RU2227266C1 - Device for localization of action of explosive mechanisms - Google Patents

Abstract

FIELD: engineer devices applicable for provision of safety at detection and disposal of explosive mechanisms and storage of blasting charges. SUBSTANCE: the device has peripheral and upper vessels of elastic material. They are filled with a dispersing agent and form a working cavity open from the bottom for placement of the explosive mechanism. Provision is made for a device for shielding of fragments and an appliance for carrying or transportation by a robot. In the upper vessel positioned above the working cavity provision is made for a through hole closed with a detachable stopper for introduction of observation instruments in the working cavity, diagnostics and/or destruction of the explosive mechanism. The peripheral vessel is made with a slope of the inner wall to the horizontal plane at an angle of less than 90 deg. on its entire height or on its largest section, mainly with a curvilinear generating line, which imparts a bowl shape to the working cavity. A grate is installed on the upper end of the peripheral vessel, which limits the deflection of the lower wall of the working cavity with the walls of the hole and stopper or the mentioned instruments downwards relative to the horizontal position under the action of gravitational, inertial forces and/or vertical outer load on the stopper and instruments. EFFECT: enhanced safety and efficiency of localization of the action of explosive mechanisms. 6 cl, 3 dwg

Description

The invention relates to engineering devices designed to ensure safety in the detection and disposal of explosive mechanisms (BM) or the safe content of explosive charges, and can be used to effectively suppress fragmentation, high explosive and thermal effects of an explosion.

Known methods and devices for attenuating a shock wave (HC) using foam or porous materials, but without using any additional quenching mechanisms [1, 2]. However, either their effectiveness is insufficient, or their use is associated with the need for large volumes of consumables, time and place, which greatly complicates the possibilities and limits the scope of practical application.

Liquid hydrocarbon localizers are widely used, for example, LBA System Bomb inhibitors [3] and Fontan series products [4], which are containers consisting of chambers with an elastic shell filled with a non-combustible liquid (liquid dispersant).

This group of localizers can also include a device with a U-shaped, in vertical section, a screen of porous open-cellular material (in particular, foam rubber) filled with a non-combustible liquid [5].

When used, these devices are installed in such a way that they shield from the sides and top of the VM (or a suspicious object). In the case of VM operation, a significant fraction of the explosion energy is spent on the deformation and destruction of the localizer.

Common drawbacks of such devices are the insufficient degree of hydrocarbon blanking and trapping fragments, as well as the difficulty in diagnosing a suspicious object covered by the device, while it is necessary for disposal and subsequent liquidation.

Closest to the claimed invention in terms of purpose and a set of essential structural features is a device for localizing the effects of explosive mechanisms, containing at least peripheral and upper containers of elastic material filled with dispersant and forming an open working cavity from the bottom to accommodate an explosive mechanism, a shielding device for fragments and a device for carrying or transporting by a robot, and in the upper container located above the working cavity, it is provided a through hole bounded by a removable plug, bounded by the walls, for introducing observation devices, diagnostics and / or destruction of the explosive mechanism into the working cavity [6].

In it, the peripheral capacity is made in the form of a horizontally arranged torus and, therefore, the inner wall (in vertical section) forming it is a semicircle with a bulge towards the working cavity of the device. Therefore, the wall at the first half of its height is inclined to the horizontal plane at a variable angle from 180 to 90 °, and at the second half of its height - at a variable angle from 90 ° to 0. The ceiling of the working cavity is the elastic upper wall of the upper tank (mainly) and end cap of the hole (in the smaller part). As a dispersant (a substance that absorbs explosion energy), a non-combustible liquid (in particular, water) is used, with which both containers and the plug of the hole are filled. The shielding device for the fragments is made in the form of an anti-fragmentation screen in the form of a “skirt” fixed along the contour of the peripheral part of the upper tank and completely located outside the device.

This known design, characterized by the presence of holes in the upper container, partially removes the problem of observation, diagnosis and / or destruction of a suspicious object.

However, this design has several disadvantages. As in close analogues, localization is limited due to the fact that the device has a closed hemispherical shape (with an axisymmetric design). When the VM is triggered, the resulting force of the direct and reflected shock wave throws the device up, opening the working cavity along the plane of the surface on which it is installed, and forming an annular gap. This is facilitated by the described shape of the wall of the working cavity, especially its inclination at an angle of more than 90 ° at the lower half of the height. The situation is aggravated when the VM is located in the lower part of the working cavity. Since the velocity of the explosion products is much higher than the velocity of the expansion of fragments, through the gap formed, the explosion products expire and the fragments expand into the surrounding space along a flat path with an expansion angle of up to 20 ° without reducing their kinetic energy. In addition, a decrease in pressure of 10-15 times can lead to temporary hearing loss and other barotrauma.

