RU2010107225A - FLOW METER SYSTEM AND METHOD FOR MEASURING THREE-PHASE FLOW PARAMETERS - Google Patents

Abstract

 1. A vibrational flow meter (5) for measuring the parameters of a three-phase flow stream, a vibrational flow meter (5), including a meter assembly (10), including strain gauge sensors (105, 105 ') and measuring electronics (20), connected to strain gauge sensors (105, 105 '), while the vibration flow meter (5) is characterized by:! measuring electronics (20), configured to receive a vibrational response signal from strain sensors (105, 105 '), generate a first three-phase flow density measurement using the first frequency component of the vibrational response signal, generate at least a second three-phase flow density measurement, using at least a second frequency component of the vibrational response signal, with at least a second frequency component, which is a frequency different from the first component frequency, and determining one or more flow parameters from the first density measurement and at least the second density measurement. ! 2. The vibrational flow meter (5) according to claim 1 with measurement electronics (20), which is further configured to receive predetermined component densities for each of the three components of the three-phase flow. ! 3. The vibrational flow meter (5) according to claim 1 with measurement electronics (20), which is further configured to receive a predetermined speed of sound quantities for each of the three components of the three-phase stream. ! 4. Vibratory flow meter (5) according to claim 1 with the determination of one or more flow parameters, additionally

Claims (39)

