RU2053482C1 - Container for isolation and transportation of blasting device - Google Patents

Abstract

FIELD: transportation safety. SUBSTANCE: container for isolation and transportation of blasting device has case with cylindrical part and bulging bottoms. One of bottoms has neck with internal thread for cover. Sleeve formed by bottom in the form of plate and flange with central hole attachably joined to it arc installed in case. Flange and neck are coupled by thin-wall shell which design and material provides for gas-tightness, amortization and plastic deformation under pulse load. Thin-walled shells are fixed between sleeve bottom and screen of aluminium alloy. Insert is placed between bottom of case and screen. Screen in the form of steel is attached in cantilever to cover by means of thin-walled shell. Additional shell is arranged inside this shell and screen overlaps flanges hole closing space of sleeve. Supporting member to fix isolated device is installed in sleeve. EFFECT: improved transportation safety. 3 cl, 1 dwg

Description

 The invention relates to safety issues when handling explosives and devices containing them. The container can be used on board any vehicles, for example, to cross the attempt to carry out terrorist acts, to expand the range of goods transported, including with explosive devices.

 The closest analogue is a container for storing and transporting explosive devices, which contains a cylindrical body with a bottom and a neck, a closed lid, at least one protective shield in the form of a metal convex plate is fixed on the inside of the lid, a cylindrical sleeve with a wall in the form of three coaxial layers: inner metal, intermediate of a gas-permeable energy-absorbing stretchable material and an outer adjacent to the cylinder ndricheskomu housing bottom, on the outer surface of which is fixed a protective shield metal plate, and a flange formed with an aperture diameter equal to the diameter of the shield cover and connected with the neck of the cylindrical body.

 A porous destructible material is placed between the screens and the surfaces to be protected, and an energy-absorbing insert is placed between the protective screen of the bottom of the sleeve and the bottom of the case. A support element is mounted in the cavity of the cylindrical sleeve for fixing the explosive device, and metal belts are additionally installed in the zone of the expected maximum explosion effect, covering the cylindrical surface of the sleeve and covering the inner cylindrical surface of the body.

 This container does not provide reliable localization of the explosive device in the event of a high power explosion due to insufficient damping during the transfer of the impulse load to the body, bottom and cover, or requires a large amplification of these elements, which leads to an increase in size and weight.

 An object of the invention is the creation of a container that allows reliable isolation of explosive devices weighing about hundreds of grams of explosives, surrounded by a shell or ready-made fragmentation elements, at the same time light enough to be accessible for manual handling by 1-2 people in transportation on board an airplane, car, ship. It must be safe for others in the event of an explosion inside the device, seized during attempts to carry out terrorist acts, or during the transportation of explosive goods.

 The problem is solved in that the container contains a cylindrical body with a bottom and a neck, a closed lid, on the inside of which a protective shield is fixed in the form of a metal plate, a cylindrical sleeve installed in a cylindrical body with a wall in the form of three coaxially arranged layers: inner metal, intermediate, formed ring winding of a gas-permeable energy-absorbing tensile material, and the outer adjacent to the cylindrical body, the bottom, on the outer surface of which a protective shield is fixed in the form of a metal plate, and a flange made with an opening whose diameter is equal to the diameter of the protective screen of the cover and connected to the neck of the cylindrical body, and between the cover and its protective screen, the bottom of the sleeve and its protective screen there is a porous destructible material, and between the protective screen of the bottom of the sleeve and the bottom of the housing is an energy-absorbing liner adjacent to the bottom, while in the cavity of the cylindrical sleeve there is a support element for fixing the explosive device, the bottom, the casing and the flange of the cylindrical sleeve are interconnected detachably, the inner layer of the wall is made of gas permeable from light metal, the outer layer of the wall is made of porous destructible material, and guaranteed gaps are formed between the layers of the wall, the connection of the flange of the cylindrical sleeve and the neck of the cylindrical body is made in the form of a thin-walled plastic deformable the metal shell, the fastening of the protective shields to the cover and the bottom of the cylindrical sleeve, respectively, represent each two coaxial but disposed plastically deformable thin-walled metal casing, the outer diameter of which is smaller than the diameter of the screen plate, and porous sacrificial material is disposed inside said shell, wherein the bottom of the cylindrical body is convex.

 The length of the cylindrical part of the body of the container is greater than the depth of the cavity of the cylindrical sleeve, and the support element for fixing the explosive device is made in the form of a shell made of elastic material fixed inside the cylindrical sleeve of the outer ring elements.

