SE532521C2 - Mechanism of action for graded blasting action and method - Google Patents

Description

A further object of the present invention has been a method of said actuating device. Purposes, as well as other objects not listed here, are satisfactorily fulfilled within the scope of what is stated in the present independent patent claims.

Thus, according to the present invention, there has been provided an improved action device for graded blasting action, especially intended to be included in a grenade for foaming out of a barrel, whereby the risk of accidental initiation has been eliminated or greatly reduced.

Actuating device comprises at least two action parts comprising a fuel and an oxidizer, an activating device for activating the action parts, which activating device comprises a detonator. Characteristic is that the fuel and the oxidizer are separated until activation and that the detonator and the action parts are arranged for initiating one or more action parts depending on the degree of explosive action to be achieved.

According to further aspects of an action device according to the invention. that the oxidizer is arranged in oxidizer containers and that the fuel is arranged in fuel containers, which oxidizer containers are tubular and arranged between the activating device and the fuel containers, the oxidizer containers comprising radially arranged oxidizer outlets adjacent to the fuel containers; inside the oxidizer containers, that the activating device comprises a pressure vessel, which pressure vessel comprises pressurized gas and that a gas outlet is arranged in the pressure vessel in connection with the oxidizer containers, which gas outlets are closed with openable closures, that in connection with the openable closures , which opening devices are aldivable in response to an activation signal fi from a control unit, 532 52% that the openable closures consist of blasting plates that the orifice devices are burst wire disposed on the openable closures, that the fuel comprises a cohesive porous fuel structure to provide a large active surface, that the porous fuel structure is coated with a picric acid for increased initiation of the fuel-porous mixture, the fuel structure is coated with a pyrophoric substance to provide a self-initiating fuel-oxidizer mixture, that the fuel comprises a compacted powder with high porosity, that the oxidizer comprises an oxygen gas for rapid mixing between fuel and oxidizer. According to the present invention there is also provided a a method of an actuating device arranged for graduated blasting action, especially intended to be part of a grenade body for ejection from a barrel, comprising at least two actuating members comprising a fuel and an oxidizer, an actuating device for activating the actuating arm, which actuating device comprises a detonator. Characteristic is that the fuel and oxidizer of the action parts are stored separately until activation and that the detonator and that the action parts are arranged for initiating one or more action parts depending on the degree of bursting action to be achieved.

Advantages and effects of the invention The invention has several advantages and effects. By storing the fuel's fuel and oxidizer separately until use, it is possible to safely handle the action device, from manufacturing, storage and transport to handling the action device in weapons and during recycling and destruction. Only when an action fraction is activated, ie when fuel and oxidizer are mixed and explosive mixture is included, does the action device pose a risk. 532 E21 The recovery process is simplified by the separation of fuel and oxidizer and no further operations required.

By using a detonator to initiate one or more of your action components, a simpler activation system is made possible if your detonators are used.

Additional advantages and effects will be apparent upon study and upon consideration of the following detailed description of the invention, including a number of its most advantageous embodiments, claims and the accompanying drawing figures therein; fi g. 1 shows a longitudinal section of an action device, fi g. 2 shows an enlargement of the activating device for the action device in Figure 1, 1. 3 shows a magnification of an oxidizer container according to the operating device in figure 1.

Detailed description I fi g. 1 shows a first embodiment of an action device 1 arranged for graduated blasting action. By graded explosive action is meant here an explosive action that can be changed gradually, in steg cra steps, from low to medium high explosive action and from medium to high explosive action b ll, bßfæ fl de on how many action parts 4,5, 6 are activated. The number of steps depends on how many action parts are included in the action device. The action device 1 is included in a grenade loop 2 between the front part of the grenade body 2, also called the nose part, and the rear part of the grenade body 2. Action device 1 comprises three action parts 4,5, 6, axially arranged one after the other in the longitudinal axis A of the grenade bodies 2, the front action part 4 of the action device being arranged closest to the nose part of the grenade body, followed by the intermediate action part 5 of the action device 1 and its rear action part 6.

