DE10222344C1 - Container, for transport of explosive devices, e.g. to disposal site, has number of holders to take explosive individually and filling of loose metal balls to absorb any detonation energy from premature explosion in transit - Google Patents

Abstract

Safety receptacle to transport explosive devices comprises a pressure-resistant container with a number of inner holders each to support an explosive device. The container is filled with loose distorting metal pieces, which fill the spaces around the mines/grenades. The holders are at a minimum gap from each other, so that, should a device explode, the released energy from the detonation is dissipated by the loose metal material. Safety receptacle to transport explosive devices, e.g. mines and grenades etc, is a pressure-resistant container (1) with a number of inner holders each to support an explosive device (7). The container is filled with loose distorting metal pieces (6), which fill the spaces around the mines/grenades. The holders are at a minimum gap from each other, so that, should a device explode, the released energy from the detonation is dissipated by the loose metal material to ensure that other devices do not explode in a sympathetic detonation. The loose metal material is in the form of balls with dimensions of 0.3-30.0 mm, and preferably 3-20 mm. The container is rotated around an axis with a horizontal component at a rate of 60 revolutions per hour, to prevent compression of the loose filling, and is supported by dampers during transport.

Description

The invention relates to a transport device for detonable objects, especially grenades.

Detona stocks exist in many areas of the world capable objects, especially grenades, Mines or the like which require disposal. In the In very few cases it is possible or expedient that Dispose of or mitigate at the site. in the general is a transport of the detonatable Objects from the place of discovery to a disposal point conducive. It is hardly practical to detona everyone transportable item on its own; a joint transport of several such items is hardly avoidable. There is always a risk that with an early detonation of a detonation capable chain reaction against the object of detonations of other objects capable of detonation is triggered with a disastrous result.

From US 5 160 468 A is a transport device known for detonable objects that a pressure-resistant containers, a plurality of in the interior of the container arranged brackets and a mixture of stone powder and binder, the mixture molded the energy between the brackets a detonation of an object capable of detonation absorbed such that detonation of the neighboring detonable objects is prevented.

The object of the present invention is a transport device for objects capable of detonation, in particular Grenades, in which the detonation of a detonable object during transport remains without harmful effects.

This object is achieved in that the transport device comprises:

• a) a pressure-resistant container;  
• b) a multiple choice of in the interior of the container arranged brackets, each one detona fix capable object;
• c) a bed of deformable metal pieces, which surrounds the objects capable of detonation and the of this unoccupied interior of the container filling;

in which

• a) the brackets a minimum distance from each other have that in the detonation of a detonations capable energy on the Path between two objects capable of detonation dissipated by deformation of the metal pieces will detonate another detonations capable object is impossible.

The present invention is based on the knowledge that Bulk metal pieces the detonation energy of detonating objects in a confined space can. By maintaining a minimum distance between two objects capable of detonation in the Filling prevents the detonation of a Detonation of a neighboring object that triggers. The required minimum distance is from the detonation energy of the detonable object the, the characteristic dimensions and the material the metal pieces and the temperature. The ent speaking interdependencies are both can be determined theoretically as well as experimentally.

Since according to the invention the container completely with the  Fill of metal pieces is filled and neither these are still the objects capable of detonation because of, the detonation energy cannot be in ki netic energy to be converted; rather it becomes completely by plastic deformation of the metal pieces added. This means that the container themselves only have sufficient compressive strength got to; however, he does not need the impact of himself bodies moving with high kinetic energy th.

The container used as a container or as a body for Designed trucks, railroad cars, ships and planes can be at the site with the detonation capable Objects are loaded and then with the filling filled up from pieces of metal. At the destination the bulk is discharged from the container; then who the detonable objects to the container taken.

The metal pieces are expediently balls or spheroidal. This promotes the flowability of the fill when filling and draining.

The characteristic dimension of the metal pieces, in In the case of metal balls, their diameter should between 0.5 and 30 mm, preferably between 3 and 20 mm.

An embodiment of the invention is particularly preferred dung, in which the container is rotatable about an axis which is a horizontal extension component sitting. By rotating the container during the trans prevents the inside of the Filling located under the influence of the  Gravity compressed downwards.

The speed of the container can be 1 to 60 revolutions conditions per hour.

The container can also move around a horizontal axis be pivotable. It can be filled in this way or emptying upright and during the trans portes are brought into a position at which the axis of rotation obliquely with respect to the vertical or hori stands zontally.

The container is expediently provided with a damping device supported so that transporter vibrations be largely kept away from the container.

In areas where there is strong sunshine, the container should be protected from the sun be provided to prevent excessive heating.

An embodiment of the invention is as follows explained in more detail with reference to the drawing; show it

Figure 1 is a horizontal, schematic section through a container for transporting grenades.

Fig. 2 is a vertical section through the container of Fig. 1, but filled with a bed of metal balls.

On the shown in the drawing and provided with the reference sign 1 rotationally symmetrical or cross-section polygonal container is attached via a flange 8 a domed lid 1 a. The container 1 has a lower, integrally formed and downwardly tapering outlet area 1 b. At the lowest area of the outlet area 1 b, an access nozzle 3 is attached, which can be closed by a detachably attached cover 4 .

