IPC분류정보
| 국가/구분 |
United States(US) Patent
등록
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| 국제특허분류(IPC7판) |
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| 출원번호 |
US-0631204
(2000-08-01)
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발명자
/ 주소 |
- Soussan, Daniel A.
- Miller, Douglas P.
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| 출원인 / 주소 |
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| 대리인 / 주소 |
Scull, Peter H.O'Connor, Edna M.Butterfield, Laura M.
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| 인용정보 |
피인용 횟수 :
23 인용 특허 :
52 |
초록
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Correction quantities are generated for yielding closer approximations of actual parameters. These are obtained by preliminarily subjecting parametric transducers to pre-selected parametric values and recording the measured values for each transducer in a data table for later use as or in correction
Correction quantities are generated for yielding closer approximations of actual parameters. These are obtained by preliminarily subjecting parametric transducers to pre-selected parametric values and recording the measured values for each transducer in a data table for later use as or in correction quantities. An embodiment includes interpolation relative to data table values closest to the operationally measured parametric value and using the resulting interpolated value as a corrected parametric value. Such interpolations may be performed for two parametric transducers relative to two substances. The resulting corrected parametric values may then be subtracted to obtain a parametric difference. A further embodiment may include using correction quantities of a reference parametric transducer in interpolation calculations for the actual parametric transducers. Similarly, other data table correction recordations such as differences between two measured parameters can be used to modify an operationally measured parametric differential. Reference transducer corrections can be used here as well.
대표청구항
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Correction quantities are generated for yielding closer approximations of actual parameters. These are obtained by preliminarily subjecting parametric transducers to pre-selected parametric values and recording the measured values for each transducer in a data table for later use as or in correction
Correction quantities are generated for yielding closer approximations of actual parameters. These are obtained by preliminarily subjecting parametric transducers to pre-selected parametric values and recording the measured values for each transducer in a data table for later use as or in correction quantities. An embodiment includes interpolation relative to data table values closest to the operationally measured parametric value and using the resulting interpolated value as a corrected parametric value. Such interpolations may be performed for two parametric transducers relative to two substances. The resulting corrected parametric values may then be subtracted to obtain a parametric difference. A further embodiment may include using correction quantities of a reference parametric transducer in interpolation calculations for the actual parametric transducers. Similarly, other data table correction recordations such as differences between two measured parameters can be used to modify an operationally measured parametric differential. Reference transducer corrections can be used here as well. where Sxx(fk) is the two-side autospectral density. 4. The method of claim 1 wherein, the logarithmic autospectral density is logarithmically converted from the the two-side autospectral density, the logarithmic autospectral density being a logarithm in base ten of the two-side autospectral density using a logarithmic equation of log[Sxx(fk)] for k=-(N/2)+1, . . . , N/2. 5. The method of claim 1 wherein, the logarithmic autospectral density is inversely Fourier transformed into the cepstrum vibration signal using a two-sided cepstrum equation of where Cyy(τn) is the cepstrum vibration signal. 6. The method of claim 1 wherein the time signal generating step comprises the steps of: detecting a movement speed signal from the periodic speed signal, averaging the movement speed signal into an average movement speed signal, and inverting the average movement speed signal into the time signal. 7. The method of claim 1 wherein, the cepstrum vibration signal is in a periodic time domain, the time signal is a value identifying a point in the periodic time domain for sampling detection a value of the cepstrum vibration signal for generating the cepstrum parameter. 8. A method of determining a defect in a machine having a moving part, the method comprising the steps of: operating the machine during run time for producing vibrations from the moving part, the moving part moving at a periodic rate, receiving vibration signals from the vibrations, receiving tachometer signals indicating the periodic rate of the periodic movement of the moving part, acquiring the vibration signals and the tachometer signals, storing the vibration and tachometer signals, retrieving the vibration and tachometer signals, converting the vibration and tachometer signals into digital form and into converted vibration signals and converted tachometer signals, respectively, transforming the converted vibration signals into a Fourier spectrum vibration signal, calculating a two-sided autospectral density signal from the Fourier spectrum vibration signal, logarithmically converting the two-sided autospectral density signal into a logarithmic autospectral density signal, inverse transforming the logarithmic autospectral density signal into a cepstrum vibration signal, detecting a speed signal from the converted tachometer signals, averaging the speed signal into an average speed signal, inverting the average speed signal into an average periodic time value signal, detecting the cepstrum vibration signal at the average periodic time value signal for providing a cepstrum parameter for the machine, repeating all of the steps for a plurality of like machines for defining a base line, and determining when the cepstrum parameter for the machine is outside the base line for indicating the defect of the machine. 9. The method of claim 8 wherein, the vibration signals and the tachometer signals are synchronized in time during the run time, the cepstrum vibration signal and the average periodic time value signal are synchronized in time, and the average periodic time value signal has an average periodic time value for locating the cepstrum parameter as a value of the cepstrum vibration signal at a time point corresponding to an instance in time during the run time. 10. The method of claim 8 wherein, the vibration signals and the tachometer signals are synchronized in time during the run time, the cepstrum vibration signal and the average periodic time value signal are synchronized in time, and the average periodic time value signal has a average periodic time value for locating the cepstrum parameter as a value of the cepstrum vibration signal at a time point corresponding to an instance in time during the run time, the method further comprising the step of: repeating all of the method steps a plurality of times for generating a respective plural ity of cepstrum parameters for the machine. 