Method and apparatus for determining the water concentration in a fluid mixture
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01N-030/95
G01N-027/00
G01N-033/28
출원번호
US-0652644
(2012-10-16)
등록번호
US-9109995
(2015-08-18)
발명자
/ 주소
Mohajer, Kam
출원인 / 주소
KAM Controls, inc.
대리인 / 주소
Hall, Elizabeth R.
인용정보
피인용 횟수 :
0인용 특허 :
25
초록▼
A measurement device for measuring water concentration in an oil water mixture has a transmitter that is used to transmit a designated spectrum of microwave frequencies to a transmitting antenna and then through the oil water mixture. A separate receiving antenna is used to detect the amplitude of e
A measurement device for measuring water concentration in an oil water mixture has a transmitter that is used to transmit a designated spectrum of microwave frequencies to a transmitting antenna and then through the oil water mixture. A separate receiving antenna is used to detect the amplitude of each frequency of the transmitted spectrum after it has interacted with the oil water mixture. The detected signal from each microwave frequency that has interacted with the fluid mixture is digitized and sent to a processing unit. The processing unit receives the digitized frequencies and identifies the microwave frequency having the lowest amplitude, or amplitudinal nadir. The microwave frequency having the lowest amplitude is then used to calculate the percentage of water in the oil water mixture.
대표청구항▼
1. A device for determining the concentration of fluid components within a fluid mixture comprising: a) a microprocessor;b) a transmitter in communication with the microprocessor, the transmitter having a phase locked loop and a voltage controlled oscillator, wherein the transmitter generates and tr
1. A device for determining the concentration of fluid components within a fluid mixture comprising: a) a microprocessor;b) a transmitter in communication with the microprocessor, the transmitter having a phase locked loop and a voltage controlled oscillator, wherein the transmitter generates and transmits a range of microwave frequencies;c) a receiver in communication with the microprocessor;d) a reference oscillator in communication with the phase locked loop of the transmitter; ande) a sensor probe including: (i) a first transmitting antenna in communication with the transmitter, wherein the transmitting antenna receives the range of microwave frequencies generated by the transmitter and transmits the range of microwave frequencies to a fluid mixture,(ii) a second receiving antenna positioned proximal the first transmitting antenna, wherein the second receiving antenna is in communication with the receiver, the receiving antenna receives a signal from each frequency in the range of microwave frequencies transmitted through the fluid mixture by the transmitting antenna, and(iii) a probe body having a fluid opening for allowing the fluid mixture to flow through the probe body in communication with the transmitting antenna and the receiving antenna;whereby the received frequency signal of each transmitted frequency of the range of microwave frequencies is communicated to the microprocessor via the receiver and is used to calculate a percentage of water in the fluid mixture based on an identified transmitted frequency that results in a minimal received frequency signal after reacting with the fluid mixture. 2. The device of claim 1, wherein the receiver includes a filter, an amplifier, and a root mean square converter. 3. The device of claim 1, further including an analog to digital converter. 4. The device of claim 1, further including a temperature sensor in communication with the fluid mixture. 5. The device of claim 4, wherein the temperature sensor communicates the temperature of the fluid mixture to the receiver. 6. The device of claim 1, wherein the phase locked loop communicates with the reference oscillator, the microcontroller and the voltage controlled oscillator to lock each frequency in the range of microwave frequencies transmitted by the transmitter to the transmitting antenna. 7. The device of claim 1, further including a thermoelectric cooler for maintaining the transmitter and the receiver at a preselected temperature. 8. The device of claim 1, wherein a densitometer communicates a density of the fluid mixture to the microprocessor. 9. A device for determining the concentration of water within a fluid mixture comprising: a) a central processing unit having a microprocessor and an analog to digital converter;b) a transmitter in communication with the microprocessor, the transmitter having a phase locked loop and a voltage controlled oscillator, wherein the transmitter generates and transmits a range of microwave frequencies comprising a plurality of locked frequencies;c) a receiver having a filter, an amplifier, and a root mean square converter, the receiver in communication with the analog to digital converter;d) a reference oscillator in communication with the phase locked loop; andc) a sensor probe including: (i) a first transmitting antenna in communication with the transmitter, wherein the transmitting antenna receives the range of microwave frequencies generated by the transmitter and transmits the range of microwave frequencies to a fluid mixture,(ii) a second receiving antenna positioned proximal the first transmitting antenna, wherein the second receiving antenna is in communication with the receiver, the receiving antenna receives a signal from each locked frequency in the range of microwave frequencies transmitted through the fluid mixture by the transmitting antenna and wherein each received frequency signal of the range of microwave frequencies received from the fluid mixture by the receiving antenna is digitized by the analog to the digital converter and used by the microprocessor to identify the transmitted frequency resulting in an amplitudinal nadir of the plurality of received frequency signals to thereby calculate a percentage of water in the fluid mixture, and(iii) a probe body having a fluid opening for allowing the fluid mixture to flow through the probe body in communication with the transmitting antenna and the receiving antenna. 