The invention relates in general to munitions and in particular to gun-launched grenades.
Some large gun-launched projectiles, such as 155 mm projectiles, may carry many submunitions or bomblets that may be expelled in flight. Each bomblet may be independently stablized and armed. One type of bomblet may include a point detonating fuze that detonates the bomblet on impact. Detonation of the bomblet may send anti-personnel fragments radially and may send a shaped-charge jet downward. A large number of gun-launched projectiles that contain bomblets may no longer be used. Thus, there may be millions of surplus bomblets.
If the surplus bomblets are destroyed, the large original capital investment in the bomblets will be lost. And, the process of de-militarizing the bomblets is an another large cost. A need exists for a cost-effective method of converting surplus bomblets into useful products.
It is an object of the invention to provide a cost-effective method for converting surplus bomblets into useful products.
One aspect of the invention is a method of converting a bomblet into a gun-launched grenade. The bomblet may include a fuze, a shaped-charge liner, a casing, and explosive material disposed between the shaped-charge liner and the casing. The method may include attaching an ogive to an open end of the bomblet. A generally cup-shaped pusher may be placed over the fuze. The pusher may be attached to the casing. A cartridge case assembly may be attached to the fuze end of the bomblet.
The pusher may include a driving band. Attaching the pusher may include press fitting the pusher to the casing. Attaching the cartridge case assembly may include mechanically crimping the cartridge case assembly to the pusher.
Another aspect of the invention is an alternative method of converting a bomblet into a gun-launched grenade. The bomblet may include a fuze, a shaped-charge liner, a casing, and explosive material disposed between the shaped-charge liner and the casing. The method may include removing the fuze from the bomblet. A generally cup-shaped pusher may be placed over the fuze end of the bomblet. The pusher may be attached to the casing. A spit back fuze may be attached to an open end of the bomblet. A cartridge case assembly may be attached to the fuze end of the bomblet.
The pusher may include a driving band. Attaching the pusher may include press fitting the pusher to the casing. Attaching the cartridge case assembly may include mechanically crimping the cartridge case assembly to the pusher. The spit back fuze may include a housing with a generally hemispherical nose.
The invention will be better understood, and further objects, features, and advantages thereof will become more apparent from the following description of the preferred embodiments, taken in conjunction with the accompanying drawings.
In the drawings, which are not necessarily to scale, like or corresponding parts are denoted by like or corresponding reference numerals.
A known Dual Purpose Improved Conventional Munition (DPICM) bomblet may be converted into a gun-launched grenade. The gun-launched grenade may be fired from, for example, 40 mm gun tubes. The process of converting the known DPICM bomblet into a gun-launched grenade may be about 30 to 60% cheaper than purchasing a new gun-launched grenade.
A method of converting bomblet 10 into a gun-launched grenade 50 (
A driving band 46 may be used to impart spin to gun-launched grenade 50. Driving band 46 may be formed integral with or separate from pusher 36. In some embodiments, driving band 46 may be made of copper. A conventional cartridge case assembly 40, such as an M118 cartridge case, may be mechanically crimped to pusher 36. Cartridge case assembly 40 may include a primer 42 and propellant 44.
Grenade 50 may be launched from a weapon with a 40 mm caliber gun tube. Propellant 44 may propel pusher 36 and casing 16 out of the gun tube. Upon exit from the gun tube, pusher 36 may separate from casing 16. Arming of fuze 12 may occur via air flow interaction with ribbon stabilizer 14 and the spinning of grenade 50. Upon impact, fuze 12 may detonate explosive material 26. Explosive material 26 may shatter casing 16 to form shrapnel. A shaped-charge jet may be formed by the action of explosive material 26 and shaped charge liner 24.
In another embodiment of the invention, bomblet 10 may be converted into a gun-launched grenade 70 (
Pusher 52 may be made of, for example, a polymer or ceramic material. Pusher 52 may be press fit to casing 16. Adhesive may be used to fix pusher 52 to casing 16. A driving band 58 may be used to impart spin. Driving band 58 may be formed integral with or separate from pusher 52. In some embodiments, driving band 58 may be made of copper.
A conventional cartridge case assembly 40, such as an M118 cartridge case, may be mechanically crimped to pusher 52. Cartridge case assembly 40 may include a primer 42 and propellant 44. A conventional 40 mm spit back fuze 56 may include a housing 60 having a generally hemi-spherical nose. Fuze 56 may be placed over open end 30 of bomblet 10. Fuze 56 may be fixed to casing 16 using, for example, glue.
Gun-launched grenade 70 may function similar to gun-launched grenade 50. In grenade 70, spit back fuze 56 may detonate explosive material 26.
While the invention has been described with reference to certain preferred embodiments, numerous changes, alterations and modifications to the described embodiments are possible without departing from the spirit and scope of the invention as defined in the appended claims, and equivalents thereof.
The inventions described herein may be manufactured, used and licensed by or for the U.S. Government for U.S. Government purposes.
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