초록 ▼

This invention proposes to make use of an already developed set of hardware which dispenses and controls the performance of towed decoys capable of defeating radar guided weapons. Using this same hardware, a new and unique payload, payload control and dispensing mechanism is inserted into a decoy to

This invention proposes to make use of an already developed set of hardware which dispenses and controls the performance of towed decoys capable of defeating radar guided weapons. Using this same hardware, a new and unique payload, payload control and dispensing mechanism is inserted into a decoy towbody. The payload consists of foils and/or foil packs of a pyrophoric material. This material creates an infrared (IR) signature behind the decoy that is more attractive than the infrared plume emitted by the aircraft engine. The fact that the IR decoy is towed insures that it will be kinematically correct by flying the same profile as the aircraft so as to remain within the field of view of the missile's seeker. Because the pyrophoric material can be metered (dispensed at varying and controllable rates) its radiant intensity can be matched with that of the engine of the towing aircraft. As the burn characteristics of the selected pyrophoric material match the burn profile of hydrocarbon based jet fuels, the towed IR decoy also emits a plume that spectrally matches that of its host aircraft's engine.

대표청구항 ▼

1. An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares, wherein the rate at

1. An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares, wherein the rate at which said flares are dispensed is determined by said commands. 2. The apparatus of claim 1An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the decoy is towed at a distance behind the aircraft that places it close enough to the aircraft'san exhaust plume of the aircraft that both the IR emissions from the aircraft's exhaust plume and the IR emissions of at least some of the flares dispensed from the towed decoy are in thea field of view of a seeker of an IR guided missile, but far enough behind the aircraft's exhaust plume that the seeker of the missile miscalculates thea location of the aircraft. 3. The apparatus of claim 1,An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the apparatus is for use to defeat an IR guided missile employing kinematic counter--counter measures (CCMs) designed to discriminate between an aircraft moving through the air and an IR emitting flare falling away from the aircraft once deployed therefrom,wherein said dispensing means continuously dispenses flares at a distance behind the aircraft that ensures both the IR emissions from the aircraft'san exhaust plume of the aircraft and the IR emissions of at least some of the flares dispensed from said decoy are in thea field of view of a seeker of the IR guided missile, thereby preventing the IR guided missile from distinguishing between the aircraft's exhaust plume and the flares, thereby defeating said kinematic CCMs. 4. The apparatus of claim 1,An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the apparatus is for use to defeat an IR guided missile employing spectral CCMs designed to discriminate between thean IR spectra of an aircraft's exhaust plume of the aircraft and thean IR spectra of an IR emitting flare, wherein said dispensing means dispenses IR emitting flares comprising pyrophoric flare materials which emit, when exposed to air, an IR spectra similar to that emitted by the aircraft's exhaust plume, thereby defeating said spectral CCMs. 5. The apparatus of claim 1,An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the apparatus is for use to defeat an IR guided missile employing IR radiation intensity CCMs designed to discriminate between thea radiant intensity of the IR emissions from the aircraft'san exhaust plume of the aircraft and thea radiant intensity of the IR emissions from an IR emitting flare, wherein said dispensing means dispenses the IR emitting flares at rates which create IR energy levels behind the decoy which cannot be effectively distinguished from that of the aircraft's exhaust plume, thereby defeating said intensity CCMs. 6. The apparatus of claim 5, wherein the IR emitting flares are dispensed at a steady rate which creates IR energy levels behind the decoy that substantially match the IR energy levels associated with the aircraft's exhaust plume. 7. The apparatus of claim 5, wherein the IR emitting flares are dispensed at rates which produce a varying IR radiation intensity pattern behind the decoy, said pattern comprising a repeating sequence of at least two IR radiation intensity spikes wherein one of the at least two spikes peaks at an IR radiation intensity above that of the aircraft's exhaust plume and another of the at least two spikes peaks at an IR radiation intensity below that of the aircraft's exhaust plume. 