10. The device of claim 9, wherein the phase locked loop communicates with the reference oscillator, the microcontroller and the voltage controlled oscillator to lock each frequency in the range of microwave frequencies transmitted by the transmitter to the transmitting antenna. 11. The device of claim 9, further including a thermoelectric cooler for maintaining the transmitter and the receiver at a preselected temperature. 12. A method for detecting the percentage of water in a fluid mixture including the steps of: (a) positioning a sensor probe of a measurement device within a fluid mixture, wherein the measurement device includes: (i) a microprocessor,(ii) a transmitter having a phase locked loop and a voltage controlled oscillator, the transmitter in communication with the microprocessor,(iii) a receiver in communication with the microprocessor,(iv) a reference oscillator in communication with the phase locked loop, and(v) a sensor probe having a first transmitting antenna in communication with the transmitter and a second receiving antenna proximal the first transmitting antenna that is in constant communication with the receiver, and a probe body having a fluid opening for allowing the fluid mixture to flow through the probe body in communication with the transmitting antenna and the receiving antenna;(b) selecting a spectrum of microwave frequencies, wherein the spectrum includes a plurality of frequencies;(c) utilizing the phase locked loop and the reference oscillator to lock a request for each of the plurality of frequencies into the voltage controlled oscillator;(d) generating each of the locked frequencies in the spectrum;(e) transmitting the generated locked frequencies to the fluid mixture via the transmitting antenna;(f) receiving a signal via the receiving antenna from each of the transmitted frequencies after each frequency has interacted with the fluid mixture;(g) identifying a specific frequency within the spectrum of frequencies having a lowest amplitude of the received frequency signals; and(h) computing a percentage of water in the fluid mixture based on the specific frequency with the lowest amplitude in the received spectrum of frequency signals. 13. The method of claim 12, wherein the fluid mixture is an oil water mixture. 14. The method of claim 12, wherein the percentage of water within the fluid mixture is equal to 5% or less of the fluid mixture. 15. The method of claim 12, further comprising the steps of measuring a temperature and a density of the fluid mixture and mathematically compensating for the fluid temperature and density in the computation of the percentage of water. 16. A method for detecting the percentage of water in a fluid mixture including the steps of: (a) positioning a sensor probe of a measurement device within a fluid mixture, wherein the measurement device includes: (i) a microprocessor and an analog to digital converter,(ii) a transmitter having a phase locked loop and a voltage controlled oscillator, the transmitter in communication with the microprocessor,(iii) a receiver having a filter, an amplifier, and a root mean square converter, the receiver in communication with the microprocessor,(iv) a reference oscillator in communication with the phase locked loop, and(v) a sensor probe having a first transmitting antenna in communication with the transmitter, a second receiving antenna proximal the first transmitting antenna that is in communication with the receiver, and a probe body having a fluid opening for allowing the fluid mixture to flow through the probe body in communication with the transmitting antenna and the receiving antenna;(b) selecting a spectrum of microwave frequencies, wherein the spectrum includes a plurality of frequencies;(c) utilizing the phase locked loop and the reference oscillator to lock a request for each of the plurality of frequencies into the voltage controlled oscillator;(d) generating each of the locked frequencies;(e) transmitting the generated frequencies to the fluid mixture via the transmitting antenna;(f) receiving a signal via the receiving antenna from each of the transmitted locked frequencies after each frequency has interacted with the fluid mixture;(g) filtering each received frequency signal;(h) amplifying each received frequency signal;(i) digitizing each received frequency signal;(j) transmitting each digitized received frequency signal to the microprocessor, wherein the microprocessor identifies a specific frequency within the spectrum of frequencies having a lowest amplitude of the received frequency signals; and(k) computing a percentage of water in the fluid mixture based on the specific frequency with the lowest amplitude in the received spectrum of frequency signals. 17. The method of claim 16, wherein the fluid mixture is an oil water mixture containing water at a concentration of 5% or less. 18. The method of claim 16, wherein the computation of the percentage of water includes a compensation for the fluid temperature. 19. The method of claim 16, wherein the computation of the percentage of water includes a compensation for the fluid density. 20. The method of claim 16, further comprising the step of maintaining the transmitter and the receiver at a preselected range of temperatures.
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