IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0619123
(2009-11-16)
|
등록번호 |
US-8544792
(2013-10-01)
|
우선권정보 |
WO-PCT/IL2008/000036 (2008-01-08) |
발명자
/ 주소 |
|
출원인 / 주소 |
- Israel Aerospace Industries Ltd.
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
70 |
초록
▼
Disclosed a towbarless airplane tug and method of operating thereof. The tug comprises a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels; an airplane wheel support turret assembly
Disclosed a towbarless airplane tug and method of operating thereof. The tug comprises a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels; an airplane wheel support turret assembly, rotatably mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane; at least one rotation sensor connected to said wheel support turret assembly and operative to sense rotation of said wheel support turret assembly relative to said chassis, said rotation resulting at least from steering control induced movement of the nose landing gear caused by pilot-controlled ground steering of said airplane, and to generate an output indicating a direction of said pilot-controlled ground steering of said airplane; at least one tug wheel driver unit operative to drive said drivable tug wheels; at least one tug wheel steering mechanism operative to steer said steerable tug wheels thereby providing steering of said chassis; and at least one tug controller operative to control operation of at least said tug wheel steering mechanism at least in response to said output of said rotation sensor, so as to cause steering said steerable tug wheels such that said chassis moves in the direction indicated in said output of said rotation sensor.
대표청구항
▼
1. A towbarless airplane tug comprising: (a) a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels;(b) an airplane wheel support turret assembly, rotatably mounted in connection with
1. A towbarless airplane tug comprising: (a) a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels;(b) an airplane wheel support turret assembly, rotatably mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane;(c) at least one rotation sensor connected to said wheel support turret assembly and operative to sense rotation of said wheel support turret assembly relative to said chassis, said rotation resulting at least from steering control induced movement of the nose landing gear caused by pilot-controlled ground steering of said airplane, and to generate an output indicating a direction of said pilot-controlled ground steering of said airplane;(d) at least one tug wheel driver unit operative to drive said drivable tug wheels;(e) at least one tug wheel steering mechanism operative to steer said steerable tug wheels thereby providing steering of said chassis; and(f) at least one tug controller operative to control operation of at least said tug wheel steering mechanism at least in response to said output of said rotation sensor, so as to cause steering said steerable tug wheels such that said chassis moves in the direction indicated in said output of said rotation sensor. 2. The towbarless airplane tug of claim 1 further comprising at least one first force sensor operative in engagement with said at least one nose landing gear wheel so as to sense forces applied to said nose landing gear wheel in at least one generally horizontal direction, and further operative to generate output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; and wherein said tug controller is further operative to control, responsive at least to said output of said first force sensor, said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 3. The towbarless airplane tug of claim 1 further comprising a horizontal base assembly supporting said wheel support turret assembly, engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis and operative to absorb energy resulting from a difference in acceleration or deceleration of said airplane tug relative to the airplane. 4. The towbarless airplane tug of claim 3 further comprising at least one second force sensor positioned in engagement with said energy absorber assembly so as to sense forces applied to said energy absorber assembly and operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane and a tug traction force applied to the tug; and wherein said tug controller is further operative to control, responsive at least to said output of said second force sensor, said tug wheel driver unit so as to maintain forces applied to said nose landing gear of said airplane within predefined limits. 5. The towbarless airplane tug of claim 1 further comprising: (a) a horizontal base assembly supporting said wheel support turret assembly, engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis and operative to absorb energy resulting from a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed; and(b) at least one second force sensor positioned in engagement with said energy absorber assembly so as to sense forces applied to said energy absorber assembly and operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to the airplane, said difference caused, at least, by pilot-controlled deceleration of the airplane and a tug traction force applied to the tug; and wherein said tug controller is operative to control, responsive at least to said output of said second force sensor, said tug driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 6. The towbarless airplane tug of claim 5 wherein said tug controller is operative to maintain the forces applied to said nose landing gear of said airplane within predefined limits by employing at least one force feedback loop characterized by the following: output generated by at least one of said force sensors and at least one input selected from a group consisting of: (a) an indication of known slopes at various locations along an airplane travel surface traversed by said tug;(b) an indication of wind forces applied to said airplane; and(c) an indication of known airplane and tug rolling friction force at various locations along airplane travel surface traversed by said tug. 7. The towbarless airplane tug of claim 1 wherein said tug controller is further operative to control speed of said tug and is adapted to employ at least one speed feedback loop utilizing at least one of the following inputs: (a) an indication of known desired speed at various locations along an airplane travel surface traversed by said tug, obtained by said tug controller using tug location sensing functionality and a predetermined map of said airplane travel surface indicating speed limits there along;(b) an indication of known desired speed obtained by said tug controller from an airplane main pilot controller;(c) a mapping of speed limits along a travel path traversed by said tug and said airplane at an airport according to road and environment conditions;(d) an indication of an instantaneous location of said tug and said airplane along a travel path; and(e) an indication of obstacles along a travel path traversed by said tug. 8. The towbarless airplane tug of claim 1 further comprising at least one front airplane wheel engagement assembly for placement of said airplane wheels on said airplane wheel support turret assembly such that a vertical axis of rotation of said nose landing gear of said airplane passes through a center of rotation of said airplane wheel support turret assembly relative to said chassis. 