초록 ▼

A fuel-storing ordnance canister for release from military aircraft that does not explode upon impact, its collapsible accordion-like structure instead forcefully dispersing atomized fuel in an upwardly direction in the impact zone after descent for dispersal in, around, and beyond the impact zone.

A fuel-storing ordnance canister for release from military aircraft that does not explode upon impact, its collapsible accordion-like structure instead forcefully dispersing atomized fuel in an upwardly direction in the impact zone after descent for dispersal in, around, and beyond the impact zone. When the fuel from multiple canisters is released into a drop zone and later ignited by a dropped or ground-based incendiary device, all life in the dispersal area is eliminated. Tail fins assure nose-down flight and provide handles for easy canister handling and loading onto airplanes. The configuration of a pop-open tail plug allows for its partial release upon canister collapse to create a spray nozzle that atomizes the fuel stored in the canister as it is being dispersed. The most preferred application is by the U.S. Military to eliminate terrorists hiding in caves, hidden ordnance, and other areas previously resistant to air-released ordnance.

대표청구항 ▼

I claim: 1. A delayed-ignition ordnance device for dropped-release from military aircraft, which does not explode upon impact, instead forcefully ejecting atomized fuel in an upwardly direction in its impact zone for airborne dispersal in, around, and beyond the impact zone, said device comprising:

I claim: 1. A delayed-ignition ordnance device for dropped-release from military aircraft, which does not explode upon impact, instead forcefully ejecting atomized fuel in an upwardly direction in its impact zone for airborne dispersal in, around, and beyond the impact zone, said device comprising: a canister having a hollow interior configured for holding liquid fuel, sides with a pleated structure configured for nose-to-tail collapse upon impact after descent from military aircraft, a concave nose configuration adapted for creation of an invisible nose cone to provide enhanced flight stability and stable storage in a tail-up position, and a tail opening configured for easy fuel entry into and forceful fuel exit in an atomized spray from said canister; a quantity of liquid fuel capable of being atomized; a pop-open tail plug configured for sealing said tail opening and partial release from said tail opening so as to form a venturi nozzle that atomizes said fuel in said canister as it is forcefully sprayed from said canister in an upwardly direction as said sides of said canister achieve nose-to-tail collapse upon impact after descent; and a plurality of tail fins outwardly extending from said canister in positions remote from said concave nose and configured for stable nose-down flight of said canister wherein once said fuel is forcefully sprayed from said canister, dispersed into and beyond an impact area, and then ignited, the intense heat from its burning eliminates all life in the entire fuel dispersal area into which said fuel has traveled and also can destroy unexploded ordnance in the dispersal area but not necessarily visible within the impact zone. 2. The device of claim 1 wherein said tail fins are configured for use as handles capable of providing for efficient transport and storage of said canister. 3. The device of claim 1 wherein said canister further comprises the capability to ignite said atomized fuel after impact. 4. The device of claim 1 further comprising an air pocket adjacent to said tail opening that is configured to prevent fuel overfill in said canister and also configured upon pressurization of air therein to cause partial release of said tail plug from said tail opening. 5. The device of claim 1 wherein said tail plug further comprises a plurality of larger primary barbs configured to prevent full release of said tail plug from said tail opening and a plurality of smaller secondary barbs configured for failure so as to partially release said tail plug from said tail opening after canister impact. 6. The device of claim 5 wherein said tail plug further comprises at least one groove configured for temporary receipt of said barbs during twisting insertion of said tail plug into said tail opening of said canister. 7. The device of claim 1 wherein said canister is made from injection molding to achieve a lower per unit cost than the currently used heavy metal-clad impact-detonated ordnance. 8. The device of claim 1 wherein said canister is configured for safe and stable storage in a vertically stackable position with other ones of said canisters. 9. The device of claim 1 wherein said canister is configured for prepositioned pallet storage with other ones of said canisters wherein said canisters can be touching with tail fins oriented to clear one another for ease of loading onto airplanes. 10. The device of claim 1 wherein ignition for said fuel is selected from a group consisting of incendiary devices associated with said canister, incendiary devices dropped separately from military aircraft simultaneously with said canister, and ground-based incendiary devices. 11. The device of claim 1 wherein said canister has a maximum fuel storage capacity of approximately five gallons. 12. The device of claim 1 wherein said canister, said tail fins, and said tail plug are consumed by conflagration after ignition. 13. The device of claim 1 wherein said quantity of fuel is lower cost, fast burning, low octane gasoline. 14. The device of claim 1 wherein said canister, said tail fins, and said tail plug are made from materials and otherwise configured to avoid radar detection while in downward flight. 15. The device of claim 1 wherein said fuel reduces the risk of the airplane transporting it from ground fire. 16. A method of making a delayed-ignition ordnance device for dropped-release from military aircraft, which does not explode upon impact, instead forcefully ejecting atomized fuel in an upwardly direction in its impact zone for airborne dispersal in, around, and beyond the impact zone, said method comprising the steps of: providing a canister having a hollow interior configured for holding liquid fuel, sides with a pleated structure configured for nose-to-tail collapse upon impact after descent from military aircraft, a concave nose configuration adapted for creation of an invisible nose cone to provide enhanced flight stability and stable storage in a tail-up position, and a tail opening configured for easy fuel entry into and forceful fuel exit in an atomized spray from said canister; also providing a quantity of liquid fuel capable of being atomized, a pop-open tail plug configured for sealing said tail opening and partial release from said tail opening so as to form a venturi nozzle that atomizes said fuel in said canister as it is forcefully sprayed from said canister in an upwardly direction as said sides of said canister achieve nose-to-tail collapse upon impact after descent, and a plurality of tail fins configured for stable nose-down flight of said canister; adding said quantity of liquid fuel to said canister via said tail opening; sealing said opening with said tail plug; and positioning said tail fins in an outwardly-extending orientation relative to said canister remotely from said concave nose so that said tail fins assist in stable nose-down flight of said canister during descent prior to impact, wherein once said fuel is forcefully sprayed from said canister after impact and dispersed into, around, and beyond an impact area, and then is ignited, the intense heat from its burning eliminates all life in the entire fuel dispersal area into which said fuel has traveled and also can destroy unexploded ordnance in the dispersal area but not necessarily visible within the impact zone. 17. The method of claim 16 wherein said tail fins are configured for use as handles capable of providing for efficient transport and storage of said canister. 18. The method of claim 16 wherein said canister further comprises an air pocket adjacent to said tail opening that is configured to prevent fuel overfill in said canister and also configured upon pressurization of air therein to cause partial release of said tail plug from said tail opening. 19. The method of claim 16 wherein said tail plug further comprises a plurality of larger primary barbs configured to prevent full release of said tail plug from said tail opening and a plurality of smaller secondary barbs configured for failure so as to partially release said tail plug from said tail opening after canister impact. 20. The method of claim 19 wherein said tail plug further comprises at least one groove configured for temporary receipt of said barbs during twisting insertion of said tail plug into said tail opening of said canister.