RU2780991C1 - Impact detonating device based on high explosive - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: invention relates to the field of blasting, in particular to percussive detonating devices (DD), whose design does not contain initiating explosives (IE) to increase their safety in production and operation, as well as increase resistance to various kinds of external influences. These DDs are equipped only with high-explosives (HEs) that have a much lower sensitivity to external influences compared to IEs. The device includes a firing pin located in the body on one axis, protruding relative to the end surface of the body, a detonator cap separated from the transfer charge by an inert metal barrier that is not destroyed during shock loading, and a detonator. At the same time, an aluminum foil gasket is placed between the striker and the detonator cap. The striker is made with a diameter, the value of which does not exceed the critical detonation diameter of the used high explosive. The thickness of the inert metal barrier is chosen to be less than the diameter of the transfer charge by 2.5-5.0 times, the porosity of the transfer charge is 0.27-0.33, and the diameter of the body in the area of ​​the detonator cap exceeds the diameter of the striker by at least 2.2 times.

EFFECT: reduction of the level of impact energy required to actuate the DD with a compact design.

1 cl, 1 dwg

Description

The invention relates to the field of blasting, in particular, to percussive detonating devices (DU), the design of which does not contain initiating explosives (IVV) to increase their safety in production and operation, as well as increase resistance to various types of external influences. These remote controls are equipped only with high explosives (BEV) that have a much lower sensitivity to external influences compared to IVV.

Such remote controls are used in fuses for various purposes, including those with a spring shock-safety mechanism (SPM), and in explosive heads of cumulative perforators lowered into oil and gas wells on tubing pipes. Improving the remote control based on the BBW, goes towards reducing the impact energy required to activate them (the kinetic energy of the striker), reducing the BBW contained in them and improving the overall mass indicators due to this.

The problem solved by the claimed invention is the creation of a compact design of PS with the lowest possible level of mechanical shock energy required to activate it.

Known remote control based on BVV, the design of which is a body in which sequentially on the same axis are the striker, deformable element of inert material in the form of a disc, detonator cap (CD), transfer charge (PC) and detonator. KD and PZ are separated by an axial channel, the diameter of which is less than the diameter of the striker (patent for invention RU 2083948, IPC: F42C 19/10. publ. Bull. 19.1997). The excitation of the explosion of the BVV in the PS is carried out by mechanical shock during the deformation of the CD by extrusion into an axial channel of small diameter. The mechanical impact ensures the achievement of critical pressure in the pressure vessel, at which the deformation of the blast furnace into the opening of the striker leads to the formation of effective hot spots in this zone, causing an explosion. Exclusion of the possibility of extrusion upon impact into the annular gap between the striker and the body is ensured by sealing this gap with the disk material flowing into it. The explosive process in the conditions of a closed volume develops in the CD until detonation, which is then transferred to the PZ and further to the detonator.

However, in the event of a PD explosion, such a seal is not able to prevent the release of gaseous products through the annular gap, as a result of which the intensity of the fire initiating pulse that ignites the PZ through a small-diameter channel decreases.

This disadvantage is absent in another well-known design of remote control (patent for invention RU 2103661, IPC: F42C 700, publ. Bull. 3, 1998), selected as a prototype. The remote control also consists of a striker, CD, PZ and a detonator located in series in the body. CD in this PS is made in the form of a metal cap filled with BVV. The striker protrudes relative to the end surface of the body, and the PD is separated from the PD by an inert metal barrier that is not destroyed during shock loading, which eliminates the requirement for the need to make the PD with a diameter not less than the critical detonation diameter of the BVV (d _cr ) for reliable transfer of the detonation pulse from the PD to PZ. This allows you to significantly reduce the diameter of the striker and. due to this, to reduce to a minimum level the impact energy necessary for excitation of the explosion of the CD.

But such a design of the capsule, providing an effective sealing of the annular gap between the body and the striker, requires an increase in the impact energy necessary to excite the explosion of the capsule, since part of the energy is spent on deforming the cap wall. And the low sensitivity of the primer to the initiating mechanical impulse leads to the need to increase the impact energy by increasing the size and weight of the shock-safety mechanism that serves to actuate the remote control.