8. The apparatus of claim 5, wherein the IR emitting flares are dispensed at rates which produce a varying IR radiation intensity pattern behind the decoy, said pattern comprising a repeating sequence of at least two IR radiation intensity spikes followed by a period of time in which no flares are dispensed, wherein one of the at least two spikes peaks at an IR radiation intensity above that of the aircraft's exhaust plume and another of the at least two spikes peaks at an IR radiation intensity below that of the aircraft's exhaust plume. 9. The apparatus of claim 1,An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the apparatus is for use to defeat an IR-guided missile employing temporal CCMs designed to distinguish between continuous IR emissions associated with the aircraft'san exhaust plume of the aircraft and rapidly decreasing IR emissions associated with aircraft-launch IR emitting flares as sensed by the IR-guided missile, wherein said dispensing means dispenses IR emitting flares from the decoy at rates that prevent the average IR emissions associated with the decoy's flares from decreasing in intensity over time, thereby defeating said temporal CCMs. 10. The apparatus of claim 1An apparatus for defeating infrared (IR)-guided missile attacks on an aircraft, comprising: a decoy towed behind the aircraft, said decoy being capable of receiving commands transmitted from said aircraft; andmeans, disposed within said decoy, for dispensing IR emitting flares carried on the decoy in solid form, wherein the rate at which said flares are dispensed is determined by said commands,wherein the towed IR decoy has a forward and an aft section, said forward section comprising:a housing;a towline attachment connected to the housing for attaching a towline from the aircraft;a motor disposed within the housing;a motor controller disposed within the housing and connected to the motor, said controller being capable of controlling the motor'sa speed of the motor;a communications modem disposed within said housing and connected to the motor controller, said modem being capable of receiving said commands communicated from the aircraft and passing said commands on to the motor controller; andan electrical interconnect connected to the communications modem, said interconnect being mateable to an electrical cable capable of transmitting communications from the aircraft, said electrical cable following the towline from the aircraft to the decoy. 11. The apparatus of claim 10 wherein the commands communicated from the aircraft comprise motor control instructions dictating the speeds at which the motor is to be operated over time. 12. The apparatus of claim 10, wherein the communications modem is further capable of transmitting communications from the decoy to the aircraft, wherein said communications comprise information concerning thea status of the decoy. 13. The apparatus of claim 12, wherein thea absence of transmitted status information from the decoy for a prescribed period of time is interpreted as a failure of the decoy prompting its replacement. 14. The apparatus of claim 10, wherein the aft sectionssection comprises: a housing having a forward and an aft end;a payload disposed within the housing comprising pyrophoric materials; anda payload dispensing mechanism capable of dispensing the pyrophoric materials from the aft end of the housing at prescribed rates. 15. The apparatus of claim 14 wherein said pyrophoric material comprises hermetically sealed packets and wherein the aft section further comprises a cutting device disposed at the aft end of the housing, said cutting device being capable of cutting open each packet of pryrophoricpyrophoric material as it is dispensed from the aft end of the housing, thereby exposing the pyrophoric material to thean atmosphere and causing itsaid pyrophoric material to emit IR radiation. 16. The apparatus of claim 15 wherein each packet of pyrophoric material is 1.5 to 2.0 mils thick and at least about 6000 packets are disposed within the aft section housing. 17. The apparatus of claim 15 wherein each packet comprises at least one of (i) a foil covered with powderized pyrophoric material and (ii) powderized pyrophoric material. 18. The apparatus of claim 15, wherein each packet comprises at least one foil covered with powderized pyrophoric material, and wherein thea number of foils contained in each packet once cut open and exposed to the atmosphere determines thean intensity of the IR radiation emitted form thatfrom a cut-open packet, and wherein the number of foils contained in each package and thean order in which the packets are placed into the aft section is selected to provide a desired IR emission pattern behind the decoy. 