CN204536249U - Based on the oil-water two-phase flow moisture content meter of frequency sweep complex impedance measurement - Google Patents
Based on the oil-water two-phase flow moisture content meter of frequency sweep complex impedance measurement Download PDFInfo
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- CN204536249U CN204536249U CN201520194820.9U CN201520194820U CN204536249U CN 204536249 U CN204536249 U CN 204536249U CN 201520194820 U CN201520194820 U CN 201520194820U CN 204536249 U CN204536249 U CN 204536249U
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Abstract
The utility model relates to a kind of oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement, comprise sensor and controller, controller comprise housing built with the identical complex impedance measurement module one of two structures, complex impedance measurement module two and processor module, keyboard and liquid crystal display, four electrodes sensor are equipped with respectively, electrode A, electrode B connects the input of complex impedance measurement module one respectively, export, electrode C, electrode D connects the input of complex impedance measurement module two respectively, export, the IIC interface one of processor module is connected with complex impedance measurement module one, the IIC interface two of processor module is connected with complex impedance measurement module two, the serial ports of processor module exports and control interface is connected with computing machine, the output of processor module connects keyboard and liquid crystal display respectively.The utility model adopts AD5933 to measure the complex impedance of oil-water two-phase flow, is applicable to water-oil phase flow measurement, and structure is simple, and degree of accuracy is high.
Description
Technical field
The utility model belongs to polyphasic flow intelligent instrument technical field, relates to a kind of oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement, and the flow velocity and the phase content that can be used for oil-water two-phase flow are measured.
Background technology
The most general with two-phase flow in commercial production and transport, as the Dual-Phrase Distribution of Gas olid that the coal dust in thermal power generation is carried, existed in the Geldart-D particle of grain processing; The biphase gas and liquid flow existed in the steam generator tube bank of steam generator system, crude oil and natural gas transmission, nuclear reactor and the course of reaction of chemical industry heat and mass equipment; The liquid fixed double phase flow existed in the silt extraction of Offshore Oil Industry and the pulp flow process of paper industry; The liquid-liquid diphasic flow etc. existed in metallurgy and chemical industry extraction process.Wherein the measurement of water ratio of oil-water two-phase flow is the target that everybody studies all the time.Current great majority adopt the method for conductance measurement, and according to the actual fact, the poor stability of conductance measurement, is subject to various environmental conditions.
Summary of the invention
Problem to be solved in the utility model is, overcome the deficiencies in the prior art, a kind of oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement is provided, AD5933 is adopted to measure the complex impedance of oil-water two-phase flow as sweep measurement parts, can more fully measure by convection cell, improve the stability measured, reduce the dependence to measurement environment.
The utility model solves its technical matters and takes following technical scheme to realize:
According to a kind of oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement that the utility model provides, comprise sensor and controller, described controller comprise housing built with the identical complex impedance measurement module one of two structures, complex impedance measurement module two and processor module, keyboard, liquid crystal display, sensor is equipped with electrode A respectively, electrode B, electrode C, electrode D, electrode A connects the input of complex impedance measurement module one, electrode B connects the output of complex impedance measurement module one, electrode C connects the input of complex impedance measurement module two, electrode D connects the output of complex impedance measurement module two, the IIC interface one of processor module is connected with complex impedance measurement module one, the IIC interface two of processor module is connected with complex impedance measurement module two, the serial ports of processor module exports and control interface is connected with computing machine, and the output of processor module connects keyboard and liquid crystal display respectively.