When the device is installed in the working position (localization of a suspicious object), deflection of the ceiling of the working cavity increases the likelihood of mechanical impact on the suspicious object, especially under vertical dynamic loads, highly probable in extreme installation conditions, inevitable subjective factor, and probable emergency situations. Naturally, the indicated mechanical effect significantly increases the likelihood of VM initiation.

The constructive solution of the through hole for introducing into the cavity devices for observing, diagnosing, and / or destroying the BM also requires careful action by the fuse. Otherwise, vertical external forces, primarily associated with the introduction of devices into the hole and their removal from there, as well as with manipulations with the plug, lead to an increase in the deflection of the ceiling of the working cavity, which is already substantially bent by the force of gravity of the dispersant (liquid) and walls. Accordingly, the likelihood of mechanical impact on a suspicious object increases even more.

All this reduces the level of security both during unauthorized operation of the VM, and when installing the device (localization of a suspicious object), when diagnosing a suspicious object and neutralizing the VM. Given these factors, the operation of such devices requires the use of additional safety features.

The task to which the claimed invention is directed is to increase the efficiency of localization of high-explosive and fragmentation explosive mechanisms, reduce the damage from the possible operation of the VM when they are detected, increase the safety of work without reducing the degree of protection of the explosive personnel and material assets during the disposal of the VM.

The solution to this problem is achieved by the fact that in a device for localizing the effects of explosive mechanisms containing at least peripheral and upper containers of elastic material filled with a dispersant and forming an open working cavity below to accommodate an explosive mechanism, a shielding device for fragments and a device for carrying or transported by a robot, and in the upper tank located above the working cavity, there is a through closed with a removable plug, bounded by the walls of the hole e for the introduction of observation devices, diagnostics and / or destruction of the explosive mechanism into the working cavity, the peripheral container is made with the inner wall inclined to a horizontal plane at an angle of less than 90 ° at its entire height or its greater part, taking into account static deformation in the assembled device, mainly with a curvilinear generatrix, giving the working cavity of the device a cup shape, and on the upper end of the peripheral container, directly below the upper tank, there is a lattice limiting the deflection of the lower wall of the upper container with the hole wall and the plug or the said devices down to the horizontal position under the action of gravity, inertia and / or the vertical load on the outer cover and instruments.

The problem is also solved due to a number of additional structural features of the device (based on the combination of the main essential structural features described above), namely:

- the peripheral capacitance can be formed by forming chambers, while the dispersant of the peripheral capacitance is placed mainly in the forming chambers, thereby achieving the shape of the working cavity wall in the recommended range, as well as improving the conditions for the absorption of hydrocarbons and reducing the kinetic energy of fragments; the implementation of the form-forming chambers toroidal allows you to further improve the conditions for the absorption of hydrocarbons due to the peculiarities of the deformation of the toroidal bodies under radial mechanical impact on them, and also improves the manufacturability of the design and ease of use;

- the implementation of the lattice with an annular stiffener, which is located in the device directly under the end of the walls of the hole and is geometrically commensurate with the horizontal projection of the specified end, increases the safety of the device in the mode of “observation, diagnosis and / or destruction” by fixing the end of the walls of the holes of the specified annular stiffener lattices during manipulations with a plug and devices;

- in particular, it is recommended that the lattice be made in the form of a rubber-fabric chamber filled with air or a non-combustible liquid under pressure, and consisting mainly of concentric tori, one of which, namely the inner one, is the ring stiffener mentioned above, and tubular, radially oriented jumpers between them, while the cavities of the tori and jumpers are interconnected, as a result of which the formation of secondary fragments during the explosion is excluded, unlike metal, plastic, etc. gratings;

- attaching the lattice to the peripheral container, making horizontal overall dimensions, in particular diameter, of the lattice at least equal to the maximum horizontal overall dimensions, in particular diameter, containers, and making devices for carrying or transporting on the lattice, mainly in the form of two or more horizontal brackets for manual gripping, located symmetrically with respect to the central vertical axis of the device, loading and unloading and transport are facilitated and simplified wka to a suspicious subject;

- the free installation of the upper tank on the grate significantly facilitates its priority tossing of the shock wave and a significant part of the explosion energy and VM fragments is discharged in a relatively safe upper direction, and by the presence of a set of additional, replaceable upper containers, including, for example, an upper container without a hole, upper containers with a built-in one of the mentioned devices and an upper tank with a different type of dispersant and / or with a different energy absorption capacity expand the possibilities of operating second mode "monitoring, diagnosis and / or destruction" through a more convenient and secure, in some cases, replace the upstream vessels taking into account the specific functionality, as well as VM various capacities localization capabilities.

