IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0392571
(2006-03-30)
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등록번호 |
US-7296562
(2007-11-20)
|
발명자
/ 주소 |
- Withrow,Michael P.
- Dea,Kevin L.
- Gehrke,Christopher R.
- Donoho, II,Michael R.
|
출원인 / 주소 |
|
대리인 / 주소 |
Finnegan, Henderson, Farabow, Garrett & Dunner
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인용정보 |
피인용 횟수 :
14 인용 특허 :
15 |
초록
▼
A control system for estimating the performance of a compressor is disclosed. The control system has a compressor fluidly connected to an inlet manifold of a power source. The control system also has a power source speed sensor to provide an indication of a rotational speed of the power source, an i
A control system for estimating the performance of a compressor is disclosed. The control system has a compressor fluidly connected to an inlet manifold of a power source. The control system also has a power source speed sensor to provide an indication of a rotational speed of the power source, an inlet pressure sensor to provide an indication of a pressure of a fluid within the inlet manifold, an inlet temperature sensor to provide an indication of a temperature of the fluid within the inlet manifold, an atmospheric pressure sensor to provide an indication of an atmospheric pressure, and a control module in communication with each of the sensors. The control module is configured to monitor an engine valve opening duration and an exhaust gas recirculation valve position, and estimate a compressor inlet pressure based on the provided indications, the monitored duration, and the monitored position.
대표청구항
▼
What is claimed is: 1. A control system for estimating performance of a compressor, comprising: a compressor fluidly connected to an inlet manifold of a power source and being configured to receive a mixed flow of air and exhaust; a power source speed sensor associated with an output of the power s
What is claimed is: 1. A control system for estimating performance of a compressor, comprising: a compressor fluidly connected to an inlet manifold of a power source and being configured to receive a mixed flow of air and exhaust; a power source speed sensor associated with an output of the power source and being configured to provide an indication of a rotational speed of the power source; an inlet pressure sensor associated with the inlet manifold and being configured to provide an indication of a pressure of a fluid within the inlet manifold; an inlet temperature sensor associated with the inlet manifold of the power source and being configured to provide an indication of a temperature of the fluid within the inlet manifold; an atmospheric pressure sensor configured to provide an indication of an atmospheric pressure; and a control module in communication with the power source speed sensor, inlet pressure sensor, inlet temperature sensor, and atmospheric pressure sensor, the control module being configured to: monitor: an engine valve opening duration; and an exhaust gas recirculation valve position; and estimate a compressor inlet pressure based on the provided indications, the monitored engine valve opening duration, and the monitored exhaust gas recirculation valve position. 2. The control system of claim 1, further including: an exhaust gas pressure sensor configured to provide an indication of an exhaust gas pressure; and an exhaust gas temperature sensor configured to provide an indication of an exhaust gas temperature, wherein the control module is further configured to determine an exhaust gas density based on the provided indications of exhaust gas pressure and temperature. 3. The control system of claim 2, further including an exhaust gas differential pressure sensor configured to provide an indication of an exhaust gas differential pressure associated with an exhaust venturi, wherein the control module is further configured estimate an exhaust gas recirculation mass air flow value based on the provided indication of exhaust gas differential pressure and the determined exhaust gas density. 4. The control system of claim 3, further including an atmospheric temperature sensor configured to provide an indication of an atmospheric temperature, wherein the control module is further configured to: estimate a total mass air flow of fluid through the compressor based on: the monitored engine valve opening duration; the provided indication of a rotational speed of the power source; the provided indication of a pressure of a fluid within the inlet manifold; and the provided indication of a temperature of the fluid within the inlet manifold; and estimate a compressor inlet temperature based on: the estimated total mass air flow; the provided indication of an atmospheric temperature; the estimated exhaust gas recirculation mass air flow; and the provided indication of an exhaust gas temperature. 5. The control system of claim 4, wherein the control module is further configured to estimate a compressor outlet pressure based on: the estimated total mass air flow; and the provided indication of a pressure of a fluid within the inlet manifold. 6. The control system of claim 5, wherein the control module is further configured to estimate a compressor efficiency based on: the estimated total mass air flow; the estimated compressor outlet pressure; and the estimated compressor inlet pressure. 7. The control system of claim 5, further including a compressor speed sensor configured to provide an indication of a rotational speed of the compressor, wherein the control module is further configured to estimate a compressor efficiency based on: the estimated compressor outlet pressure; the estimated compressor inlet pressure; and the provided indication of a rotational speed of the compressor. 8. The control system of claim 4, further including a compressor speed sensor configured to provide an indication of a rotational speed of the compressor, wherein the control module is further configured to estimate a compressor efficiency based on: the estimated total mass air flow; and the provided indication of a rotational speed of the compressor. 