RU86726U1 - INSULATING DEVICE FOR EXPLOSIVE OBJECTS - Google Patents

Abstract

1. An insulating device for an explosive object, containing an explosive chamber with a neck mounted on the platform, the loading hole of which is closed by a lid fixed to a trolley moving along the platform guides, a trolley moving mechanism, and an explosive object holder installed in the cavity of the explosive chamber, one end of the holder fixed to the cover, and the other is equipped with rolling bearings for movement in the cavity of the blasting chamber, characterized in that the blasting chamber is equipped with an additional cover, which An open one is installed in the feed opening of the neck with a guaranteed gap and is rigidly fixed by fastening units having plastically deformable elements from the outside of the previously mentioned cover with the formation of a cavity between the covers, each fastening unit is hermetically closed from the outside by a plug made with a cavity whose depth is not less than the estimated maximum strain of the mounting unit, an annular groove is made on the cylindrical lateral surface of the additional cover, barking ring gasket of a resilient material to overlay it in working condition of said guaranteed clearance, said cavity liner as well as the space between the lids are connected with independent channels of high pressure pneumatic source. ! 2. The insulating device according to claim 1, characterized in that the additional cover consists of a flat round metal plate, to which a hollow conical metal plate is rigidly attached through an annular seal, facing outward by the top of the cone.

Description

The claimed device relates to explosive technology and can be used for safe transportation, experimental work or the destruction of explosive objects, including those containing volatile toxic and radioactive substances.

Known container according to US Pat. No. 2087848, publ. Bull. No. 23, 1997, containing a cylindrical multilayer metal body with bottoms and a neck, a closed lid, a cylindrical sleeve with a bottom installed in the body, on the outer surface of which a protective shield in the form of a metal plate is fixed, and a flange connected to the neck of the cylindrical body in the cavity sleeves mounted support element for an explosive device, the lid of the container is equipped with two groups of locking radial ring elements arranged in series along the longitudinal axis and a common mechanism m of their radial movement, while one group of elements is installed with the possibility of placement in the annular groove of the neck of the housing, and the other is movably connected to the protective screen and installed with the possibility of placement in the annular cavity of the sleeve flange.

This container effectively solves the problem of ensuring reliable localization of explosive objects weighing up to 5 kg of TNT during transportation and disposal. But it does not provide sufficient tightness in the event of an explosion of objects containing volatile toxic and radioactive substances.

The closest analogue of the claimed is an insulating device according to US Pat. No. 3797, publ. Bull. No. 4 of 1997. This isolation device for explosive objects contains an explosive chamber mounted on the platform and equipped with a loading hole, a closed lid, an explosive object holder fixed to the lid in the chamber cavity, and a trolley mounted on the platform with the possibility of moving along the rails to it the cover of the explosive chamber and the mechanism for moving the cart, and the holder for the explosive object is equipped with rolling bearings for movement in the cavity of the explosive chamber.

This isolating device not only provides reliable isolation of explosive objects during transportation and disposal, but also increases the safety and efficiency of handling them by mechanizing the processes of loading and unloading objects and the ability to remotely control these processes. But this device does not provide sufficiently reliable tightness in the area of the loading hole when handling objects containing volatile toxic and radioactive substances.

The technical task to be solved is the development of an insulating device that ensures the complete localization of explosion products, including volatile toxic and radioactive substances inside the explosive chamber. Particularly problematic is the exclusion of the output of these explosion products through a large-sized loading neck, which can be achieved only with a complete tightness of the closing of the loading opening of the neck with the cover of the blast chamber.

The expected technical result from the implementation of the device is the environmentally friendly conduct of experimental work, destruction work, as well as transportation of explosive objects, including those containing toxic and radioactive substances.

The stated technical problem is solved by an insulating device containing an explosive chamber with a neck mounted on the platform, the loading hole of which is closed by a lid fixed to a trolley moving along the platform guides, a trolley moving mechanism and an explosive object holder installed in the cavity of the explosive chamber, one end of the holder being fixed to lid, and the other is equipped with rolling bearings for movement in the cavity of the explosive chamber. New in the device is that the blast chamber is equipped with an additional cover, which is installed in the feed opening of the neck with a guaranteed gap and is rigidly fixed by fixing units having plastically deformable elements, on the outside of the previously mentioned cover with the formation of a cavity between the covers. Each mounting unit is hermetically closed from the outside of the additional cover with a plug made with a cavity, the depth of which is not less than the expected maximum value of the deformation of the mounting unit. An annular groove is made on the cylindrical side surface of the additional cover, a hollow annular gasket of elastic material is placed in it with the possibility of overlapping it in the working state of the aforementioned guaranteed gap. In this case, the gasket cavity, as well as the cavity between the covers, are connected by channels with autonomous pneumatic sources of high pressure. The additional cover consists of a flat round metal plate, to which a hollow conical metal plate is turned rigidly attached through an annular seal, facing outward by the top of the cone.