The technical result of the claimed invention is to reduce the level of impact energy required to actuate the propulsion system with a compact design.

The specified technical result is achieved due to the fact that in a percussive detonating device based on a high explosive, including a striker located in the body on the same axis, protruding relative to the end surface of the body, a detonator cap separated from the transfer charge by an inert metal barrier that is not destroyed in in the process of shock immersion, and the detonator, what is new is that a gasket made of plastic metal is placed between the striker and the detonator cap, the striker is made with a diameter that does not exceed the critical detonation diameter of the high explosive used, the thickness of the inert metal barrier is chosen less than the diameter of the transfer charge in 2.5-5 times, the porosity of the transfer charge is 0.27-0.33, and the diameter of the body in the area of the detonator cap exceeds the diameter of the striker by at least 2.2 times.

It should be noted that, at small values of the striker diameter (<4 mm), only the low-velocity mode (LSD) of explosive transformation can be initiated by a mechanical impact in a blast furnace based on an explosive transformation. This regime, which, unlike combustion, has a wave character, is capable, like normal detonation, of being transmitted through an inert metal barrier, but at a much smaller thickness than in the case of detonation. Prior to normal detonation, the NSR develops in the PS at some distance from the barrier (pre-detonation section - L _PR ). In the _{case of a sufficiently strong shell, the value of LP} depends on the porosity of the PZ, its diameter, and the intensity of the NSR transferred from the PD through an inert metal barrier. As for the intensity of the NSR in the SC itself, it is determined mainly by the mass of the BBW charge initiated by the mechanical impact under the striker and the strength of the PS body in the area of the SC location. Taking into account all these relationships, the design parameters of the PS should be chosen such that when it is triggered, the value of L _{PR is} the minimum possible. It is obvious that only under this condition will the mass of the explosives contained in the PS and the height of the PS itself also be minimal. All these ratios are chosen by calculation and experiment.

In FIG. shows a diagram of the proposed sensor, where: 1 - striker; 2 - CD; 3 - gasket; 4 - body; 5 - PZ: 6 - detonator.

An example of a specific implementation of the claimed device can serve as a remote control based on a heating element (it has, according to table 9.9 in the book "Physics of the Explosion" / Edited by L.P. Orlenko. - 3rd edition, revised. - In 2 vols. T. 1. - M.: FIZMATLIT, 2002. - ISBN 5-9221-0219-2, with a particle size of 0.15-0.25 mm and a density of 1.0 g / cm ³ d _KP = 2.2 mm). In addition, for equipping this remote control, such explosives as benztrifuroxan (BTF), bis-trinitroethylethylenedinitramine (substance "N"), etc., which, compared with other explosives, have the smallest critical detonation diameter, the greatest sensitivity to mechanical stress and high tendency to go from burning to detonation. The remote control consists of a housing 4, in which a striker 6 mm high and 2 mm in diameter, separated by a CD and PZ barrier, as well as a detonator, are sequentially located on the same axis. A blind axial hole with a diameter of 0.5 and a depth of 3 mm is made in the striker on the CD side. KD is a high-density heating element ≈2 mm thick. The outer diameter of the housing in the area of the CD location exceeds 4.4 mm. Between the striker and CD is placed, as in DU according to patent RU 2083948 C1, 07/10/1997, a thin round gasket made of ductile metal (aluminum foil 0.1 mm thick). The striker protrudes 1 mm relative to the end surface of the body. The barrier between the CD and the PZ, having a diameter of 1.5 mm, is made 0.5 mm thick in one piece with the body. The height of the PS, pressed to a density of 1.2-1.3 g/cm ³ exceeds L _PR and is ≈13 mm. A high-density heating element charge is used as a detonator, pressed into a thin-walled metal cap with an outer diameter of 3.6 mm and a height of 3 mm. The fastening of the firing pin and the detonator, as well as the sealing between them and the body of the annular gaps, is carried out either with epoxy glue or sealant. The remote control body and striker are made of hardened steel. It is also possible to use a titanium alloy.

