IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0210896
(2008-09-15)
|
등록번호 |
US-8253357
(2012-08-28)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
3 인용 특허 :
110 |
초록
▼
An electric drive system includes a prime mover connected to a generator, which is controlled in part by an excitation current. The generator makes electrical power available on a dc link. A method of load demand and power generation balancing within the electric drive system includes determining a
An electric drive system includes a prime mover connected to a generator, which is controlled in part by an excitation current. The generator makes electrical power available on a dc link. A method of load demand and power generation balancing within the electric drive system includes determining a voltage of the dc link and determining a torque command by an operator of the system. A speed for each of one or more drive motors receiving power from the dc link is determined and normalized to derive an average motor speed. A mechanical power being commanded is derived based on the average motor speed and the torque command. A predicted excitation current that is required to achieve the derived mechanical power is determined and an actual excitation current is determined based on the predicted excitation current. The actual excitation current is then applied to the generator.
대표청구항
▼
1. A method of load demand and power generation balancing within an electric drive system comprising one or more electric drive motors supplying torque used to propel a machine, the electric drive system including a fuel-driven prime mover for driving an electrical power generator including a field
1. A method of load demand and power generation balancing within an electric drive system comprising one or more electric drive motors supplying torque used to propel a machine, the electric drive system including a fuel-driven prime mover for driving an electrical power generator including a field circuit through which a controlled excitation current flows, the electrical power generator providing electrical power for a DC link having a voltage characteristic and a current characteristic, the method comprising: determining a voltage value of the DC link;determining a torque command by an operator of the electric drive system;determining a speed for each of the one or more electric drive motors receiving power provided from the DC link at the voltage value;normalizing the determined speed to derive an average motor speed;deriving a mechanical power that is being commanded based on the average motor speed and the torque command;determining, using an excitation current predictor function, a predicted excitation current value, for the controlled excitation current flowing through the field circuit of the electrical power generator, based on the derived mechanical power and the voltage value of the DC link, wherein the excitation current predictor function references excitation current data providing, for each of a plurality of constant excitation current levels for the field circuit, a current output produced by the electrical generator at the voltage value of the DC link; andapplying an actual excitation current to the field circuit of the electrical power generator, the actual excitation current being based on the predicted excitation current. 2. The method of load demand and power generation balancing according to claim 1, further comprising determining the actual excitation current using a model based function, and wherein determining the actual excitation current further comprises approximating, using the model based function, a transient performance of the electrical power generator as the excitation current changes to reach a state corresponding to the predicted excitation current. 3. The method of load demand and power generation balancing according to claim 2, wherein approximating the transient performance of the electrical power generator as the excitation current changes includes applying a computational representation of the electrical power generator. 4. The method of load demand and power generation balancing according to claim 2, wherein approximating the transient performance of the electrical power generator as the excitation current changes includes modeling the electrical power generator. 5. The method of load demand and power generation balancing according to claim 2, wherein deriving the mechanical power that is being commanded based on the average motor speed and the torque command includes applying an efficiency function. 6. The method of load demand and power generation balancing according to claim 5, wherein the efficiency function determines an efficiency of each motor at the average motor speed to convert electrical power to mechanical power. 7. The method of load demand and power generation balancing according to claim 1, further including using a power predictor function to determine a power available to the electric drive system based on the actual excitation current and the voltage value of the DC link. 8. The method of claim 1, wherein the excitation current data comprises a plurality of excitation current curves, and wherein each excitation current curve, for a particular constant excitation current level, relates a range of voltage values of the DC link and a range of current output produced by the electrical generator over the range of voltage values. 9. The method of claim 1, wherein the excitation current data is provided for a constant generator rotor rate of rotation. 10. The method of claim 1, wherein the predicted excitation current value is determined, by the excitation current predictor function, based upon a constraint of maintaining the voltage of the DC link at the voltage value of the DC link while changing the current output produced by the electrical generator in response to the torque command. 