초록 ▼

An orbital launch system and its method of operation use a maneuver to improve the launch condition of a booster rocket and payload. A towed launch aircraft, to which the booster rocket is mounted, is towed to a predetermined elevation and airspeed. The towed launch aircraft begins the maneuver by i

An orbital launch system and its method of operation use a maneuver to improve the launch condition of a booster rocket and payload. A towed launch aircraft, to which the booster rocket is mounted, is towed to a predetermined elevation and airspeed. The towed launch aircraft begins the maneuver by increasing its lift, thereby increasing the flight path angle, which increases the tension on the towline connecting the towed launch aircraft to a towing aircraft. The increased tension accelerates the towed launch aircraft and booster rocket, while decreasing the speed (and thus the kinetic energy) of the towing aircraft, while increasing kinetic energy of the towed launch aircraft and booster rocket by transferring energy from the towing aircraft. The potential energy of the towed launch aircraft and booster rocket is also increased, due to the increased lift. The booster rocket is released and ignited, completing the launch.

대표청구항 ▼

1. A method of launching a payload into orbit above a body, the method comprising: mounting a booster rocket connected to the payload to a towed launch aircraft;towing the towed launch aircraft with a towing aircraft via a tow line to a predetermined elevation;executing a first maneuver that increas

1. A method of launching a payload into orbit above a body, the method comprising: mounting a booster rocket connected to the payload to a towed launch aircraft;towing the towed launch aircraft with a towing aircraft via a tow line to a predetermined elevation;executing a first maneuver that increases a lift of the towed launch aircraft to increase a flight path angle of the towed launch aircraft to approximately 25 degrees above horizontal, wherein a tension on the tow line increases substantially, resulting in an acceleration of the towed launch aircraft along a flight path of the towed launch aircraft that increases a kinetic energy of the towed launch aircraft and a deceleration of the towing aircraft that decreases the kinetic energy of the towing aircraft, and wherein the increase in lift of the towed launch aircraft causes an increase in potential energy of the towed launch aircraft, whereby both a kinetic energy and a potential energy of the booster rocket are increased to improve a launch condition of the booster rocket;decoupling the booster rocket and the payload from the towed launch aircraft to end the first maneuver; andigniting the booster rocket to deliver the payload to an orbital distance from the body. 2. The method of claim 1, further comprising continuing to increase the flight path angle of the towed launch aircraft after the decoupling to further increase a flight path angle of the booster rocket and the potential energy of the booster rocket after completing the decoupling. 3. The method of claim 2, wherein the executing a first maneuver increases the flight path angle to approximately 25 degrees above horizontal, and wherein the continuing to increase the flight path angle of the towed launch aircraft further increases the fight path angle after the decoupling to approximately 50 degrees above horizontal. 4. The method of claim 1, wherein the executing a first maneuver comprises raising elevators at a tail of the towed launch aircraft. 5. The method of claim 1, wherein the booster rocket and payload are secured with straps, and wherein the decoupling is commenced by releasing the straps. 6. The method of claim 1, wherein the decoupling comprises the towed launch aircraft executing a second maneuver that decreases the flight path angle of the towed launch aircraft after completion of the decoupling to increase separation of the towed launch aircraft and the booster rocket at the end of the first maneuver. 7. The method of claim 6, wherein the second maneuver is performed by raising flaps along a wing of the towed launch aircraft to reverse the lift of the towed launch aircraft. 8. The method of claim 1, wherein the towed launch aircraft is a glider, and wherein the method further comprises returning the towed launch aircraft to a landing on the body without power. 9. The method of claim 1, wherein the towed launch aircraft is a powered aircraft, and wherein the method further comprises returning the towed launch aircraft to a landing on the body under power. 10. The method of claim 1, wherein the mounting mounts the booster rocket in a cradle provided atop the towed launch aircraft. 11. The method of claim 10, wherein the cradle is located above a wing of the towed launch aircraft and is rotatable with respect to a fuselage of the towed launch aircraft, and wherein the method further comprises rotating the cradle to tilt the booster rocket upward during at least a portion of the executing of the first maneuver. 