This application claims the priority, under 35 U.S.C. ยง119, of German patent application DE 10 2009 060 658.0-15, filed Dec. 22, 2009; the prior application is herewith incorporated by reference in its entirety.
The invention relates to a grenade that can be fired from a barrel, and to a grenade launching apparatus having such a grenade. A grenade of the generic type can be fired from a launcher barrel, for recoilless firing from a barrel which is open at both ends without any flow cross-section constrictions. The grenade has a grenade base body which surrounds an explosive charge.
One known concept for achieving recoilless firing of a grenade from a grenade firing apparatus, or grenade launcher, is based on the grenade firing apparatus consisting of a barrel which is open at both ends and has no flow cross-section constrictions. Ideally, in this case, not only is the size of the flow cross-sectional area constant over the entire barrel length, but also the shape of the flow cross-sectional area. By way of example, the flow cross-sectional area is in the form of a circular disc with a constant radius over the entire barrel length. This ensures that, when the grenade is fired, no axial forces are transmitted to the barrel. The propellant charge gases of the grenade which is being fired can leave the barrel of the grenade firing apparatus at the rear, without any impediment. The impulse of the grenade as it is accelerated forwards has a magnitude which corresponds precisely to that of the impulse of the propellant charge gases which leave the barrel at the rear. Although this concept has the advantage that this allows a grenade which can be fired from a barrel to be fired without recoil in a simple manner with a grenade firing apparatus of relatively simple design, the concept at the same time has the disadvantage, however, that the gas pressure which is created after the propellant charge has been fired flows very quickly to the rear away through the open barrel end. The propulsion effect on the grenade to be fired is therefore only minor.
It is accordingly an object of the invention to provide a barrel-fired grenade and an associated grenade firing apparatus which overcome a variety of disadvantages of the heretofore-known devices and methods of this general type and which on the one hand ensures that the grenade is fired without recoil, but on the other hand also at the same time achieves a large propulsion effect on the grenade.
With the foregoing and other objects in view there is provided, in accordance with the invention, a grenade for recoilless firing from a barrel that is open at both ends and does not have any flow cross-section constrictions, the grenade comprising:
a grenade base body containing therein at least one explosive charge;
a flow cross-section reduction device for reducing a flow cross-section of the barrel, said device being disposed rearward of said grenade base body relative to a firing direction; and
a connecting device connecting said flow cross-section reduction device to said grenade base body at a spacing distance therefrom and connecting said flow cross-section reduction device to said grenade base body rigidly stable during firing.
The invention is in this case based on the concept that, in principle, a flow cross-section constriction in the firing barrel makes it possible to prevent a gas pressure which is created when the propellant charge burns away from flowing away too quickly, thus in the end making it possible to improve the propulsion effect on the grenade body. However, if the rearward opening of the firing barrel is for this purpose constricted, for example, in the form of a nozzle, then this results not only in the advantageous boosting of the propulsion effect on the grenade body but also in a force which is directed axially to the rear being disadvantageously introduced into the firing apparatus.
A flow cross-section reduction device is therefore provided according to the invention, which is not firmly connected to the firing barrel but is connected to the grenade base body, separated from it, via a connecting device, and is connected to it such that it is stable during firing. This on the one hand ensures that no axial forces are introduced into the grenade firing apparatus when the grenade is fired, while on the other hand the flow cross-section reduction device for reducing the flow cross-section of the barrel, which device is arranged in the opposite direction to the firing direction with respect to the grenade base body, advantageously prevents the gas pressure from flowing away too quickly when the grenade is fired.
The grenade base body preferably has a cylindrical shape whose external diameter corresponds essentially to the internal diameter of the firing barrel. This on the one hand allows the charge volume of the grenade to be maximized, while thus on the other hand optimizing the guidance of the grenade body in the firing barrel.
In this case, it is particularly advantageous for the grenade base body to have sealing means on its envelope surface, which sealing means are suitable for sealing gaps between the envelope surface of the grenade base body and the inner surface of the firing barrel. This makes it possible to prevent propellant charge gases from leaving the firing barrel at the front, past the grenade base body, which would lead to a reduction in the propulsion effect on the grenade.
