Total air temperature probe and method for reducing de-icing/anti-icing heater error
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01K-015/00
G01F-013/00
G01P-005/00
출원번호
US-0610804
(2009-11-02)
등록번호
US-8392141
(2013-03-05)
발명자
/ 주소
Wigen, Scott John
출원인 / 주소
Rosemount Aerospace Inc.
인용정보
피인용 횟수 :
3인용 특허 :
34
초록▼
A method of reducing de-icing heater error (DHE) in total air temperature (TAT) probes is provided. Using the method, a nominal DHE function is obtained for a particular type of TAT probe, with the nominal DHE function having been derived from a plurality of TAT probes of the particular type. A prob
A method of reducing de-icing heater error (DHE) in total air temperature (TAT) probes is provided. Using the method, a nominal DHE function is obtained for a particular type of TAT probe, with the nominal DHE function having been derived from a plurality of TAT probes of the particular type. A probe specific correction coefficient is calculated for an individual TAT probe of the particular type as a function of a measured DHE at a first airflow and a predicted DHE at the first airflow. The predicted DHE at the first airflow is determined using the nominal DHE function derived from the plurality of TAT probes of the particular type. The probe specific correction coefficient is then stored for later use, or used to determine DHE with the individual TAT probe over a range of airflows as a function of the probe specific correction coefficient.
대표청구항▼
1. A method of reducing de-icing heater error (DHE) in total air temperature (TAT) probes, the method comprising: using processing circuitry to obtain a nominal DHE function derived from a plurality of TAT probes of a particular type;using the processing circuitry to calculate a probe specific corre
1. A method of reducing de-icing heater error (DHE) in total air temperature (TAT) probes, the method comprising: using processing circuitry to obtain a nominal DHE function derived from a plurality of TAT probes of a particular type;using the processing circuitry to calculate a probe specific correction coefficient for an individual TAT probe of the particular type as a function of a measured DHE at a first airflow and a predicted DHE at the first airflow, the predicted DHE at the first airflow being determined using the nominal DHE function derived from the plurality of TAT probes of the particular type; andusing the processing circuitry to determine de-icing heater error with the individual TAT probe over a range of airflows as a function of the probe specific correction coefficient. 2. The method of claim 1, wherein using the processing circuitry to calculate the probe specific correction coefficient for the individual TAT probe of the particular type comprises calculating the probe specific correction coefficient for the individual TAT probe while the individual TAT probe is mounted on an aircraft, and with the first airflow being a steady state airflow. 3. The method of claim 2, wherein calculating the probe specific correction coefficient for the individual TAT probe while the individual TAT probe is mounted on the aircraft, and with the first airflow being a steady state airflow, further comprises calculating the probe specific correction coefficient while the aircraft is on the ground. 4. The method of claim 2, wherein calculating the probe specific correction coefficient for the individual TAT probe while the individual TAT probe is mounted on the aircraft, and with the first airflow being a steady state airflow, further comprises calculating the probe specific correction coefficient while the aircraft is flying at a cruising speed. 5. The method of claim 1, wherein using the processing circuitry to calculate the probe specific correction coefficient further comprises: using the individual TAT probe and the processing circuitry to determine a first TAT at the first airflow and with a probe heater in a first on/off heating state, wherein the first airflow is a steady state airflow;using the processing circuitry to control the probe heater to place the probe heater in a second on/off heating state;using the individual TAT probe and the processing circuitry to determine a second TAT at the first steady state airflow and with the probe heater in the second on/off heating state;using the processing circuitry to calculate the measured DHE as a difference between the first TAT and the second TAT; andusing the processing circuitry to calculate the probe specific correction coefficient by dividing the measured DHE by the predicted DHE at the first steady state airflow determined using the nominal DHE function for the plurality of TAT probes of the particular type. 6. The method of claim 5, and before using the individual TAT probe and the processing circuitry to determine the second TAT at the first steady state airflow with the probe heater in the second on/off state, further comprising waiting a predetermined length of time to allow probe heat to reach a steady state condition. 7. The method of claim 5, and further comprising: using the processing circuitry to control the probe heater to place the probe heater back into the first on/off heating state;using the individual TAT probe and the processing circuitry to determine a third TAT at the first steady state airflow and with a probe heater again in the first on/off heating state;using the processing circuitry to calculate a verification measured DHE as a difference between the second TAT and the third TAT; andusing the processing circuitry to verify the measured DHE by comparing the measured DHE to the verification measured DHE. 8. The method of claim 1, wherein using the processing circuitry to determine DHE with the individual TAT probe over the range of airflows as a function of the probe specific correction coefficient further comprises using the probe specific correction coefficient for the individual TAT probe to modify the nominal DHE function derived from the plurality of TAT probes of the particular type to generate a probe specific DHE function for the individual TAT probe. 