19. The apparatus of claim 14, wherein the payload dispensing mechanism comprises: a threaded screw shaft longitudinally mounted within said housing, said screw shaft being capable of rotating about its longitudinal axis;an endcap enclosing the aft end of the housing, said endcap being in correspondence with an aft end of the screw shaft such that whenever the screw shaft is rotated in a first direction, the end cap detaches from the aft end of the housing and falls away;a piston disposed within the aft section housing, wherein said piston comprises a treadedthreaded central channel threadably mated to the screw shaft and an anti-rotation mechanism capable of preventing the piston from rotating in relation to the aft housing, and wherein said piston moves aftward within the housing whenever the screw shaft is rotated in said first direction; and whereinpackets of pyrophoric material are mounted on the screw shaft aft of the piston such that whenever the screw shaft is rotated in said first direction, the piston pushes the packets aftward causing the packets to be dispensed one by one from the aft end of the housing. 20. The apparatus of claim 19, wherein the packets of pyrophoric material are compressed together in the longitudinal direction of the housing so as to prevent any additional compression whenever the screw shaft is rotated in said first direction and to maximize the number of packets disposed within the housing. 21. The apparatus of claim 19 wherein the forward section's motor has an output connector which is releasably mateable with a forward end of the screw shaft of the aft section, such that whenever the motor is operated it rotates the screw shaft in said first direction. 22. The apparatus of claim 21, wherein the speed at which the motor is operated by the motor controller dictates a speed of rotation of the screw shaft, thereby controlling thea speed at which the piston moves aftward and so thea rate at which the packets of pyrophoric material are dispensed from the towed decoy, said rate of dispensing dictating the IR emission levels behind the decoy. 23. The apparatus of claim 22, wherein the motor controller is instructed via communications comprising motor speed instructions to vary the speed of the motor over time, thereby modulating the IR emissions levels behind the decoy. 24. A method for defeating infrared (IR) guided missile attacks on an aircraft comprising the steps of: towing an IR flare-dispensing decoy behind the aircraft; anddispensing the IR flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein the rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy. 25. The method of claim 24A method for defeating infrared (IR) guided missile attacks on an aircraft, comprising: towing an IR flare-dispensing decoy behind the aircraft, wherein IR-emitting flares are carried on the decoy in solid form; anddispensing the IR emitting flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein a rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy,wherein the towing step comprises towing the decoy at a distance behind the aircraft that places it close enough to the aircraft'san exhaust plume of the aircraft such that both the IR emissions from the aircraft's exhaust plume and the IR emissions of at least some of the flares dispensed from the towed decoy are in thea field of view of a seeker of an IR-guided missile, but far enough behind the aircraft's exhaust plume that the seeker of the missile miscalculates thea location of the aircraft. 26. The method of claim 24,A method for defeating infrared (IR) guided missile attacks on an aircraft, comprising: towing an IR flare-dispensing decoy behind the aircraft, wherein IR-emitting flares are carried on the decoy in solid form; anddispensing the IR emitting flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein a rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy,wherein the IR guided missile employs kinematic counter-countermeasures (CCMs) designed to discriminate between an aircraft moving through the air and aan IR emitting flare falling away from the aircraft once deployed therefrom, and wherein the towed decoy defeats the kinematic CCMs by continuously dispensing IR emitting flares at a distance behind the aircraft that ensures both the IR emissions from the aircraft's exhaust plume and the IR emissions of at least some of the flares dispensed from the towed decoy are in thea field of view of a seeker of the IR guided missile, thereby preventing the missile from distinguishing between the aircraft's exhaust plume and the flares. 27. The method of claim 24,A method for defeating infrared (IR) guided missile attacks on an aircraft comprising: towing an IR flare-dispensing decoy behind the aircraft, wherein IR-emitting flares are carried on the decoy in solid form; anddispensing the IR emitting flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein a rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy,wherein the IR guided missile employs spectral CCMs designed to discriminate between the IR spectra of an aircraft's exhaust plume and the IR spectra of an IR emitting flare, and wherein the spectral CCMs are defeated by the step of employing IR emitting flares comprising pyrophoric flare materials which emit, when exposed to air, an IR spectra similar to that emitted by the aircraft's exhaust plume. 