RU2386102C1 - Device for environment protection against explosion products - Google Patents

Abstract

FIELD: explosives.

SUBSTANCE: protection device comprises obstacle made of two layers installed around highly explosive object one after another and comprising fragments of absorbers having a shape of pyramids or prisms, the second layer fragments arranged with radial displacement relative to fragments of the first layer and with gap between layers. Fragments-absorbers of the first and second layers are arranged on power metal frames 9, which are rigidly joined to each other. Each fragment is made of its own metal frame with plates arranged on its outer surface along with gas flow direction. Inside frame there is an absorbing element that consists of porous material, with density of not more than 0.2 g/cm³ and multilayer packet of wire nets of various dimension type arranged on top of it. As plates are installed, gap is provided between them and multilayer packet, and holes are arranged in bottom of fragments-absorbers, which communicate to air gap for exhaust of gas flows, at the same time height of plates, distance between them and value of air gap are selected as based on the following ratios: 1.1l≤h≤≤1.2l, 1.1s≤l≤1.2s, where h is height of plates; l is distance between plates; S is value of air gap.

EFFECT: invention makes it possible to increase safety, due to absorption of hazardous substances and weakening of impact wave effect, near highly explosive objects in emergency conditions.

Description

The invention relates to means of protection against the effects of an explosion, and is intended to increase safety near explosive objects in emergency situations by attenuating an explosive shock wave and absorbing harmful dispersed particles during an explosion, and can be used in transportation and storage of explosive objects containing explosive and radioactive substances .

A device is known that implements a method of absorbing shock waves during blasting operations (RF patent No. 2030708 with priority from 12/30/92, R42D 5/045, publ. BI No. 7 from 03/10/95), including placement of barriers from a gas-liquid medium before undermining the charge. As a barrier, a waterproof shell filled with hollow spheres and / or pieces of foam and water is used. The device is designed to improve the safety of blasting by attenuating air shock waves.

The disadvantage of this device is the low reliability of protection against explosion products containing harmful substances, due to the fact that the barrier consists of a gas-liquid medium having a low density, insufficient to capture fragments, as well as the indeterminate nature of the destruction of the barrier, as a result of which breakouts can form in the barrier explosion products, entraining fine particles without being absorbed by obstacle elements, there is no impact effect for the absorption of fine particles.

A device that implements a method of protecting the environment then the explosion products adopted for the prototype (RF patent No. 2255225 with priority of 09/10/03, E21F 5/00, F42D 5/045, publ. Bulletin No. 18 of 06/27/05), including in two layers, one after another. The first layer consists of dividers with weak absorption capacity for trapping small dispersed particles. The second layer is made of absorbent fragments that sorb hazardous substances by impaction. Fragments of the first and second layers are in the form of pyramids or prisms placed with a radial displacement of fragments of the second layer relative to fragments of the first layer with a gap between the layers. The gap between the layers of the dividers and fragments of the absorbers is filled with a foam aerogel mass to capture small particles. The device is designed to attenuate an explosive shock wave and absorb harmful dispersed particles during the explosion of objects containing explosive and radioactive substances.

The disadvantage of this device is that the first layer, consisting of dividers, makes almost no contribution to the collection of harmful dispersed particles, as it is mainly intended for the formation of explosion products in a large number of gas flows, of which most of the dispersed particles must be collected by the second layer . Due to the fact that the absorbers of the second layer have smooth surfaces of nets and low permeability for the passage of gas flows with particles, blockage of passage channels is possible. As a result of this, the formation of a boundary layer on the side surfaces of the absorber and their flow around the air stream with partial absorption of harmful particles and going beyond the protective structure, which affects the decrease in the reliability of protection against explosion products.

The objective of the present invention is to provide a reliable device for protecting the environment from explosion products, which attenuates the blast shock wave and reduces the release of harmful dispersed particles into the environment due to their absorption.