The presence of an additional cover installed with a guaranteed clearance from the outside from the other and rigidly connected to it fastening units having plastically deformable elements excludes the action of large dynamic loads on the additional cover due to the possibility of moving the other cover during crushing or destruction of deformable elements of the fastening units. In this case, the additional cover practically does not receive longitudinal displacement, and the gap seal by the annular gasket is retained. Fastening an additional cover to the aforementioned one with the formation of a cavity between create a buffer zone of increased pressure, which prevents the explosion products from leaving the cavity of the explosive chamber. A cap with a cavity covering the fastening assembly ensures tightness of the cavity between the covers and holds the fastening assembly after the integrity of the deformable element is violated. A hollow annular gasket of elastic material, placed in an annular groove on the cylindrical side surface of the additional cover, eliminates the leakage of explosion products through the gap between the surfaces of the neck and the additional cover. The connection of the annular gasket cavity and the cavity between the covers with high pressure sources by channels allows remote filling of these cavities. The design of the additional cover of flat and conical plates allows you to place the necessary mechanisms inside the conical recess.

Figure 1 shows the device in a state of preparation for loading into an explosive chamber of an explosive object.

Figure 2 shows the area of the loading neck in working condition. The device consists of an explosive chamber 1 having a neck with a loading hole and mounted on a platform 2 with guides 3 for moving the cart 4. The mechanism for moving the cart (not shown) can be either manual or remotely controlled. The lid 5 of the explosive chamber 1 and the end face of the holder 6 for an explosive object are fixed to the trolley 4. The other end of the holder 6 is equipped with rolling bearings 7 for movement in the chamber cavity. The blast chamber is equipped with an additional cover 8, which is installed with a guaranteed gap “B” in the filler opening of the neck on the outside of the cover 5 and is rigidly connected to it by means of fastening units with the formation of a cavity 17 between the covers 5 and 8. Each fastening unit can be made in in the form of a threaded rod 9 passed through an opening in the cover 8, while one end of the pin 9 is screwed into the threaded hole of the protrusion of the cover 5, and a nut 10 is screwed onto the other end, under which a plastically deformable element 11 is placed. Each the mounting unit is hermetically closed from the outside of the cover 8 with a plug 12 made with a cavity, the depth of which is not less than the expected maximum value of the deformation of the mounting unit. An annular groove is made on the cylindrical side surface of the lid 8, into which a hollow annular gasket 16 is made of an elastic material, for example rubber, with the possibility of overlapping the gap “B” in the working state. The cavity of the strip 16 and the cavity 17 between the covers 5 and 8 are connected by channels with autonomous pneumatic sources of high pressure (not shown). The additional cover 8 consists of a flat round metal plate 13, to which a hollow conical metal plate 15, facing outward by the apex of the cone, is rigidly attached through an annular seal 14.

The claimed device is used as follows. The holder 6 is placed subject to transportation or destruction of the object. Using the mechanism for moving the trolley 3, roll it into the explosive chamber 1 and close the filler neck with covers 5 and 8. Excess pressure is supplied through the channels into the cavity of the ring gasket 16 and into the cavity 17 between the covers 5 and 8 from high-pressure pneumatic sources. Moreover, when filling the cavity of the annular gasket 16, its free surface completely covers the gap "B". It is possible to supply excess pressure remotely, which is especially valuable when handling objects containing toxic or radioactive substances. The device is ready to use. Immerse the device with the object on the vehicle and evacuate to the destination for destruction or experimental testing. In the case of an authorized or unauthorized explosion of an object, a pulsed dynamic load propagates in all directions in the cavity of the explosive chamber, including towards the covers that cover the neck. In this case, deformation of the cover 5 and its longitudinal movement can occur. As a result, the load is transferred to the fixing nodes and plastic deformation of the elements 11 occurs to one degree or another, possibly up to failure. But even in this extreme case, the load is not transferred to the cover 8, therefore, it practically does not move and crush the gasket 16, and the tightness of the chamber is maintained due to the overlap of the gap "B". The deformation of the mounting nodes also does not lead to the depressurization of the chamber due to the presence of plugs 12. In addition, the release of volatile toxic or radioactive substances prevents them from the zone of a higher pressure than the chamber between the covers 5 and 8. Thus, the safety task was solved during explosive experiments or the destruction of explosive objects due to the complete localization of explosion products. The technical feasibility of the claimed device was tested experimentally and confirmed its full effectiveness in the detonation of an explosive device weighing 1.5 kg of TNT containing toxic and radioactive substances.

Claims (2)

1. An insulating device for an explosive object, containing an explosive chamber with a neck mounted on the platform, the loading hole of which is closed by a lid fixed to a trolley moving along the platform guides, a trolley moving mechanism, and an explosive object holder installed in the cavity of the explosive chamber, one end of the holder fixed to the cover, and the other is equipped with rolling bearings for movement in the cavity of the blasting chamber, characterized in that the blasting chamber is equipped with an additional cover, which An open one is installed in the feed opening of the neck with a guaranteed gap and is rigidly fixed by fastening units having plastically deformable elements from the outside of the previously mentioned cover with the formation of a cavity between the covers, each fastening unit is hermetically closed from the outside by a plug made with a cavity whose depth is not less than the estimated maximum strain of the mounting unit, an annular groove is made on the cylindrical lateral surface of the additional cover, barking ring gasket of a resilient material to overlay it in working condition of said guaranteed clearance, said cavity liner as well as the space between the lids are connected with independent channels of high pressure pneumatic source. 2. The insulating device according to claim 1, characterized in that the additional cover consists of a flat round metal plate, to which a hollow conical metal plate is rigidly attached through an annular seal, facing outward by the top of the cone.