Method and system for continuous monitoring of the water fraction in an oil well stream
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01N-033/28
G01N-027/02
E21B-047/10
E21B-049/08
출원번호
US-0373463
(2016-12-09)
등록번호
US-10197546
(2019-02-05)
발명자
/ 주소
Rahaliou, Aleksander
Chakhouski, Aliaksander
Sottsau, Aliaksei
Akbashev, Ramir
Orel, Sergei
출원인 / 주소
Piltsov, Sergei
대리인 / 주소
Zall, Michael E.
인용정보
피인용 횟수 :
0인용 특허 :
13
초록▼
A method, system and apparatus for continuously determining the watercut of production fluid flowing in a pipeline from an oil reservoir. The method includes providing an electrochemical impedance sensor at a fixed location in the pipeline for continuously measuring the impedance value of the flowin
A method, system and apparatus for continuously determining the watercut of production fluid flowing in a pipeline from an oil reservoir. The method includes providing an electrochemical impedance sensor at a fixed location in the pipeline for continuously measuring the impedance value of the flowing production fluid at such location. A sample of the production fluid is obtained from the pipeline to determine the watercut value of the sample. From such watercut values from the sample, a correlation formula is determined of the watercut value of the sample with the measured impedance value at the fixed location. Subsequently the continuously measured impedance values are inputted into the correlation formula to continuously calculate the watercut value of the flowing production fluid to thereby continuously determine the watercut of the flowing production fluid with the impedance sensor.
대표청구항▼
1. A method of continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the flowing production fluid comprising oil, water and gas, the method comprising: a. providing an impedance sensor unit at a fixed location in the pipeline for con
1. A method of continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the flowing production fluid comprising oil, water and gas, the method comprising: a. providing an impedance sensor unit at a fixed location in the pipeline for continuously measuring impedance values of the flowing production fluid in the pipeline, wherein the impedance sensor unit comprising at least one current electrode that is coupled to a first amplifier, at least one voltage electrode that is coupled to the first amplifier, an analog to digital converter (ADC) that is coupled to the first amplifier, a microprocessor; wherein the microprocessor includes a plurality of terminals, a first terminal that is coupled to the ADC and a second terminal that is coupled to a frequency generator; wherein a terminal of the frequency generator is coupled to a second amplifier and the second amplifier is coupled to the at least one current electrodes; wherein the microprocessor is in communication with a computer, via an Ethernet interface module, configured to convert the impedance values to watercut values;b. continuously measuring the impedance value of the flowing production fluid at the fixed location in the pipeline;c. obtaining a sample of the production fluid from the pipeline proximate the fixed location in the pipeline to determine a watercut value of the sample;d. determining a correlation formula of the watercut value of the sample with the measured impedance value at the fixed location at the time of obtaining the sample;e. Subsequently inputting the continuously measured impedance values into the correlation formula to continuously calculate the watercut value of the flowing production fluid at the fixed location to thereby continuously determine the watercut of the flowing production fluid at the fixed location. 2. The method of claim 1, further comprising repeating steps c., d., and e. 3. The method of claim 1, further including continuously measuring the temperature of the flowing production fluid at the fixed location and determining the correlation formula of the watercut value of the samples with the measured impedance value and temperature. 4. The method of claim 1, wherein obtaining the sample of the flowing production fluid from the pipeline consists of removing the sample of the production fluid during a shutdown of the fluid flow through the pipeline. 5. The method of claim 1, wherein the correlation formula is: W=A×|Z|+B×|Z|×T+C/T+D, whereW=watercut,|Z|=amplitude of complex impedance, ohms;T=temperature, ° C.;A, B, C, D=empirically determined constants. 6. A method of continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the flowing production fluid comprising oil and water, the method comprising: a. providing an impedance sensor unit and a temperature sensor at a fixed location in the pipeline for continuously measuring impedance values and temperature of the flowing production fluid in the pipeline, wherein the impedance sensor unit comprising at least one current electrode that is coupled to a first amplifier, at least one voltage electrode that is coupled to the first amplifier, an analog to digital converter (ADC) that is coupled to the first amplifier, a microprocessor; wherein the microprocessor includes a plurality of terminals, a first terminal that is coupled to the ADC and a second terminal that is coupled to a frequency generator; wherein a terminal of the frequency generator is coupled to a second amplifier and the second amplifier is coupled to the at least one current electrodes; wherein the microprocessor is in communication with a computer, via an Ethernet interface module, configured to convert the impedance values to watercut values;b. continuously measuring the impedance value and temperature of the flowing production fluid at the fixed location in the pipeline;c. removing a sample of the production fluid during a shutdown of the fluid flow through the pipeline proximate the fixed location in the pipeline to determine a watercut value of the sample;d. determining a correlation formula of the watercut value of the sample with the measured impedance value and temperature at the fixed location at the time of obtaining the sample;e. Subsequently inputting the continuously measured impedance values and temperature of the flowing production fluid into the correlation formula to continuously calculate the watercut value of the flowing production fluid at the fixed location to thereby continuously determine the watercut of the flowing production fluid at the fixed location. 