A plurality of grenades 7 which are still capable of detonation are located in the interior of the pressure-resistant container 1 . Each of these grenades 7 is spatially fixed by a holding device 5, not shown in the drawing. The holding devices 5 can be bowls, containers or clamping devices which are matched to the size of the grenade. The holding devices 5 can be mounted in racks, which are designed differently with regard to the number of grenades 7 to be accommodated and the distance between them depending on the size. The racks are loaded with grenades 7 outside the container 1 and are introduced into the container 1 and anchored there in the manner described below before transport.

In the illustrated embodiment, the grenades 7 are arranged on four circles, two of which lie in the same axial plane. The circles lying in the same axial plane, as FIG. 1 clearly shows, have a different radius. The angular positions of the brackets 5 and thus also the grenades 7 held by them on the circles, the distance between the circles in one plane and the axial distance between the grenades 7 in the different axial heights does not fall below a certain minimum distance.

As shown in FIG. 2, the entire interior, which is not occupied by the grenades 7 , is filled with a bed of metal balls 6 , in particular steel balls, during the transport of the container 1 . The metal balls have a diameter between 0.5 and 30 mm, preferably between 3 and 20 mm.

The entire container 1 is supported on a frame, not shown in the drawing, that its axis of symmetry can be pivoted ver about a horizontal axis relative to the vertical alignment shown in FIG. 2, so that this axis of symmetry is inclined relative to the vertical or even runs horizontally. A drive device ensures that the container 1 can be rotated around the oblique or horizontal axis of symmetry during transport at a speed which is between one and 60 revolutions per minute. The above-mentioned frame also contains a damping device which largely suppresses the transmission of transporter vibrations to the container 1 .

The described transport device for grenades 7 is used as follows:
At the site of the grenades 7 , these lines are inserted into the holding devices 5 of the above-mentioned racks and the loaded racks are introduced into the initially empty interior of the container 1 via the large access opening 3 which arises after removal of the curved cover 1 a. The Gra naten 7 are now spatially fixed there with the help of the brackets 5 that they have the said minimum distance from each other. Now the domed lid 1 a is placed on the container 1 and firmly connected to it. Then the container 1 with the bed of metal balls 6 is completely filled, the access port 3 being closed by the cover 4 . This is the state shown in FIG. 2. Now the container 1 is pivoted relative to the frame holding it in such a way that the axis of symmetry of the container 1 runs obliquely or horizontally. The container 1 is set in rotation about this symmetry axis and, for example, transported on a truck to the desired disposal point. The rotation of the container 1 is continued and in this way a compression of the bed of metal balls 6 is avoided.

If one of the grenades 7 detonates prematurely during transport, the following occurs:
Since the container 1 is completely filled with the bed of metal balls 6 , movement of parts within the container 1 is not possible. The energy released during the detonation is rather converted into a plastic deformation of the metal balls 6 , which are adjacent to the detonating grenade 7 . The detonation energy is dissipated in this way over a relatively short distance within the bed of metal balls 6 . The energy that reaches the adjacent grenades 7 is not sufficient to detonate them as well. The dreaded chain reaction of detonations cannot occur.

At the destination of the transport, the container 1 is again pivoted into the position shown in FIG. 2, in which its axis of symmetry runs vertically. The lid 4 is removed from the access nozzle 3 and the bed of metal balls 6 is discharged. Then the domed lid 1 a is removed from the container 1 and the racks with the grenades 7 located in the holding devices 5 are removed and fed to the actual disposal.

Claims (9)

1. Transport device for detonable objects, in particular grenades, characterized in that it comprises:

• a) a pressure-resistant container ( 1 );
• b) a plurality of brackets ( 5 ) arranged in the interior of the container ( 1 ), each of which fix a detonable object ( 7 );
• c) a bed of deformable metal pieces ( 6 ) which surrounds the detonable objects ( 7 ) and fills the inner space of the container ( 1 ) which is not taken up by them,

in which

• a) the brackets ( 5 ) have a minimum distance from each other such that the energy released during the detonation of an object capable of detonation ( 7 ) on the way between two objects capable of detonation ( 7 ) is deformed by deformation of the metal pieces ( 6 ), that a detonation of another detonatable object ( 7 ) is impossible.

2. Transport device according to claim 1, characterized in that the metal pieces ( 6 ) balls or ball are similar. 3. Transport device according to claim 1 or 2, characterized in that the metal pieces ( 6 ) have a characteristic dimension between 0.3 and 30 mm. 4. Transport device according to claim 3, characterized in that the metal pieces ( 6 ) have a characteristic dimension between 3 and 20 mm. 5. Transport device according to one of the preceding claims, characterized in that the container ( 1 ) is rotatable about an axis which has a horizontal extension component. 6. Transport device according to claim 5, characterized in that the speed of the container ( 1 ) is one to 60 revolutions per hour. 7. Transport device according to claim 5 or 6, characterized in that the container ( 1 ) is pivotable about a horizon tal axis. 8. Transport device according to one of the preceding claims, characterized in that the container ( 1 ) is held via a damping device. 9. Transport device according to one of the preceding claims, characterized in that the container ( 1 ) has protection against heating by the sun's rays.