Among the known devices were not found those whose combination of essential features would coincide with the declared one. At the same time, it is due to the latter that a new technical result is achieved in accordance with the task.

The inventive device for localizing the effects of explosive mechanisms is shown in the drawings:

figure 1 shows the device Assembly, in the operational mode "standard localization", a vertical section along the axis of symmetry, where: α is the angle of inclination of the inner wall of the peripheral container to a horizontal plane; h is the height of the working cavity of the device; D ₁ - variable in height h horizontal size (diameter) of the working cavity of the device; D _2max - the maximum horizontal size (diameter) of the capacities of the device; d _o - the average diameter of the end wall of the hole in the upper tank; F - gravity, inertia and / or vertical external load on the plug holes and devices;

figure 2 is a fragment of a design variant of the peripheral container with three toroidal forming chambers with dispersant, a vertical section along the axis of symmetry;

figure 3 is an example of the design of the lattice (with an annular stiffener and a device for carrying or transporting), a plan view, where d _to - the average diameter of the annular stiffener lattice;

A device for localizing the effects of explosive mechanisms (see Fig. 1) contains a peripheral container 1 and an upper container 2 of elastic material (eg rubber), closed in a horizontal plane along the contour. The containers 1, 2 are filled with a dispersant, for example a non-combustible liquid (water), as in the prototype, and / or a granular, granular substance that effectively absorbs the energy of the explosion. Capacity 2 is located above the capacity 1. Their horizontal size (diameter) is equal to D _2max .

A container has a through hole bounded by walls 3 (impermeable to liquid dispersant, in any case, when used) with an average end diameter d _o and designed to monitor, diagnose and / or destroy a suspect object with an explosive mechanism (see . Further). In the “standard localization” mode, the indicated hole is closed by a removable plug 4, for example, a container filled with a liquid dispersant, and in the “observation, diagnostics and / or destruction” mode it is open for visual observation or closed (partially or completely) by an instrument for monitoring, diagnostics, and / or destruction (not shown).

At the upper end of the container 1, directly below the container 2, a grill 5 is horizontally mounted, made rigid for deflection and, accordingly, limiting the deflection of the lower wall of the container 2 with the walls of the hole 3 and the plug 4 or the mentioned devices downward relative to the horizontal position under the action of gravity, inertia forces F and / or vertical external load on the plug 4 and devices.

To reduce the possible local deflection, it is preferable to perform a lattice 5 with an annular stiffener 6 with an average diameter d _k (see Fig. 3) located directly below the end of the walls of the hole 3. In this case, d _k ≈ d _o and element 6 is geometrically proportional to the horizontal projection end of walls 3.

In order to avoid the formation of secondary fragments during the explosion, it is recommended that the lattice 5 be made in the form of a rubber-fabric chamber formed by the external 7 and internal 6 (the mentioned ring element) tori and tubular, radially oriented jumpers 8 between them, and the cavities of the tori 6, 7 and jumpers 8 are interconnected and filled air or a non-combustible liquid (liquid dispersant) under a pressure above atmospheric. To fill cavities 6-8, a lockable filling hole (not shown) is provided.

In principle, it is possible that additional containers with dispersant (not shown) are available in a volume free of the volume occupied by containers 1, 2, plug 4 and filled with air or liquid dispersant variant of the grill 5.

The inner walls of the container 1 and the lattice 5 (taking into account the configuration of the lattice 5 and static deformations) form a working cavity 9 for placing a suspicious object 10 with a suspected explosive mechanism (VM) 11. The possibilities of placing the object 10 in the cavity 9 are determined by the dimensions of the latter: height h and variable longitudinal dimension (diameter) D ₁ .

Capacity 1 is mandatory made with the inclination α of the inner wall to a horizontal plane at an angle of less than 90 ° at its entire height h or its greater part (taking into account static deformation in the assembled device).

This can be achieved, for example, by performing a container 1 with radial and, possibly, other partitions (stiffeners - shown in Fig. 1 on the left by hatching).

In the particular embodiment shown in FIG. 2, inside the container 1 are three toroidal forming (i.e., giving the container 1 volume and shape) chambers 12-14 of different at least diameters. The liquid or granular granular dispersant of the container 1 is located mainly in these chambers 12-14. When the “pyramidal” layout of the chambers 12-14 in the tank 1 (see figure 2), the inner wall of the tank 1 acquires, in a vertical plane, curvature with a convexity inward (i.e., the generatrix of the wall is directed towards the middle part of the internal volume of the tank 1) .