9. The towbarless airplane tug of claim 8 wherein said airplane wheel engagement assembly is adaptive to airplane wheel size for placement of said airplane wheels on said airplane wheel support assembly such that a vertical line of rotation of said airplane wheel lies along a vertical axis of rotation of said airplane wheel support turret assembly. 10. The towbarless airplane tug of claim 1 wherein said airplane wheel support turret assembly mounted on a horizontal base assembly which is pivotably connected to said chassis, thereby accommodating tilt of said airplane nose landing gear wheels during airplane movement. 11. The towbarless airplane tug of claim 1 wherein said tug controller is further responsive to commands received from an airport command and control center. 12. The towbarless airplane tug of claim 1 wherein said tug controller is further responsive to preprogrammed driving pathways and speed limits. 13. The towbarless airplane tug of claim 1 wherein said tug controller is operative to control steering of said tug by employing at least one position feedback loop utilizing at least an indication of rotation of said airplane nose landing gear wheels clamped in the airplane wheel support turret assembly, said indication provided by said rotation sensor. 14. A towbarless airplane tug comprising: (a) a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels;(b) an airplane wheel support turret assembly, rotatably mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane;(c) a horizontal base assembly supporting said wheel support turret assembly and engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis;(d) at least one rotation sensor connected to said wheel support turret assembly and operative to sense rotation of said wheel support turret assembly relative to said chassis, said rotation resulting at least from steering control induced movement of the nose landing gear caused by pilot-controlled ground steering of said airplane, and further operative to generate an output indicating a direction of said pilot-controlled ground steering of said airplane;(e) at least one first force sensor operative in engagement with at least one nose landing gear wheel so as to sense forces applied to said nose landing gear wheel in at least one generally horizontal direction, and further operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane;(f) at least one second force sensor positioned in engagement with said energy absorber assembly so as to sense forces applied to said energy absorber assembly and operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane;(g) at least one tug controller operative to control operation of said tug in response to at least one output among the outputs generated by said sensors. 15. A towbarless airplane tug comprising: (a) a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels;(b) an airplane wheel support turret assembly, rotatably mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane;(c) a horizontal base assembly supporting said wheel support turret assembly and engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly said chassis;(d) at least one tug wheel driver unit operative to drive said drivable tug wheels;(e) at least one first force sensor positioned in engagement with said energy absorber assembly so as to sense forces applied to said energy absorber assembly and operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; and(f) at least one tug controller operative to control, responsive at least to said output of said first force sensor, said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 16. The towbarless airplane tug of claim 15 further comprising at least one second force sensor operative in engagement with said nose landing gear wheel so as to sense forces applied to said nose landing gear wheel in at least one generally horizontal direction, and further operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; wherein said tug controller is operative to control said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits responsive at least to one output among said outputs of said first force sensor and said second force sensor. 17. The towbarless airplane tug of claim 16 wherein said tug controller is operative to maintain the forces applied to said nose landing gear of said airplane within predefined limits by employing at least one force feedback loop characterized by the following: said output generated by at least one of said first and second force sensors and at least one input selected from a group consisting of: (a) an indication of known slopes at various locations along an airplane travel surface traversed by said tug;(b) an indication of wind forces applied to said airplane; and(c) an indication of known airplane and tug rolling friction force at various locations along airplane travel surface traversed by said tug. 18. The towbarless airplane tug of claim 15 wherein said predefined limits is sufficiently below an acceptable nose landing gear forte limit, so as to leave a margin for unexpected accelerations or decelerations of either the airplane or the airplane tug. 19. A towbarless airplane tug comprising: (a) a chassis mounted on a plurality of tug wheels, at least some of said tug wheels being steerable tug wheels and at least some of said tug wheels being drivable tug wheels;(b) an airplane wheel support turret assembly, rotatably mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane;(c) at least one tug wheel driver unit operative to drive said drivable tug wheels thereby providing a tug traction force;(d) at least one first force sensor operative in engagement with said nose landing gear wheel so as to sense forces applied to said nose landing gear wheel in at least one generally horizontal direction, and further operative to generate an output indicating a difference in acceleration or deceleration of said airplane tug relative to the airplane, said difference caused, at least, by pilot-controlled deceleration of the airplane; and(e) at least one tug controller operative to control, responsive at least to said output of said first force sensor, said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 20. A method of operating a towbarless airplane tug comprising a chassis mounted on a plurality of tug wheels, an airplane wheel support turret assembly mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane, at least one tug wheel driver unit operative to drive drivable tug wheels among said plurality of tug wheels, and at least one tug wheel steering mechanism operative to steer steerable tug wheels among said plurality of tug wheels, the method comprising: (a) sensing rotation of said airplane wheel support turret assembly relative to said chassis with the help of at least one rotation sensor connected to said wheel support turret assembly, said rotation is resulted at least from steering control induced movement of nose landing gear caused by pilot-controlled ground steering of said airplane;(b) generating an output of said rotation sensor indicative of direction of pilot-controlled ground steering of said airplane;(c) controlling, responsive at least to said generated output of said rotation sensor, said tug wheel steering mechanism so as to cause steering said tug wheels such that said chassis moves in the direction indicated in said output of said rotation sensor. 