RU2761916C1 - Detonating apparatus - Google Patents

Abstract

FIELD: blasting.SUBSTANCE: invention relates to the field of high-safety blasting means, namely, to low-voltage bridge electric detonators, and can be used as a small-sized initiation means during blasting operations. The detonating apparatus comprises a body 1 with an insert 2 installed therein with an explosive charge made in the form of hitches: an output hitch 3, an intermediate hitch 5 and an initiating hitch 6 coupled with the initiator 7. The body is made in the form of a shell with an insert 2 made in the form of a socket made of a material with a high acoustic impedance. The bottom of the socket is in contact with the output hitch 3 of the explosive charge, equipped with a reinforcing hitch 4 made of high-density energy-saturated metal complexes (NCP), located between the output hitch 3 and the intermediate hitch 4 of the explosive charge, made of low-density energy-saturated metal complexes (NCP) of and coupled with the initiating hitch 6 of the explosive charge, located inside the initiator 7. The height of the bottom of the insert 2 along the axis is determined from the ratio h=(0.020 to 0.025)d, wherein d is the inner diameter of the insert, mm. The total height of the reinforcing 4 and intermediate 5 hitches is determined from the ratio L=(44 to 46)/d, wherein d is the inner diameter of the insert, mm. The insert 2 is made of metal. The initiator 7 is made in the form of a low-voltage initiating apparatus. The output hitch 3 of the explosive is made of a high explosive - PETN. The intermediate hitch 5 of the explosive is made of a low-density energy-saturated metal complex (NCP). The reinforcing hitch 4 of the explosive is made of a high-density energy-saturated metal complex (NCP). The initiating hitch 6 of the explosive is made of a high-density energy-saturated metal complex (NCP).EFFECT: increase in the initiating capability, increase in the speed of the detonating apparatus.7 cl, 3 dwg

Description

The invention relates to the field of means for initiating an explosion, namely to detonating devices and can be used as an element of explosive automation.

Known technical solution RU 2640446 C1, 01/09/2018, IPC F42B 3/10, 33/00, F42C 19/12, which describes a method for assembling the device, which includes the installation of a pre-assembled and equipped detonating unit with the main explosive charge ( BB), in which the combustion is converted into detonation, and the initiator, the installation and equipment of the latter consists in pressing the central and annular electrodes with electrical insulating material, to which the glow bridge is soldered and installed in the sleeve by pressing on a press fit.

The disadvantages of the device include:

- the complexity of the design, significant geometric dimensions and weight, high cost and laboriousness of manufacturing the device;

- insufficient initiating ability.

Known device RU 2466349 C1, 11/10/2012, IPC F42C 19/12, electric detonator, which contains a sleeve with a liner installed in it with an explosive charge placed in it, made in the form of weighed portions of an output from a secondary explosive of high density, an intermediate sample from a deflagrating explosive of low density and an initiating sample from a deflagrating high-density explosive coupled with an exploding bridge mounted on a sealing block with current leads, and a safety sample installed between the outlet end of the sleeve and the output sample of the explosive charge made of smokeless powder.

The disadvantages of the device include: a decrease in the initiating ability of the detonator when placing a substance inert for the detonation wave between the output charge and the bottom of the cap.

Closest to the claimed technical solution is a device adopted for the prototype described in the patent for invention RU 2389971 C1, 05/20/2010, IPC F42C 19/12, containing a housing equipped with an insert with an explosive charge made in the form of weighed portions: output, intermediate and initiator coupled with the initiator.

The disadvantages of the device include:

- inconvenience during operation due to the complexity of the assembly of the device;

-complex design of detonator elements;

- insufficient initiating ability.

The object of the invention is to provide an effective safe detonating device with improved operational characteristics, including operational safety.

The technical result of this invention consists in a significant increase in the output shock-wave parameters of the detonating device and, accordingly, in its initiating ability, increasing the response speed by reducing the response time without increasing the mass of the explosives contained in it.

This is achieved by the fact that in a detonating device containing a housing with an insert with an explosive charge installed inside it, made in the form of weighed portions: output, intermediate and initiating, coupled with an initiator, according to the invention, the housing is made in the form of a shell with an insert made in the form of a glass made of a material with a high acoustic impedance, the bottom of which is in contact with the output charge of explosive charge, equipped with a reinforcing charge made of energy-saturated metal complexes (NKT) - diperchlorate (5-nitrotetrazolato) cobalt pentaamine) of high density, located between the output charge and an intermediate charge of the explosive charge , made of energy-saturated metal complexes (tubing) of low density and conjugated with an initiating charge of explosives located in the initiator, while the height of the bottom of the insert along the axis is determined from the ratio

h = (0.020-0.025) d,

where d is the inner diameter of the insert (mm),

and the total height of the reinforcing and intermediate portions is determined from the ratio

L = (44-46) / d,

where d is the inner diameter of the insert (mm).