It is take following technical scheme to realize further that the utility model solves its technical matters:
The complex impedance measurement module one that aforesaid two structures are identical, complex impedance measurement module one in complex impedance measurement module two comprises AD5933 U3, precision voltage source ADR435 U1, active crystal oscillator U5, power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3, power filtering capacitor C7, power filtering capacitor C9, calibration capacitance Ccal1, feedback resistance R2, sensor connector P1, sensor connector P2 and sensor connector P3, power supply is connected with precision voltage source ADR435 U1, the output of precision voltage source ADR435 U1 and power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3 is in parallel, then the power end of AD5933 U3 is connected to, No. 2 pin of one end connecting sensor joint P3 of feedback resistance R2, the other end of feedback resistance R2 connects No. 4 pin of U3, No. 1 pin of one end connecting sensor joint P3 of calibration capacitance Ccal1, No. 2 pin of the other end connecting sensor joint P2 of calibration capacitance Ccal1, No. 3 pin of active crystal oscillator U5 export No. 8 pin being connected to AD5933 U3, and one end of power filtering capacitor C9 connects power supply No. 4 pin of active crystal oscillator U5, and the other end of power filtering capacitor C9 is connected to power cathode, sensor connector P1, power filtering capacitor C7 are reserved test interface, and one end of power filtering capacitor C7 is connected to No. 5 pin of AD5933 U3, and the other end of power filtering capacitor C7 is connected to No. 6 pin of AD5933 U3, No. 1 pin of sensor connector P1 is connected to power supply, and No. 2 pin of sensor connector P1 are connected to power cathode, and No. 3 pin of sensor connector P1 are connected to No. 16 pin of AD5933 U3, and No. 4 pin of sensor connector P1 are connected to No. 15 pin of AD5933 U3, sensor connector P1 is connected with CPU module, sensor connector P2, sensor connector P3 are connected respectively to electrode A, the electrode B of sensor, and the sensor connector P2 of another complex impedance measurement module two, sensor connector P3 are connected respectively to electrode C and the electrode D of sensor.
The utility model compared with prior art has significant advantage and beneficial effect:
Because the utility model adopts precision voltage source as sensor measurement module for power supply, effectively can improve the precision of measurement, result of calculation has higher sensitivity and precision, and precision can reach 2%.Adopt integrated complex impedance measurement module to reduce conventional measurement systems adopts discrete component to design the error and noise that cause simultaneously.Utilizing built-in digital processing unit to calculate complex impedance makes measuring speed faster.The foundation adopting complex impedance to calculate as water percentage more accurately can reflect water percentage than single conductance measurement or capacitance measurement.Adopt the method measuring complex impedance parameter, design concept have advance and practicality, the electrical quantity measured is abundanter than traditional conductance measurement, embody the change (i.e. impedance and phase angle variations) of conduction current and displacement current in fluid, reduce the measuring error caused by water salinity to a certain extent.
Embodiment of the present utility model is provided in detail by following examples and accompanying drawing thereof.
Embodiment
Below in conjunction with accompanying drawing and preferred embodiment, to embodiment, structure, feature and effect thereof of providing according to the utility model, be described in detail as follows.
A kind of oil-water two-phase flow moisture content meter based on complex impedance measurement as shown in figs. 1 to 6, comprise sensor 5 and controller 6, described controller comprise housing 9 and housing built with the identical complex impedance measurement module one of two structures, complex impedance measurement module two and processor module, keyboard 7 and liquid crystal display 8, sensor is equipped with electrode A 1 respectively, electrode B 2, electrode C 3, electrode D 4, electrode A connects the input of complex impedance measurement module one, electrode B connects the output of complex impedance measurement module one, electrode C connects the input of complex impedance measurement module two, electrode D connects the output of complex impedance measurement module two, the IIC interface one of processor module is connected with complex impedance measurement module one, the IIC interface two of processor module is connected with complex impedance measurement module two, the serial ports of processor module exports and control interface is connected with computing machine, and the output of processor module connects keyboard and liquid crystal display respectively.
