초록 ▼

An unmanned aerial vehicle (UAV) is designed for low-speed, low altitude, long endurance missions typical to UAVs of this size and class. The UAV structure is configured to be substantially impervious to small arms fire and to have a very small representative radar cross-section. The UAV is modular

An unmanned aerial vehicle (UAV) is designed for low-speed, low altitude, long endurance missions typical to UAVs of this size and class. The UAV structure is configured to be substantially impervious to small arms fire and to have a very small representative radar cross-section. The UAV is modular such that the main wings and tail wing assembly are quickly and easily, detached from the fuselage for ease of transport and to provide an airframe that is quickly and easily adapted to any particular mission.

대표청구항 ▼

What is claimed is: 1. An unmanned aerial vehicle (UAV) comprising: a fuselage assembly; a left main wing assembly attached to the fuselage; a right main wing assembly attached to the fuselage; a first tail boom assembly having a first end and a second end; a second tail boom assembly having a firs

What is claimed is: 1. An unmanned aerial vehicle (UAV) comprising: a fuselage assembly; a left main wing assembly attached to the fuselage; a right main wing assembly attached to the fuselage; a first tail boom assembly having a first end and a second end; a second tail boom assembly having a first end and a second end; a first mounting plate attached to the first tail boom assembly at the first end thereof; a second mounting plate attached to the second tail boom assembly at the first end thereof; wherein the first mounting plate is disposed between the left main wing assembly and the fuselage assembly and the second mounting plate is disposed between the right main wing assembly and the fuselage assembly; the first mounting plate and the second mounting plate each includes a plurality of through holes, and a plurality of tubes extend from the fuselage assembly through the through holes in the first and second mounting plates and into the left and right main wing assemblies; and a tail wing assembly attached to the second ends of the first and second tail boom assemblies; wherein the fuselage assembly, left main wing assembly, right main wing assembly, first tail boom assembly, second tail boom assembly and tail wing assembly are modular such that each assembly is detachably connected and may be replaced by similar assemblies having alternative configurations and capabilities. 2. The UAV according to claim 1, wherein the right main wing assembly, left main wing assembly and tail wing assembly are each comprised of a polystyrene foam core overlaid with aircraft grade plywood veneer. 3. The UAV according to claim 1, wherein the fuselage assembly is configured with exterior chine structures configured to enhance maneuverability and to reduce overall representative radar cross-section. 4. The UAV according to claim 1, wherein the fuselage assembly includes a payload access opening covered by a removable access panel. 5. The UAV according to claim 1, wherein the fuselage assembly includes an engine access opening covered by a removable access panel, and an engine connected to the fuselage assembly. 6. The UAV according to claim 5, wherein the engine comprises a push-type engine. 7. The UAV according to claim 5, wherein the engine comprises a pull-type engine. 8. The UAV according to claim 1, wherein the fuselage assembly includes a plurality of skeleton structures, the skeleton structures including a plurality of aligned through holes formed therein; the right main wing assembly and the left main wing assembly each includes a plurality of holes aligned with the through holes in the skeleton structures; the through holes of the first mounting plate and the second mounting plate are aligned with the through holes in the skeleton structures; and the plurality of tubes extend through the through holes in the skeleton structures and into the holes in the right main wing assembly and the left main wing assembly and through the through holes in the first mounting plate and the second mounting plate. 9. The UAV according to claim 8, wherein the tubes have different cross-sectional sizes. 10. An unmanned aerial vehicle (UAV) comprising: a fuselage assembly; a left main wing assembly removably attached to the fuselage; a right main wing assembly removably attached to the fuselage; and a tail wing assembly that includes a first tail boom assembly connected to a first mounting plate that is compressed between the left main wing assembly and the fuselage assembly, a second tail boom assembly connected to a second mounting plate that is compressed between the right main wing assembly and the fuselage assembly, and a tail wing section connected to the first and second tail boom assemblies; and the first mounting plate and the second mounting plate each includes a plurality of through holes, and a plurality of tubes extend from the fuselage assembly through the through holes in the first and second mounting plates and into the left and right main wing assemblies. 