The flow cross-section reduction device preferably comprises a hollow-cylindrical ring, which is connected via one or more webs to the connection device. This makes it possible to ensure that the flow cross-section reduction device has a lightweight structure, which is nevertheless robust.
The external diameter of the ring in this case preferably corresponds to the external diameter of the cylindrical grenade base body at least over a portion of the height of the hollow cylinder. This improves the guidance of the grenade which can be fired from a barrel, and prevents the grenade from tilting in the firing barrel.
It is also advantageous for the edges of the webs and/or of the ring to be inclined on the side facing the grenade base body. This results in the propellant charge gases flowing onto the webs and/or the ring in an aerodynamically advantageous manner.
It is also advantageous for the walls of the webs and/or of the ring to be shaped such that the cavities between them are in the form of nozzles. This makes it possible to ensure an improved thrust effect on the grenade. A particularly good thrust effect is achieved if the nozzle shape is that of a de Laval nozzle.
The flow cross-section reduction device is preferably in the form of an annular fin structure. This has the advantage that the grenade is stabilized in flight after leaving the barrel.
According to one preferred embodiment of the invention, the connecting device comprises a launch barrel, which extends on an elongation of the cylindrical longitudinal axis of the grenade base body. This launch barrel contains a basic charge. In this case, the basic charge may represent the central part of a firing chain which comprises the relay charge, basic charge and main charge. The launch barrel preferably has radial holes which allow the ignited basic charge to flash over to a main charge which can be arranged in an annular shape around the launch barrel and between the grenade base body and the flow cross-section reduction device. These overflow holes in the launch barrel can be sealed by a brass foil. Once the bursting pressure of the brass foil has been reached, the main charge is ignited by the basic charge combustion gases flowing out of the overflow holes.
According to a further preferred embodiment of the invention, the flow cross-section reduction device is a support for a wire-based data link, which can be unwound while the grenade is being fired and connects the grenade to a fire control computer at least until it leaves the firing barrel or else in the initial flight phase of the grenade after leaving the firing barrel. In this case, the wire which can be unwound for the data link is preferably arranged on the flow cross-section reduction device such that the wire is affected as little as possible by the hot powder gases and particles which are created when the grenade is fired. This advantageously ensures that the wire for the data link is not torn when the grenade is fired. In this case, it is particularly advantageous for the wire to be wound in the form of a coil around the ring in a hollow-cylindrical gap, which is open only in the opposite direction to the firing direction, between the external diameter of the ring and the inner surface of the firing barrel. The wire is therefore particularly well protected against the hot powder gases which are created when the grenade is fired, while at the same time ensuring that the wire can be unwound easily.
Furthermore, the present invention also covers a grenade firing apparatus having a grenade as has been described above. In this case, the grenade firing apparatus has a barrel which is open at both ends without any flow cross-section constrictions.
The barrel of the grenade firing apparatus is preferably closed by a cover at its front and/or rear end before the grenade is fired. This makes it possible to prevent foreign bodies from entering the barrel of the grenade firing apparatus. The rear cover is preferably connected to the grenade via a holding device, which is designed to hold the grenade in a rear position in the barrel before firing. This makes it possible to prevent the grenade from sliding to and fro in the barrel before being fired. This therefore prevents damage to the grenade located in the grenade firing apparatus, in particular while the grenade firing apparatus is being transported.
The rear cover is preferably designed to burst under the influence of the gas pressure which is built up by the main charge of the grenade, in order to open the rear end of the barrel. This makes it possible to ensure that the protective effect of the cover is maintained for as long as possible.
In this case, it is particularly advantageous for the holding device via which the rear cover is connected to the grenade to have a weak point at which the holding device breaks during acceleration of the grenade. This makes it possible to minimize the introduction of axial forces into the grenade firing apparatus when the grenade is fired.