The complex impedance measurement module one that two described structures are identical, complex impedance measurement module one in complex impedance measurement module two comprises AD5933 U3, precision voltage source ADR435 U1, active crystal oscillator U5, power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3, power filtering capacitor C7, power filtering capacitor C9, calibration capacitance Ccal1, feedback resistance R2, sensor connector P1, sensor connector P2 and sensor connector P3, power supply is connected with precision voltage source ADR435 U1, the output of precision voltage source ADR435 U1 and power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3 is in parallel, then the power end of AD5933 U3 is connected to, No. 2 pin of one end connecting sensor joint P3 of feedback resistance R2, the other end of feedback resistance R2 connects No. 4 pin of U3, No. 1 pin of one end connecting sensor joint P3 of calibration capacitance Ccal1, No. 2 pin of the other end connecting sensor joint P2 of calibration capacitance Ccal1, No. 3 pin of active crystal oscillator U5 export No. 8 pin being connected to AD5933 U3, and one end of power filtering capacitor C9 connects power supply No. 4 pin of active crystal oscillator U5, and the other end of power filtering capacitor C9 is connected to power cathode, sensor connector P1, power filtering capacitor C7 are reserved test interface, and one end of power filtering capacitor C7 is connected to No. 5 pin of AD5933 U3, and the other end of power filtering capacitor C7 is connected to No. 6 pin of AD5933 U3, No. 1 pin of sensor connector P1 is connected to power supply, and No. 2 pin of sensor connector P1 are connected to power cathode, and No. 3 pin of sensor connector P1 are connected to No. 16 pin of AD5933 U3, and No. 4 pin of sensor connector P1 are connected to No. 15 pin of AD5933 U3, sensor connector P1 is connected with CPU module, sensor connector P2, sensor connector P3 are connected respectively to electrode A, the electrode B of sensor, and the sensor connector P2 of another complex impedance measurement module two, sensor connector P3 are connected respectively to electrode C and the electrode D of sensor.
Based on the measuring method of the oil-water two-phase flow moisture content meter of frequency sweep complex impedance measurement, it comprises the following steps:
(1) set complex impedance measurement module one frequency sweep Frequency point and, step-length and measuring period number;
(2) read the measurement result of complex impedance measurement module one, close complex impedance measurement module one and export;
(3) set complex impedance measurement module two frequency sweep Frequency point and, step-length and measuring period number;
(4) read the measurement result of complex impedance measurement module two, close complex impedance measurement module two and export;
(5) flow velocity and phase content is calculated according to the result of twice measurement;
(6) result be shown to liquid crystal display and exported by serial ports;
(7) step 1-6 is repeated.
Principle of work:
First by data write AD5933 such as survey frequency points when moisture content meter of the present utility model starts, then AD5933 can produce corresponding sinusoidal excitation signal in order, and sinusoidal excitation signal is added on exciting electrode.Receiving electrode B is 20mm apart from exciting electrode A distance.AD5933 carries out calculating the complex impedance obtaining current fluid according to the signal of the signal received and transmitting.Every 2ms completes one-shot measurement.500 data points are preserved in processor module inside, and the reduced data that the result of data and processor module inside are preserved is compared and calculated current water percentage and shown, and what measurement data can be real-time is sent to computing machine by serial ports.
Moisture content meter of the present utility model measures two arrays of electrodes data with the switching frequency timesharing be exceedingly fast, electrode C and electrode D spacing 30mm.Flow velocity can be calculated by directly related algorithm.In Fig. 2, electrode A, electrode B are one group of electrode, and electrode C, electrode D are one group of electrode.
The utility model adopts two panels 1MSPS, 12 network analysis instrument chip AD5933, AD5933 is in order to realize complex impedance measurement, processor module adopts stm32f103vbt6 processor, stm32f103vbt6 processor reads the data measured in AD5933 by IIC interface, and the tables of data that experimentally room had been done converts out current ducted real-time oil-water ratio.Adopt AD5933 sweep measurement complex impedance information, measure three groups of data at 20k, 50k, 80k tri-Frequency points.Use in the lab and the peristaltic pump of accurate quantification can produce and specify the two-phase flow of water percentage, the pipeline of two-phase flow is plexi-glass tubular, its external diameter 30mm, internal diameter 20mm; Complex impedance measurement data and the fluctuation characteristic of water percentage 70%-98% is comprised in tables of data, this tables of data is kept in stm32f103vbt6 processor, in the measurement of reality, calculate current actual water percentage according to the comparison that complex impedance data and the fluctuation characteristic of actual measurement are shown therewith.
Accompanying drawing explanation
Fig. 1 is external structure schematic diagram of the present utility model;
Fig. 2 is principle of work block diagram of the present utility model;
Fig. 3 is complex impedance measurement module circuit diagram of the present utility model;
Fig. 4 is display module circuit diagram of the present utility model;
Fig. 5 is processor module circuit diagram of the present utility model;
Fig. 6 is power supply of the present utility model and Keysheet module circuit diagram.