11. The UAV according to claim 10, wherein the fuselage assembly, left main wing assembly, right main wing assembly, and tail wing assembly are modular such that each assembly is detachably connected and may be replaced by similar assemblies having alternative configurations and capabilities. 12. The UAV according to claim 10, wherein the right main wing assembly, left main wing assembly and tail wing assembly are each comprised of materials substantially impervious to small arms fire, such that the small arms fire will pass through the wing assemblies without the UAV being substantially impacted by the full force of the small arms fire. 13. The UAV according to claim 10, wherein the surface of the fuselage assembly is configured with chines to enhance maneuverability and to reduce the overall UAV representative radar cross-section. 14. The UAV according to claim 10, wherein the fuselage assembly includes a payload access opening covered by a removable access panel. 15. The UAV according to claim 10, wherein the fuselage assembly includes an engine access opening covered by a removable access panel, and an engine connected to the fuselage assembly. 16. The UAV according to claim 10, wherein the fuselage assembly includes a plurality of skeleton structures, the skeleton structures including a plurality of aligned through holes formed therein; the right main wing assembly and the left main wing assembly each includes a plurality of holes aligned with the through holes in the skeleton structures; the through holes of the first mounting plate and the second mounting plate are aligned with the through holes in the skeleton structures; and the plurality of tubes extend through the through holes in the skeleton structures and into the holes in the right main wing assembly and the left main wing assembly and through the through holes in the first mounting plate and the second mounting plate. 17. The UAV according to claim 16, wherein the tubes have different cross-sectional sizes. 18. A method of assembling a UAV, the method comprising the steps of: providing a modular fuselage assembly, a modular left main wing assembly, a modular right main wing assembly, first and second modular tail boom assemblies each having a mounting plate attached thereto, and a modular tail wing assembly, each mounting plate includes a plurality of through holes; disposing the mounting plate of the first modular tail boom assembly between the modular left main wing assembly and the fuselage assembly; disposing the mounting plate of the second modular tail boom assembly between the modular right main wing assembly and the fuselage assembly; removably attaching the modular left and right main wing assemblies to the modular fuselage assembly with the respective mounting plates disposed therebetween by installing a plurality of tubes that extend from the modular fuselage assembly through the through holes in the mounting plates and into the modular left and right main wing assemblies; and removably attaching the modular tail wing assembly to each modular tail boom assembly. 19. An unmanned aerial vehicle (UAV), comprising: a modular fuselage assembly including upper and lower fuselage shells, the lower fuselage shell is constructed of a molded composite that includes a honeycomb core surrounded on one side by a layer of carbon/aramid and surrounded on the other side by a layer of carbon/aramid and a layer of fiberglass; a modular left main wing assembly removably attached to the modular fuselage assembly and configured to allow penetration of small arms fire; a modular right main wing assembly removably attached to the modular fuselage assembly and configured to allow penetration of small arms fire; and a modular tail wing assembly that includes a first tail boom assembly connected to a first mounting plate that is disposed between the modular left main wing assembly and the modular fuselage assembly, a second tail boom assembly connected to a second mounting plate that is disposed between the modular right main wing assembly and the modular fuselage assembly, and a tail wing section connected to the first and second tail boom assemblies; and the first mounting plate and the second mounting plate each includes a plurality of through holes, and a plurality of tubes extend from the modular fuselage assembly through the through holes in the first and second mounting plates and into the modular left and right main wing assemblies. 20. The UAV according to claim 19, wherein the modular fuselage assembly, modular left main wing assembly, modular right main wing assembly, and modular tail wing assembly are configured to allow replacement by similar assemblies having alternative configurations and capabilities. 21. The UAV according to claim 19, wherein each modular wing assembly has a wing section comprising a solid foam material core laminated over with aircraft grade plywood.