RU2273821C1 - Explosion-proof chamber - Google Patents

Abstract

FIELD: provision of safety in transit, liquidation and experimental finishing-off of explosive devices with an energy release up to 60 kg of thermal energy.

SUBSTANCE: the chamber has a body consisting of a cylindrical part and two flat bottoms with conical transitions. The body cylindrical part consists of two coaxially positioned metal pipes, the central part of the inner pipe is made with a thickening, the area between the pipes in the central part is filled with concrete, and in the peripheral sections- with foam concrete. The inner pipe is strengthened from the inside with rings and cones, with ribs positioned between them. Each bottom has a charging opening with a neck; the bottoms consist of an inner and outer plates hermetically coupled to each other, the plates have openings for installation of transfer components of the operating purpose. Each charging opening is hermetically closed from the inside by a convex power metal cover. A sealing component is installed between the inner plate and the cover; the power cover is hinge-joined to the plate with the aid of a bracket, and in the closed position it is fastened to the plate by bolts installed on the outer side of the plate. From the outside the neck is hermetically closed by a cover with the aid of bolts, the sealing components are installed in the cover grooves. An antifragment protection made in the form of layers of a metal net is installed on the inner surface of the cylindrical part and on the power covers. Armored turrets are installed on the openings from the inside on the openings in the cylindrical inserts of the bottoms. A longitudinal beam with a carriage is installed in the upper part of the chamber cavity. The chamber has an expanded range of use and provides safety in transit, liquidation and experimental finishing-off of explosive devices with an energy release up to 60 kg of thermal energy, which may contain ecologically dangerous toxicants; the explosion products are reliably localized inside the chamber without penetration of them in the environment in dangerous concentrations.

EFFECT: expanded range of use and provided reliable localization of the explosion products.

4 cl, 2 dwg

Description

The invention relates to explosive technology and can be used to ensure safety during transportation, liquidation and experimental testing of explosive devices with an energy release of up to 60 kg of fuel cells, which may include environmentally hazardous highly toxic substances.

Known blast chamber with a protective screen, designed for explosive processing of products (AS USSR No. 1064740, class F 42 D 5/00, publ. 01.20.95, BI No. 2).

The camera contains a power shell, including a movable cylindrical body with a bottom, a cover with a lock, a movement mechanism that provides butt flange connection (separation) of the cover with the body, a sealing element with the mating surfaces of the flanges of the cover and the body, removable sections of the protective screen, a desktop located inside the cylindrical corps. Each section of the protective screen is composed of plates with different acoustic stiffness and is fixed by shock-absorbing-damping nodes to the inner surface of the power shell. All sections are mounted so that they form an open protective shield both on the cylindrical and on the end surfaces of the camera shell.

The disadvantages of this camera are:

1) unreliable method of sealing the flange connection of the cover with the housing. Under the influence of an explosive dynamic load, deformation of the components of the shell occurs, at the same time, the joint can open, which worsens the working conditions of the sealing element and, as a result, the explosion products can break through into the environment, which does not allow this camera to be used to detonate explosive devices in it, which include environmentally hazardous highly toxic substances;

2) the range of use of the camera is limited, it cannot be used for experimental testing of explosive devices that require a significant number of passage elements in the camera shell to transmit information about the operation of the explosive device. The presence of passage elements will lead to a change in the shape of the chamber, the design of the sections of the protective screen and the nature of the operation of the main parts of the chamber when exposed to explosive dynamic load;

3) there is a complicated method of connecting (disconnecting) the cover with the body, requiring a special movement mechanism and a lock, while loading an explosive device onto the desktop is possible only from above or from the sides of the camera, which is not always acceptable in conditions of limited access to the camera.

Also known is a container for an explosive device, which is intended to ensure safety during isolation, transportation and liquidation of explosive devices containing an explosive charge of up to 5 kg of TNT (RF patent No. 2087848, class F 42 D 5/04, F 42 B 39/00 Publ. 20.08.97, BI No. 23).

The container contains a cylindrical body with convex bottoms, a neck, a closed lid; a cylindrical sleeve installed in the housing with a wall consisting of layers: inner - of light metal, intermediate - of corrugated sheet of plastic metal and a number of parallel extended elements, outer - of armored sheet of metal. The same set of layers makes up the bottom of the sleeve. The sleeve flange is connected to the neck of a thin-walled, plastically deformable shell. A groove is made in the neck of the body, and an annular cavity in the flange. The lid is provided with two groups of annular elements arranged in series along the longitudinal axis, which are mounted with the possibility of radial movement, while one group of elements is installed with the possibility of placement in the annular groove of the neck of the body, and the other is movably connected to the protective screen and installed with the possibility of placement in the annular cavity of the flange. The free volume between the wall layers and the bottom of the sleeve, as well as between the sleeve and the housing is filled with porous destructible material.

This container is taken as a prototype, as the closest in technical essence to the claimed.