9. A method of estimating performance of a compressor, comprising: receiving an indication of a rotational speed of the power source; receiving an indication of a pressure of a fluid within the inlet manifold; receiving an indication of a temperature of the fluid within the inlet manifold; receiving an indication of an atmospheric pressure; receiving an indication of an engine valve opening duration; receiving an indication of an exhaust gas recirculation valve position; and estimating a compressor inlet pressure based on the received indications. 10. The method of claim 9, further including: receiving an indication of an exhaust gas pressure; receiving an indication of an exhaust gas temperature; and determining an exhaust gas density based on the received indications of exhaust gas pressure and temperature. 11. The method of claim 10, further including: receiving an indication of an exhaust gas differential pressure associated with an exhaust venturi; and estimating an exhaust gas recirculation mass air flow value based on the received indication of exhaust gas differential pressure and the determined exhaust gas density. 12. The method of claim 11, further including: receiving an indication of an atmospheric temperature; estimating a total mass air flow of fluid through the compressor based on: the received indication of an engine valve opening duration; the received indication of a rotational speed of the power source; the received indication of a pressure of a fluid within the inlet manifold; and the provided indication of a temperature of the fluid within the inlet manifold; and estimating a compressor inlet temperature based on: the estimated total mass air flow; the received indication of an atmospheric temperature; the estimated exhaust gas recirculation mass air flow; and the received indication of an exhaust gas temperature. 13. The method of claim 12, further including estimating a compressor outlet pressure based on: the total mass air flow; and the received indication of a pressure of a fluid within the inlet manifold. 14. The method of claim 13, further including estimating a compressor efficiency based on: the estimated total mass air flow; the estimated compressor outlet pressure; and the estimated compressor inlet pressure. 15. The method of claim 13, further including: receiving an indication of a rotational speed of the compressor; and estimating a compressor efficiency based on: the estimated compressor outlet pressure; the estimated compressor inlet pressure; and the received indication of a rotational speed of the compressor. 16. The method of claim 12, further including: receiving an indication of a rotational speed of the compressor; and estimating a compressor efficiency based on: the estimated total mass air flow; and the received indication of a rotational speed of the compressor. 17. A machine, comprising: an engine having variable engine valve timing and an inlet manifold; an air induction system having a compressor configured to supply compressed air through the inlet manifold to the engine; an exhaust recirculation system having a recirculation valve configured to meter exhaust gas to the compressor; an engine speed sensor associated configured to provide an indication of a rotational speed of the engine; an inlet manifold pressure sensor configured to provide an indication of a pressure of a fluid within the inlet manifold; an inlet manifold temperature sensor configured to provide an indication of a temperature of the fluid within the inlet manifold; an atmospheric pressure sensor configured to provide an indication of an atmospheric pressure; and a control module in communication with the inlet manifold pressure, inlet manifold temperature, and atmospheric pressure sensors, the control module being configured to: monitor: an engine valve opening duration; and a position of the recirculation valve; and estimate a compressor inlet pressure based on the provided indications, monitored engine valve opening duration, and monitored recirculation valve position. 18. The machine of claim 17, further including: an exhaust gas pressure sensor configured to provide an indication of an exhaust gas pressure; an exhaust gas temperature sensor configured to provide an indication of an exhaust gas temperature; and an exhaust gas differential pressure sensor configured to provide an indication of an exhaust gas differential pressure associated with an exhaust venturi, wherein the control module is further configured to: determine an exhaust gas density based on the provided indications of exhaust gas pressure and temperature; and estimate an exhaust gas recirculation mass air flow value based on the provided indication of exhaust gas differential pressure and the determined exhaust gas density. 19. The machine of claim 18, further including an atmospheric temperature sensor configured to provide an indication of an atmospheric temperature, wherein the control module is further configured to: estimate a total mass air flow of fluid through the compressor based on: the monitored engine valve opening duration; the provided indication of a rotational speed of the power source; the provided indication of a pressure of a fluid within the inlet manifold; and the provided indication of a temperature of the fluid within the inlet manifold; and estimate a compressor inlet temperature based on: the estimated total mass air flow; the provided indication of an atmospheric temperature; the estimated exhaust gas recirculation mass air flow; and the provided indication of an exhaust gas temperature. 20. The machine of claim 19, wherein the control module is further configured to: estimate a compressor outlet pressure based on: the total mass air flow; and the indication of a pressure of a fluid within the inlet manifold; and estimate a compressor efficiency based on: the estimated total mass air flow; the estimated compressor outlet pressure; and the estimated compressor inlet pressure. 21. The machine of claim 20, further including a compressor speed sensor configured to provide an indication of a rotational speed of the compressor, wherein the control module is further configured to: estimate a compressor efficiency based on: the estimated compressor outlet pressure; the estimated compressor inlet pressure; and the provided indication of a rotational speed of the compressor; and estimate a compressor efficiency based on: the estimated total mass air flow; and the provided indication of a rotational speed of the compressor.
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