9. The method of claim 8, wherein using the probe specific correction coefficient for the individual TAT probe to modify the nominal DHE function derived from the plurality of TAT probes of the particular type to generate the probe specific DHE function for the individual TAT probe further comprises multiplying the nominal DHE function by the probe specific correction coefficient. 10. The method of claim 1, wherein using the processing circuitry to determine DHE with the individual TAT probe over the range of airflows as a function of the probe specific correction coefficient further comprises using the probe specific correction coefficient for the individual TAT probe to modify DHE determined using the nominal DHE function derived from the plurality of TAT probes of the particular type. 11. A total air temperature (TAT) probe system having reduced de-icing heater error (DHE), comprising: a first TAT probe having a heater and configured to measure TAT;memory;processing circuitry coupled to the memory and to the first TAT probe, the processing circuitry configured to perform steps comprising:obtaining a nominal DHE function derived from a plurality of TAT probes of the same type as the first TAT probe;calculating a probe specific correction coefficient for the first TAT probe as a function of a measured DHE for the first TAT probe at a first steady state airflow and a predicted DHE for the first TAT probe at the first steady state airflow, the predicted DHE for the first TAT probe at the first steady state airflow being determined using the nominal DHE function derived from the plurality of TAT probes of the same type as the first TAT probe; andstoring the probe specific correction coefficient in the memory for use in configuring the processing circuitry to determine de-icing heater error with the first TAT probe over a range of airflows as a function of the probe specific correction coefficient. 12. The TAT probe system of claim 11, wherein the processing circuitry is configured to calculate the probe specific correction coefficient for the first TAT probe while the first TAT probe is mounted on an aircraft. 13. The TAT probe system of claim 12, wherein the processing circuitry is configured to calculate the probe specific coefficient for the first TAT probe while the aircraft is on the ground. 14. The TAT probe system of claim 12, wherein the processing circuitry is configured to calculate the probe specific coefficient for the first TAT probe while the aircraft is flying at a cruising speed. 15. The TAT probe system of claim 11, wherein the processing circuitry is configured to store the probe specific correction coefficient in the memory by modifying the nominal DHE function derived from the plurality of TAT probes to generate a probe specific DHE function for the first TAT probe, and storing the probe specific DHE function for use in configuring the processing circuitry to determine DHE with the first TAT probe over the range of airflows. 16. A method of configuring a total air temperature (TAT) probe system to reduce de-icing heater error (DHE) for an individual TAT probe of a particular type, the method comprising: using processing circuitry coupled to the individual TAT probe to obtain a nominal DHE function derived from a plurality of TAT probes of the particular type;using the processing circuitry to calculate a probe specific correction coefficient for the individual TAT probe of the particular type as a function of a measured DHE at a first steady state airflow and a predicted DHE at the first steady state airflow, the predicted DHE at the first steady state airflow being determined using the nominal DHE function derived from the plurality of TAT probes of the particular type; andstoring the probe specific correction coefficient for use by the processing circuitry in determining de-icing heater error with the individual TAT probe over a range of airflows as a function of the probe specific correction coefficient. 17. The method of claim 16, wherein storing the probe specific correction coefficient for use by the processing circuitry further comprises using the probe specific correction coefficient to modify the nominal DHE function derived from the plurality of TAT probes of the particular type to generate a probe specific DHE function for the individual TAT probe, and storing the probe specific DHE function for use by the processing circuitry in determining DHE with the individual TAT probe over the range of airflows. 18. The method of claim 17, wherein using the probe specific correction coefficient to modify the nominal DHE function derived from the plurality of TAT probes of the particular type to generate the probe specific DHE function for the individual TAT probe further comprises multiplying the nominal DHE function by the probe specific correction coefficient. 19. The method of claim 16, wherein using the processing circuitry to calculate the probe specific correction coefficient for the individual TAT probe of the particular type comprises calculating the probe specific correction coefficient for the individual TAT probe while the probe is mounted on an aircraft. 20. The method of claim 19, wherein using the processing circuitry to calculate the probe specific correction coefficient further comprises: using the individual TAT probe and the processing circuitry to determine a first TAT at the first steady state airflow and with a probe heater in a first on/off heating state;using the processing circuitry to control the probe heater to place the probe heater in a second on/off heating state;waiting a length of time to allow probe heat to reach a steady state condition after the probe heater has been placed in the second on/off state;using the individual TAT probe and the processing circuitry to determine a second TAT at the first steady state airflow and with the probe heater in the second on/off heating state;using the processing circuitry to calculate the measured DHE as a function of a difference between the first TAT and the second TAT;using the processing circuitry to calculate the probe specific correction coefficient as a function of a ratio of the measured DHE and the predicted DHE at the first steady state airflow determined using the nominal DHE function for the plurality of TAT probes of the particular type.
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