The actuating device 1 also comprises an actuating unit 3 for activating one or more actuating parts 4,5, 6. The activating unit 3 is arranged between the nose part of the grenade body 2 and the front actuating part 5. Each actuating part 4,5, 6 comprises a fuel container 7,8,9 comprising a fuel 10, and an oxidizer container 11,12, 13 comprising an oxidizer 14. The front working part 4 comprises a lower fuel container 7 and a lower oxidizing container 11. 532 521 The intermediate operating part 5 comprises an intermediate fuel container 8 and an intermediate oxidizer container 12. Finally, the rear working part 6 comprises a rear fuel container 9 and a rear oxidizer container 13.

By storing fuel 10 and oxidizer 14 separately in each other in respective fuel containers 7,8, 9 and oxidizer containers 11,12, 13 until activation of the actuating device 1, i.e. when fuel 10 and oxidizer 14 and thereby form an explosive mixture , a safe handling of the action device is possible, the risk of unintentional irritation is minimal. Barriers 15, 16, 17 are arranged between the actuators 45, 6 to prevent oxidizer 14 from spreading between the actuators 5, 6, 7. The barriers 15, 16, 17 are gas and liquid-tight and consist, preferably, of a plastic or metal material, for example in the form of foil.

The plastic or metal foil can be mounted on the inside of the grenade body 2, for example with a welded joint. Alternatively, the barriers 15,16, 17 can be arranged so as to enclose the fuel containers 7,8, 9. The barriers 15,16, 17 are dimensioned so that they lack the pressure which arises during a detonation. The detonation fi from the action part 4 initiates the action part 5, and the detonation from the action part 5 initiates the action part 6. Thus, by said arrangement, only a detonator 23 is needed for initiating one, two or three action parts depending on the degree of explosive action to be achieved. A precondition, however, is that the fuel 10 and the oxidizer 14 in the active parts 4,5, 6 that are initiated, have entered into an explosive mixture, ie. has been mixed.

As shown in fi g. 2, the activating unit 3 comprises a pressure vessel 18, preferably a cylinder with closed ends. The pressure vessel 18 is pressurized with a gas 19, preferably an inert gas, for example helium, nitrogen or argon. The activating unit 3 further comprises three gas outlets 20, to which the three oxidizer containers 11, 12, 13 are connected. The gas outlets 20 are, initially, closed with openable seals 21 to prevent the pressurized gas 19 from flowing out into the oxidizer containers 11, 12, 13 before activation. The closure rings 21 preferably consist of blasting plates. In direct connection to the closures 21, opening devices 22 are also arranged for opening the closure ring 21 in response to an activation signal from a control unit 24, called CPU (Control Process Unit) 24. One or more closures 21 can be opened independently of each other. , preferably, of explosive wire / stub mounted on the closures 21. Alternatively, the opening devices 22 may consist of pyrotechnic charges mounted on the closures 2 l. 533 5É ° l Other types of opening devices 22 can also be used, for example electromagnetic devices in which pistons or needles (not shown) are activated for puncturing the closures 21. The opening device 22 is activated electrically via the CPU unit 24 in the nose part of the grenade body 2, either by a torque-activated activation program or by a signal from an active target search sensor 25.

The oxidizer containers 11, 12, 13 are axially arranged in the grenade body 2 between the activating unit 3 and the fuel containers 7,8, 9. The front oxidizing container 11 runs from the activating unit 3 through the upper fuel container 7 in front of the front barrier 15.

The intermediate oxidizer container 12 runs from the activating unit 3 parallel to the inner oxidizer container 11, through the front fuel container 7 and further through the intermediate fuel container 8 to the intermediate oxidizer barrier 12. The rear oxidizer container 13 runs parallel to the activating unit 3 and the intermediate 11 the oxidizer container 12 up to the rear oxidizer barrier 16. The part of the oxidizer containers 11, 12, 13 which resides in the respective fuel containers 7, 8, 9 comprises radially arranged oxidizer outlets 26. The oxidizer outlets 26 are, initially, closed with gas-tight openable oxidizer closures 27. The openable the oxidizer slurries 27 are preferably made of plastic or metal foil arranged on the inside of the oxidizer containers 11, 12, 13.

