Efficient operating point for double-ended inverter system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H02J-003/38
H02J-003/46
출원번호
UP-0106871
(2008-04-21)
등록번호
US-7847437
(2011-01-31)
발명자
/ 주소
Chakrabarti, Sibaprasad
Smith, Gregory S.
Nagashima, James M.
Welchko, Brian A.
Perisic, Milun
John, George
출원인 / 주소
GM Global Technology Operations, Inc.
대리인 / 주소
Ingrassia Fisher & Lorenz, P.C.
인용정보
피인용 횟수 :
25인용 특허 :
13
초록▼
Systems and methods are provided for controlling a double-ended inverter system coupled to a first energy source and a second energy source. The method comprises determining a constant power line associated with operation of the double-ended inverter system, the constant power line representing a de
Systems and methods are provided for controlling a double-ended inverter system coupled to a first energy source and a second energy source. The method comprises determining a constant power line associated with operation of the double-ended inverter system, the constant power line representing a desired power flow to the second energy source. The method further comprises determining an operating point on the constant power line, the operating point producing a minimum power loss in the double-ended inverter system for a required output current, and modulating the double-ended inverter system using a first voltage command and a second voltage command corresponding to the operating point.
대표청구항▼
What is claimed is: 1. A method for controlling a double-ended inverter system coupled to a first energy source and a second energy source, the double-ended inverter system including a controller and a motor, the method comprising: determining, by the controller, a required output current for produ
What is claimed is: 1. A method for controlling a double-ended inverter system coupled to a first energy source and a second energy source, the double-ended inverter system including a controller and a motor, the method comprising: determining, by the controller, a required output current for producing a commanded torque in the motor; determining, by the controller, a required voltage for producing the required output current in the motor; determining, by the controller, a constant power line associated with operation of the double-ended inverter system, the constant power line representing a desired power flow to the second energy source, each point along the constant power line corresponding to a combination of voltage commands capable of producing the required voltage while achieving the desired power flow to the second energy source; determining, by the controller, an operating point on the constant power line, the operating point producing a minimum power loss in the double-ended inverter system for the required output current, the operating point comprising a first voltage command and a second voltage command; and modulating, by the controller, the double-ended inverter system using the first voltage command and the second voltage command to operate the double-ended inverter system at the operating point. 2. The method of claim 1, wherein determining the operating point on the constant power line further comprises: selecting a plurality of evaluation points on the constant power line; for each of the plurality of evaluation points: determining a respective first voltage command and a respective second voltage command corresponding to an evaluation point; determining a respective power loss value based on the respective first voltage command and the respective second voltage command, to obtain a plurality of power loss values; identifying a minimum power loss value from the plurality of power loss values; and selecting a designated evaluation point corresponding to the minimum power loss value for use as the operating point. 3. The method of claim 2, further comprising: calculating a first inverter loss based on a peak value of the respective first voltage command, an angle of the respective first voltage command relative to the required output current, a voltage level of the first energy source, and a first inverter switching frequency; and calculating a second inverter loss based on a peak value of the respective second voltage command, an angle of the respective second voltage command relative to the required output current, a voltage level of the second energy source, and a second inverter switching frequency. 4. The method of claim 3, wherein determining the respective power loss value further comprises adding the first inverter loss and the second inverter loss. 5. The method of claim 3, further comprising storing data indicative of the first inverter loss and the second inverter loss. 6. The method of claim 5, further comprising: obtaining a stored first inverter loss corresponding to the peak value of the respective first voltage command and the angle of the respective first voltage command relative to the required output current; and obtaining a stored second inverter loss corresponding to the peak value of the respective second voltage command and the angle of the respective second voltage command relative to the required output current. 7. The method of claim 6, wherein determining the respective power loss value further comprises adding the stored first inverter loss and the stored second inverter loss. 8. A method for controlling a double-ended inverter system coupled to a first energy source and a second energy source, the double-ended inverter system including a controller and a motor, the method comprising: determining a constant power line associated with operation of the double-ended inverter system, the constant power line representing a desired power flow to the second energy source, each point along the constant power line being capable of producing an output current in the motor to achieve a commanded torque; selecting an initial evaluation point on the constant power line corresponding to an angle of 0° relative to a vector corresponding to a required output current; determining a first voltage command and a second voltage command corresponding to the initial evaluation point; determining an initial system power loss based on the first voltage command and the second voltage command; for at least one additional evaluation point: increasing the angle relative to the vector corresponding to the required output current; determining a respective first voltage command and a respective second voltage command corresponding to the additional evaluation point; and determining a respective system power loss from the respective first voltage command and the respective second voltage command, to obtain a plurality of power loss values; identifying a minimum power loss value among the initial system power loss value and the plurality of power loss values; selecting a designated evaluation point on the constant power line corresponding to the minimum power loss value for use as an operating point; and operating, by the controller, the double-ended inverter system in accordance with the operating point to achieve the desired power flow to the second energy source and the commanded torque in the motor. 