It is desirable that the curvilinear generatrix gives the working cavity 9 of the device a cup shape, which is the case in the structures of FIGS. 1, 2.

In the recommended embodiment of the device, the grill 5 is attached by any known means, for example, glued and / or sewn, fastened with straps with the span of tubular jumpers 8 to the container 1. It is also recommended that the lattice 5 be made with horizontal overall dimensions (outer diameter) equal to or slightly greater than D _2max .

In this case, it is advisable to perform (in whole or in part) devices for carrying or transporting the device by the robot directly on the grill 5, mainly in the form of two or more staples (handles) 15 (see Figs. 1, 3) for manual gripping or for special gripping (you) the robot. The brackets 15 should be located, as a rule, symmetrically with respect to the central vertical axis of the device.

It should also be considered rational to secure the skirt type 16, borrowed from the prototype, (of course, if any) on the grill 5.

In any of the considered design options, the tank 2 is installed on the grate 5 (with a grating size of at least D _2max ) or directly on the tank 1 (with a grating size of 5 less than D _2max ) either freely (more preferred option) or with a relatively weak relationship allowing the possibility of unimpeded or almost unimpeded movement upward under the influence of the triggered VM 11.

With the free installation of the container 2, the device for carrying or transporting may include (for more reliable “transport” integrity), in addition, a lightweight fabric cover of the device, straps, belts, etc. (not shown).

A set of additional, replaceable (with identical seats) upper containers may be provided, including, for example, an upper container without an opening, upper containers with a built-in one of the aforementioned devices and an upper container with a different type of dispersant and / or with a different energy absorption capacity (not shown )

The design options described above do not exclude other possible options within the scope of the claims.

The device operates as follows.

Choose a device size whose working cavity 9 shape approximately corresponds to the shape of a suspicious object 10, and the dimensions h and D ₁ obviously exceed the corresponding dimensions of the object 10. Take into account, if possible, the a priori estimated (probable) power of the VM explosion. So, in the presence of a set of interchangeable upper containers, which include containers with a dispersant of various energy absorption capacity, choose the appropriate one. Transfer (transport) the device to item 10, using brackets (handles) 15, and carefully, gently cover it so that it is located at approximately equal distance from the wall (s) of cavity 9 in azimuth, and the gaps between the lower end of the tank 1 ( the bottom of the device) and the supporting surface were minimal. Since the brackets 15 are made directly on the lattice 5 as the most rigid device construct, and the lattice 5 is attached to the peripheral container 1, the device is mixed in space as a whole. This contributes to the cover. Due to the high stiffness of the lattice 5, the lower wall of the tank 2 under the action of gravity and inertia forces F does not significantly bend (does not “sink”) into the working cavity and, therefore, there is no threat of unforeseen mechanical impact (force contact) with the object 10.

With the free installation of capacity 2, it can be installed later (after the initial visual examination of subject 10) or removed and put into a regular place after the specified visual examination.

Then carry out the following regulated organizational measures to ensure security when VMs are detected.

If necessary, conduct an observation (if the primary observation described above was not carried out by an explosion technician or for other reasons), diagnose and / or destroy the object 10, the explosion technician removes the plug 4, inspects the object through the hole and inserts the corresponding device (optical, infrared, x-ray and etc.). If the destruction of the object through the hole was not made, then the explosion technician installs plug 4 in its regular place and is removed to a safe distance. Due to the relatively high rigidity of the lattice 5, the vertical movements of the plug 4 and devices, especially when they are rubbed against the walls 3 of the hole, do not lead to a significant deflection of the lattice 5 down from its horizontal position.

In the presence of a set of removable upper tanks, which includes containers with built-in devices that correspond to the next operations, an explosion engineer can, instead of manipulating devices inserted into the hole, replace the upper tank 2 with other additional ones.

In case of authorized or unauthorized operation of BM 11 and subsequent explosion, the resulting (jointly direct and reflected) shock wave, acting on the wall (s) of the tank 1, presses it due to the acute angle α and the concavity of the cavity 9 from the side (i.e., due to its cup shape), to the supporting surface, preventing the inherent prototype from tossing the device upward with opening of the cavity 9 along the plane of the supporting surface and the formation of an annular gap. Accordingly, the formation of the specified gap is reduced or completely eliminated, and hence the expiration of the explosion products and the expansion of fragments through the gap into the surrounding space along a lay trajectory, as well as the likelihood of barotrauma.