28. The method of claim 24,A method for defeating infrared (IR) guided missile attacks on an aircraft comprising: towing an IR flare-dispensing decoy behind the aircraft, wherein IR-emitting flares are carried on the decoy in solid form; anddispensing the IR emitting flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein a rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy,wherein the IR guided missile employs IR radiation intensity CCMs designed to discriminate between thea radiant intensity of the IR emissions from the aircraft'san exhaust plume of the aircraft and thea radiant intensity of the IR emissions from an IR emitting flare, and wherein the IR radiation intensity CCMs are defeated by the step of causing the decoy to dispense the IR emitting flares at rates which create IR energy levels behind the decoy which cannot be effectively distinguished from thatIR energy levels of the aircraft's exhaust plume. 29. The method of claim 28, wherein the dispensing step comprises dispensing the IR emitting flares at a steady rate to create IR energy levels behind the decoy that substantially match the IR energy levels associated with the aircraft's exhaust plume. 30. The method of claim 28, wherein the dispensing step comprises dispensing the IR emitting flares at rates which produce a varying IR radiation intensity pattern behind the decoy, said pattern comprising a repeating sequence of at least two IR radiation intensity spikes wherein one of the at least two spikes peaks at an IR radiation intensity above that of the aircraft's exhaust plume and another of the at least two spikes peaks at an IR radiation intensity below that of the aircraft's exhaust plume. 31. The method of claim 28, wherein the dispensing step comprises dispensing the IR emitting flares at rates which produce a varying IR radiation intensity pattern behind the decoy, said pattern comprising a repeating sequence of at least two IR radiation intensity spikes followed by a period of time in which no flares are dispensed, wherein one of the at least two spikes peaks at an IR radiation intensity above that of the aircraft's exhaust plume and another of the at least two spikes peaks at an IR radiation intensity below that of the aircraft's exhaust plume. 32. The method of claim 24,A method for defeating infrared (IR) guided missile attacks on an aircraft comprising: towing an IR flare-dispensing decoy behind the aircraft, wherein IR-emitting flares are carried on the decoy in solid form; anddispensing the IR emitting flares behind the towed decoy to cause an IR guided missile targeting the aircraft to miss the aircraft, wherein a rate at which said IR emitting flares are dispensed is controlled by commands communicated from said aircraft to said decoy,wherein the IR guided missile employs temporal CCMs designed to distinguish between continuous IR emissions associated with thean aircraft's exhaust plume and rapidly decreasing IR emissions associated with aircraft-launched IR emitting flares as sensed by the IR guided missile, and wherein the temporal CCMs are defeated by a step of dispensing IR emitting flares from the decoy at rates that prevent the average IR emissions associated with the decoy's flares from decreasing in intensity over time, and dispensing the flares from the decoy for a longer period of time relative to the dispensing of aircraft-launched flares. 33. The apparatus of claim 15, wherein the aft section further comprises a sealing structure disposed at its aft end which seals the interior of the aft section from intrusion by outside air, while still allowing the pyrophoric foilsmaterial to be dispensed from the aft end of the section. 34. The apparatus of claim 33, wherein the sealing structure comprises an O-ring which projects into thean interior of the aft section's housing to an extent that causes it to contact a periphery of a rearward directed face of each pyrophoric foil whenever the foil is in the aftmost position in the payload. 35. A method for dispensing infrared flare material from an aircraft having an engine, comprising: providing an infrared flare material-dispensing mechanism that moves with the aircraft in a kinematically equivalent fashion; anddispensing the infrared flare material from the infrared flare material-dispensing mechanism to cause an infrared guided missile targeting the aircraft to miss the aircraft,wherein a rate at which said infrared flare material is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein a dispensed pattern of the infrared flare material is selected responsive to a characteristic of a seeker of the infrared guided missile,wherein the step of dispensing includes dispensing the infrared, flare material responsive to a counter-countermeasure of the infrared guided missile. 36. A method for dispensing infrared flare material from an aircraft having an engine, comprising: providing an infrared flare material-dispensing mechanism that moves with the aircraft in a kinematically equivalent fashion; anddispensing the infrared flare material from the infrared flare material-dispensing mechanism to cause an infrared guided missile targeting the aircraft to miss the aircraft,wherein a rate at which said infrared flare material is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein a dispensed pattern of the infrared flare material is selected responsive to a characteristic of a seeker of the infrared guided missile,wherein said infrared flare material comprises a pyrophoric material. 