In addition, in order to increase the output shock-wave characteristics and reduce the response time, the insert is made of metal.

In addition, in order to unify the device, the initiator is made in the form of various low-voltage initiating devices, for example, a dielectric block with incandescent bridges, semiconductor energy-converting devices.

In addition, in order to increase the blasting capacity, the outlet charge of the explosive is made of blasting explosive - pentaerythritol tetranitrate (PETN) a.

In addition, in order to reduce the response time, the intermediate charge of explosives is made of an energy-saturated metal complex (tubing) - low density, prone to transition from combustion to detonation and safe to handle.

In addition, in order to increase the output shock-wave characteristics, the reinforcing explosive charge is made of a high-density energy-saturated metal complex (tubing).

In addition, in order to stabilize the output shock-wave characteristics and time parameters, the initiating explosive charge is made of a high-density energy-saturated metal complex (tubing).

The analysis of the state of the art carried out by the applicant, including a search for patent and scientific and technical sources of information and the identification of sources containing information about analogues of the claimed invention, made it possible to establish that the applicant did not find an analogue characterized by features identical to all essential features of the claimed invention, but the definition from the list identified analogs of the prototype, as the closest analogue in terms of a set of features, made it possible to identify a set of significant in relation to the technical result perceived by the applicant of the distinctive features in the claimed object set forth in the claims. Consequently, the claimed invention meets the requirement of "novelty" under the current legislation.

To verify the compliance of the claimed invention with the condition of the inventive step, the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the prototype of the claimed invention, the results of which show that the claimed invention does not follow for a specialist explicitly from the prior art.

Therefore, the claimed invention meets the requirement of "inventive step".

The invention is illustrated in the following drawings, where:

in fig. 1 shows the design of the detonating device;

in fig. 2 shows the experimental results of operation of a detonating device with an inner diameter of the insert 2 d = 5 mm (curve a - stainless steel insert; curve b - aluminum insert);

in fig. 3 shows the dependence of the output characteristics of the detonating device (c is the amplitude generated by the EM of the shock wave, d is the integral characteristic of the initiating ability ∫p ² τdτ) on the total height along the axis of the amplifying sample of explosive 4 and intermediate sample of explosive 5 with the inner diameter d of the insert 2, equal to five mm.

FIG. 1 introduced the following items:

1 - case;

2 - insert;

3 - output sample of explosives;

4 - reinforcing hinge of explosives;

5 - intermediate sample of explosives;

6 - initiating hinge of explosives;

7 - initiator.

The detonating device consists of a housing 1 made in the form of a shell, in which an insert 2, made of a material with a high acoustic impedance, in the form of a glass is installed. Inside the insert 2, there is an explosive charge made of weighed portions of explosives of the outlet 3, reinforcing 4, intermediate 5 and initiating 6. The outlet weighed portion of explosive 3, made of blasting explosive, borders on the reinforcing weighed portion of explosive 4 from high-density energy-saturated metal complexes (NKT). Between the reinforcing sample of BB 4 and the initiating sample of BB 6, there is an intermediate sample of BB 5 made of low-density energy-saturated metal complexes (NKT). The initiating sample BB 6 is located inside the initiator 7, which can be a low-voltage initiating device, for example, a dielectric block with glow bridges, semiconductor energy converting devices. The height along the h axis of the bottom of the insert 2 is determined from the ratio h = (0.020-0.025) d, where d is the inner diameter of the insert 2, and the total height L of the reinforcing hinge 4 and the intermediate hinge 5 is determined from the ratio L = (44-46) / d , where d is the inner diameter of the insert 2.

The work is carried out as follows.

A low-voltage electrical pulse is supplied to the initiating device 7, which is converted into thermal energy, which activates the initiating sample of BB 6, the firing pulse of which is transmitted to the intermediate sample of BB 5. Energy-saturated metallocomilexes (tubing) are used as explosives for the amplifying sample of BB 4 and the intermediate sample of BB 5. The intermediate sample of BB 5 has a lower pressing density compared to the reinforcing sample of BB 4, which ensures a faster development of the energy parameters of the explosive transformation at the stage of convective combustion and its fastest completion with the transition to the low-speed detonation mode. An increase in the density of the amplifying sample of explosives 4 makes it possible to accordingly increase the energetics of the initiating detonation wave acting on the output sample of explosives 3 (blasting explosives - BVV), since it is directly proportional to the density of the reacting explosive.