9. The method of claim 8, wherein determining the second voltage command is based on P=3| v2∥īs|sin αs, where v2 is the second voltage command, īs is the required output current, αs is the angle relative to the required output current, and P is a constant based on the constant power line. 10. The method of claim 9, wherein determining the first voltage command is based on the second voltage command and a required output voltage, by subtracting the second voltage command from the required output voltage. 11. The method of claim 10, further comprising: calculating a first inverter loss based on a peak value of the first voltage command, an angle of the first voltage command relative to the required output current, a voltage level of the first energy source, and a first inverter switching frequency; and calculating a second inverter loss based on a peak value of the second voltage command, an angle of the second voltage command relative to the required output current, a voltage level of the second energy source, and a second inverter switching frequency. 12. The method of claim 11, wherein determining a system power loss further comprises adding the first inverter loss and the second inverter loss. 13. The method of claim 11, further comprising storing data indicative of the first inverter loss and the second inverter loss. 14. The method of claim 13, further comprising: obtaining a stored first inverter loss corresponding to the peak value of the first voltage command and the angle of the first voltage command relative to the required output current; and obtaining a stored second inverter loss corresponding to the peak value of the second voltage command and the angle of the second voltage command relative to the required output current. 15. The method of claim 14, wherein determining a system power loss further comprises adding the stored first inverter loss and the stored second inverter loss. 16. The method of claim 8, wherein operating the double-ended inverter system comprises modulating the double-ended inverter system using the first voltage command and the second voltage command corresponding to the operating point. 17. A double-ended inverter system for use with a motor in a vehicle having a first energy source and a second energy source, the double-ended inverter system comprising: a first inverter coupled to the first energy source and the motor; a second inverter coupled to the second energy source and the motor; and a controller coupled to the first inverter and the second inverter, the controller being configured to achieve a desired power flow within the double-ended inverter system, and the controller comprising a computer-readable medium having stored thereon computer-executable instructions for controlling the double-ended inverter system, the computer-executable instructions being written to: determine a required output current for producing a commanded torque in the motor; determine a constant power line associated with operation of the double-ended inverter system, the constant power line representing the desired power flow to the second energy source, each point on the constant power line corresponding to a combination of voltage commands capable of producing the required output current; determine an operating point on the constant power line, the operating point producing a minimum power loss in the double-ended inverter system for the required output current; modulate the first inverter using a first voltage command corresponding to the operating point; and modulate the second inverter using a second voltage command corresponding to the operating point to achieve the desired power flow to the second energy source and the commanded torque in the motor. 18. The double-ended inverter system of claim 17, the computer-executable instructions being written to: select a plurality of evaluation points on the constant power line; for each of the plurality of evaluation points: determine a respective first voltage command and a respective second voltage command corresponding to an evaluation point; determine a respective power loss value based on the respective first voltage command and the respective second voltage command, to obtain a plurality of power loss values; identify a minimum power loss value from the plurality of power loss values; and select a designated evaluation point corresponding to the minimum power loss value for use as the operating point. 19. The double-ended inverter system of claim 18, the computer-executable instructions being written to: calculate a first inverter loss based on a peak value of the respective first voltage command, an angle of the respective first voltage command relative to the required output current, a voltage level of the first energy source, and a first inverter switching frequency; and calculate a second inverter loss based on a peak value of the respective second voltage command, an angle of the respective second voltage command relative to the required output current, a voltage level of the second energy source, and a second inverter switching frequency; and store the first inverter loss and the second inverter loss. 20. The double-ended inverter system of claim 19, the computer-executable instructions being written to: obtain a stored first inverter loss corresponding to the peak value of the respective first voltage command and the angle of the respective first voltage command relative to the required output current; and obtain a stored second inverter loss corresponding to the peak value of the respective second voltage command and the angle of the respective second voltage command relative to the required output current; and add the stored first inverter loss and the stored second inverter loss.
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