CN202204828U - Device for measuring flow velocity and flow rate of fluid in small channel - Google Patents
Device for measuring flow velocity and flow rate of fluid in small channel Download PDFInfo
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- CN202204828U CN202204828U CN2011203343081U CN201120334308U CN202204828U CN 202204828 U CN202204828 U CN 202204828U CN 2011203343081 U CN2011203343081 U CN 2011203343081U CN 201120334308 U CN201120334308 U CN 201120334308U CN 202204828 U CN202204828 U CN 202204828U
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Abstract
The utility model discloses a device for measuring flow velocity and flow rate of fluid in a small channel. The device comprises an AC excitation source, an insulating pipeline, a five-electrode non-contact conductive sensor, an amplitude modulation demodulation circuit, a data acquisition module and a microcomputer, wherein the first electrode of the five-electrode non-contact conductive sensor serves as an excitation electrode, and the fifth electrode serves as a grounding electrode to form an AC path; AC voltage signals are applied on the first electrode; and two groups of voltage signals independently reflecting conductive information of the fluid in the pipe are respectively obtained between the second electrode and the third electrode as well as between the third electrode and the fourth electrode, and then sent to the microcomputer via the amplitude modulation demodulation circuit and the data acquisition module, so as to perform mutual correlation operation to the two groups of obtained voltage signals by using the mutual correlation theory, to obtain the flow velocity of the detected fluid and further obtain the flow rate of the fluid. The device provided by the utility model is non-contact, does not affect the flow of the fluid in the pipe, has less pressure loss, and provides a beneficial method for solving the measurement to the flow velocity and the flow rate of the heterogeneous fluid in the small channel.
Description
Technical field
The utility model relates to the flow rate detection technique, relates in particular to a kind of passage aisle rate of flow of fluid flow measurement device.
Background technology
Ducted fluid extensively is present in the research and production process of industry departments such as food pharmaceutical, petrochemical complex, environmental protection, and flow velocity and flow are the significant process parameters in the commercial production.Along with the progress of new material technology, various application of new and development, industrial devices and device steps demonstrate the trend of microminiaturization, miniaturization.Though in industrial processes, the flow measurement device of conventional pipeline or the research of instrument are comparatively ripe with application, also very deficient for the passage aisle flow measurement technology of millimeter level caliber, lack effective measurement means at present.In addition; In field production runes such as chemical pharmaceutical; The conducting fluid that has suspension, solid particle etc. is also comparatively common; And existing flow rate measurement instrument is primarily aimed at the single and pure homogeneous fluid of medium, and the flow rate measurement of above-mentioned this inhomogeneous fluid is never had good solution.Therefore, be badly in need of a kind of instrument that is applicable to that passage aisle inhomogeneous fluid flow rate is measured of exploitation.
The capacity coupling non-contact conductance measuring technique is a kind of new non-contact conductance measurement technology.Its electrode does not directly contact with fluid, has avoided traditional contact method for measuring conductance problem, the problem includes: problems such as electrode polarization and galvanic corrosion effectively.Yet this Study on Technology and the measurement of using kapillary in the fields such as mainly being confined to analytical chemistry or following caliber solution conductivity, ion concentration etc. belong to blank basically in passage aisle inhomogeneous fluid flow rate field of measurement at present.
Summary of the invention
The purpose of the utility model is the deficiency that overcomes prior art, and a kind of stable, reliable passage aisle rate of flow of fluid flow measurement device is provided.
