IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
UP-0036797
(2008-02-25)
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등록번호 |
US-7643949
(2010-02-11)
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발명자
/ 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
0 인용 특허 :
12 |
초록
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Flowmeters are described in which a sensor signal received from a sensor that is attached to vibratable flowtube, so as to determine properties of a fluid within the flowtube, contains a drive signal component and a coriolis mode component. The flowmeters are operable to determine drive parameters o
Flowmeters are described in which a sensor signal received from a sensor that is attached to vibratable flowtube, so as to determine properties of a fluid within the flowtube, contains a drive signal component and a coriolis mode component. The flowmeters are operable to determine drive parameters of the drive signal component, as well as coriolis parameters of the coriolis mode component. By analyzing the sensor signal based on the drive signal parameters, and not on the coriolis signal parameters, the flowmeters are able to provide stable and accurate determinations of the properties of the fluid.
대표청구항
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What is claimed is: 1. A method comprising: passing a fluid through a flowtube having at least two natural modes of vibration, the modes of vibration having different periods of oscillation; applying a drive signal to the flowtube such that the flowtube vibrates; receiving a first sensor signal fro
What is claimed is: 1. A method comprising: passing a fluid through a flowtube having at least two natural modes of vibration, the modes of vibration having different periods of oscillation; applying a drive signal to the flowtube such that the flowtube vibrates; receiving a first sensor signal from a first sensor that is operable to sense a vibration of the flowtube, the first sensor signal comprising a first major signal component associated with a first one of the modes of vibration, and a first minor signal component associated with a second one of the modes of vibration; receiving a second sensor signal from a second sensor that is operable to sense a vibration of the flowtube, the second sensor signal comprising a second major signal component associated with the first mode of vibration, and a second minor signal component associated with the second mode of vibration; analyzing the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; analyzing the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; and determining a difference between a phase of the first sensor signal and the second sensor signal based on the analysis of the first received sensor signal and the analysis of the second received sensor signal. 2. The method of claim 1, wherein: analyzing the first received signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration comprises analyzing the first received sensor signal over a time period that is defined with respect to the period of oscillation of the second mode of vibration; and analyzing the second received signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration comprises analyzing the second received sensor signal over a time period that is defined with respect to the period of oscillation of the second mode of vibration. 3. The method of claim 1, wherein: analyzing the first received signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration comprises analyzing the first received sensor signal over a time period that is defined with respect to the period of oscillation of the first mode of vibration; and analyzing the second received signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration comprises analyzing the second received sensor signal over a time period that is defined with respect to the period of oscillation of the first mode of vibration. 4. The method of claim 1, wherein the first mode of vibration comprises a mode of vibration associated with applying the drive signal to the flowtube, and the second mode of vibration comprises a mode of vibration associated with a contaminant. 5. The method of claim 1, wherein the second mode of vibration comprises a mode of vibration excited by an external disturbance applied to the flowtube. 6. The method of claim 5, wherein the external disturbance comprises a change in a flowrate of the fluid passing through the flowtube. 7. The method of claim 1 further comprising determining a mass flowrate of the fluid based on the determined difference between the phase of the first sensor signal and the phase of the second sensor signal. 8. The method of claim 1, wherein the first major signal component has a major amplitude, and the first minor signal component has a minor amplitude, and further comprising determining a value of the major amplitude based on the analysis of the first received sensor signal. 9. The method of claim 8, further comprising: generating an updated drive signal based on the determined value of the major amplitude; and applying the updated drive signal to the flowtube. 10. The method of claim 1, wherein the first minor signal component is related to a coriolis mode signal that is present in the sensor signal. 11. The method of claim 1, further comprising: determining, based on the analysis of the first received sensor signal, a first timing offset between a zero-crossing of the first major signal component and a zero-crossing of the first received sensor signal, the first offset caused at least in part by a presence of the first minor signal component. 12. A method comprising: passing a fluid through a flowtube having at least two natural modes of vibration, the modes of vibration having different periods of oscillation; applying a drive signal to the flowtube such that the flowtube vibrates; receiving a first sensor signal from a first sensor that is operable to sense a vibration of the flowtube, the first sensor signal comprising a first major signal component associated with a first one of the modes of vibration, and a first minor signal component associated with a second one of the modes of vibration; analyzing the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; and determining a representation of a phase of the first major signal component based on the analysis of the first received sensor signal. 13. The method of claim 12, wherein analyzing the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube comprises analyzing the first received sensor signal over a time period that is defined with respect to the second mode of vibration. 14. The method of claim 12 further comprising: receiving a second sensor signal from a second sensor that is operable to sense a vibration of the flowtube, the second sensor signal comprising a second major signal component associated with the first mode of vibration, and a second minor signal component associated with the second mode of vibration; analyzing the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration; determining a representation of a phase of the second major signal component based on analyzing the second received sensor signal; and determining a difference between the representation of the phase of the first major signal component and the representation of the phase of the second major signal component based on the analysis of the first received sensor signal and the analysis of the second received sensor signal. 15. The method of claim 14 further comprising determining a mass flowrate of the fluid based on the difference between the representation of the phase of the first major signal component and the representation of the phase of the second major signal component. 16. The method of claim 12, wherein the first major signal component has a major amplitude, and the first minor signal component has a minor amplitude, and further comprising determining a value of the major amplitude based on the analysis of the first received sensor signal. 17. The method of claim 16, further comprising: generating an updated drive signal based on the determined value of the major amplitude; and applying the updated drive signal to the flowtube. 18. The method of claim 12, wherein the first minor signal component is related to a coriolis mode signal that is present in the sensor signal. 19. The method of claim 12, wherein the first mode of vibration comprises a mode of vibration associated with applying the drive signal to the flowtube, and the second mode of vibration comprises a mode of vibration associated with a contaminant. 