DE4435898C1 - Mobile explosive material disposal plant - Google Patents

Abstract

The mobile explosive material disposal plant has an explosion-proof container (1). It has a closable opening (5) and a container chamber (7) in which a is positioning device (9) for location of an object contg. explosive to be destroyed and a destruction device (11) are arranged. A supply device (13,15,17,19) is incorporated for prodn. of a space air conditioning in the closed container chamber and involves a monitoring system (21), with which the space air conditioning and the destruction process are adjustable and controllable. The support device involves an inert gas feed system (13,15) which supplies the closed chamber with an inert gas. It also involves an evacuation system (17), with which a vacuum is producible in the closed chamber.

Description

The present invention relates to a mobile explosives disposal system.

Mobile explosion chambers are from the general state of the art known. Such explosion chambers consist essentially of one explosion-proof container in which explosives through an opening objects are stored, which then, after tightly closing the Opening in the container chamber can be detonated in a controlled manner.

Such explosion chambers are used wherever explosive devices are found, the free explosion of which is the health of individuals would endanger and disrupt public order.

The explosive is usually contained in an object. Such an object either serves as camouflage, such as B. a piece of luggage or a package, or the functional use, such as B. ammunition. In any case the known explosion chambers designed so that the to be disposed of Explosives, together with his object, in the chamber controlled to explode and then the detonated Material, the so-called residue, in its chemical by heat and pressure, physically and ultimately also physically changed form from the Chamber removed and disposed of as hazardous waste as a whole.

The use of explosion chambers as described above State of the art therefore leads to one only as special waste declaring waste product. Taking into account the fact that such Explosion chambers also for disposal as a result of general Disarmament accumulating large amounts of ammunition can be used wins the correspondingly large amount of the residual waste arising as hazardous waste in importance.

The object of the present invention is therefore a mobile To create an explosives disposal facility that produces residues,  which are classified and sorted and for the most part one Recycle can be recycled to make it as hazardous waste to be reduced to a minimum.

The object is achieved by an explosion-proof Containers with a closable container opening and with a container chamber, in which a positioning device for positioning a to be dismantled explosive object and a disassembly device are arranged, and with a supply device that is used to create a room climate in the closed container chamber is connected to this and a Surveillance system with which the indoor climate and the Disassembly process is adjustable and controllable.

The possibility of using the supply facility in the closed Container chamber to set a room climate, in which a disassembly of the Object, which can be carried out without an explosion, allows the disassembled individual parts, according to their material composition can be classified and sorted. For example, a grenade in its three components explosives, detonator and housing are disassembled so that the metal case is scrapped, the explosives are reused and under certain circumstances only the detonator must be disposed of as special waste.

The explosion-free disassembly leads to a significant reduction in the Residues.

The explosion-free disassembly with the disposal chamber according to the invention also has a much longer lifespan and significantly shorter Operating costs as a result of an explosion chamber of the prior art Technology is the case. Because of the long life of the invention Chamber much larger quantities of ammunition can be disposed of. At conventional explosion chambers every explosion leads to an extreme one Strain on the housing material, and therefore it is costly Material testing after every triggered explosion for safety reasons absolutely necessary.

Further advantageous developments of the mobile according to the invention Explosives disposal chambers are set out in subclaims 2 to 9.  

So it is z. B. according to claim 2 that the advantage Supply device comprises an inert gas supply system with which the an inert gas can be supplied in the closed chamber. So it is possible that Inertize the indoor climate in the chamber. In the inert environment you can the object, for example, using an invention Disassemble the arranged disassembly device into its individual parts. Choosing one Inert gas also leads to better heat dissipation from the chamber and a better decay of the reaction front. A major advantage is also that the production of by-products that are difficult to dispose of is prevented.

An embodiment of the present invention will now be described the drawing described in more detail.

The single figure shows a schematic side view of a container and its functional integration into a mobile explosives disposal facility according to the present invention.

In the figure, a container 1 is shown, which has a container flap 3 on a front side (left in the figure), which is arranged to be pivotable about a horizontal pivot axis (not shown). In the closed position shown in the figure, the container flap 3 tightly closes a container opening 5 . A bayonet lock (not shown) is provided as the locking system.

The container 1 encloses a chamber 7 together with the container flap 3 in the closed position. When the container flap 3 is in an open position (not shown), the chamber 7 is accessible via the container opening 5 . The container opening 5 extends over the entire clear cross section.

A cross table is arranged in the chamber 7 as the positioning device 9 . Objects containing explosives can be aligned and clamped in a predetermined, object-specific manner on the cross table. As a result, they assume a defined position.

A saw is arranged above the cross table as a dismantling device 11 .

Outside the container 1 , a supply device is provided, which is composed of various individual components for supplying the chamber 7 , the cross table and the saw 11 . The components of the supply device essentially comprise an inert gas supply system 13 and 15 , an evacuation system 17 , a heat exchange system 19 and a monitoring system 21 .

The inert gas supply system 13 has a storage bottle 13.1 for the inert gas, the content of which is connected to the chamber 7 via a supply line 13.2 , a shut-off valve 13.3 , a check valve 13.4 and a connection 13.5 . The inert gas supply system 15 has a storage bottle 15.1 for the inert gas, the content of which is connected to the saw 11 via a supply line 15.2 , a shut-off valve 15.3 , a check valve 15.4 and a connection 15.5 . The supply line 15.2 is led through the container wall via a tight connection piece 23 . In addition, the inert gas supply system 15 also has a second supply line 15.6 , which connects the storage bottle 15.1 via a shut-off valve 15.7 , a check valve 15.8 and a connection 15.9 to the cross table 9 . The supply line 15.6 is led through the container wall via a tight connection piece 25 .

