A variable-speed constant-frequency (VSCF) power converter includes a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency. The VSCF power generator also includes an inverter control operable to regulate a VSCF output voltage at a point-o
A variable-speed constant-frequency (VSCF) power converter includes a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency. The VSCF power generator also includes an inverter control operable to regulate a VSCF output voltage at a point-of-regulation at a constant frequency, where the generator control and the inverter control independently control a main line contactor of the point-of-regulation to provide redundant fault protection for an aircraft use.
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1. A variable-speed constant-frequency (VSCF) power converter, comprising: a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency; andan inverter control operable to regulate a VSCF output voltage at a point-of-regulation at a constant fr
1. A variable-speed constant-frequency (VSCF) power converter, comprising: a generator control operable to regulate an output voltage of a variable frequency generator at a variable frequency; andan inverter control operable to regulate a VSCF output voltage at a point-of-regulation at a constant frequency, wherein the generator control and the inverter control independently control a main line contactor of the point-of-regulation as an AND-gate function to provide redundant fault protection for an aircraft use, wherein the main line contactor is opened responsive to either the generator control or the inverter control, and the main line contactor is closed when commanded by both of the generator control and the inverter control. 2. The VSCF power converter of claim 1, wherein the generator control adjusts an exciter current of the variable frequency generator to maintain the output voltage of the variable frequency generator within a predetermined voltage range. 3. The VSCF power converter of claim 2, wherein the inverter control dynamically adjusts gate drive timing to an inverter based on a direct current (DC) conversion of the output voltage of the variable frequency generator at a DC link and one or more outputs of the inverter. 4. The VSCF power converter of claim 1, wherein the generator control provides a redundant point-of-regulation status to the inverter control as a backup in case of a fault or damage to one or more lines providing a point-of-regulation status between the point-of-regulation and the inverter control. 5. The VSCF power converter of claim 4, wherein the inverter control provides an inverter status, inverter faults, and load faults to the generator control. 6. The VSCF power converter of claim 1, wherein the generator control commands enablement of the inverter control. 7. The VSCF power converter of claim 1, wherein the output voltage of the variable frequency generator is a multi-phase voltage and the VSCF output voltage is a three phase voltage. 8. A variable-speed constant-frequency (VSCF) power generating system comprising: a variable frequency generator; anda VSCF power converter in an aircraft power panel, the VSCF power converter comprising: a generator control operable to regulate an output voltage of the variable frequency generator at a variable frequency; andan inverter control operable to regulate a VSCF output voltage at a point-of-regulation of the aircraft power panel at a constant frequency, wherein the generator control and the inverter control independently control a main line contactor of the point-of-regulation as an AND-gate function to provide redundant fault protection for an aircraft use, wherein the main line contactor is opened responsive to either the generator control or the inverter control, and the main line contactor is closed when commanded by both of the generator control and the inverter control. 9. The VSCF power generating system of claim 8, wherein the generator control adjusts an exciter current of the variable frequency generator to maintain the output voltage of the variable frequency generator within a predetermined voltage range. 10. The VSCF power generating system of claim 9, wherein the inverter control dynamically adjusts gate drive timing to an inverter based on a required point-of-regulation voltage, direct current (DC) conversion of the output voltage of the variable frequency generator at a DC link, and one or more outputs of the inverter. 11. The VSCF power generating system of claim 8, wherein the generator control provides a redundant point-of-regulation status to the inverter control as a backup in case of a fault or damage to one or more lines providing a point-of-regulation status between the point-of-regulation and the inverter control. 12. The VSCF power generating system of claim 11, wherein the inverter control provides inverter status, inverter faults, and load faults to the generator control. 13. The VSCF power generating system of claim 8, wherein the generator control commands enablement of the inverter control. 14. The VSCF power generating system of claim 8, wherein the output voltage of the variable frequency generator is a multi-phase voltage and the VSCF output voltage is a three phase voltage. 15. A method of controlling a variable-speed constant-frequency (VSCF) power converter, the method comprising: regulating an output voltage of a variable frequency generator at a variable frequency by a generator control of the VSCF power converter;regulating a VSCF power converter output voltage at a point-of-regulation at a constant frequency by an inverter control of the VSCF power converter; andindependently controlling a main line contactor of the point-of-regulation by the generator control and the inverter control as an AND-gate function to provide redundant fault protection for an aircraft use, wherein the main line contactor is opened responsive to either the generator control or the inverter control, and the main line contactor is closed when commanded by both of the generator control and the inverter control. 16. The method of claim 15, further comprising: adjusting, by the generator control, an exciter current of the variable frequency generator to maintain the output voltage of the variable frequency generator within a predetermined voltage range. 17. The method of claim 16, further comprising: dynamically adjusting, by the inverter control, gate drive timing to an inverter based on a required point-of-regulation voltage, a direct current (DC) conversion of the output voltage of the variable frequency generator at a DC link and one or more outputs of the inverter. 18. The method of claim 15, further comprising: providing a redundant point-of-regulation status from the generator control to the inverter control as a backup in case of a fault or damage to one or more lines providing a point-of-regulation status between the point-of-regulation and the inverter control; andproviding an inverter status, inverter faults, and load faults from the inverter control to the generator control. 19. The method of claim 15, further comprising controlling enablement of the inverter control by the generator control. 20. The method of claim 15, wherein the output voltage of the variable frequency generator is a multi-phase voltage and the VSCF output voltage is a three phase voltage.
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이 특허에 인용된 특허 (20)
Cronin Michael J. (Sherman Oaks CA), AC Motor-starting for aircraft engines using APU free turbine driven generators.
Iden Steven M. (Belvidere IL) Shires Edwin J. (Rockford IL) Said Waleed (Rockford IL), Active no-break power transfer control for a VSCF power generating system.
Ejzak Richard P. (Rockford IL) Thom James B. (Rock City IL) Peterson William J. (Rockford IL) Glennon Timothy F. (Rockford IL), Control for an electrical generating and distribution system, and method of operation.
Chang, Jie; LeMond, Charles H.; Wang, Anhua, Distributed system and methodology of electrical power regulation, conditioning and distribution on an aircraft.
Recker Bradley J. (Rockford IL) Cheng Thong-Meng (Rockford IL) Roe Derrick I. (Rockford IL) Rozman Christopher J. (Delavan WI), Low distortion control for a VSCF generating system.
Recker Bradley J. (Rockford IL) Rozman Christopher J. (Delavan WI) Roe Derrick I. (Rockford IL), No break power transfer control for a VSCF power generating system.
Rozman Gregory I. (boyh of P.O. Box 7003 Rockford IL 61125-7003) Risley John (boyh of P.O. Box 7003 Rockford IL 61125-7003), VSCF system with voltage estimation.
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