Passage aisle rate of flow of fluid flow measurement device comprises isolated pipe, first electrode, second electrode, third electrode, the 4th electrode, the 5th electrode, ac-excited source, amplitude modulation demodulation circuit, data acquisition module, microcomputer; The isolated pipe outside is provided with first electrode, second electrode, third electrode, the 4th electrode, the 5th electrode in order; First electrode links to each other with ac-excited source; Second electrode, third electrode, the 4th electrode link to each other with amplitude modulation demodulation circuit respectively; Amplitude modulation demodulation circuit, data acquisition module, microcomputer link to each other in order, the 5th electrode grounding; Constitute five electrode non-contact electric conductivity sensors by first electrode, second electrode, third electrode, the 4th electrode and the 5th electrode; First electrode is as exciting electrode; The 5th electrode is a ground-electrode; Second electrode, third electrode and the 4th electrode are the output terminal of five electrode non-contact electric conductivity sensors, constitute the upstream electrical derivative sensor by isolated pipe, second electrode and third electrode, constitute the downstream electrical derivative sensor by isolated pipe, third electrode and the 4th electrode.
Described amplitude modulation demodulation circuit is: second coupling capacitance, one end, second resistance, one end are connected with the positive input of first operational amplifier; One end of first resistance, an end of first electric capacity are connected with the inverting input of first operational amplifier; One end of the second resistance other end, the first electric capacity other end, the 3rd resistance is connected; The other end ground connection of the 3rd resistance; The 3rd coupling capacitance one end, the 5th resistance one end are connected with the positive input of second operational amplifier; One end of the 4th resistance, an end of second electric capacity are connected with the inverting input of second operational amplifier; One end of the 5th resistance other end, the second electric capacity other end, the 6th resistance is connected; The other end ground connection of the 6th resistance; The 4th coupling capacitance one end, the 8th resistance one end are connected with the positive input of the 3rd operational amplifier; One end of the 7th resistance, an end of the 3rd electric capacity are connected with the inverting input of the 3rd operational amplifier, and an end of the 8th resistance other end, the 3rd electric capacity other end, the 9th resistance is connected, the other end ground connection of the 9th resistance; The other end of the output terminal of first operational amplifier, first resistance is connected with the positive input of first instrumentation amplifier; The other end of the output terminal of second operational amplifier, the 4th resistance is connected with the reverse input end of first instrumentation amplifier, the positive input of second instrumentation amplifier, and the other end of the output terminal of the 3rd operational amplifier, the 7th resistance is connected with the reverse input end of second instrumentation amplifier, and the output terminal of first instrumentation amplifier is connected with an input end of first multiplier; The output terminal of second instrumentation amplifier is connected with an input end of second multiplier; Ac-excited source is connected with another input end of first multiplier, another input end of second multiplier, and the output terminal of first multiplier is connected with an end of the 4th electric capacity, an end of the 12 resistance, the reverse input end of four-operational amplifier through the tenth resistance, and the positive input of four-operational amplifier is through the 16 resistance eutral grounding; The output terminal of four-operational amplifier is connected with an end of the 6th electric capacity through the 14 resistance; The other end ground connection of the 6th electric capacity, the output terminal of second multiplier is connected with an end of the 5th electric capacity, an end of the 13 resistance, the reverse input end of the 5th operational amplifier through the 11 resistance, and the positive input of the 5th operational amplifier is through the 17 resistance eutral grounding; The output terminal of the 5th operational amplifier is connected with an end of the 7th electric capacity through the 15 resistance, the other end ground connection of the 7th electric capacity.
The utility model compared with prior art has beneficial effect:
1) metering system is a non-intrusion type, and the pressure loss is little, does not destroy pipeline inner fluid flow field, electrode not with pipeline in fluid contact, so electrode do not receive fluid impact, burn into polarization, is applicable to that passage aisle inhomogeneous fluid flow rate measures;
2) five electrode non-contact electric conductivity sensors obtain directly to reflect that pipeline inner fluid electricity leads the weak voltage signal of information; The structure of five electrodes can be avoided the influence of coupling capacitance in the traditional capacitance manifold type non-contact conductance measuring technique, improves the sensitivity of sensor;
3) utilize amplitude modulation demodulation circuit to realize detection, suppressed circuit noise effectively, improved the signal to noise ratio (S/N ratio) of output signal the weak voltage signal.
