in contact with the surface of the explosive end sections of the detonation wiring, allows you to form the initiating pulse transmitted to the main explosive charge, sufficient for its reliable initiation without increasing the number of explosives in the end sections, in this case, the detonation waves will collide with the other between the projections of the end sections, increasing the pressure amplitude and providing front synchronization.

The implementation of the through holes of the lower layer with a certain minimum step l was chosen experimentally, which allowed us to increase the number and uniformity of the distribution of the end sections over the surface of the sublayer without increasing the negative effects of the products of chemical transformation released during the passage of the detonation pulse through the sections of the detonation wiring located along the surface of the matrix.

In FIG. 1, 2 schematically shows the claimed device in two projections, where: 1 is the source of initiation; 2 - the upper layer of the matrix; 3 - the bottom layer of the matrix; 4 - sublayer; 5 - sections of detonation wiring located in the upper layer; 6 - detonation wiring sections located in the lower layer.

An example of a specific implementation of the claimed device can serve as a device for generating a detonation wave in an explosive charge with a flat surface, including an inert two-layer matrix with detonation wiring, which has one common input section and 256 end sections, as well as an initiating device, which is used as an electric detonator, associated with the common input of detonation wiring. Detonation wiring is a network of channels made in two layers of the matrix and filled with explosives. Each matrix layer includes wiring sections along the surface of the layers and sections located in through holes. The sections located in the through holes of the lower layer of the matrix are the end sections of the detonation wiring and are distributed on the lower surface of the matrix, from the side of the placement of the explosive sublayer, which is 1.8 mm thick. In this case, the detonation wiring outputs are evenly distributed over the surface of the sublayer with a step l = 6 × 6 mm. The detonation wiring sections located on the surface of the matrix layers are 1.2 mm wide, the diameter of the end sections is 2 mm. The thickness of the matrix layer under the detonation wiring section located along the layer surface (locking layer) is 1 mm. Thus, the experimentally selected ratio is satisfied: l≥2Δ _s + D + Δ _k (for this design, the minimum pitch l is 5.2 × 5.2 mm). The design of the claimed device in comparison with the closest analogue is more technological and simple. A prototype was made, which showed the possibility of achieving the claimed technical result.

The operation of the claimed device is as follows.

A matrix consisting of two layers 2, 3 is applied to the detonated explosive charge and the common input of detonation wiring 5 is connected to the detonator 1. When a pulse is supplied from the detonator 1 to the common input of detonation wiring, the pulse propagates first along sections 5 made along the surface of layer 2, and then through the sections located in the through channels of the layer 2. Next, the pulse is transmitted to the ignition zones of the detonation wiring sections 6 made in the layer 3, and propagates along the surface of the layer and along the sections located in possible openings of layer 3. When the detonation wiring channels of the upper matrix layer are triggered, shock waves are formed that reach the surface of the explosive channels of the detonation wiring of the lower matrix layer before the detonation signal arrives at them, which does not impede the passage of detonation signals through the channels of this matrix layer and leads to synchronization of operation devices. The detonation pulse almost simultaneously reaches the detonation wiring outputs evenly placed on the surface of the sublayer 4. The two-layer matrix allows increasing the number of detonation wiring outputs, the distance between which, chosen experimentally, avoids the negative effect of chemical conversion products released during the passage of the pulse through the detonation wiring sections . In sublayer 4, detonation waves collide with each other between the projections of the end sections, increasing the pressure amplitude and decreasing the asymmetry at the front of the detonation wave. The shape of the detonation wave front obtained on the surface of the detonated charge from the outputs of the detonation wiring corresponds to the shape of the detonated charge while ensuring the synchronism of its occurrence in the detonated explosive charge.

Thus, the implementation of the invention allows to initiate a detonated explosive charge with a minimum level of initial asymmetry.

Claims (5)

A device for generating a detonation wave, including a multilayer inert matrix with detonation wiring in the form of a network of channels filled with explosive (BB), the upper layer of which includes a common input section of the detonation wiring, and the lower one includes end sections located in through holes made in this layer, except addition, the upper layer includes sections located along the surface of the layer, and sections located in through holes made therein, characterized in that the lower layer of the matrix also includes detonation wiring sections located along its surface, with a sublayer of explosives in contact with the surface of the explosive end sections of detonation wiring adjacent to the bottom layer of the matrix, the through holes of the lower layer being made with step l, which is selected from the following relation: l≥2Δ _s + D + Δ _k , where Δ _z is the thickness of the matrix layer under the detonation wiring section located along the layer surface (locking layer), mm; D is the diameter of the through hole, mm; Δ _to - the width of the detonation wiring located along the surface of the matrix layer, mm

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