초록 ▼

Propellant management systems and methods are provided for controlling the delivery of liquid propellants in a space launch vehicle utilizing multiple rockets. The propellant management systems and methods may be configured to enable substantial simultaneous depletion of liquid propellants in each o

Propellant management systems and methods are provided for controlling the delivery of liquid propellants in a space launch vehicle utilizing multiple rockets. The propellant management systems and methods may be configured to enable substantial simultaneous depletion of liquid propellants in each of a plurality of active rockets during operation of various booster stages of the launch vehicle.

대표청구항 ▼

What is claimed is: 1. A launch vehicle, comprising: a plurality of liquid booster rockets comprising first and second boosters, wherein each said booster comprises: a first tank comprising a first propellant constituent; a second tank comprising a second propellant constituent; and a throttle regu

What is claimed is: 1. A launch vehicle, comprising: a plurality of liquid booster rockets comprising first and second boosters, wherein each said booster comprises: a first tank comprising a first propellant constituent; a second tank comprising a second propellant constituent; and a throttle regulator valve fluidly interconnected with said first and second tanks, wherein said throttle regulator valve controls a thrust of its corresponding said booster; and a differential propellant logic that is operatively interconnected with said throttle regulator valve of said first and second boosters, wherein said differential propellant logic outputs a first differential propellant control signal to said throttle regulator valve of said first booster based at least in part upon there being difference in an amount of said first propellant constituent associated with said first booster and an amount of said first propellant constituent associated with said second booster. 2. The launch vehicle of claim 1, wherein said first propellant constituent is one of an oxidizer and a fuel, and said second propellant constituent is the other of said oxidizer and said fuel. 3. The launch vehicle of claim 1, wherein each said booster further comprises: means for determining an amount of said first propellant constituent in said first tank of each of said plurality of liquid booster rockets, wherein said differential propellant logic is operatively interconnected with said means for determining of said first booster and means for determining of said second booster. 4. The launch vehicle of claim 1, wherein each said booster further comprises: first means for determining a mass of said first propellant constituent in said first tank and second means for determining a mass of said first propellant constituent in said second tank, wherein said differential propellant logic is operatively interconnected with said first and second means for determining. 5. The launch vehicle of claim 1, further comprising: a first total flow rate logic that is operatively interconnected with said throttle regulator valve of said first booster, wherein said first total flow rate logic outputs a first total flow rate control signal to said throttle regulator valve of said first booster based upon a difference between a theoretical total propellant flow rate associated with said first booster and an actual total propellant flow rate associated with said first booster; and a second total flow rate logic that is operatively interconnected with said throttle regulator valve of said second booster, and wherein said second total flow rate logic outputs a second total flow rate control signal to said throttle regulator valve of said second booster based upon a difference between a theoretical total propellant flow rate associated with said second booster and an actual total propellant flow rate associated with said second booster. 6. The launch vehicle of claim 5, wherein each said booster further comprises a first mixture ratio valve, wherein said launch vehicle further comprises: a mixture ratio logic operatively interconnected with said first mixture ratio valve of said first and second boosters, wherein said mixture ratio logic operatively interfaces with said first mixture ratio valve of said first booster so that said first and second propellant constituents of said first booster are at least substantially simultaneously depleted, and wherein said mixture ratio logic further operatively interfaces with said first mixture ratio valve of said second booster so that said first and second propellant constituents of said second booster are at least substantially simultaneously depleted. 7. The launch vehicle of claim 1, further comprising: first means for operating said throttle regulator valve of said first booster to account for a difference between a theoretical total propellant flow rate associated with said first booster and an actual total propellant flow rate associated with said first booster; and second means for operating said throttle regulator valve of said second booster to account for a difference between a theoretical total propellant flow rate associated with said second booster and an actual total propellant flow rate associated with said second booster. 8. The launch vehicle of claim 7, wherein each said booster comprises a first mixture ratio valve, wherein said launch vehicle further comprises: third means for operating said first mixture ratio valve of said first booster so that said first and second propellant constituents of said first booster are at least substantially simultaneously depleted; and fourth means for operating said first mixture ratio valve of said second booster so that said first and second propellant constituents of said second booster are at least substantially simultaneously depleted. 