Sequential pressing of the main part of all weighed portions of explosives of the explosive charge of the detonating device into insert 2 makes it possible to significantly improve the quality of the interface between the amplifying weighed amount of BB 4, the intermediate weighed amount of BB 5 and the output weighed amount of VV 3 (BVV), which has a significant effect on the output energy parameters of the detonating device as a whole, which confirmed experimentally. The height along the h axis of the bottom of the insert 2 and the material of the insert 2 significantly affect the output energy parameters of the device as a whole. The height along the h axis of the bottom of the insert 2, made of material with high acoustic and dynamic impedance, is determined from the ratio h = (0.020-0.025) d, which is confirmed experimentally (see Fig. 2), where the materials of the insert 2 are compared: curve a - stainless steel liner; curve b - aluminum insert, with an inner diameter of the insert 2 d = 5 mm. From the drawing (Fig. 2) it can be seen that in order to increase the initiating ability (which is determined by the value of P ² τ), the height along the h axis of the bottom of the stainless steel insert 2 should be as close as possible to 0.1 mm. With the inner diameter of the insert 2 d = 5 mm, from the above formula we obtain the following values for the height along the h axis of the bottom of the insert 2: h = 0.1-0.125, which is consistent with the experimental results.

It has been experimentally confirmed (see Fig. 3) that for detonating devices with a diameter d from 4 to 5 mm, the value of L is determined by the expression L = 45 / d. FIG. 3 shows the results of experiments to determine the effect of the total length of the amplifying sample of explosives 4 and the intermediate sample 5 of the explosive charge on the pressure amplitude of the output shock wave of the detonating device and the integral characteristic of its initiating ability (curve c is the amplitude generated by the EM of the shock wave, curve d is the integral characteristic initiating ability ∫р ² τdτ). Analyzing the shape of the whig curves, we can conclude that for a reinforcing sample of BB 4 and an intermediate sample of 5 from tubing with a diameter of 5 mm, the optimal total length L is 8-10 mm (based on the above expression L = 45 / d = 45/5 = 9 mm), at a shorter length, there is a noticeable decrease in the output energy parameters of the detonating device as a whole, and an increase in length, accordingly, does not lead to their significant increase.

The material of the insert 2 also significantly affects the response time of the detonating device, for example, when switching from the aluminum insert 2 to the insert 2 made of stainless steel, the response time of the investigated variants of detonating devices decreased by 40%. This is due to the influence of the housing 1 made of a material with high acoustic impedance on the process of explosive transformation of substances. The maximum effect of the material of the insert 2 is manifested when the diameters of the explosive charge are less than the limiting one, or, as in the described invention, at the initial stage of the development of the explosive transformation.

An example of a specific implementation is a detonating device, in which the body 1 is made of annealed stainless steel, the insert 2 is made of stainless steel, to form the output sample of explosive 3, a standard BVV - heating element is used, reinforcing the sample of VV 4 - an energy-saturated metal complex (tubing) of high density and an intermediate sample BB 5 is an energy-rich metal complex (tubing) of low density; a dielectric block with glow bridges is used as an initiator 7.

The use of this invention will improve the operational characteristics of the detonating device, namely, significantly increase its initiating ability, speed, reducing the response time, without increasing the mass of explosives contained in the device.

For the claimed invention in the form as it is described in the claims, the possibility of its implementation using the above-described design solutions and the ability to ensure the achievement of the specified technical result are confirmed. Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (12)

1. A detonating device containing a housing, with a liner installed inside it with an explosive charge made in the form of weighed portions: output, intermediate and initiating, coupled with an initiator, characterized in that the housing is made in the form of a shell with an liner made in the form of a glass material with a high acoustic impedance, the bottom of which is in contact with the output charge of an explosive charge, equipped with a reinforcing charge made of high-density energy-saturated metal complexes, located between the output charge and an intermediate charge of an explosive charge made of energy-saturated metal complexes of low density and coupled with an initiating charge explosive located in the initiator, while the height of the bottom of the insert along the axis is determined from the ratio h = (0.020-0.025) d, where d is the inner diameter of the insert, mm; and the total height of the reinforcing and intermediate portions is determined from the ratio L = (44-46) / d, where d is the inner diameter of the insert, mm. 2. The detonating device according to claim 1, characterized in that the insert is made of metal. 3. The detonating device according to claim 1, characterized in that the initiator is made in the form of a low-voltage initiating device. 4. The detonating device according to claim 1, characterized in that the output charge of the explosive is made of a high explosive - heating element. 5. The detonating device according to claim 1, characterized in that the intermediate charge of the explosive is made of a low-density energy-saturated metal complex (NKT). 6. The detonating device according to claim 1, characterized in that the reinforcing explosive charge is made of a high-density energy-saturated metal complex (NKT). 7. The detonating device according to claim 1, characterized in that the initiating charge of the explosive is made of a high-density energy-saturated metal complex (NKT).

Images