21. The method of claim 20 further comprising: (a) sensing, with the help of at least one first force sensor positioned in engagement with said nose landing gear wheel, forces applied to said nose landing gear wheel in at least one generally horizontal direction;(b) generating an output of said first force sensor indicative of a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; and(c) controlling, responsive at least to said generated output of said first force sensor, said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 22. The method of claim 20 wherein the towbarless airplane tug further comprises a horizontal base assembly supporting said wheel support turret assembly and engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis, the method further comprising: (a) sensing force applied to said energy absorber assembly, said sensing provided with the help of at least one second force sensor positioned in engagement with said energy absorber assembly;(b) generating an output of said second force sensor indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane;(c) controlling, responsive at least to said output of said second force sensor, said tug wheel driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 23. A method of operating a towbarless airplane tug comprising a chassis mounted on a plurality of tug wheels, an airplane wheel support turret assembly mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane, and at least one tug wheel driver unit operative to drive drivable tug wheels among said plurality of tug wheels, the method comprising: (a) sensing, with the help of at least one first force sensor positioned in engagement with said nose landing gear wheel, forces applied to said nose landing gear wheel in at least one generally horizontal direction;(b) generating an output of said first force sensor indicative of a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; and(c) controlling, responsive at least to said generated output of said first force sensor, said tug driver unit so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 24. The method of claim 23 wherein the towbarless airplane tug further comprises a horizontal base assembly supporting said wheel support turret assembly and engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis, the method further comprising: (a) sensing forces applied to said energy, absorber assembly, said sensing provided with the help of at least one second force sensor positioned in engagement with said energy absorber assembly;(b) generating an output of said second force sensor indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane; and(c) controlling said tug wheel driver unit responsive at least to one output among said outputs of said first force sensor and said second force sensor so as to maintain the forces applied to said nose landing gear of said airplane within predefined limits. 25. The method of claim 24 wherein said predefined limits are sufficiently below an acceptable nose landing gear force limit, so as to leave a margin for unexpected accelerations or decelerations of either the airplane or the airplane tug. 26. The method of claim 23 further comprising: (a) sensing rotation of said airplane wheel support turret assembly relative to said chassis with the help of at least one rotation sensor connected to said wheel support turret assembly, said rotation is resulted at least from steering control induced movement of nose landing gear caused by pilot-controlled ground steering of said airplane;(b) generating an output of said rotation sensor indicative of direction of pilot-controlled ground steering of said airplane;(c) controlling, responsive at least to said generated output of said rotation sensor, said tug wheel steering mechanism so as to cause steering said tug wheels such that said chassis moves in the direction indicated in said output of said rotation sensor. 27. A method of operating a towbarless airplane tug comprising a chassis mounted on a plurality of tug wheels, an airplane wheel support turret assembly mounted in connection with said chassis and operative to support at least one wheel of a nose landing gear of an airplane, a horizontal base assembly supporting said wheel support turret assembly and engaged to said chassis by at least one energy absorber assembly mounted between said horizontal base assembly and said chassis, at least one tug wheel driver unit operative to drive drivable tug wheels among said plurality of tug wheels, and at least one tug wheel steering mechanism operative to steer steerable tug wheels among said plurality of tug wheels, the method comprising: (a) sensing rotation of said wheel support turret assembly relative to said chassis with the help of at least one rotation sensor connected to said wheel support turret assembly, said rotation resulting at least from steering control induced movement of the nose landing gear caused by pilot-controlled ground steering of said airplane, and generating an output of said rotation sensor indicating a direction of said pilot-controlled ground steering of said airplane;(b) sensing forces applied to said nose landing gear wheel in at least one generally horizontal direction with the help of at least one first force sensor operative in engagement with said nose landing gear wheel, and generating an output of said first force sensor indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane;(c) sense forces applied to said energy absorber assembly with the help of at least one second force sensor positioned in engagement with said energy absorber assembly, and generating an output of said second force sensor indicating a difference in acceleration or deceleration of said airplane tug relative to acceleration or deceleration of the airplane being towed, said difference caused, at least, by pilot-controlled deceleration of the airplane;(d) controlling operation of said tug with the help of at least one tug controller operative to control said tug in response to at least one output among the outputs generated by said sensors.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.