11. The method of claim 8 wherein, the vibration signals and the tachometer signals are synchronized in time during the run time, the cepstrum vibration signal and the average periodic time value signal are synchronized in time, the average periodic time value signal has a average periodic time value for locating the cepstrum parameter as a value of the cepstrum vibration signal at a time point corresponding to an instance in time during the run time, the method further comprising the steps of: repeating all of the steps a plurality of times for generating a set of cepstrum parameters for the machine, and comparing the test set of cepstrum parameters to the base line for determining when the test set of cepstrum parameters are within the base line for indicating a proper operation of the machine and for determining when the test set of cepstrum parameters are outside the base line for indicating the defect of the machine. 12. The method of claim 8 wherein, the vibration signals and the tachometer signals are synchronized in time during the run time, and the cepstrum vibration signal and the average periodic time value signal are synchronized in time, and the average periodic time value signal has a average periodic time value for locating the cepstrum parameter as a value of the cepstrum vibration signal at a time point corresponding to an instance in time during the run time, the method further comprising the steps of: repeating all of the method steps a plurality of times for generating a respective plurality of cepstrum parameters for the machine as a test set of cepstrum parameters, repeating all of the method steps a plurality of times for the machine for generating a respective plurality of cepstrum parameters through the run time as a test set of cepstrum parameters, and for generating a plurality of cepstrum parameters as a plurality of sets of cepstrum parameters respectively for the plurality of like machines for generating the base line, and comparing the test set of cepstrum parameters to the base line of cepstrum parameters, the base line of cepstrum parameters indicating a healthy operating range for determining when the test set of cepstrum parameters are within the base line for indicating a proper operation of the machine and for determining when the test set of cepstrum parameters are outside the base line for indicating a defective operation of the machine indicating the defect. 13. The method of claim 8 wherein, the machine is a rocket engine, the moving part is a set of gears coupled to a rotating shaft of the rocket engine, and the tachometer signal indicates the periodic rotation of the rotating shaft. 14. A method of determining a defect in a rocket engine having a gear box enclosing a rotating shaft with gears coupled to the rotating shaft, the method comprising the steps of: operating the rocket engine during run time for producing vibrations from the gear box, the rotating shaft moving at a periodic rate, receiving vibration signals from the vibrations of the gear box, receiving tachometer signals indicating the rate of the periodic rotation of the rotating shaft, acquiring the vibration signals and the tachometer signals, the vibration signals and the tachometer signals are synchronized in time, recording the vibration and tachometer signals, playing back the vibration and tachometer signals, converting the vibration and tachometer signals into digital form into converted vibration signals and converted tachometer signals, respectively, transforming the converted vibration signals into a Fourier spectrum vibration signal, calculating a two-sided autospectral density signal from the Fourier spectrum vibration signal, logarithmically converting the two-sided autospectral density signal into a logarithmic autospectral density signal, inverse transforming the logarithmic autospectral density signal into a cepstru m vibration signal, detecting a speed signal from the converted tachometer signals, averaging the speed signal into an average speed signal, inverting the average speed signal into an average periodic time value signal, detecting the cepstrum vibration signal at the average periodic time value signal for providing a cepstrum parameter, the cepstrum vibration signal and the average periodic time value signal are synchronized in time, the average periodic time value signal has an average periodic time value for locating the cepstrum parameter as a value of the cepstrum vibration signal at a point during the run time, repeating all of the repeating steps a plurality of times for a plurality of like rocket engines for generating sets of cepstrum values for generating a base line of normally operating rocket engines for the plurality of like rocket engines over the run time, and for generating a respective plurality of cepstrum parameters for the rocket engine as a test set of cepstrum parameters, and comparing the test set of cepstrum parameters to the base line of normally operating like rocket engines for determining when the test set of cepstrum parameters are within the base line for indicating a proper operation of the rocket engine under test and for determining when the test set of cepstrum parameters are outside the base line for indicating a defective operation of the rocket engine under test indicating the defect. 15. The method of claim 14 further comprising the step of: storing the base line of cepstrum parameters for the plurality of like rocket engines. 16. The method of claim 14 wherein, the vibration signals are generated from accelerometers disposed on the gear box, and tachometer signals are generated from a magnetic transducer disposed on the gear box. 17. The method of claim 14 wherein, the rocket engine is a liquid propellant rocket engine. 18. The method of claim 14 wherein, the averaging step averages time displacements between peaks of the tachometer signals, the peaks occurring at the periodic rate of the rotating shaft, the periodic rate corresponding to the revolution rate of the shaft, the average speed signal being a rotation rate value of the periodic rate. 19. The method of claim 14 wherein, the ceptrum vibration signal detecting step detects a cepstrum peak value of the cepstrum vibration signal at a periodic time associated with the inverse of the average rotation rate of the shaft, and the cepstrum peak value tending to increase in value as the defect in the gear box progressing towards failure of the rocket engine. 20. 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