20. The method of claim 12, further comprising: determining, based on the analysis of the first received sensor signal, a first timing offset between a first zero-crossing of the first major signal component and a second zero-crossing of the first received sensor signal, the first timing offset caused at least in part by a presence of the first minor signal component. 21. The method of claim 20 further comprising determining characteristics of the second mode of vibration based on the timing offset, the characteristics comprising one or more of an amplitude, a phase, and a frequency associated with the second mode of vibration. 22. The method of claim 12 further comprising: determining a frequency of the first received sensor signal; and determining a density of the fluid based on the determined frequency. 23. A flowmeter transmitter comprising: at least one processing device; and a storage device, the storage device storing instructions for causing the at least one processing device to: induce motion in a flowtube by applying a drive signal to the flowtube, the flowtube having at least two natural modes of vibration, the modes of vibration having different periods of oscillation; receive a first sensor signal from a first sensor that is operable to sense a vibration of the flowtube, the first sensor signal comprising a first major signal component associated with a first one of the modes of vibration, and a first minor signal component associated with a second one of the modes of vibration; receive a second sensor signal from a second sensor that is operable to sense a vibration of the flowtube, the second sensor signal comprising a second major signal component associated with the first mode of vibration, and a second minor signal component associated with the second mode of vibration; analyze the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; analyze the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; and determine a difference between a phase of the first sensor signal and the second sensor signal based on the analysis of the first received sensor signal and the analysis of the second received sensor signal. 24. The flowmeter transmitter of claim 23, wherein: to analyze the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration, the instructions further include instructions for causing the at least one processing device to analyze the first received sensor signal over a time period that is defined with respect to the period of oscillation of the second mode of vibration, and to analyze the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration, the instructions further include instructions for causing the at least one processing device to analyze the second received sensor signal over the time period that is defined with respect to the period of oscillation of the second mode of vibration. 25. The flowmeter transmitter of claim 23, wherein: to analyze the first received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration, the instructions further include instructions for causing the at least one processing device to analyze the first received sensor signal over the time period that is defined with respect to a period of oscillation of the first mode of vibration, and to analyze the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration, the instructions further include instructions for causing the at least one processing device to analyze the second received sensor signal over the time period that is defined with respect to a period of oscillation of the first mode of vibration. 26. A flowmeter transmitter comprising: at least one processing device; and a storage device, the storage device storing instructions for causing the at least one processing device to: induce motion in a flowtube by applying a drive signal to the flowtube, the flowtube having at least two natural modes of vibration, which have modes of vibration having different periods of oscillation, the flowtube being configured to pass fluid by applying a drive signal to the flowtube; receive a sensor signal from a sensor that is operable to sense a vibration of the flowtube, the sensor signal comprising a major signal component associated with a one of the modes of vibration, and a minor signal component associated with a second one of the modes of vibration; analyze the received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube; and determine a representation of a phase of the major signal component based on the analysis of the received signal. 27. The flowmeter transmitter of claim 26, wherein to analyze the received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration of the flowtube, the instructions further include instructions for causing the at least one processing device to analyze the received sensor signal over a time period that is defined with respect to the second one of the modes of vibration. 28. The flowmeter transmitter of claim 26, wherein the storage device further stores instructions to cause the at least one processing device to: receive a second sensor signal from a second sensor that is operable to sense a vibration of the flowtube, the second sensor signal comprising a second major signal component associated with the one of the modes of vibration, and a second minor signal component associated with the second one of the modes of vibration; analyze the second received sensor signal over a time period that is defined with respect to the period of oscillation of one of the modes of vibration; determine a representation of a phase of the second major signal component based on analyzing the second received sensor signal; and determine a difference between the representation of the phase of the major signal component and the representation of the phase of the second major signal component based on the analysis of the received sensor signal and the analysis of the second received sensor signal. 29. The flowmeter transmitter of claim 28, wherein the storage device further stores instructions for causing the at least one processing device to determine a mass flowrate of the fluid based on the difference between the representation of the phase of the major signal component and the representation of the phase of the second major signal component. 30. The flowmeter transmitter of claim 26, wherein the major signal component has a major amplitude, and the minor signal component has a minor amplitude, and the storage device further stores instructions to cause the at least one processing device to determine a value of the major amplitude based on the analysis of the received sensor signal. 31. The flowmeter transmitter of claim 30, wherein the storage device further stores instructions to cause the at least one processor to: generate an updated drive signal based on the determined value of the major amplitude; and apply the updated drive signal to the flowtube. 32. The flowmeter transmitter of claim 26, wherein the minor signal component is related to a coriolis mode signal that is present in the sensor signal. 33. The flowmeter transmitter of claim 26, wherein the one of the modes of vibration comprises a mode of vibration associated with applying the drive signal to the flowtube, and the second one of the modes of vibration comprises a mode of vibration associated with a contaminant. 34. The flowmeter transmitter of claim 26, wherein the storage device further stores instructions for causing the at least one processing device to: determine, based on the analysis of the received sensor signal, a first timing offset between a first zero-crossing of the major signal component and a second zero-crossing of the received sensor signal, the first timing offset caused at least in part by a presence of the minor signal component. 35. The flowmeter transmitter of claim 34, wherein the storage device further stores instructions for causing the at least one processing device to determine characteristics of the second one of the modes of vibration based on the timing offset, the characteristics comprising one or more of an amplitude, a phase, and a frequency associated with the second one of the modes of vibration. 36. The flowmeter transmitter of claim 26, wherein the storage device further stores instructions for causing the at least one processing device to: determine a frequency of the received sensor signal; and determine a density of the fluid based on the determined frequency.
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