The disadvantages of this container are:

1) the container is leaky, therefore it cannot be used for isolation, transportation and liquidation of explosive devices, which include environmentally hazardous highly toxic substances, i.e. it does not meet environmental safety requirements when such explosive devices are detonated in it;

2) the explosion resistance of the container is insufficient to 5 kg of TNT, which sharply narrows the type of explosive devices to be isolated, transported and eliminated;

3) the range of use of the container is limited, its design does not provide for experimental testing of explosive devices, since this requires a significant number of passage elements in the walls of the container to transmit information about the operation of the explosive device. The implementation of the passage elements in the existing container design will change its shape, which will lead to a different than originally expected, the nature of the work of its main components when exposed to explosive dynamic load.

The technical task to be solved is the creation of an explosion-proof chamber of a wide range of applications, capable of withstanding the explosion of explosive devices in it with an energy release of up to 60 kg of fuel cells, which may include environmentally hazardous highly toxic substances, while ensuring reliable localization of the explosion products without introducing them into the environment into hazardous concentrations.

The stated technical problem is solved in that in an explosive chamber containing a cylindrical metal multilayer body with two bottoms, a loading hole with a neck closed externally by a lid, and anti-splinter protection, the cylindrical metal case is made of two coaxially arranged pipes, with the inner pipe wall in the central its parts are made with a thickening, the space between the pipes in the central part is filled with concrete, and in the peripheral areas with foam concrete, the inner pipe is reinforced from the inside by rings and cones between which the ribs are installed, a loading hole with a neck is also made in the second bottom, each loading hole is hermetically closed from the outside by a cover that is bolted to the neck, and the sealing elements are located in grooves made in the cover; from the inside, each loading opening is hermetically closed by a convex power metal cover, while the convex power metal cover is pivotally connected to the bottom plate of the bottom with a bracket and bolted to it in the closed position from the outside of the plate, and the sealing element is located between the bottom plate and the convex power cover with a metal cover, the bottoms are made of two-layer flat with conical transitions to the cylindrical part of the body and consist of internal and external plates, hermetically sealed o and rigidly interconnected, in the plates there are openings for passage elements for operational use; on the inner surface of the cylindrical part of the body and convex power metal covers there is a shatterproof protection made in the form of layers of a metal mesh; armored caps are installed on the openings in the bottoms for passage elements for operational purposes from the inside of the chamber; in the upper part of the cylindrical body, a beam with a carriage is installed longitudinally inside.

The implementation of a cylindrical metal body of two coaxially arranged pipes, the walls of the inner pipe in the central part with a thickening, filling the space between the pipes in the central part with concrete, and foam on the periphery, reinforcing the inner pipe from the inside with rings and cones, between which ribs are installed, the bottoms are made with two-layer flat with conical transitions to the cylindrical part of the housing, consisting of internal and external plates interconnected hermetically and rigidly, execution in plates holes for passage elements for operational purposes, closing the loading holes from the inside with a convex power metal cover using bolts, closing the mouths of the loading holes from the outside with a cover using bolts, ensures the stability of the chamber walls under the influence of internal dynamic load, while the deformation in the main power elements of the camera (in the central the cylindrical part of the body, along the bottoms, in the zones of conjugation of the conical transitions with the bottoms and the cylindrical part of the body) are but at the same level, indicating that the design of equal strength in areas subject to the greatest impact of explosive loads.

The installation on the inner surface of the cylindrical part of the body and the convex power metal covers of anti-shatter protection, made in the form of layers of a metal mesh, as well as the installation of armored caps on the openings in the bottoms for passage elements for operational use, provides reliable protection of the main load-bearing elements of the chamber from the damaging effects of fragments generated during detonating an explosive device.

The installation of a convex power metal cover on the inner plate with a loading hole from the inside of the chamber ensures the cover is clamped to the plate when an explosive dynamic load is applied to them at the initial moment, which allows the convex power metal cover to be fastened to the internal plate using relatively small diameter bolts, with the opening the joint to a value that worsens the operating conditions of the sealing element installed between the aforementioned plate and the lid does not occur, which ensures reliable joint sealing.

Installing on the neck of the boot holes on the outside of the hermetically sealed cover and fastening it to the neck with bolts creates a second loop for sealing the boot hole, while the sealing elements installed in the grooves of the cover provide reliable sealing of the joint.

The hinged fastening of the convex power metal covers using the bracket to the inner plate of the bottom, as well as the placement of the fixing bolts of the convex metal cover on the outside of the inner plate, makes it easy to open (close) the loading opening.

The implementation of the loading hole with a neck in each of the bottoms can improve the operating conditions of the camera when it is used for its intended purpose, namely:

- provides visual alignment and control of the relative position of the camera and placed inside and outside the camera products;

- simplifies the process of mounting products placed in the chamber.