The resulting HC, directed upwards, raises a freely installed or easily fixed tank 2, opening the conditionally closed working cavity 9 and providing an overpressure discharge, i.e. in a less dangerous direction. It also prevents the inherent prototype from jumping the entire device.

The aforementioned phenomenon of preloading of the container 1 to the supporting surface also contributes to the described separation of the container 2.

The “lattice” of the body 5 (see the shape of the lattice 5 in FIG. 3) allows the shock wave to act directly on the lower wall of the tank 2 over its larger area.

The shock wave is extinguished during interaction with the elastic walls of tanks 1, 2, 4 and their internal structure. The bulk of the explosion energy is absorbed by the dispersant. More specifically, the exothermic process associated with the HC causes an inverse high-speed endothermic reaction of the granular and / or liquid dispersant and a significant dissipation of the energy of the explosion. Since the amount of energy absorbed as a result of the endothermic reaction is commensurate with the amount of energy released during the explosion and is directly proportional to the mass of the dispersant. The materials of the device together suppress the thermal effect of the explosion, preventing burns to people and burning of objects. In addition, a reduction in fragmentation is ensured by reducing the initial energy of the fragments. The secondary and most significant braking of the VM 11 fragments occurs when they interact with the screen 16.

Thus, the use of the inventive device allows, in accordance with the task, to increase the efficiency of localization of fragmentation and high-explosive impact of the VM, to reduce the damage from the possible operation of the VM when they are detected, to increase the safety of work without reducing the degree of protection of explosive personnel and material assets.

Sources of information taken into account:

1. Kudinov V.M., Palamarchuk B.I., Gelfand B.E., Gubin S.A. Parameters of shock waves during the explosion of an explosive charge in foam // “Doklady AN SSSR”, V.228, 1974, No. 4. - S. 555-558.

2. Gelfand B.E., Gubanov A.V., Timofeev E.I. Interaction of shock air waves with a porous screen // Izvestia AN SSSR, MZHG, 1983, No. 4. - S. 79-84.

3. US 4836079 A, 06/06/1989.

4. RU 2125232 C1, F 42 B 39/00, 33/00, 09/23/1997.

5. RU 2150669 C1, F 42 B 33/00, F 42 D 5/04, 03/15/1999.

6. RU 2150670 C1, F 42 B 33/00, F 42 D 5/04, 03/15/1999 (prototype).

Claims (6)

1. A device for localizing the effects of explosive mechanisms, containing at least a peripheral and upper containers of elastic material, filled with dispersant and forming an open bottom working cavity for placing an explosive mechanism, a shielding device for fragments and a device for carrying or transporting by a robot, and in the upper of the container located above the working cavity, a through hole, bounded by the walls, closed by a removable plug for introducing testing, diagnostics and / or destruction of the explosive mechanism, characterized in that the peripheral container is made with the inner wall inclined to a horizontal plane at an angle of less than 90 ° at its entire height or its greater part, taking into account static deformation in the assembled device, mainly with a curvilinear generatrix , giving the working cavity of the device a cup-shaped form, and on the upper end of the peripheral container, immediately below the upper tank, there is a lattice limiting the deflection of the lower wall of the upper tank with by the hole tenks and the plug or the above-mentioned devices downward relative to the horizontal position under the action of gravity, inertia and / or vertical external load on the plug and devices. 2. The device according to claim 1, characterized in that the peripheral capacity is formed by forming chambers, mainly toroidal, while the dispersant of the peripheral capacity is placed completely or mainly in the forming chambers. 3. The device according to claim 1, characterized in that the lattice is made with an annular stiffener, which is located in the device directly under the end of the walls of the hole and is geometrically proportional to the horizontal projection of the specified end. 4. The device according to claim 3, characterized in that the lattice is made in the form of a rubber-tissue chamber filled with air or a non-combustible liquid under pressure and consisting mainly of concentric tori, one of which, namely the inner one, is the said ring stiffener, and tubular, radially oriented jumpers between them, while the cavities of the tori and jumpers are interconnected. 5. The device according to claim 1, characterized in that the lattice is attached to the peripheral container, the horizontal overall dimensions, in particular, the diameter of the lattice, is at least equal to the maximum horizontal overall dimensions, in particular, the diameter of the containers, and a device for carrying or transporting the robot is made on the grill, mainly in the form of two or more horizontal brackets for manual gripping, located symmetrically relative to the central vertical axis of the device. 6. The device according to claim 1 or 5, characterized in that the upper tank is installed on the grill freely and a set of additional, replaceable upper tanks is provided, including, for example, an upper container without a hole, upper containers with an integrated device from the number mentioned and an upper container with a different type of dispersant and / or with a different energy absorption capacity.

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