1. A vibrational flow meter (5) for measuring the parameters of a three-phase flow stream, a vibrational flow meter (5), including a meter assembly (10), including strain gauge sensors (105, 105 ') and measuring electronics (20), connected to the strain sensors (105, 105 '), while the vibration flow meter (5) is characterized by: measuring electronics (20), configured to receive a vibrational response signal from strain sensors (105, 105 '), generate a first three-phase flow density measurement using the first frequency component of the vibrational response signal, generate at least a second three-phase flow density measurement, using at least a second frequency component of the vibrational response signal, with at least a second frequency component, which is a frequency different from the first component frequency, and determining one or more flow parameters from the first density measurement and at least the second density measurement. 2. The vibrational flow meter (5) according to claim 1 with measurement electronics (20), which is further configured to receive predetermined component densities for each of the three components of the three-phase flow. 3. The vibrational flow meter (5) according to claim 1 with measurement electronics (20), which is further configured to receive a predetermined speed of sound quantities for each of the three components of the three-phase stream. 4. The vibrational flow meter (5) according to claim 1, with the determination of one or more flow parameters, further comprising determining the constituent phases for each of the three components of the three-phase flow. 5. The vibrational flow meter (5) according to claim 1, with the determination of one or more flow parameters, further comprising determining a gas vapor content (GVF) of a three-phase flow. 6. The vibrational flow meter (5) according to claim 1, with the determination of one or more flow parameters, further including determining the water cut of a three-phase stream. 7. The vibrational flow meter (5) according to claim 1 with at least a second frequency component, which is essentially superimposed on the first frequency component. 8. The vibrational flow meter (5) according to claim 1 with a first frequency component and at least a second frequency component occurring essentially at different time periods by a vibrational response signal. 9. The vibrational flow meter (5) according to claim 1 with measurement electronics (20), additionally configured for vibration of the meter assembly (10) at the first frequency and vibration of the meter assembly (10) at least at the second frequency, s at least a second frequency, which is a frequency different from the first frequency, receiving a vibrational response signal from strain sensors (105 105 ′) and dividing the vibrational response signal into a first frequency component and at least a second frequency component. 10. The vibrational flow meter (5) according to claim 1 with measuring electronics (20), further configured to vibrate the assembly (10) at the first frequency, receive a vibrational response from strain sensors (105, 105 ') and separate the vibrational response to the first frequency component and at least the second frequency component, where the first frequency component and at least the second frequency component are generated by vibrations at the first frequency. 11. The vibrational flow meter (5) according to claim 1 with receiving a vibrational response signal, further comprising separating the vibrational response signal into a first frequency component and at least a second frequency component. 12. The vibrational flow meter (5) according to claim 1, with a vibrational response signal, further comprising filtering the vibrational response signal to the first frequency component and at least the second frequency component. 13. The system of a vibratory flow meter (700) for measuring the parameters of a three-phase flow, the system of a vibratory flow meter (700) is characterized by: first vibratory flow meter (5A); at least a second vibratory flow meter (5B); and a processing system (707) connected to the first vibrational flow meter (5A) and with at least a second vibrational flow meter (5B), with a processing system (707) configured to receive a first vibrational response signal from the first vibrational flow meter ( 5A), receiving at least a second vibrational response signal from at least a second vibrational flow meter (5B), with at least a second vibrational response signal having a frequency different from the first vibrational response signal la, generating a first density measurement of a three-phase flow of a first vibrational response signal of a first vibrational flow meter (5A), generating at least a second density measurement of a three-phase flow of at least a second vibrational frequency of a response signal of at least a second vibrational flow meter (5B) and determining one or more flow parameters from the first density measurement and at least the second density measurement. 14. The vibratory flow meter system (700) of claim 13 with a processing system (707), further configured to receive a predetermined component density for each of the three components of the three-phase flow. 15. The vibratory flow meter system (700) according to claim 13 with a processing system (707), further configured to receive a predetermined speed of sound quantities for each of the three components of the three-phase flow. 16. The vibratory flow meter system (700) according to claim 1, with the determination of one or more flow parameters, further comprising determining the constituent phases for each of the three components of the three-phase flow. 17. The system of a vibratory flow meter (700) according to item 13 with the determination of one or more flow parameters, further comprising determining a gas vapor content (GVF) of a three-phase flow. 18. The system of a vibratory flow meter (700) according to item 13 with the determination of one or more flow parameters, further comprising determining the water content of a three-phase flow. 19. The vibratory flow meter system (700) according to claim 13, wherein the first vibrational flow meter (5A) vibrates at a first frequency to generate a first vibrational response signal and at least a second vibrational flow meter (5B) vibrates at, at least a second frequency for generating at least a second vibrational response signal. 20. A method for measuring parameters of a three-phase flow, the method comprises: receiving a vibrational response signal from a vibratory flow meter; generating a first three-phase flow density measurement using the first frequency component of the vibrational response signal; generating at least a second three-phase flow density measurement using at least a second frequency component of the vibrational response signal with at least a second frequency component having a frequency different from the first frequency component; and determining one or more flow parameters from a first density measurement and at least a second density measurement. 21. The method according to claim 20, further comprising a preliminary step of obtaining predetermined component densities for each of the three components of the three-phase flow. 22. The method according to claim 20, further comprising a preliminary stage of receiving a predetermined speed of sound quantities for each of the three components of the three-phase stream. 23. The method according to claim 20 with the determination of one or more flow parameters, further comprising determining the constituent phases for each of the three components of the three-phase flow. 24. The method according to claim 20 with determining one or more flow parameters, further comprising determining a gas vapor content (GVF) of a three-phase flow. 25. The method according to claim 20 with the determination of one or more flow parameters, further comprising determining the water content in the three-phase stream. 26. The method according to claim 20 with at least a second frequency component, which is essentially superimposed on the first frequency component. 27. The method according to claim 20 with a first frequency component and at least a second frequency component, appearing at substantially different times in the vibrational response signal. 28. The method according to claim 20 with receiving a vibrational response signal further comprises: vibration of the assembly of the vibratory flow meter at a first frequency and further vibration of the assembly of the meter at at least a second frequency with at least a second frequency, which is a different frequency from the first frequency; receiving a vibrational response signal from strain-sensitive sensors of the meter assembly; and dividing the vibrational response signal into a first frequency component and at least a second frequency component. 29. The method according to claim 20 with receiving a vibrational response signal, further comprising: vibration of the meter assembly of the vibratory flow meter at a first frequency; receiving a vibrational response signal from strain-sensitive sensors of the meter assembly; and dividing the vibrational response signal into a first frequency component and at least a second frequency component, where the first frequency component and at least the second frequency component are generated by vibrations at the first frequency. 30. The method according to claim 20 with receiving a vibrational response signal, further comprising separating the vibrational response signal into a first frequency component and at least a second frequency component. 31. The method according to claim 20 with receiving a vibrational response signal, further comprising filtering the vibrational response signal to the first frequency component and at least the second frequency component. 32. A method for measuring flow parameters of a three-phase flow, the method comprises: receiving a first vibrational response signal and at least a second vibrational response signal; generating a first three-phase flow density measurement from a first vibrational response signal; generating at least a second three-phase flow density measurement from at least a second vibrational frequency of the response signal, with at least a second vibrational frequency response signal, which is a frequency different from the first vibrational frequency of the response vibration of the output signal; and determining one or more flow parameters from a first density measurement and at least a second density measurement. 33. The method of claim 32, further comprising a preliminary step of receiving predetermined component densities for each of the three components of the three-phase flow. 34. The method according to p, optionally containing a preliminary stage of receiving a predetermined speed of sound quantities for each of the three components of the three-phase stream. 35. The method according to p. 32 with the determination of one or more flow parameters, further comprising determining the constituent phases for each of the three components of the three-phase flow. 36. The method according to p. 32 with determining one or more flow parameters, further comprising determining a gas vapor content (GVF) of a three-phase flow. 37. The method according to p. 32 with the determination of one or more flow parameters, further comprising determining the water content in the three-phase stream. 38. The method according to p with receiving a vibrational response signal, further comprising: receiving a first vibrational response signal from a first vibrational flow meter; and receiving at least a second vibrational response signal from the second vibrational flow meter with at least a second vibrational response output signal other than the frequency from the first vibrational response signal. 39. The method according to p with receiving a vibrational response signal, further comprising: vibration of the first vibrational flow meter at a first frequency to generate a first vibrational response signal; and vibration of at least a second vibrational flow meter at at least a second frequency to generate at least a second vibrational response signal with at least a second vibrational response signal having a frequency different from the first vibrational response signal.