SE501138C2 - Method and apparatus for the destruction of explosive-filled objects or bodies - Google Patents

Abstract

The present invention relates to a method and a device for destruction of explosives-filled objects or bodies (g, G) such as shells and other types of warheads, propellant charges, hand grenades, anti-personnel mines etc. in that these, while they are in a state of free fall through a bursting chamber, are initiated to detonation from a distance within the bursting chamber by an energetic radiation such as a pulsed high-power laser (31) or a projectile, or alternatively via a delayed-action charge before being fed into the bursting chamber, whereafter explosive gases formed in such operation are removed from the bursting chamber.

Description

According to the invention, the explosive-filled objects or bodies are destroyed by detonating them while they are in free fall through an explosion chamber adapted thereto.

The initiation of the explosives contained in the respective objects or bodies for detonation can then take place either at a distance while the object or body is already in free fall through the explosive chamber or by means of an initiation charge which contains a time delay and which is initiated before the free fall. is initiated but which, due to its built-in time delay, initiates the main charge only after the explosive-filled object or body has reached its intended position in the explosion chamber during its free fall.

A remote initiation according to alternative one can be carried out, for example, by means of an energetic radiation directed towards the explosive charge, such as a pulsed high-energy laser. In this case, it can be aimed directly at the charge surface of an explosive capsule or equivalent with which the original explosive-filled object or body has been completed. If the explosive-filled object or body then consists of a grenade or other type of warhead, this detonator can, if required supplemented with a smaller booster charge, be placed in its ordinary spark plug opening.

Another way to initiate the actual explosive charge while it falls through the detonation chamber is to replace the detonator with a corresponding one containing a tear-sensitive charge against which a projectile is fired while it and the charge fall through the chamber. In both of these variants with distance initiation, it applies that the detonators can be supplemented with a time delay so that a protective hatch has time to close after the initiation of the detonator but before the main charge is initiated.

In the alternative of initiating a time-delayed initial charge before the explosive-filled object or body begins its trajectory through the detonation chamber but where the detonation of the main charge takes place during this trajectory, a time-delayed detonator complemented by a percussion cap initiated by a corresponding igniter may be provided.

The basic principle behind the invention is thus that the explosive filling contained in the respective objects or bodies must be initiated while they fall freely through the explosive chamber. This provides maximum disintegration of the objects or the outer casings of the bodies at the same time as a complete destruction of their charges. This relatively fine disintegration facilitates the continued recovery of the scrap metal, among other things by making it easy to remove from the explosion chamber. In order to enable the objects or bodies' explosive charges to be initiated at the correct point in their trajectory through the blast chamber, it is further proposed, firstly, that if the initiation is to take place at a distance according to alternative the energetic radiation or projectile responsible for initiating the explosive charges, this shall be switched on or fired only when the object or body during its free fall through the chamber reaches a predetermined position in it. Secondly, that the switching on of the energetic radiation or the firing of the projectile is controlled by either a measuring system which follows the fall of the object or body through the blasting chamber, for example in the form of a measuring laser, microwave transmitter or ultrasonic meter or a system coils, photocells or otherwise state that the object or body has passed a certain point in its orbit. Thirdly, it is proposed that each explosive charged object or body to facilitate the initiation of its main charge before supply to the detonation chamber be provided with an initiating charge consisting of a booster charge and an detonator open in the direction of the energetic radiation so that the radiation can act directly against the detonator. it must be initiated with a projectile fitted with an upper tear-sensitive charge. When it comes to destroying ammunition such as grenades or other combat parts in the manner characteristic of the invention, the initial charge can often be advantageously placed in the opening previously intended for the product's ordinary spark plug or 501 138 equivalent where the initial charge is in close contact with the main charge. The end of the object or body in question provided with said initiation charge was thus turned towards the initiation direction during the free fall through the explosion chamber. As already mentioned, the detonator can advantageously be provided with a delay set which delays main initiation sufficiently for a protective hatch or the like to have time to open for the inlet opening through which the explosive-filled objects or bodies are supplied to the detonation chamber before their main charges are detonated.