9. The launch vehicle of claim 1, further comprising: means for calculating an amount of said first propellant constituent in each of said first and second boosters, wherein said means for calculating comprises means for accounting for an angular acceleration of said launch vehicle. 10. The launch vehicle of claim 1, wherein each said booster further comprises: first mass determination logic associated with said first tank; and second mass determination logic associated with said second tank, wherein said first and second mass determination logics are each operatively interconnected with said differential propellant logic. 11. The launch vehicle of claim 10, further comprising: an axial acceleration logic that addresses an angular acceleration of said launch vehicle, wherein said axial acceleration logic is operatively interconnected with said first mass determination logic and said second mass determination logic. 12. The launch vehicle of claim 1, further comprising: an axial acceleration logic that addresses an angular acceleration of said launch vehicle and that is operatively interconnected with said differential propellant logic. 13. A launch vehicle, comprising: a thrust source comprising a plurality of rockets, wherein each of said plurality of rockets comprises: a tank containing a propellant constituent; a tank sensor at least operably interconnected with said tank; and a throttle valve fluidly interconnected with said tank, wherein said throttle valve controls a thrust of said rocket; propellant logic operably interconnected with said tank sensor of each of said plurality of rockets, wherein said propellant logic is adapted to calculate an amount of said propellant constituent in each of said plurality of rockets; differential propellant logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said differential propellant logic is adapted to calculate a difference in said amount of said propellant constituent between each of said plurality of rockets, and wherein said differential propellant logic is adapted to send a first signal to said throttle valve of at least one of said plurality of rockets to account for said difference; a plurality of gyro sensors; and axial acceleration logic operably interconnected with said plurality of gyro sensors and said propellant logic, wherein said axial acceleration logic is adapted to calculate an axial acceleration based upon an angular acceleration of said launch vehicle and send an axial acceleration adjustment signal to said propellant logic, wherein said propellant logic is further adapted to use said axial acceleration adjustment signal in calculating said amount of said propellant constituent in said tank of each of said plurality of rockets. 14. The launch vehicle of claim 13, wherein said propellant constituent comprises an oxidizer. 15. The launch vehicle of claim 13, wherein said propellant constituent comprises a fuel. 16. The launch vehicle of claim 13, further comprising: total flow rate logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said total flow rate logic is adapted to calculate a difference between a theoretical total propellant flow rate and an actual total propellant flow rate for each of said plurality of rockets, and wherein said total flow rate logic is adapted to send a second signal to said throttle valve of each of said plurality of rockets if a corresponding said difference is more than a predetermined amount. 17. The launch vehicle of claim 13, wherein said tank is a first tank and said propellant constituent is a first propellant constituent; wherein each of said plurality of rockets further comprises: a second tank containing a second propellant constituent, wherein said throttle valve for each of said plurality of rockets is fluidly interconnected with its corresponding said first and second tanks; and a second tank sensor at least operably interconnected with said second tank. 18. The launch vehicle of claim 17, wherein said propellant logic is operably interconnected with said second tank sensor of each of said plurality of rockets. 19. The launch vehicle of claim 17, wherein said first propellant constituent is an oxidizer and wherein said second propellant constituent is a fuel. 20. The launch vehicle of claim 17, wherein each of said plurality of rockets comprises: a first mixture ratio valve in fluid communication with said first and second tanks. 21. The launch vehicle of claim 20, further comprising: mixture ratio logic operably interconnected with said propellant logic and said first mixture ratio valve of each of said plurality of rockets, wherein said mixture ratio logic is adapted to compare an amount of said first propellant constituent and an amount of said second propellant constituent for each of said plurality of rockets, and wherein said mixture ratio logic operatively interfaces with said first mixture ratio valve of each of said plurality of rockets so that said first propellant constituent and said second propellant constituent in each said rocket are at least substantially simultaneously depleted. 22. The launch vehicle of claim 17, further comprising: total flow rate logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said total flow rate logic is adapted to calculate a difference between a theoretical total propellant flow rate and an actual total propellant flow rate for each of said plurality of rockets, and wherein said total flow rate logic is adapted to send a second signal to said throttle valve of each of said plurality of rockets if a corresponding said difference is more than a predetermined amount. 