The technical result achieved by using the inventive device is to reduce the level of release of harmful dispersed particles into the environment, increase safety near explosive objects in emergency situations by increasing the absorption of harmful substances and weakening the effect of the blast wave on environmental objects.

The technical result is achieved by the fact that in the known device for protecting the environment from explosion products, containing a barrier of two layers installed around the explosive object one after another and consisting of fragments of absorbers in the form of pyramids or prisms placed with a radial displacement of fragments of the second layer relative to fragments the first layer and with a gap between the layers. Absorbent fragments of the first and second layers are placed on power metal frames rigidly interconnected. Each of the fragments is made of its own metal frame with plates mounted on its outer surface in the direction of the gas flow. An absorbing element is installed inside the frame, consisting of a porous material with a density of not more than 0.2 g / cm ³ and a multilayer packet of wire mesh of various sizes placed on top of it. When installing the plates, a gap is provided between them and the multilayer package, and in the bottom of the absorber fragments there are openings in communication with the air gap for the exit of gas flows. The height of the plates, the distance between them and the size of the air gap selected from the following ratios:

1,1l≤h≤1,2l, 1,1s≤l≤1,2s

where h is the height of the plates;

l is the distance between the plates;

s is the air gap.

Introduction to the design of the power metal frame on which the absorbing fragments are placed allows avoiding the expansion of the absorbing fragments when exposed to the shock wave and explosion products and to ensure a more complete passage of the gas stream through them, and, therefore, the maximum absorption of radioactive materials in the stream, which reduces the level of release of harmful dispersed particles into the environment and increases safety near explosive objects in emergency situations.

The execution of each absorber fragment from a metal frame with plates mounted on its outer surface in the direction of the gas flow prevents the formation of a boundary layer and free flow of absorber fragments by gas flows without filtering them in the layers of absorbent fragments, which increases the absorption of radioactive materials, thereby reducing the level of release of harmful dispersed particles into the environment and increasing safety near explosive objects in emergency situations.

A multilayer bag of wire mesh of various sizes is used to capture particles formed after the explosion of an object containing radioactive and explosive materials. Fine particles passing through the packet of grids are captured by a porous material with a density of not more than 0.2 g / cm ³ . The density of the porous material is selected from the condition of the maximum number of pores that ensure the deposition of fine particles in the pores of the claimed material, thereby reducing the level of release of harmful dispersed particles into the environment and increasing safety near explosive objects in emergency situations.

The claimed ratio of the plate height dimensions, the distance between them and the size of the air gap are selected from the condition of increasing the gas flow velocity to reduce its pressure along the entire travel path to exit the holes, excluding the occurrence of a boundary layer above the plates, which increases the absorption of radioactive materials, thereby reducing the level release of harmful dispersed particles into the environment and increasing safety near explosive objects in emergency situations.

The inventive device is illustrated by drawings, where Fig. 1 is a cross-sectional diagram of a device as one of the embodiments of this device, where 1, 2 are I and II layer of absorbent fragments, and Fig. 2 is a transverse section of one of absorbent fragments. where 3 is a metal frame, 4 is a gas stream, 5 is a plate, 6 is a foam plastic, 7 is a wire mesh, 8 is a base, 9 is a hole, 10 is a power metal frame, h is the height of the plate, l is the distance between the plates, s is the air gap between the plates and the multilayer package.

The device consists of a first layer of absorbing fragments (1) made in the form of pyramids and installed at a distance R from the object where explosion products (PV) develop. The base of the pyramids is followed by a second layer of absorbing fragments (2), overlapping the joints of the base of the pyramids placed on a power metal frame (10).

The pyramid has an aerodynamically perfect shape, the center of pressure of which is located behind the center of mass. These properties provide a constant orientation to the center of the explosion and low resistance to PV. The latter quality gives the prism a small acceleration of motion from the explosion. At the same time, its shape contributes to the formation of jets with an increased concentration of hazardous substances in the gaps between the pyramids.

The principle of operation of the device is illustrated by the circuit shown in figure 1. and is based on the following.