Alternatively, the oxidizer seal slats 27 are constituted by blasting sheets arranged, either, on the outside or on the inside of the oxidizer outlets 26. The oxidizer release rings 27 are openable in response to a definite increase in pressure in the oxidizer containers 11, 12, 13.

The pressure increase in the oxidizer tanks 11, 12, 13 is generated by the pressurized gas 19 after the opening device 22 has been activated. The gas pressure in the oxidizer containers 11,12,13 rises rapidly, which leads to oxidizer closures 27 breaking. The pressure increase means that oxidizer 10 is forced out into the fuel container 7,8, 9, via the oxidizer outlets 26, and fills the pore structure of the fuel 10.

The oxidizer containers 11, 12, 13 preferably consist of stainless steel to withstand the corrosion of corrosive gas, but may also consist of corrosion-resistant plastic. The oxidizer 14 is gaseous and / or liquid and comprises oxygen, nitrous oxide, nitric acid, or hydrogen peroxide, or mixtures thereof. 532 52% Alternatively, the oxidizer 14 may be a dinitrinide salt dissolved in a suitable solvent, for example dimethylformamide or tetralhydrogen or mixtures thereof.

The fuel 10 is preferably a cohesive porous fuel structure 10, consisting of silicon, carbon, vanadium, beryllium urn, magnesium, iron or mixtures thereof. The highly porous fuel 10 is designed for the fastest possible absorption of a gaseous or liquid oxidizer 14 in that the fuel 10 is arranged in the form of thin porous discs at a certain distance from each other in the fuel containers 7,8, 9. The porous fuel 10 has a porosity, preferably, in the range of 60 to 95 vol. %. Alternatively, the fuel 10 may comprise an uncompressed compacted powder 10 comprising silicon, carbon or vanadium, beryllium, magnesium, iron or mixtures thereof. The powder mixture 10 has a porosity and structure which on contact with a gaseous and / or liquid oxidizer 14, upon initiation, can be caused to detonate.

In a second embodiment, not shown in the figures, the cohesive porous fuel structure 10 is coated with an additive to facilitate the initiation of fuel / oxidant mixing.

The additive may advantageously consist of a granular zirconium powder, evenly distributed in the pore structure of the fuel. To further increase the initiability, the additive may also be mixed with a primer, for example picric acid. In a further special variant, the porosity structure of the fuel 10 is coated with a pyrophoric substance which upon contact with the oxidizer 14 leads to self-ignition, which self-ignition initiates the fuel-oxidant mixture. The advantage is that no further initiation via a detonator is required.

In a third embodiment, not shown in the figures, the oxidizer 14 is stored together with the pressurized gas 19 in the pressure vessel 18. The oxidizer vessels 11, 12, 13 for storing oxidizer 14 thus become superfluous. The function of the oxidizer containers 11,12, 13 instead becomes to constitute transport channels for the oxidizer 14 up to the fuel containers 7,8, 9. The oxidizer containers 11,12, 13 can thereby be simplified by being made thinner and narrower.

After the oxidizer 14 and fuel 10 are mixed in one or more of the action parts 4,5, 6, depending on the intended degree of explosive action, the verk upper action part 4 is initiated. The lower action part 4, in turn, initiates the intermediate action part 5 and the intermediate action part 5 initiates it rear action part 6 provided that these have been activated. initiation of action 5 takes place after a certain time delay from the time activation has taken place. 532 53 "! The time delay can be programmed via a time relay or via a pyrotechnic delay unit. Alternatively, the time delay can be determined during the grenade's flight towards a target by a needle search sensor. The target search sensor can be of the radar or laser type.

Alternatively, the time delay can be determined from a ground control via radar or IR link. The velocity with which the oxidizer 14 is distributed in the pore nozzle of the fuel 11 is determined mainly by the gas pressure in the pressure vessel 18 and by the physical properties of the fuel 10, such as porosity but also the rotational speed of the grenade body 2. High rotational speed means higher mixing speed while low rotational speed means lower mixing speed.