This remote control works as follows. When an axial blow is applied to the striker 1 by a striker with sufficient kinetic energy, the CD 2 in the PS first compresses, and the gasket 3, plastically deforming, closes the annular gap between the body 4 and the striker 1, then when the pressure of strength failure in the CD 2 is reached, which exceeds critical value (for example, for a heating element, according to the data given in the book by G.T. Afanasiev and V.K. Bobolev “Initiation of solid explosives by impact”. M .: Nauka, 1968, the critical pressure is 0.48 GPa), BVV is thrown into the blind hole of the striker 1, as a result of which effective heating centers are formed in the zone of this hole, leading to ignition and, ultimately, explosive transformation of the substance in the form of HCP. Further, the NSR is transmitted through the barrier to PZ 5, where, under conditions of a closed volume, it passes at a certain distance into normal detonation, then the detonation pulse is amplified to the required level in the detonator 6. The barrier is destroyed as a result of the action of the explosive explosion products on it in the PZ and the detonator.

As studies have shown, the above design parameters of the PS provide, at a minimum impact energy, both the excitation of an explosion in the CP with its development to the NSR, and the receipt in the DE of the minimum possible value L _{PR ,} which is (7.6 ± 0.5) mm. At the same time, the PS, which has a sufficiently high probability of failure-free operation, can be made with a height of no more than 25 mm with a mass of the heating element contained in it ≈0.1 g. It was experimentally found that this PS has the following main characteristics:

- the impact energy required for reliable actuation of the PS under normal climatic conditions is at least 1.5 J, and at an ambient temperature lowered to minus 60 ⁰ С, - ≥ 2.2 J;

- DU with the required reliability is capable of initiating a plastic composition based on a heating element of the PT-83 type;

- the triggering time of the PS (the time interval between the moments when the impactor touches the striker and the detonation reaches the end of the PS) at an impact speed of about 20 m/s, like in school CDs with IVS, is ≈70 μs. As the impact speed increases, this time decreases;

- The remote control maintains its performance under the action of inertial overloads of about 100,000 g:

- in fire conditions, the remote control does not work;

- when the outer diameter of the DU is ≈12 mm, it is not destroyed when triggered.

This remote control can be used both as a head fuse in conventional ammunition, and as part of fuses with a spring UPM. Moreover, in the latter case, the UPM can be operated by hand and used repeatedly.

The indestructibility of the remote control when triggered makes it possible to use it in explosive systems operating in a confined space in the presence of an operator (naturally, in this case, the explosive circuit initiated by the fuse and the actuators must also be made indestructible). And in order to exclude the release of gaseous explosion products into the environment through a through channel formed as a result of the destruction of the barrier and the expulsion of the striker into the cavity of the fuse UPM, a cover is installed on the remote control, in the upper part of which there is an additional stepped striker with a plastic metal ring. In the process of actuation of the PS, the stepped striker is moved by the pressure of the gaseous products of the explosion towards the striker and deforms the ring of ductile metal. As a result of this, the annular gap between the above-mentioned striker and the cover is sealed and the breakthrough of the PV into the cavity of the UPM and into the environment does not occur when the fuse is triggered.

Claims (1)

A percussive detonating device based on a high explosive, including a striker located in the housing on the same axis, protruding relative to the end surface of the housing, a detonator cap separated from the transfer charge by an inert metal barrier that is not destroyed during shock loading, and a detonator, characterized in that that a spacer made of aluminum foil is placed between the striker and the detonator cap, the striker is made with a diameter that does not exceed the critical detonation diameter of the used high explosive, the thickness of the inert metal barrier is chosen 2.5-5.0 times less than the diameter of the transfer charge, the porosity of the transfer charge charge is 0.27-0.33, and the diameter of the body in the zone of placement of the detonator cap exceeds the diameter of the striker by at least 2.2 times.

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