7. The method of claim 6, further comprising repeating steps c., d., and e. 8. The method of claim 6, wherein the correlation formula is: W=A×|Z|+B×|Z|×T+C/T+D, whereW=watercut,|Z|=amplitude of complex impedance, ohms;T=temperature, ° C.;A, B, C, D=empirically determined constants. 9. A method of continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the flowing production fluid comprising oil, water and gas, the method comprising: a. providing an impedance sensor unit and a temperature sensor at a fixed location in the pipeline for continuously measuring impedance values and temperature of the flowing production fluid in the pipeline, wherein the impedance sensor unit comprising at least one current electrode that is coupled to a first amplifier, at least one voltage electrode that is coupled to the first amplifier, an analog to digital converter (ADC) that is coupled to the first amplifier, a microprocessor; wherein the microprocessor includes a plurality of terminals, a first terminal that is coupled to the ADC and a second terminal that is coupled to a frequency generator; wherein a terminal of the frequency generator is coupled to a second amplifier and the second amplifier is coupled to the at least one current electrodes;b. continuously measuring the impedance value and temperature of the flowing production fluid at the fixed location in the pipeline;c. removing a sample of the production fluid during a shutdown of the fluid flow through the pipeline proximate the fixed location in the pipeline to determine a watercut value of the sample;d. determining a correlation formula of the watercut value of the sample with the measured impedance value and temperature of the flowing production fluid at the fixed location at the time of obtaining the sample;e. programming a computer with the correlation formula to provide a programmed computer to calculate the watercut of the flowing production fluid from impedance values inputted into the computer;f. Subsequently inputting into the programmed computer the continuously measured impedance values and temperature to continuously calculate the watercut value of the flowing production fluid at the fixed location to thereby continuously determine the watercut of the flowing production fluid at the fixed location. 10. The method of claim 9, wherein the correlation formula is: W=A×|Z|+B×|Z|×T+C/T+D, whereW=watercut,|Z|=amplitude of complex impedance, ohms;T=temperature, ° C.;A, B, C, D=empirically determined constants. 11. The method of claim 9, further comprising repeating steps c., d., e., and f. 12. The method of claim 9, wherein the step of continuously measuring the impedance value and temperature of the flowing production fluid at the fixed location in the pipeline is performed at a fixed frequency of voltage. 13. A system for continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the flowing production fluid comprising oil, water and gas, the system comprising: a. an impedance sensor unit at a fixed location in the pipeline having electrodes in the flowing production fluid, wherein the impedance sensor continuously measures impedance values of the flowing production fluid in the pipeline, wherein the impedance sensor unit comprising at least one current electrode that is coupled to a first amplifier, at least one voltage electrode that is coupled to the first amplifier, an analog to digital converter (ADC) that is coupled to the first amplifier, a microprocessor; wherein the microprocessor includes a plurality of terminals, a first terminal that is coupled to the ADC and a second terminal that is coupled to a frequency generator; wherein a terminal of the frequency generator is coupled to a second amplifier and the second amplifier is coupled to the at least one current electrodes;b. a temperature sensor at the fixed location in the pipeline, wherein the sensor continuously measures temperature of the flowing production fluid in the pipeline;c. a programmed computer, wherein the computer is programmed with a correlation formula correlating the continuously measured impedance value and temperature of the flowing production fluid with the watercut of such flowing production fluid;d. a means for inputting the continuously generated impedance values and temperatures of the flowing production fluids from the sensors to the programmed computer for calculating the continuous watercut of the flowing production fluid at the fixed location and displaying such watercut on a display of the programmed computer. 14. The system of claim 13, wherein the impedance sensor and temperature sensor are combined into one unitary sensor unit. 15. The system of claim 13, wherein the correlation formula is: W=A×|Z|+B×|Z|×T+C/T+D, whereW=watercut,|Z|=amplitude of complex impedance, ohms;T=temperature, ° C.;A, B, C, D=empirically determined constants. 16. A sensor unit for continuously determining and monitoring watercut in a production fluid flowing through a pipeline from an oil reservoir, the sensor unit comprising: a. an impedance sensor unit for measuring an impedance value of the flowing production fluid, wherein the impedance sensor unit comprising at least one current electrode that is coupled to a first amplifier, at least one voltage electrode that is coupled to the first amplifier, an analog to digital converter (ADC) that is coupled to the first amplifier, a microprocessor; wherein the microprocessor includes a plurality of terminals, a first terminal that is coupled to the ADC and a second terminal that is coupled to a frequency generator; wherein a terminal of the frequency generator is coupled to a second amplifier and the second amplifier is coupled to the at least one current electrodes;b. A temperature sensor unit for measuring a temperature value in the flowing production fluid;c. A means for mounting the sensory unit in the pipeline wherein the impedance sensor unit and temperature sensor unit continuously measure the impedance value and temperature value of the flowing production fluid;d. A means for communicating the continuously measured impedance value and temperature value to a programmed computer for calculating the continuous watercut of the flowing production fluid and displaying such watercut on a display of the programmed computer.
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이 특허에 인용된 특허 (13)
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