As the inlet opening or window for the energetic radiation or the firing of the previously mentioned projectile, the same opening can be used as the one through which the objects or bodies in question are supplied to the blasting chamber. The same opening can also be used by the measuring means of the type which follows the objects' or trajectories of the bodies. Pressure-sensitive sensors or the like can also be arranged in the blasting chamber, which register when a detonation takes place. Such sensors could then be used to stop further supply as soon as a dead end has been detected.

By detonating the explosive-filled objects or bodies during free fall inside an explosive chamber at least substantially closed during the detonation in accordance with the present invention, it is possible to utilize explosive gases formed therewith in a simple manner for further treatment. With the aid of an efficient supply device of the type described in connection with the appended figures or another device which meets the corresponding requirements, it is namely possible to carry out successive detonations so close to each other that the blasting chamber will be under an overpressure of explosive gases. which can be drained via a choke or ejector to the gas purification plant which is assumed to be part of a complete plant but which is not part of the invention and which is therefore not discussed in more detail in this context. In order to prevent the outflow of disturbing amounts of explosive gases through the inlet opening through which the explosive-filled objects or bodies are supplied to the explosive chamber, this can, in addition to a closable door, also be provided with a number of nozzles arranged around the opening for supplying compressed air. It would also be possible to arrange a lock arrangement here with several cooperating hatches.

The invention has been defined in the following claims and it will now be described somewhat further in connection with the accompanying figures.

Figure 1a shows a section through a destruction plant according to the invention, Figure 1b a top view of the same plant, Figure 2: 1 a section through the blasting chamber included therein on a larger scale, Figure 2b a cross section through the same chamber, Figures 3a and 3b show in larger scale device for supplying grenades to the explosive chamber according to Fig. 1a, Figures 4a and 4b show the grenade holder according to Figs.

The device according to the invention shown in Figures 1a and b shows an explosion chamber 1 consisting of a cylindrical stone-filled casing wall 2 of steel, a cylinder head 3 made of steel with a central inlet opening 4, a support arm 6 pivotable about a vertical axis 5 which in its end carries vertical grenade holders 7 and 8, a stand 9 for supporting the shaft 5 and a device 10 for supplying grenades (see Figs. 2 and 2a) to either of the grenade holders 7 or 8 depending on which of the grenade holders is located directly above the loading device 10. The arm 6 is also raised and lowerable along the axis 5. Other details regarding the arm 6 and with it more directly cooperating parts will be described in connection with Figs. 3a and b. In addition, the figures show that the bottom of the blasting chamber 501 138 b 11 is surrounded of a reindeer channel 12 sloping towards a discharge opening 13 for discharging the obtained scrap metal.

A complete production facility also includes spaces for preparing the explosive-filled objects or bodies for destruction in this case in the form of artillery shells before being fed into the device 10 for supply to the grenade holders 7 and 8, respectively, means for recovering the scrap discharged through the outlet 13 ( possibly this should be subjected to a second control firing before it is removed), means for recovering and purifying explosive gases formed at the detonations as well as measuring devices and means for supplying energetic radiation for the initiation (these will be discussed later) and finally various auxiliary systems such as compressed air, hydraulics and the like.

The blasting chamber shown in Figs. 1a and b may be designed in the manner shown in Figs. 2a and b. This consists of a cylindrical outer sheet metal shell 14 an inner stone filling 15 which is held in place by double rows of steel baffles 16 and 17 each consisting of vertically arranged flat iron facing one longitudinal edge towards the interior of the chamber. Both the roof of the chamber and its bottom 18 and 19, respectively, are pure metal constructions, although a protective cover 20 of pebble gravel or the like covers the bottom 19. It is this bottom cover which can be given the conform 11 shown in Fig. 1a. The discharge channel 12 is also found in the figures. Figures 2a, 2b also show a pull-out door 21.

In the roof 18 of the chamber there is a central inlet opening 22. In Fig. 2a a grenade g detonating inside the chamber is also indicated.

With regard to the means for feeding the grenades into the blasting chamber 1 and related details, reference is made to Figs. 3a and 3b and 4a and 4b where this is shown on a larger scale.