Alternative possibilities for using the action device The action device 1 according to the invention is especially intended to be included in grenades for ejection from a barrel, the degree of explosive action of the action device 1 being pre-programmed or determined during the grenade's journey towards a target. Alternatively, the action device 1 may be included in robots, missiles or various types of mines. The action device 1 can also include blasting devices for civilian use, for example in the case of gnawing or road work.

Claims (6)

An actuating device (1) arranged for graduated blasting action, specially intended for engaging a gun body (2) for projecting from a barrel, which actuating device (1) comprises at least two actuating parts (4,5, 6) comprising a fuel (10) and an oxidizer (14), an activating device (3) for activating the action elements (4,5, 6), which activating device also comprises a detonator, characterized in that the fuel (10) and the oxidizer (14) are separated till atn for activation and that the detonator (23) and the action parts (4,5, 6) are arranged for irritation of one or fl your action parts (4,5, 6) depending on the degree of jumping action to be achieved. Actuating device (1) according to claim 1, characterized in that the oxidizer (14) is arranged in oxidizer containers (11, 12, 13) and that the fuel (10) is arranged in fuel containers (7, 8, 9). which oxidizer containers (11,12, 13) are tubular and arranged between the activating device (3) and the fuel containers (7,8, 9), the oxidizer containers (1 1,12, 13) comprising radially arranged oxidizer outlets (26) adjacent to the fuel containers (7, 8, 9) and that the oxidizer outlets (26) are lined with openable oxidizer dryers (27). Action device (1) according to claim 2, characterized in that the oxidizer dry slurries (27) consist of plastic foils arranged on the inside of the oxidizer containers (1 1,12, 13). Actuating device (1) according to claim 2, characterized in that the activating device (3) comprises a pressure vessel (18), which pressure vessel (18) comprises pressurized gas (19) and that a gas outlet is arranged in the pressure vessel (18). (20) in connection with the oxidizer containers (1 1,12, 13), which gas outlets (20) are closed with the openable closure '(21). Action device (1) according to claim 2, characterized in that in connection with the openable closures (21) opening devices (22) are arranged, which opening devices (22) are activatable in response to an activation signal from a control unit (24). . Action device (1) according to claim 4 or 5, characterized in that the openable closures (21) consist of blasting plates. 10. ll. 12. 532 531 An action device (1) according to any one of claims 4 to 6, characterized in that the opening devices (22) consist of explosive wire arranged on the openable closures (21). Actuating device (1) according to claim 1 or 2, characterized in that the fuel (10) comprises a cohesive porous fuel structure for producing a large active surface. Actuating device (1) according to claim 8, characterized in that the porous fuel structure is coated with a picric acid for increased initiability of the fuel-oxidant mixture. Actuating device (1) according to claim 8, characterized in that the porous fuel structure is coated with a pyrophoric substance to provide a self-initiating fuel-oxidant mixture. Action device (1) according to claim 1 or 2, characterized in that the fuel (10) comprises a compacted powder with high porosity. Actuating device (1) according to claim 1 or 2, characterized in that the oxidizer (14) comprises oxygen for rapid mixing between fuel (10) and oxidizer (14). Actuating device (1) according to one of Claims 4 to 7, characterized in that the openable closures (21) can be opened independently of one another in response to an activation signal from a control unit (24). Method for an action device (1), which action device is arranged for graded explosive action, especially intended to be part of a grenade body (2) for ejection from a barrel, which action device (1) comprises at least two action parts (4,5, 6) comprising a fuel (10) and an oxidizer (14), an activating device (3) for activating the actuators (4,5,6), which activating device (3) comprises a detonator (23), characterized in that the actuating anias (4 , 5, 6) fuel (10) and oxidizer (14) are stored separately for activation and that the detonator (23) and the working elements (4,5,6) are arranged for initiating one or more working parts (4,5, 6) depending on the degree of explosive action to be achieved.