In an accidental explosion, the vaporous particles of radioactive material contained in the explosion products in the form of submicron aerosols, the liquid phase of radioactive materials in the form of crushing droplets with sizes of ~ 1 μm, and the solid phase in the form of fragments with sizes up to several millimeters fall on the absorbing fragments of the first layer. Finely dispersed particles of the explosion products are inhibited and partially absorbed by the flow of gas flows in the absorbing fragments. Large fragments with a size of ~ 1 mm fly out from the cloud of explosion products at speeds of up to several kilometers per second, then, braking in the air, fall into absorbing fragments, burn completely or partially, crush, forming a secondary cloud of fine aerosols of radioactive material absorbed by the second layer . High-energy fragments penetrating two layers of the device also leave hazardous substances in the fragments-absorbers of the device contained on their surface due to penetration and deposition. In the gaps between the pyramids and in the pyramids themselves jets are formed, opposite which fragments-absorbers of the second layer are installed. PV particles due to the impact effect - a sharp change in the direction of motion in the labyrinths and in the absorbing fragments proper - are absorbed by metal grids and porous material of the fragments.

An example of a specific design can be a device (Fig. 2), where the absorbing fragments are made in the form of pyramids, consisting of a metal frame of steel 3 (3) with plates of steel 3 installed on its outer surface in the direction of the gas flow (4) (5) ) The plates are installed in order to prevent the formation of a boundary layer and free flow of absorbent fragments by gas flows without filtering them in the layers of absorbent fragments. An absorbing element is installed inside the frame, consisting of a foam plastic with a density of 0.1 g / cm ³ (6), and on top of it is a multilayer package of steel wire meshes with light mesh sizes of 40, 50, 100, 200, 500 μm and 1, 2 mm (7). When installing the plates, a gap (s) is provided between them and the multilayer package, and holes (9) in communication with the air gap for the exit of gas flows are provided in the base of steel 3 (8) fragments-absorbers. The height of the plates, the distance between them and the size of the air gap are selected as follows: h = 11.5 mm; l = 10 mm; s = 9 mm.

All of the claimed features together can reduce the damaging factors of the shock wave, localize large fragments, form high-speed jets (with a high concentration of harmful substances), absorb them and thereby ensure a reduction in the load on environmental objects, reduce the scale of destruction from an explosion, and reduce the yield harmful dispersed particles and increase safety when working with explosive objects.

The ability to achieve a technical result when using the proposed device is confirmed by model experiments conducted with individual fragments of the device, with the explosion of an object containing explosives and radioactive materials. Thus, experiments conducted using prisms and pyramids with an absorbing element in the form of a package of stainless steel nets of various sizes and soft PS-1 polystyrene (ρ = 0.1 g / cm ³ ) showed their high efficiency for the absorption of radioactive materials. The implementation in the inventive device of all the signs in full will allow you to get a new claimed technical result and significantly increase the effectiveness of protecting the environment from explosion products.

Claims (1)

A device for protecting the environment from explosion products, containing a barrier of two layers installed around the explosive object one after another and consisting of fragments of absorbers in the form of pyramids or prisms placed with a radial displacement of fragments of the second layer relative to fragments of the first layer and with a gap between the layers, characterized in that the absorbing fragments of the first and second layers are placed on power metal frames rigidly interconnected, each of the fragments is made of its own meta -crystal frame mounted with its outer surface on the gas flow direction of the plates inside the frame mounted absorbing element consisting of porous material, a density of not more than 0.2 g / cm ^3, and placed on top of it laminate of wire meshes of different sizes, when installing there is a gap between them and the multilayer package, and in the bottom of the absorber fragments there are openings in communication with the air gap for the exit of gas flows, while the height of the plates, the distance between them and elichina air gap are selected from the following relationships:
1,11≤h≤1,21,1,1s≤l≤1,2s
where h is the height of the plates;
l is the distance between the plates;
s is the air gap.

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