Figures 3a and 3b show the support arm 6 with its bearing point for the shaft 5. The support arm is thus vertically displaceable along this shaft. ., 501 138 This is so that the grenade holders 7 and 8 can be lowered into and lifted out of guide sleeves 23 and 24, respectively, which define their positions in relation to the feeding device 10 and the upper inlet opening 4 and 22 of the blasting chamber 1, respectively.

As can be seen from Fig. 3b, the grenade holders 7 and 8, respectively, are hinged and can thereby pivot in two planes, this means that their orientation is completely determined by the guide sleeves 23 and 24, respectively.

These are also axially displaceable and resiliently suspended in outer sleeves 25 and 26, respectively, in order to give the system a smooth ride.

The explosion chamber opening 22 can further be covered by a displaceable protective hatch 27. The two grenade holders 7 and 8 are provided with centered axial windows 28, which in the example shown (see Fig. 4a) are also protected by a displaceable glass-clear plastic foil 38 which ensures that it is always free view through the respective window. The grenade holders 7 and 8, respectively, are further provided with hydraulically or pneumatically controlled clamping teeth 29 or the like for holding the grenades.

Centered over the inlet opening 4, 22 of the blasting chamber 1, a measuring laser 30 is mounted. In addition, there is a mirror 31 for mirroring in the same direction of the beam from a pulsed high-power laser.

When using the device according to the invention, the function is as follows.

A grenade G prepared for destruction is fed with its spark plug opening upwards of the device 10 into either of the grenade holders 7 or 8 while this is in its end position in the guide sleeve 23. Once inside the grenade holder, the grenade is locked in this position by its clamping tooth 29. Thereafter the beam 6 is lifted vertically along the shaft 5 so that the grenade holder moves free from the guide sleeve 23, after which the beam is pivoted half a turn and the grenade holder is lowered into the guide sleeve 24 arranged above the opening 22. As soon as it has reached its end position, the door 27 and the measuring laser 30 open is activated, then the latch 29 is unlocked and the grenade G begins to fall through the chamber 1 along its center line. The measuring laser follows the fall of the grenade (Bach at a predetermined point above the floor of the explosive chamber) The measuring laser initiates via a suitable control system a pulsed high-power laser which is reflected via the mirror 31 directly in an explosive capsule 35 arranged in the grenade's ignition opening (see Fig. 5a and Sb). While this is burning, the grenade G has time to reach another piece and at the same time the door 27 illustrated in Figs. 3a and 4a and 4b, respectively, is closed at the same time as the pulsed high-power laser is switched off.After the door 27 is closed and the pyrotechnic delay set is burned out and the main charge is detonated while the grenade G is still in free fall, meanwhile a new grenade is supplied to the second grenade holder, and any explosive smoke penetrating through the closed door 27 is blown away with compressed air.

In the above, reference has already been made to the initialization charge shown in Figs. 5a and 5b. This is thus intended to be placed on the grenade 'G spark plug opening.

It consists of an outer capsule of plastic, cardboard, metal or the like 32. In this is mounted a less explosive charge 33, a cover cap 34 with space for a detonator 35. The latter is mounted with its free opening facing upwards so that the high-power laser can act directly against the charge surface of the detonator. The detonator comprises a pyrotechnic short-term delay kit which enables the door 27 to be closed in the manner previously described before the detonation takes place, which is advantageous both environmentally and in terms of the protection of the plant's more sensitive parts such as the laser etc.

The booster shown in Figures 5a and b is provided with two rows of resilient legs or rods 37 and 38, respectively, which allow the booster to be centered in grenades of different diameters on the spark plug threads contained therein and at the same time ensure that the detonator is axially aligned in the longitudinal direction of the spark plug. 9 501 138 The examples discussed above thus refer almost alternatively to energetic radiation as initiation medium, but the device shown can be used relatively unchanged for the alternative with a projectile as initiation means, but in that case the mirror and the pulsed high energy laser are replaced with a firing means fired with the grenade G trajectory carefully centered projectiles.