 The execution of a sleeve installed inside the case with a wall in the form of three coaxially located shells made of these materials and detachably connected to the bottom and flange allows you to form a closed explosion-proof chamber with equal strength in all directions with a cavity for placing an explosive device in any shell or with ready-made fragmentation elements. The gaseous products of detonation of the explosive formed during the explosion and the fragmentation elements propagate in the chamber cavity in the same direction. Reflecting from the bottom and screen of the cover, they act in a radial direction on the walls of the cylindrical sleeve. In this case, the energy of the leading edge of the gaseous explosion products is dissipated by the inner shell of a light gas-permeable metal, for example, a perforated aluminum sheet with a large perforation coefficient of about 95%. Partially attenuated gaseous products of the explosion and fragments passing through the first shell act on the second shell. Due to the ring winding of the layers, the layer materials radially stretch. As a stretchable gas-permeable energy-absorbing material, fiberglass or organofibre yarns or perforated metal tape, wire winding, wire rope can be used. Shards are captured sequentially in layers. Each layer in the presence of a gap between the layers acts as an attached mass. The successive stretching of materials in each layer and each layer within the gap absorbs the energy of trapped fragments and the process of energy dissipation of gaseous explosion products continues. In addition, the plastic deformation of the material of each layer also takes away the energy of the fragments colliding with it. The intermediate multilayer shell with the fragments absorbed by it collides when it is radially stretched with the last outer shell of a porous destructible material, for example, expanded clay. The energy of the intermediate shell with the attached mass of fragments is attenuated due to the destruction of the elements that make up the outer shell and the remaining energy is distributed in a distributed manner to the container body, posing no threat or integrity to the magnitude or nature of the impact. The perception of axial impulse loading is as follows. Explosion products acting on the steel plate, which is the bottom of the sleeve, and the plate covering the cavity of the sleeve on the opposite side and impacting with them, are reflected in the radial direction. Under the influence of the axial impulse load, some movement of the bottom of the sleeve and the sleeve as a whole occurs. This movement is transmitted to thin-walled cylindrical shells, fixed on one side between the bottom and the plate of the screen and then through the energy-absorbing insert on the convex bottom of the body, and on the other hand, on the shell between the flanges of the sleeve and the body and between the plate, the cover screen and the cover. Due to the plastic deformation of the shells and the deformation of the destructible porous material filling the shell, and the deformation of the liner adjacent to the bottom of the body, the load is sequentially amortized to safe values. The presence of additional shells with filling the gap between the shells with porous destructible material prevents the possible asymmetric crushing of the main outer shells, and therefore the asymmetric transfer of the load to the body and cover in the axial direction. Provided that the sleeve cavity is axially blocked, the protection system from the shells with the filler turns out to be equally strong in all directions for the perception of an internal impulse explosive load.

 The implementation of the cylindrical part of the body with a length exceeding the length of the cavity is adopted in order to bring the place of interface with the bottoms from the zone of greatest loading and, in addition, will provide the possibility of longitudinal movement of the sleeve under the influence of explosive loading. The implementation of the support element in the form of a shell of elastic material with outer ring elements provides a room inside its object of arbitrary shape, preventing its collision with the walls of the sleeve.

 The drawing shows the proposed container in section.

 The container comprises a housing 1 with a cylindrical part and convex bottoms 2 and 3. The bottom 3 is provided with a neck 4 with an internal threaded thread into which the cover 5 is screwed. The housing and the cover are made of steel. Inside the housing 1 there is a sleeve formed by the bottom 6 in the form of a steel plate and detachably connected to it using, for example, studs 7 of the flange 8 with a central hole. The flange 8 and the neck 4 are connected by a thin-walled shell 9 of aluminum alloy. Between the bottom 6 and the flange 8 are placed coaxial shells 10, 11 and 12. The shell 10 is made of light metal, for example, aluminum alloy and is gas permeable due to the high degree of perforation, of the order of 95%. The second shell 11 is a few layers separated by gaps, from gas-permeable stretchable material, for example, perforated metal tape, wire, mesh of organic fibers or glass fiber. The layers are formed by ring winding of the specified material, which allows them to be subjected to radial tension under internal stress. The possibility of radial movement of the layers is provided by the presence of a gap between them. The shell 12 is a filler of a porous destructible material, for example, expanded clay or foam concrete. Thin-walled shells 14 and 15 of plastically deformable material, for example, an aluminum alloy, are fixed between the bottom 6 and the screen 13 of aluminum alloy. In the gap between the bottom 2 of the housing 1 and the screen 13 is placed a liner 16 of energy-absorbing material, for example, foam. A shield 17 in the form of a steel plate is cantilevered to the lid 5 by means of a thin-walled shell 18 made of plastically deformable metal, for example, an aluminum alloy. An additional shell 19 is placed inside the shell 18. The screen 17 completely covers the central hole of the flange 8 so that the cavity of the sleeve is closed. The cavities of the shell 14, 15, 18 and 19 are filled with a porous destructible material 20, the same as the shell 12. Inside the sleeve for fixing the insulated devices, a support element 21 is installed or in the form of rings of elastic material, for example, rubber or a shell of rubber worn on her rings. A rubber sheath is fixed to flange 8.

