SE502616C2 - Pressure- and splice-resistant shielding device as well as ways of making the same - Google Patents

Abstract

The present invention relates to a blast and splinter-proof device, a so-called blast canister (3, 6), intended to screen off and protect its surroundings against the detonation forces and possible splinters from detonating charges by, on the one hand, absorbing them itself and, on the other hand, deflecting them in that direction most favourable to the surroundings, i.e. in the majority of cases in an upward direction.

Description

502 616 works according to the double principle of deflecting first as large a part of it as possible in the detonation of one of the the same placed explosive charge formed the detonation force and possibly thereby forming splinters in one for the environment harmless direction, ie in most cases upwards, and that second, itself absorb the remaining detonation forces. IN the idea of the invention is that this should not be overpowering without on the contrary having to accept yes even in its construction builds in deformation possibilities that can used to convert the detonation forces into mechanical work. The blasting canister according to the invention is thus gel consumed after a detonation but this disadvantage is outweighed many times over from the fact that it could have been made and relatively inexpensive. In a particularly advantageous construction, the blasting canister consists of several layers spirally wound sheet after the first or first rounds gradually less and less width either rolled inwards or outwards.

This construction only needs to be fastened together with spot welding so that it holds together until it is exposed to one internal detonation. At the rapid course of the detonation namely, it becomes the friction between the plate layers which mainly responsible for the cohesion between the sheet metal layers. Through to manufacture the blasting canister from spirally wound sheet metal, use the high specific strength of the thinner sheet material values while providing a simple manufacturing process and by allowing the plate to have a successively smaller width, i.e. one starts from a mainly triangular platform after that the first lap or laps a blasting canister is obtained with downwards gradually thicker walls. If you now think that the blasting canister is placed around one on or in the ground floor placed charge with its thicker wall part down towards the ground level so you have got an explosive canister with maximum strength in it the part that will be exposed to the greatest strain.

By starting the spiral winding of the plate either with it narrowest or its widest part, blasting can be produced 502 616 nistrar with either a substantially smooth and complete exterior or one essentially smooth and whole inside. This makes it possible to set the blasting canisters in pairs that fit close together and which can be used together as soon as one suspects a single could be in the weakest team. In the same way, several equal pairs are given successively larger diameters so that they fit in each others to facilitate transportation. At equally strong explosive regardless of their own internal diameter, they can be set of equally long spirally wound 'plates but if deflection- the angle from the detonation site seen, i.e. basically the center for the bottom floor of the blasting canister, shall be equally independent of the diameters of the canisters, so must the different pairs of canisters gradually becoming increasingly dependent on its own internal diameters. tern, i.e. they must be made of successively everything wider plates, although these can be kept the same length for all couple. The latter because the detonation force decreases with distance it and the blasting canisters therefore manage with a successive smaller wall thickness as their diameters grow.

In its simplest form, the blasting canister is thus an open cylinder whose largest wall thickness is facing down towards the ground level.

For military use, however, there are so-called jumping mines as of one less propellant charge is thrown up maybe a few meters into the air before they burst. Such a mine could thus jump out the blasting canister if no special measures are taken. According to a somewhat more developed form of the device according to the invention the blasting canister is therefore provided with a fixed grid. roof as if it were sprained along the edges so that it first stretches obliquely up from the upper sheet metal edge of the blasting canister to after forming a substantially flat lattice roof so can its oblique edge part offer a good handle when lifting and shorter transports. In addition, the blasting canister will be on it way good to sit on during breaks at work.

The blasting canister according to the invention has been defined in the subsequent claims and it will now be somewhat further described in connection with some examples. 502 616 Figure 1 shows a longitudinal section through a double blasting canister invention.

Figure 2 shows half the cross section of the same blasting canister.

Figure 3 shows on a smaller scale a plate for the production of the blasting canister according to Figs. 1 and 2.

Figure 4 shows a longitudinal section through an explosive canister kit.

The plate 1 shown in Fig. 3 is obtained after that in Figs marked the division along line 2 two different plates la and lb. As can be seen from the figure, each plate starts with an even width part la 'and lb' of which, however, la 'is somewhat narrower than lb' this in order for the finished blasting canister parts to fit in each other. In addition, it is shielded by the respective canister part. the angle, from the center of its ground plane, essentially equal in this way because the canister with the larger diameter in this case made of the plate lb it also becomes higher. Plague The middle part of the t 1 has been omitted as indicated in the figure because the figure would otherwise have an all too small scale.

As an example, it can be stated that the plate is 10 meters long and 500 mm wide and 2 mm thick.