Corresponding plant could in principle also be used in the option of initiation before the start of the free fall by the detonator 35 in addition to a time delay kit also being provided with an upper percussion cap which is initiated by a percussion lighter which is placed in the same position as the window 28 and which affects the percussion cap immediately before clamping tooth 29 releases its grip.

Claims (15)

501 138/0 1. A method of destroying explosive-filled objects or bodies such as grenades, other combat parts, propellant charges, etc., characterized in that explosive substances contained therein are detonated, while in free fall, through an explosion chamber adapted thereto. 2. A method according to claim 1, characterized in that said explosive substances are initiated for detonation while they are in free fall through the explosion chamber. 3. A method according to claim 1 or 2, characterized in that the position for the initiation of the explosive charges in the respective free-falling objects or bodies is determined on the basis of the measured values obtained from a measuring system which continuously or stepwise follows their trajectory. 4. A method according to either of claims 1 or 2, characterized in that the position for the initiation of the explosive charges in the respective objects or bodies in free fall is determined on the basis of measuring systems which read when they have passed certain points in the fall path. 5. A method according to any one of claims 1-4, characterized in that the initiation of the explosive filling in the respective object or body takes place by means of an energetic initiation jet directed towards a free explosive surface. 6. A method according to any one of claims 1-5, characterized in that said free explosive surface is supplied in the form of the batch surface in an outwardly open detonator. ,, sm 1st Method according to either of Claims 1 to 4, characterized in that the initial charge of the respective object or body to detonation is initiated by means of a projectile fired during its free fall in the direction of the same which affects a tear-sensitive charge applied in connection with the explosive charge. 8. A method according to any one of claims 1-7, characterized in that the initiation of the explosive charge is delayed by means of a pyrotechnic delay set arranged between the original initiation point and the explosive charge which makes it possible to close a door for the opening through which the explosive charge to the object or body is charged. 9. A method according to one or more of claims 2-8, characterized in that the detonations are brought to follow so closely together that the detonation chamber will be under a continuous overpressure and that this overpressure is used to discharge the explosive gases for further treatment. Device for carrying out the method according to one or more of claims 1-9, characterized in that it comprises an explosion chamber (1) with an at least substantially central upper inlet opening (4, 22) and a certain internal drop height, means (10 , 6,7,8) of explosive-filled objects or bodies such as artillery shells to said opening and lowering them through the opening (4, 22), a device (31) adapted for initiating explosive substance therein which provides detonation when the object or body falls through the blasting chamber (1). Device according to claim 10, characterized in that said initiating device (31) is designed to act at a distance along the fall line of the object or body in the form of an energetic beam (31) or by means of a projectile fired in said direction. 501 138 f; Device according to claim 11, characterized in that it comprises means (30) which determines the position of the object or body (G) relative to the desired detonation position in the explosive chamber (1) and fires the initiating means (31) in the form of an energetic beam or a projectile with respect to said position. Device according to one of Claims 10 to 12, characterized in that a support arm (6) which is pivotable about a vertical axis (5) is arranged in connection with the explosion chamber and which carries at its outer end at least one grenade holder (7) provided with releasable locking means (29). 8) for such bodies which are to be destroyed and which with closed locking means (29) can hold the relevant body (G) vertically with its opening towards the explosive facing upwards and which is pivotable from a first charging position (23) outside the blasting chamber (1) where the body (G) can be supplied to the holder (8) and locked in it, to a second position (24) where the holder (7) and the body are immediately above and centered with the top opening (22) of the blasting chamber and where the body (G) by loosening the locking means (29) can be lowered vertically through the top opening of the blast chamber. Device according to claim 13, characterized in that said shaft (5) has at least two arms (6) extending on either side of the vertical shaft (5) and each arm has a holder (7 and 8, respectively) for such bodies to be destroyed. Device according to claim 10, characterized in that in connection with the inlet opening (4, 22) for supplying the objects or bodies (G) to be detonated to the blasting chamber (1), there is a device for initiating (31) an object in the respective object or body (G) arranged time-delayed initialization charge (35) immediately before the body is dropped into the explosion chamber and which detonates inside it.