12. A system for launching a payload into orbit above a body, comprising: a booster rocket connected to the payload;a towed launch aircraft for carrying the booster rocket, wherein the booster rocket and payload are detachably secured to the towed launch aircraft; anda towing aircraft for towing the towed launch aircraft and coupled to the towed launch aircraft by a tow line, wherein the towed launch aircraft executes a first maneuver that increases a lift of the towed launch aircraft to increase a flight path angle of the towed launch aircraft to an angle of approximately 25 degrees above horizontal, wherein a tension on the tow line increases substantially, resulting in an acceleration of the towed launch aircraft along a flight path of the towed launch aircraft that increases a kinetic energy of the towed launch aircraft and a deceleration of the towing aircraft that decreases the kinetic energy of the towing aircraft until the tow line is released and the booster rocket and the payload are decoupled from the towed launch aircraft, whereby the booster rocket can be ignited to deliver the payload to an orbital distance from the body, and wherein the increase in lift of the towed launch aircraft causes an increase in potential energy of the towed launch aircraft, whereby both a kinetic energy and a potential energy of the booster rocket are increased to improve a launch condition of the booster rocket. 13. The system of claim 12, wherein the towed launch aircraft continues to increase the flight path angle of the towed launch aircraft after the decoupling of the tow line to further increase a flight path angle of the booster rocket and the potential energy of the booster rocket after completing the decoupling of the tow line. 14. The system of claim 13, wherein the execution of the first maneuver increases the flight path angle to an angle of approximately 25 degrees above horizontal, and wherein the towed launch aircraft continues to increase the flight path angle to approximately 50 degrees above horizontal after the decoupling. 15. The system of claim 12, wherein the towed launch aircraft executes the first maneuver by raising elevators at a tail of the towed launch aircraft. 16. The system of claim 12, wherein the booster rocket and payload are detachably secured with straps and wherein the decoupling of the booster rocket and payload from the towed launch aircraft is commenced by releasing the straps. 17. The system of claim 12, wherein the towed launch aircraft executes a second maneuver that decreases a flight path angle of the towed launch aircraft to increase separation of the towed launch aircraft and the booster rocket at the end of the first maneuver. 18. The system of claim 17, wherein the second maneuver is performed by raising flaps along a wing of the towed launch aircraft to reverse the lift of the towed launch aircraft. 19. The system of claim 12, wherein the towed launch aircraft is a glider, whereby the towed launch aircraft can be returned to a landing on the body without power. 20. The system of claim 12, wherein the towed launch aircraft is a powered aircraft, whereby the towed launch aircraft can be returned to a landing on the body under power. 21. The system of claim 12, wherein the towed launch aircraft comprises a cradle for mounting the booster rocket, and wherein the booster rocket is mounted in the cradle. 22. The system of claim 21, wherein the cradle is located above a wing of the towed launch aircraft and is rotatable with respect to a fuselage of the towed launch aircraft, and wherein the cradle is rotated to tilt the booster rocket upward during at least a portion of the first maneuver. 23. A method of launching a payload into orbit above a body, the method comprising: securing a booster rocket connected to the payload in a cradle of a towed launch aircraft with a plurality of straps, wherein the cradle is located above a wing of the towed launch aircraft;towing the towed launch aircraft with a towing aircraft via a tow line to a predetermined elevation;executing a first maneuver by raising elevators at a tail of the towed launch aircraft to increase a lift of the towed launch aircraft to increase a flight path angle of the towed launch aircraft to approximately 25 degrees above horizontal, wherein a tension on the tow line increases substantially, resulting in an acceleration of the towed launch aircraft along a flight path of the towed launch aircraft that increases a kinetic energy of the towed launch aircraft and a deceleration of the towing aircraft that decreases the kinetic energy of the towing aircraft, and wherein the increase in lift of the towed launch aircraft causes an increase in potential energy of the towed launch aircraft, whereby both a kinetic energy and a potential energy of the booster rocket are increased to improve a launch condition of the booster rocket;disconnecting the tow line, releasing the straps and executing a second maneuver by raising flaps of a wing of the towed launch aircraft to reverse the lift of the towed launch aircraft to decrease a flight path angle of the towed launch aircraft to separate the towed launch aircraft and the booster rocket and end the first maneuver; andigniting the booster rocket to deliver the payload to an orbital distance from the body. 24. The method of claim 23, wherein the cradle is rotatable with respect to a fuselage of the towed launch aircraft, and wherein the method further comprises rotating the cradle to tilt the booster rocket upward during at least a portion of the first maneuver to increase a lengthwise orientation of the booster rocket to an angle of approximately 50 degrees above horizontal.