IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0341331
(2008-12-22)
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등록번호 |
US-8171895
(2012-05-08)
|
발명자
/ 주소 |
- Scolton, Chris J.
- Koehler, Douglas W.
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
11 |
초록
▼
A coolant flow control system includes a fluid cooling device, a coolant bypass circuit, and a controller. The controller is configured to generate a control signal indicative of a desired flow of coolant through the coolant bypass circuit as a function of the projected rate of change in the cooling
A coolant flow control system includes a fluid cooling device, a coolant bypass circuit, and a controller. The controller is configured to generate a control signal indicative of a desired flow of coolant through the coolant bypass circuit as a function of the projected rate of change in the cooling device temperature gradient.
대표청구항
▼
1. A coolant flow control system, comprising: a fluid cooling device, the fluid cooling device having a temperature gradient comprising a rate of change in temperature through a core of the fluid cooling device in relation to a displacement from a given reference point,a first temperature sensor con
1. A coolant flow control system, comprising: a fluid cooling device, the fluid cooling device having a temperature gradient comprising a rate of change in temperature through a core of the fluid cooling device in relation to a displacement from a given reference point,a first temperature sensor configured to monitor a first heat energy parameter associated with the temperature gradient of the cooling device and generate a first heat energy signal, a coolant bypass circuit, anda controller configured to: determine a projected rate of change in the temperature gradient as a function of the heat energy signal, andgenerate a control signal indicative of a desired flow of coolant through the coolant bypass circuit as a function of the projected rate of change in the temperature gradient. 2. The coolant flow control system of claim 1, further comprising a coolant bypass valve, the bypass valve controlling the flow of coolant through the coolant bypass circuit, wherein the control signal is indicative of a desired position of the bypass valve. 3. The coolant flow control system of claim 1, in which the first heat energy parameter monitored by the first temperature sensor comprises a heat input parameter associated with the cooling device, and the first heat energy signal is indicative of a heat input to the cooling device, the system further comprising: a second temperature sensor configured to monitor a heat output parameter associated with the cooling device and generate a second heat energy signal indicative of a heat output from the cooling device,wherein the controller is configured to generate a heat input to the fluid cooling device as a function of the first heat energy signal, a heat output to the fluid cooling device as a function of the second heat energy signal, and the control signal as a function of the heat input to the fluid cooling device and the heat output from the fluid cooling device. 4. The coolant flow control system of claim 3, further comprising: an engine,an engine speed sensor configured to generate a speed signal indicative of the engine speed, andan engine load sensor configured to generate a load signal indicative of the engine load, andwherein the controller is configured to determine the heat input as a function of the first heat energy signal, the speed signal and the load signal. 5. The coolant flow control system of claim 4, wherein the controller is configured to determine the heat output as a function of the second heat energy signal and the speed signal. 6. The coolant flow control system of claim 4, wherein the fluid cooling device includes an aftercooler operable to cool engine intake air. 7. The coolant flow control system of claim 3, in which the first temperature sensor comprises an intake fluid temperature sensor, the heat input parameter comprises a temperature of fluid entering the fluid cooling device, and the first heat energy signal comprises an intake fluid temperature signal indicative of the temperature of fluid entering the fluid cooling device, the system further comprising: an exit fluid temperature sensor configured to generate an exit fluid temperature signal indicative of a temperature of fluid exiting the fluid cooling device, andwherein the controller is configured to determine the heat input as a function of the intake fluid temperature signal and the exit fluid temperature signal. 8. The coolant flow control system of claim 3 in which the second temperature sensor comprises an input coolant temperature sensor, the heat output parameter comprises a temperature of coolant entering the fluid cooling device, and the second heat energy signal comprises an input coolant temperature signal indicative of the temperature of coolant entering the fluid cooling device, the system further comprising: an output coolant temperature sensor configured to generate an output coolant temperature signal indicative of a temperature of coolant exiting the fluid cooling device, andwherein the controller is configured to determine the heat output as a function of the input coolant temperature signal and the output coolant temperature signal. 9. The coolant flow control system of claim 1, in which the first temperature sensor comprises a surface temperature sensor, the first heat energy parameter comprises a surface temperature of the cooling device, and the first heat energy signal comprises a first surface temperature signal indicative of the surface temperature of the cooling device, and wherein the controller is configured to generate the control signal as a function of a change in the first surface temperature signal. 10. The coolant flow control system of claim 9, further comprising a plurality of second temperature sensors configured to generate a plurality of second surface temperature signals indicative of surface temperatures at different locations on the fluid cooling device, and wherein the controller is configured to generate the control signal as a function of the first surface temperature signal and the plurality of second surface temperature signals. 11. A coolant flow control system, comprising: a fluid cooling device, the fluid cooling device having a temperature gradient comprising a rate of change in temperature through a core of the fluid cooling device in relation to a displacement from a given reference point,a first temperature sensor configured to monitor a first heat energy parameter associated with the temperature gradient of the cooling device and generate a first heat energy signal,a coolant bypass circuit, anda controller configured to: determine a projected rate of change in the temperature gradient as a function of the heat energy signal, andgenerate a control signal indicative of a desired flow of coolant through the fluid cooling device as a function of the projected rate of change in the temperature gradient. 12. A coolant flow control method, comprising: providing a fluid cooling device, the fluid cooling device having a temperature gradient comprising a rate of change in temperature through a core of the fluid cooling device in relation to a displacement from a given reference point,determining a first heat energy parameter associated with the temperature gradient of the cooling device,determining a projected rate of change of the temperature gradient of the fluid cooling device as a function of the first heat energy parameter, anddetermining a desired flow of coolant through a coolant bypass circuit as a function of the projected rate of change of the temperature gradient. 13. The coolant flow control method of claim 12, further comprising determining a desired position of a coolant bypass valve as a function of the desired flow of coolant. 14. The coolant flow control method of claim 12, in which the first heat energy parameter comprises a heat input parameter associated with the cooling device, the method further comprising: monitoring a heat output parameter associated with the cooling device,determining a heat input to the fluid cooling device as a function of the heat input parameter,determining a heat output from the fluid cooling device as a function of the heat output parameter, anddetermining the projected rate of change of the temperature gradient as a function of the heat input and the heat output. 15. The coolant flow control method of claim 12, in which the first heat energy parameter comprises a surface temperature of the cooling device, the method further comprising: determining the projected rate of change of the temperature gradient as a function of the surface temperature of the cooling device. 16. The coolant flow control method of claim 14 further comprising: determining an engine speed, andfurther determining at least one of the heat input and the heat output as a function of the engine speed. 17. The coolant flow control method of claim 14, further comprising: determining an engine load, andfurther determining the heat input as a function of the engine load. 18. The coolant flow control method of claim 14, in which the heat input parameter comprises an intake fluid temperature of a fluid entering the fluid cooling device, the method further comprising: determining an exit fluid temperature of the fluid exiting the fluid cooling device, anddetermining the heat input as a function of the intake fluid temperature and the exit fluid temperature. 19. The coolant flow control method of claim 14, in which the heat output parameter comprises an input coolant temperature of a coolant entering the fluid cooling device, the method further comprising: determining an output coolant temperature of the coolant exiting the fluid cooling device, anddetermining the heat output as a function of the input coolant temperature and the output coolant temperature. 20. The coolant flow control method of claim 14, further comprising storing experimental data, and determining at least one of the heat input and the heat output as a function of the experimental data.
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