Further advantageous embodiments and improvements of the invention will become evident from the following description of preferred exemplary embodiments of the invention. It should be noted that the invention also covers further embodiments which result from a combination of features which are mentioned separately in the patent claims and/or in the description and the figures.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a grenade and grenade firing apparatus, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now to the figures of the drawing in detail and first, particularly, to
The grenade 1, which may also be referred to as a shell 1, which can be fired from a barrel has a grenade base body 10. The grenade has a flow cross-section reduction device 12 which is arranged in the opposite direction to the firing direction X of the grenade 1, with respect to the grenade base body 10. The flow cross-section reduction device 12 is connected to the grenade base body 10, separated from it, via a connecting device 13, and is connected to it such that it is stable during firing. This grenade 1 can be fired without recoil from a barrel 2 which is open at both ends. The design of the flow cross-section reduction device 12 according to the invention ensures that no axial forces are introduced into the grenade firing apparatus when the grenade 1 is fired. At the same time, this ensures that the flow cross-section of the firing barrel 2 is reduced, thus preventing the gas pressure from flowing away too quickly when the grenade 1 is fired.
The features described in the following text represent advantageous refinements of the principle of the invention as described above.
For example, the grenade base body 10 illustrated in
One preferred embodiment of a grenade firing apparatus according to the invention and one preferred embodiment of the flow cross-section reduction device 12 will be explained in the following text with reference to
The grenade firing apparatus has a barrel 2 which is open at both ends without any flow cross-section constrictions. A grenade 1 is mounted in the barrel, as is described above and in the following text.
The flow cross-section reduction device 12 is a support for a wire-based data link 18, which can be unwound while the grenade 1 is being fired. This data link 18 connects the grenade 1 to a fire control computer (not illustrated) at least until it leaves the firing barrel 2 or else in the initial flight phase of the grenade 1 after leaving the firing barrel 2. The wire 18 is wound in the form of a coil around the ring 12a in a hollow-cylindrical gap, which is open only in the opposite direction to the firing direction X, between the external diameter of the ring 12a and the inner surface of the firing barrel 2. In consequence, the wire 18 is affected only to a minimal extent by the hot powder gases and particles which are created when the grenade 1 is fired.
The barrel 2 of the grenade firing apparatus is closed by a cover 19a, 19b at its front end and rear end for protection against the ingress of foreign particles. The rear cover 19a is connected to the grenade 1 via a holding device 20, which is designed to hold the grenade 1 in a rear position in the barrel 2 before firing. The rear cover 19a does not represent a ballistic, effective flow cross-section constriction of the firing barrel 2, because it bursts under the initial influence of the gas pressure building up from the main charge 17 of the grenade 1. The rear end of the barrel 2 is therefore opened immediately, without axial forces being introduced into the grenade firing apparatus. The holding device 20 has a weak point 21 where the holding device 20 breaks during acceleration of the grenade 1. The grenade 1 has a firing chain which comprises a propellant charge igniter 22, a relay charge 23, a basic charge 15 and a main charge 17. This is only one of the possible configurations of a firing chain for the grenade according to the invention. However, the firing chain may also have a greater or lesser number of elements. The propellant charge igniter 22 ignites the relay charge 23 (for example 500 mg of potassium nitrate bore). The propellant charge consists of two parts: by way of example, 60 g of Benits powder can be used as the basic charge, and is located in the launch barrel 13. The overflow holes 16 in the launch barrel 13 are sealed by a brass foil. Once the bursting pressure of the brass foil has been reached, the main charge 17 (for example 300 g of Tecna powder) is finally ignited. The gas pressure of the propellant charge 15, 17 bursts the cover 19a at the rear, and tears the holding element 20 at its weak point 21. As a consequence of the constriction in the cross section caused by the fin structure cross-sectional area, the gas pressure builds up further, acting on the base of the grenade (that is to say on the rear face of the grenade base body 10), and accelerates it.
According to the invention, a flow cross-section reduction device 12 is provided, which is not firmly connected to the firing barrel 2 but is connected to the grenade base body 10, separated from it, via a connecting device 13, and is connected to it such that it is stable during firing. On the one hand, this ensures that no axial forces are introduced into the grenade firing apparatus when the grenade 1 is fired, while on the other hand the flow cross-section reduction device 12 for reducing the flow cross-section of the barrel 2, which device is arranged in the opposite direction to the firing direction X with respect to the grenade base body 10, advantageously prevents the gas pressure from flowing away too quickly when the grenade 1 is fired.
Number | Date | Country | Kind |
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102009060658.0-15 | Dec 2009 | DE | national |