37. A method for dispensing solid flare material from an aircraft having an engine, comprising: providing an infrared flare material-dispensing mechanism that moves with an aircraft in a kinematically equivalent fashion and is controllable to dispense therefrom infrared flare material that is carried in the mechanism in solid form; andcontrollably dispensing a pattern of the infrared flare material from the dispensing mechanism as the aircraft flies,wherein a rate at which said pattern is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein the pattern includes spikes of different radiant intensities, and wherein the more units of flare material dispensed per unit time during each spike, the higher a radiant intensity of each spike,wherein the infrared flare material comprises a pyrophoric material. 38. A method for dispensing solid flare material from an aircraft having an engine, comprising: providing an infrared flare material-dispensing mechanism that moves with an aircraft in a kinematically equivalent fashion and is controllable to dispense therefrom infrared flare material that is carried in the mechanism in solid form; andcontrollably dispensing a pattern of the infrared flare material from the dispensing mechanism as the aircraft flies,wherein a rate at which said pattern is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein the pattern includes spikes of different radiant intensities, and wherein the more units of flare material dispensed per unit time during each spike, the higher a radiant intensity of each spike,wherein the step of controllably dispensing comprises dispensing the pattern of the infrared flare material to have approximately a same infrared spectral characteristics as an exhaust plume of the engine of the aircraft. 39. A method for dispensing solid flare material from an aircraft having an engine, comprising the steps of: providing an infrared flare material-dispensing mechanism that moves with an aircraft in a kinematically equivalent fashion and is controllable to dispense therefrom infrared flare material that is carried in the mechanism in solid form;controllably dispensing a pattern of the infrared flare material from the dispensing mechanism as the aircraft flies,wherein a rate at which said pattern is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein the pattern includes spikes of different radiant intensities, and wherein the more units of flare material dispensed per unit time during each spike, the higher a radiant intensity of each spike,wherein the step of controllably dispensing includes dispensing the pattern of the infrared flare material, wherein a dispensed pattern has a first spike having a first-spike radiant intensity, and a second spike having a second-spike radiant intensity less than the first-spike radiant intensity; andafter the step of dispensing, repeating the step of dispensing the infrared flare material after a waiting period of time. 40. A method for dispensing infrared flare material from an aircraft having an engine, comprising: providing an infrared flare material-dispensing mechanism that moves with the aircraft in a kinematically equivalent fashion; anddispensing the infrared flare material from the infrared flare material-dispensing mechanism to cause an infrared guided missile targeting the aircraft to miss the aircraft,wherein a rate at which said infrared flare material is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein the flare material is carried in the flare material-dispensing mechanism in a solid form, and wherein a set of infrared-emitting properties of the flare material is selected responsive to a set of operating characteristics of the aircraft,wherein the step of dispensing includes the step of dispensing the infrared flare material responsive to a counter-countermeasure of the infrared guided missile. 41. A method for dispensing infrared flare material from an aircraft having an engine, comprising the steps of: providing an infrared flare material-dispensing mechanism that moves with the aircraft in a kinematically equivalent fashion; anddispensing the infrared flare material from the infrared flare material-dispensing mechanism to cause an infrared guided missile targeting the aircraft to miss the aircraft,wherein a rate at which said infrared flare material is dispensed is controlled by commands communicated from said aircraft to said infrared flare material-dispensing mechanism,wherein the flare material is carried in the flare material-dispensing mechanism in a solid form, and wherein a set of infrared-emitting properties of the flare material is selected responsive to a set of operating characteristics of the aircraft,wherein the infrared flare material comprises a pyrophoric material.