11. A controller for balancing a load demand and power generation within an electric drive system comprising one or more electric drive motors supplying torque used to propel a machine, the electric drive system including a fuel-driven prime mover for driving an electrical power generator including a field circuit through which a controlled excitation current flows, the electrical power generator providing electrical power for a DC link having a voltage characteristic and a current characteristic, the controller including computer-executable instructions on a computer-readable medium, the computer-executable instructions comprising instructions for: determining a voltage value of the DC link;determining a torque command by an operator of the electric drive system;determining a speed for each of the one or more electric drive motors receiving power provided from the DC link at the voltage value;normalizing the determined speed to derive an average motor speed;deriving a mechanical power that is being commanded based on the average motor speed and the torque command;determining, using an excitation current predictor function, a predicted excitation current value, for the controlled excitation current flowing through the field circuit of the electrical power generator, based on the derived mechanical power and the voltage value of the DC link, wherein the excitation current predictor function references excitation current data providing, for each of a plurality of constant excitation current levels for the field circuit, a current output produced by the electrical generator at the voltage value of the DC link; andapplying an actual excitation current to the field circuit of the electrical power generator, the actual excitation current being based on the predicted excitation current. 12. The controller for balancing the load demand and power generation according to claim 11, further comprising instructions for determining the actual excitation current using a model based function, and wherein the instructions for determining the actual excitation current further comprise instructions for approximating, using the model based function, a transient performance of the electrical power generator as the excitation current changes to reach a state corresponding to the predicted excitation current. 13. The controller for balancing the load demand and power generation according to claim 12, wherein the instructions for approximating the transient performance of the electrical power generator as the excitation current changes include instructions for applying a computational representation of the electrical power generator. 14. The controller for balancing the load demand and power generation according to claim 12, wherein the instructions for approximating the transient performance of the electrical power generator as the excitation current changes include instructions for modeling the electrical power generator. 15. The controller for balancing the load demand and power generation according to claim 12, wherein the instructions for deriving the mechanical power that is being commanded based on the average motor speed and the torque command include instructions for applying an efficiency function. 16. The controller for balancing the load demand and power generation according to claim 15, wherein the efficiency function determines an efficiency of each motor at the average motor speed to convert electrical power to mechanical power. 17. The controller for balancing the load demand and power generation according to claim 11, wherein the computer-executable instructions further include instructions for using a power predictor function to determine a power available to the electric drive system based on the actual excitation current and the voltage value of the DC link. 18. A computer-readable medium having thereon computer-executable instructions for balancing a load demand and power generation within an electric drive system comprising one or more electric drive motors supplying torque used to propel a machine, the electric drive system including a fuel-driven prime mover for driving an electrical power generator including a field circuit through which a controlled excitation current flows, the electrical power generator providing electrical power for a DC link having a voltage characteristic and current a characteristic, a controller including the computer-executable instructions on the computer-readable medium, the computer-executable instructions comprising instructions for: determining a voltage value of the DC link;determining a torque command by an operator of the electric drive system;determining a speed for each of the one or more electric drive motors receiving power provided from the DC link at the voltage value;normalizing the determined speed to derive an average motor speed;deriving a mechanical power that is being commanded based on the average motor speed and the torque command;determining, using an excitation current predictor function, a predicted excitation current value, for the controlled excitation current flowing through the field circuit of the electrical power generator, based on the derived mechanical power and the voltage value of the DC link, wherein the excitation current predictor function references excitation current data providing, for each of a plurality of constant excitation current levels for the field circuit, a current output produced by the electrical generator at the voltage value of the DC link; andapplying an actual excitation current to the field circuit of the electrical power generator, the actual excitation current being based on the predicted excitation current. 19. The computer-readable medium according to claim 18, further comprising instructions for determining the actual excitation current using a model based function, and wherein the instructions for determining the actual excitation current that is required to achieve the derived mechanical power further comprise instructions for approximating, using the model based function, a transient performance of the electrical power generator as the excitation current changes to reach a state corresponding to the predicted excitation current, by applying a computational representation of the electrical power generator. 20. The computer-readable medium according to claim 18, wherein the instructions for deriving the mechanical power that is being commanded based on the average motor speed and the torque command include instructions for applying an efficiency function.
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