 The container is used as follows.

 The insulated device is placed through the inlet opening of the neck 4 into the cavity of the sleeve and fixed by the supporting element 21. The cover is screwed into the neck 4. In the case of an explosion of an isolated explosive device, the walls of the cavity are subjected to pulsed loading. In this case, the gaseous products of the explosion penetrate through the gas-permeable shells 10 and 11 into the free volume of the body, gradually weakening. Fragmented elements scattering in the same direction are captured sequentially by the shells 11 and 12, losing energy due to both the amortization of the stretching of the layers of the shell 11 and the movement with the attached mass of fragments within the gaps between the layers. In addition, the energy absorption of the fragments occurs due to plastic deformation of the material inside the layer and upon destruction of the shell material 12. The extinction of energy in the axial direction occurs due to plastic deformation of the shock-absorbing shells 9, 14, 15, 18, 19 and due to the selection of energy for the destruction of the filler 20. The impulse load, weakened to safe values, is transferred to the housing 1 distributed over a larger area of contact with the shell 12 and the liner 16, does not cause destruction of the housing.

 Thus, the task of creating a container suitable for operational isolation and transportation is reliable and safe for others, even in the event of an explosion of an insulated object inside. The container with the indicated advantages is at the same time quite light (for example, with a diameter of 400 mm and a length of 600 mm its weight is 68 kg), accessible for manual handling and transportation by plane, automobile, sea vessels and other modes of transport.

Claims (3)

 1. CONTAINER FOR INSULATION AND TRANSPORT OF AN EXPLOSIVE DEVICE, comprising a cylindrical body with a bottom and a neck, a closed lid, on the inside of which a protective shield is fixed in the form of a metal plate, a cylindrical sleeve installed in a cylindrical body with a wall in the form of three coaxially arranged layers: the inner - metal, intermediate, formed by ring winding of a gas-permeable energy-absorbing stretchable material, and an outer adjacent to the cylindrical body, days ohm on the outer surface of which a protective shield in the form of a metal plate is fixed, and a flange made with an opening whose diameter is equal to the diameter of the protective shield of the cover and connected to the neck of the cylindrical body, and between the cover and its protective screen, the bottom of the sleeve and its protective screen porous destructible material, and between the protective screen of the bottom of the sleeve and the bottom of the body placed an energy-absorbing liner adjacent to the bottom, while in the cavity of the cylindrical sleeve mounted support element for fixing explosive device, characterized in that the bottom, walls and flange of the cylindrical sleeve are interconnected detachably, the inner layer of the wall is made of gas permeable of light metal, the outer layer of the wall is made of porous destructible material, and guaranteed gaps are formed between the layers of the wall, connection of the flange of the cylindrical sleeve and the neck of the cylindrical body is made in the form of a thin-walled plastically deformable metal shell, fastening the protective screens to the cover and the bottom of the cylindrical sleeve ootvetstvenno represent every two coaxially arranged a plastically deformable thin-walled metal casing, the outer diameter of which is smaller than the diameter of the screen plate, and porous sacrificial material is disposed inside said shell, wherein the bottom of the cylindrical body is convex.  2. The container according to claim 1, characterized in that the length of the cylindrical part of the body is greater than the depth of the cavity of the cylindrical sleeve.  3. The container according to claim 1 or 2, characterized in that the supporting elements for fixing the explosive device are made in the form of a shell of an elastic material fixed to the inside of a cylindrical sleeve with outer ring elements.

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