23. A launch vehicle, comprising: a thrust source comprising a plurality of rockets, wherein each of said plurality of rockets comprises: a first tank containing a first propellant constituent; a second tank containing a second propellant constituent; a first tank sensor at least operably interconnected with said first tank; a second tank sensor at least operably interconnected with said second tank; a throttle valve fluidly interconnected with said first and second tanks, wherein said throttle valve controls a thrust of said rocket; and a first mixture ratio valve in fluid communication with said first and second tanks; propellant logic operably interconnected with said tank sensors of each of said plurality of rockets, wherein said propellant logic is adapted to calculate an amount of said propellant constituents in each of said plurality of rockets; differential propellant logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said differential propellant logic is adapted to calculate a difference in said amount of said propellant constituents between each of said plurality of rockets, and wherein said differential propellant logic is adapted to send a first signal to said throttle valve of at least one of said plurality of rockets to account for said difference; and mixture ratio logic operably interconnected with said propellant logic and said first mixture ratio valve of each of said plurality of rockets, wherein said mixture ratio logic is adapted to compare an amount of said first propellant constituent and an amount of said second propellant constituent for each of said plurality of rockets, and wherein said mixture ratio logic operatively interfaces with said first mixture ratio valve of each of said plurality of rockets so that said first propellant constituent and said second propellant constituent in each said rocket are at least substantially simultaneously depleted. 24. The launch vehicle of claim 23, wherein said first propellant constituent comprises an oxidizer. 25. The launch vehicle of claim 23, wherein said second propellant constituent comprises a fuel. 26. The launch vehicle of claim 23, further comprising: total flow rate logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said total flow rate logic is adapted to calculate a difference between a theoretical total propellant flow rate and an actual total propellant flow rate for each of said plurality of rockets, and wherein said total flow rate logic is adapted to send a second signal to said throttle valve of each of said plurality of rockets if a corresponding said difference is more than a predetermined amount. 27. The launch vehicle of claim 23, wherein said propellant logic is operably interconnected with said second tank sensor of each of said plurality of rockets. 28. The launch vehicle of claim 23, wherein said first propellant constituent is an oxidizer and wherein said second propellant constituent is a fuel. 29. The launch vehicle of claim 23, further comprising: total flow rate logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said total flow rate logic is adapted to calculate a difference between a theoretical total propellant flow rate and an actual total propellant flow rate for each of said plurality of rockets, and wherein said total flow rate logic is adapted to send a second signal to said throttle valve of each of said plurality of rockets if a corresponding said difference is more than a predetermined amount. 30. The launch vehicle of claim 23, further comprising: a plurality of gyro sensors; and axial acceleration logic operably interconnected with said plurality of gyro sensors and said propellant logic, wherein said axial acceleration logic is adapted to calculate an axial acceleration based upon an angular acceleration of said launch vehicle and send an axial acceleration adjustment signal to said propellant logic, wherein said propellant logic is further adapted to use said axial acceleration adjustment signal in calculating said amount of said propellant constituents in said tank of each of said plurality of rockets. 31. A launch vehicle, comprising: a thrust source comprising a plurality of rockets, wherein each of said plurality of rockets comprises: a first tank containing a first propellant constituent; a second tank containing a second propellant constituent; a first tank sensor at least operably interconnected with said first tank; a second tank sensor at least operably interconnected with said second tank; and a throttle valve fluidly interconnected with said first and second tanks, wherein said throttle valve controls a thrust of said rocket; propellant logic operably interconnected with said first tank sensor of each of said plurality of rockets, wherein said propellant logic is adapted to calculate an amount of said propellant constituent in each of said plurality of rockets; differential propellant logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said differential propellant logic is adapted to calculate a difference in said amount of said propellant constituents between each of said plurality of rockets, and wherein said differential propellant logic is adapted to send a first signal to said throttle valve of at least one of said plurality of rockets to account for said difference; and total flow rate logic operably interconnected with said propellant logic and said throttle valve of each of said plurality of rockets, wherein said total flow rate logic is adapted to calculate a difference between a theoretical total propellant flow rate and an actual total propellant flow rate for each of said plurality of rockets, and wherein said total flow rate logic is adapted to send a second signal to said throttle valve of each of said plurality of rockets if a corresponding said difference is more than a predetermined amount. 32. The launch vehicle of claim 31, wherein said first propellant constituent comprises an oxidizer. 33. The launch vehicle of claim 31, wherein said second propellant constituent comprises a fuel. 34. The launch vehicle of claim 31, wherein said propellant logic is operably interconnected with said second tank sensor of each of said plurality of rockets. 35. The launch vehicle of claim 31, wherein said first propellant constituent is an oxidizer and wherein said second propellant constituent is a fuel. 36. The launch vehicle of claim 31, wherein each of said plurality of rockets comprises: a first mixture ratio valve in fluid communication with said first and second tanks.