The evacuation system 17 essentially has a pump 17.1 , which is connected to the chamber 7 via the line 17.2 and a connection 17.3 in the container wall . A shut-off valve 17.4 is arranged between the pump 17.1 and the container 1 . The structure and mode of operation of evacuation systems and vacuum pumps as such are generally known, so that a further description is omitted here.

The heat exchange system 19 essentially has a pump 19.1 , which is connected on the suction side via a line 19.2 and a shut-off valve 19.3 inserted into line 19.2 to a connection 19.4 in the container wall. On the pressure side of the pump 19.1 , the line 19.2 connects it to a heat exchanger 19.5 . The line 19.2 leads from the heat exchanger 19.5 via a valve 19.6 to a connection 19.7 in the container wall. Flushing lines (not shown) are provided in the container wall, in and / or at the cross table, on the saw 11 and wherever heat dissipation seems reasonable. The principle of cooling by means of heat exchangers is also generally known and will therefore not be explained further here.

The monitoring system 21 comprises a pressure controller 21.1 with redundantly connected pressure sensors (not shown) and a temperature controller 21.2 . In addition, the heat exchange system 19 , the evacuation system 17 and the inert gas supply system 13, 15 are connected to the monitoring system 21 via a control device (not shown). Such a control device is, for example, a commercially available computer (PC) with which different control programs can be executed. It can e.g. B. very different control programs can be used for the different explosives and ammunition types, in which the exact positioning of the object on the cross table, the ideal room climate and the number and orientation of the object-related cutting cuts have been taken into account.

In the event that an object to be disposed of which contains explosives Ammunition, a procedure is described below.

The mobile explosives disposal chamber is assigned to its location, e.g. B. brought a decommissioned ammunition warehouse with old ammunition stocks to be disposed of. In the opened chamber 7 , the ammunition is firmly clamped on the cross table 9 in a defined position. The container 1 is then sealed with the flap 3 . The evacuation system then creates a vacuum in chamber 7 . If it is determined on the monitoring system that the desired vacuum has been reached, this is broken with an inert gas, for example nitrogen. This means that only chemically bound oxygen (rust) is left. The process of this action is monitored and released by the redundantly connected pressure transducers. The release starts a pneumatically driven circular saw 11 . Nitrogen under a pressure of 7 bar is used as the pressure medium.

The circular saw 11 executes several cuts fully automatically in accordance with the control program selected depending on the ammunition. In general, the impact detonator is first separated. Then the cross table 9 is moved pneumatically. In the pneumatic drive of the cross table, an inert gas, such as. B. nitrogen, used as a pressure medium. The cross table is also moved according to the program. After moving the cross table, the propellant charge is sawn off. Finally, one or more housing cuts are made depending on the ammunition.

After the control program has ended and the inert gas has been removed, the opening of chamber 7 is released. The disassembled components can be removed from chamber 7 .

During the separation process, the gas temperature in the chamber 7 is constantly monitored by the temperature control 21.2 . If the temperature rises above 40 ° C, nitrogen is blown off and replaced with cold nitrogen.

The chamber 7 or the container 1 is made explosion-proof. In the embodiment described, the chamber is explosion-proof for 10 kg of TNT and has a volume of approx. 1 m³. The outer shape is almost spherical.

Claims (9)

1. Mobile explosives disposal system, characterized by an explosion-proof container ( 1 ) with a closable container opening ( 5 ) and a container chamber ( 7 ) in which a positioning device ( 9 ) for positioning an object to be dismantled and a dismantling device ( 11 ) are arranged, and with a supply device ( 13, 15, 17, 19 ) which is connected to the closed container chamber ( 7 ) in order to produce a room climate and which comprises a monitoring system ( 21 ) with which the room climate and the dismantling process can be set and controlled. 2. Mobile explosives disposal system according to claim 1, characterized in that the supply device ( 13, 15, 17, 19 ) comprises an inert gas supply system ( 13, 15 ) with which the closed chamber ( 7 ) can be supplied with an inert gas. 3. Mobile explosives disposal system according to claim 1 or 2, characterized in that the supply device ( 13, 15, 17, 19 ) comprises an evacuation system ( 17 ) with which a vacuum can be generated in the closed chamber ( 7 ). 4. Mobile explosives disposal system according to one of the preceding claims, characterized in that the supply device ( 13, 15, 17, 19 ) comprises a heat exchange system ( 19 ) with which the heat generated in a dismantling process can be dissipated. 5. Mobile explosives disposal system according to one of the preceding claims, characterized in that the positioning device ( 9 ) is a cross table on which the object can be fixed in a defined direction. 6. Mobile explosives disposal system according to one of the preceding claims, characterized in that the monitoring system ( 21 ) controls the setting and control of the room climate and the disassembly process fully automatically depending on the object and explosives. 7. Mobile explosives disposal system according to one of the preceding claims, characterized in that the dismantling device ( 11 ) is a saw with a pneumatic drive, the pressure medium used being inert. 8. Mobile explosives disposal system according to one of claims 2 to 7, characterized, that the inert gas is nitrogen. 9. Mobile explosives disposal system according to one of the preceding claims, characterized in that the supply device ( 13, 15, 17, 19 ) has a check valve ( 13.4, 15.4, 15.8 ) at a connection ( 13.5, 15.5, 15.9 ) with the container ( 1 ) .