Performing the required number of holes for passage elements for operational use in cylindrical inserts of the bottoms does not reduce the strength of the chamber and allows you to place inside the chamber the required number of operational equipment controlled outside the chamber.

The presence in the upper part of the cylindrical body inside a longitudinally mounted beam with a carriage allows the installation of products placed inside the chamber.

Figure 1 shows the design of the explosion-proof chamber, figure 2 is a cross section of the chamber.

The camera has a housing 1, consisting of a cylindrical part and two flat bottoms 2 and 3 with conical transitions.

The cylindrical metal casing is made of two coaxially arranged pipes 4 and 5, while the wall of the inner pipe 5 in its central part is thickened, the space between the pipes 4 and 5 in the central part is filled with concrete 6, and in the peripheral sections - with foam concrete 7.

The inner pipe 5 is reinforced from the inside by rings 8 and cones 9, between which ribs 10 are installed. The bottoms 2 and 3 have a loading hole with a neck 11, are made of two layers and consist of an inner plate 12 and an outer plate 13, the plates are sealed together by welding using cylindrical inserts 14, in parts of which holes are made for the installation of passage elements for operational use.

Each loading hole is hermetically sealed from the inside by a convex power metal cover 15. Between the inner plate 12 and the cover 15, a sealing element 16 is installed, the power cover 15 is pivotally connected to the inner plate 12 using an arm 17 (Fig. 2), the power cover 15 is attached to the inner plate 12 is produced by bolts 18. Outside, the neck 11 is sealed by a cap 19 with bolts 20. Sealing elements 21 are installed in the grooves of the cap 19.

The inner surfaces of the cylindrical part of the housing 1 and the power covers 15 are lined with anti-shatter protection 22, made in the form of layers of a metal mesh. On the openings in the flat bottoms 2 and 3, armored caps 23 are installed inside the passage elements for operational purposes. In the upper part of the cylindrical body, a beam 24 with a carriage 25 is longitudinally installed inside.

The explosion-proof chamber is used as follows.

The explosive device is placed in the chamber cavity and suspended from the carriage 25, which is then moved along the beam 24 and the desired position with the suspended explosive device and locked. Install measuring equipment inside the chamber, connect blasting line cables and measuring methods to the explosive device and measuring equipment, which are inserted inside the chamber through openings in the plates of flat bottoms 2 and 3 hermetically using passage elements. The passage elements are covered by armored caps 23. A part of the holes in the plates of flat bottoms 2 and 3 is used to install equipment elements that provide:

- the ability to check the camera for leaks;

- venting the overpressure of the gaseous products of the explosion through the filters after blasting the explosive device and cooling the products of the explosion;

- injection, if necessary, into the inside of the chamber of the preserving solution after venting the gaseous products of the explosion.

After installation of all systems close the power cover 15, then install on the neck 11 of the cover 19.

When an explosive device is detonated, gaseous explosion products and solid fragments propagate axially and radially. The energy of the fragments is extinguished by layers of ballistic protection, the final detention of the fragments occurs in a collision with the internal structural elements of the camera. The energy of the gaseous products of the explosion is extinguished due to the elastic and insignificant plastic deformation of the main power elements of the chamber.

Tests of prototypes of the chamber were conducted. The release of explosion products into the environment using known methods and means of registration was not recorded.

Claims (5)

1. An explosion-proof chamber containing a cylindrical metal multilayer body with two bottoms, a loading hole with a neck closed tightly outside by a lid, and anti-splinter protection, characterized in that the cylindrical metal case is made of two coaxially arranged pipes, the wall of the inner pipe in its central parts made with a thickening, the space between the pipes in the central part is filled with concrete, and in the peripheral areas with foam concrete, the inner pipe is reinforced inside With cones and cones between which ribs are installed, a loading hole with a neck, hermetically closed by a lid is also made in the second bottom, each loading hole is closed from the inside by a convex power metal cover using a sealing element, the bottoms are made of two-layer flat and consist of internal and external plates, hermetically sealed and rigidly interconnected, the bottom plates have openings for passage elements for operational use, the anti-splinter protection is made in the form of layers of metal mesh and is located on the inner cylindrical part of the body and the convex power metal covers, and in the upper part of the cylindrical body, a beam with a carriage is longitudinally installed inside. 2. The explosion-proof chamber according to claim 1, characterized in that the convex power metal cover is pivotally connected to the inner bottom plate with a bracket and in the closed position is fixed to it by bolts mounted on the outer side of the plate, and the sealing element is located between the inner bottom plate and convex power metal cover. 3. The explosion-proof chamber according to claim 1, characterized in that the cap on the neck is bolted, and the sealing elements are located in grooves made in the cap. 4. The explosion-proof chamber according to claim 1, characterized in that the openings in the plates of the bottoms for passage elements for operational purposes are closed from the inside by armored caps. 5. The explosion-proof chamber according to claim 1, characterized in that the bottoms are equipped with conical transitions to the cylindrical part of the housing.

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