The plate 1a is now spirally wound from the tip in close comparison. laps where the first lap may, for example, have an inner diameter of 430 mm. When the spiral winding is completed, it has in figure 1 shown inner blasting canister part 3 has been obtained. The different plate var- ven is held together by continuous spot welds marked 4 on the figure. The first two turns may also be edge welded.

This has been marked with 5 in the figure.

The plate 1b is now spirally wound to a second blasting canister part 6 which if we stick to the previously given measurement data can be given an inner diameter of 470 mm and then as shown in Figs. 1 and 2 fit over part 3. The welding markings are the same in all 502 616 rer. At the top, the two blasting canisters are provided with a grid ceilings 7 and 8 respectively in the form of a strong net shaped as one lid with a flat upper surface 7a and 8a, respectively, which cover larger the part of the upper surfaces of the canisters and beveled edge parts 7b respectively 8b. At the outer edges of the edge parts are the nets welded to the respective upper edges of the blasting canister parts.

The blasting canister shown in Figures 1 and 2 is thus ready for use and then it is simply placed over the charge that one wishes to protect oneself and the surroundings against so that the charge ends up in the middle of the canister. If you are sure that the charge is small, only one canister part may be used.

Through its specific manufacturing method, the canister gets its greatest strength and wall thickness closest to the charge, ie closest to the ground level. The use of rolled sheet metal does so too possible to make maximum use of the good specifics of the sheet material strength, which means that the blasting canisters can be made relatively light and at a relatively low price. Since it is mainly the friction between the different plate turns that gets take up the detonation's very fast course so you do not need make some special demands on spot welding and it any edge welding other than to obstruct the plate from rolling up before use.

The lattice roof or net shall in turn prevent the are thrown out of the canister. Otherwise, it is not that big requirements for this. For example, it does not matter if the grille roof is torn broken by the detonation force and splinter only it ensures that the detonation really takes place inside the blasting canister.

Figure 4 shows four different double blasting canisters 9-16 placed ready for transport. These can be made of the same sheet material and of sheets of the same length but successively increased width. 502 616 Of course, several double pairs can be used on top of each other if one suspects that the current charge is extra large.

Claims (10)

502 616 PATENT CLAIMS Pressure- and splinter-resistant shielding device, so-called blasting canisters (3,6) intended to be placed on the ground and there surrounding and protect the environment against the detonation forces and possibly splitter_from on, in the immediate vicinity of or in the ground plane detonating explosive charges of primarily limited strength characterized in that it has the shape of an essentially open cylinder at the ends, the mantle surface of which has a gradually increasing wall thickness in the direction of the end which is intended to face the ground plane. Explosive canisters (3,6) according to claim 1, characterized in that its circumferential surface is made of a number of turns of spirally wound sheet (1a, 1b) which, after the distance corresponding to one or a few turns, is given one from the longitudinal edge to form the end which is intended to face the ground plane gradually less and less width. Explosive canisters according to claim 2, characterized in that the different plate turns (1a, 1b) of the mantle surface are fixed relative to each other by means of continuous spot welding (4) and possibly edge welding (5) along one or a few turns closest to its outside and inside. Explosive canisters according to either of Claims 1 to 3, characterized in that the one of its ends which is intended to be turned away from the ground plane is covered by a strongly welded wire grid (7, 8) for protection against jumping charge. nings. Explosive canister according to claim 4, characterized in that the wire grid (7,8) is formed as a lid with a first plane or in the nearest plane main surface (7a, 8a) which covers most of the upper part of the explosive canister and from 502 616 s this main surface towards the edge of the mantle surface in the form of a truncated cone obliquely tucked-in second edge part (7b, 8b) along whose outer edge the wire grid is welded towards the upper edge of the mantle surface. Explosive canister set (3,6) consisting of two loosely arranged canisters according to either of claims 2-5, characterized in that the inner (3) is spirally wound with the successively tapered part of the plate (1a) facing inwards while the outer (6) is spirally wound with the tapered part of the plate (1b) facing outwards and wherein the distance between the substantially smooth outer side of the inner blasting canister part and the substantially smooth inside of the outer part does not exceed the greatest thickness of the canisters. Explosion canister delivery comprising several canister sets placed in each other, each consisting of two pairs of canisters adapted to each other (9-16) in accordance with claim 6, characterized in that the canisters have a successive height from the smallest innermost to the largest outer canister. Canister delivery according to claim 7, characterized in that all the canisters in the kit are made of equally long spirally wound plates. Method of making blasting canisters according to one or more of Claims 1 to 8, characterized in that they are made of a spirally wound sheet (1) open in dense turns to one end at one end, where the turns are joined by means of spot welding (5). . 10. A method according to claim 9, characterized in that the plate (1) before the spiral winding after a distance corresponding to one or a few full turns is obliquely cut to an increasingly smaller width along one of its edges.