Wherein: 1, electrode A, 2, electrode B, 3, electrode C, 4, electrode D, 5, sensor, 6, controller, 7, keyboard, 8, liquid crystal display, 9, housing.
Claims (2)
1. the oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement, comprise sensor and controller, it is characterized in that: described controller comprise housing built with the identical complex impedance measurement module one of two structures, complex impedance measurement module two and processor module, keyboard, liquid crystal display, sensor is equipped with electrode A respectively, electrode B, electrode C, electrode D, electrode A connects the input of complex impedance measurement module one, electrode B connects the output of complex impedance measurement module one, electrode C connects the input of complex impedance measurement module two, electrode D connects the output of complex impedance measurement module two, the IIC interface one of processor module is connected with complex impedance measurement module one, the IIC interface two of processor module is connected with complex impedance measurement module two, the serial ports of processor module exports and control interface is connected with computing machine, and the output of processor module connects keyboard and liquid crystal display respectively.
2. the oil-water two-phase flow moisture content meter based on frequency sweep complex impedance measurement according to claim 1, it is characterized in that: the complex impedance measurement module one that two described structures are identical, complex impedance measurement module one in complex impedance measurement module two comprises AD5933 U3, precision voltage source ADR435 U1, active crystal oscillator U5, power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3, power filtering capacitor C7, power filtering capacitor C9, calibration capacitance Ccal1, feedback resistance R2, sensor connector P1, sensor connector P2 and sensor connector P3, power supply is connected with precision voltage source ADR435 U1, the output of precision voltage source ADR435 U1 and power filtering capacitor C1, power filtering capacitor C2, power filtering capacitor C3 is in parallel, then the power end of AD5933 U3 is connected to, No. 2 pin of one end connecting sensor joint P3 of feedback resistance R2, the other end of feedback resistance R2 connects No. 4 pin of U3, No. 1 pin of one end connecting sensor joint P3 of calibration capacitance Ccal1, No. 2 pin of the other end connecting sensor joint P2 of calibration capacitance Ccal1, No. 3 pin of active crystal oscillator U5 export No. 8 pin being connected to AD5933 U3, and one end of power filtering capacitor C9 connects power supply No. 4 pin of active crystal oscillator U5, and the other end of power filtering capacitor C9 is connected to power cathode, sensor connector P1, power filtering capacitor C7 are reserved test interface, and one end of power filtering capacitor C7 is connected to No. 5 pin of AD5933 U3, and the other end of power filtering capacitor C7 is connected to No. 6 pin of AD5933 U3, No. 1 pin of sensor connector P1 is connected to power supply, and No. 2 pin of sensor connector P1 are connected to power cathode, and No. 3 pin of sensor connector P1 are connected to No. 16 pin of AD5933 U3, and No. 4 pin of sensor connector P1 are connected to No. 15 pin of AD5933 U3, sensor connector P1 is connected with CPU module, sensor connector P2, sensor connector P3 are connected respectively to electrode A, the electrode B of sensor, and the sensor connector P2 of another complex impedance measurement module two, sensor connector P3 are connected respectively to electrode C and the electrode D of sensor.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109070592A (en) * | 2016-07-21 | 2018-12-21 | 惠普发展公司,有限责任合伙企业 | Complex impedance detection |
CN109187649A (en) * | 2018-08-14 | 2019-01-11 | 天津大学 | Moisture content and salinity measuring device based on the anti-sensor of plug-in resistance type |
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2015
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109070592A (en) * | 2016-07-21 | 2018-12-21 | 惠普发展公司,有限责任合伙企业 | Complex impedance detection |
CN109070592B (en) * | 2016-07-21 | 2021-05-25 | 惠普发展公司,有限责任合伙企业 | Complex impedance detection |
US11090929B2 (en) | 2016-07-21 | 2021-08-17 | Hewlett-Packard Development Company, L.P. | Complex impedance detection |
CN109187649A (en) * | 2018-08-14 | 2019-01-11 | 天津大学 | Moisture content and salinity measuring device based on the anti-sensor of plug-in resistance type |
CN109187649B (en) * | 2018-08-14 | 2020-11-27 | 天津大学 | Water content and mineralization measuring device based on plug-in electrical impedance sensor |
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Granted publication date: 20150805 Termination date: 20170401 |