Description of drawings
Fig. 1 is the structural representation of rate of flow of fluid flow measurement device;
Fig. 2 is the five electrode non-contact electric conductivity sensor equivalent circuit diagrams of the utility model;
Fig. 3 is the amplitude modulation demodulation circuit figure of the utility model;
Among the figure: isolated pipe 1, first electrode 2, second electrode 3, third electrode 4, the 4th electrode 5, the 5th electrode 6, ac-excited source 7, amplitude modulation demodulation circuit 8, data acquisition module 9, microcomputer 10.
Embodiment
As shown in Figure 1, passage aisle rate of flow of fluid flow measurement device comprises isolated pipe 1, first electrode 2, second electrode 3, third electrode 4, the 4th electrode 5, the 5th electrode 6, ac-excited source 7, amplitude modulation demodulation circuit 8, data acquisition module 9, microcomputer 10; Isolated pipe 1 outside is provided with first electrode 2, second electrode 3, third electrode 4, the 4th electrode 5, the 5th electrode 6 in order; First electrode 2 links to each other with ac-excited source 7; Second electrode 3, third electrode 4, the 4th electrode 5 link to each other with amplitude modulation demodulation circuit 8 respectively; Amplitude modulation demodulation circuit 8, data acquisition module 9, microcomputer 10 link to each other in order, the 5th electrode 6 ground connection; Constitute five electrode non-contact electric conductivity sensors by first electrode 2, second electrode 3, third electrode 4, the 4th electrode 5 and the 5th electrode 6; First electrode 2 is as exciting electrode; The 5th electrode 6 is a ground-electrode; Second electrode 3, third electrode 4 and the 4th electrode 5 are the output terminal of five electrode non-contact electric conductivity sensors, constitute the upstream electrical derivative sensor by isolated pipe 1, second electrode 3 and third electrode 4, constitute the downstream electrical derivative sensor by isolated pipe 1, third electrode 4 and the 4th electrode 5.
Utilize this apparatus and method measurement rate of flow of fluid flow flow process to be: ac-excited source output AC voltage signal; And be applied on first electrode; The 5th electrode grounding is to constitute alternating current path; Reflect that independently the tube fluid electricity leads the voltage signal of information obtaining two groups between second electrode, third electrode and between third electrode, the 4th electrode respectively, be sent to microcomputer, utilize the simple crosscorrelation principle that two groups of voltage signals that obtained are carried out computing cross-correlation through amplitude modulation demodulation circuit and data acquisition module; Obtain the flow velocity of detected fluid, and and then obtain the flow of fluid.
The first coupling capacitance C as shown in Figure 2, that ac-excited source 7 and first electrode 2, isolated pipe 1 and pipeline inner fluid form
X1One end is connected, the second coupling capacitance C that second electrode 3, isolated pipe 1 and pipeline inner fluid form
X2One termination is gone into the first current potential output terminal V
1, the 3rd coupling capacitance C that third electrode 4, isolated pipe 1 and pipeline inner fluid form
X3One termination is gone into the second current potential output terminal V
2, the 4th coupling capacitance C that the 4th electrode 5, isolated pipe 1 and pipeline inner fluid form
X4One termination is gone into the 3rd current potential output terminal V
3, the 5th electrode 6, isolated pipe 1 and formed the 5th coupling capacitance C of pipeline inner fluid
X5One end ground connection, the first coupling capacitance C
X1The other end and the second coupling capacitance C
X2The other end passes through first fluid equivalent resistance R between the two
X1Be connected the second coupling capacitance C
X2The other end and the 3rd coupling capacitance C
X3The other end passes through the second fluid equivalent resistance R between the two
X2Be connected the 3rd coupling capacitance C
X3The other end and the 4th coupling capacitance C
X4The other end passes through three-fluid equivalent resistance R between the two
X3Be connected the 4th coupling capacitance C
X4The other end and the 5th coupling capacitance C
X5The other end passes through the 4th fluid equivalent resistance R between the two
X4Be connected.
As shown in Figure 3, described amplitude modulation demodulation circuit 8 is: the second coupling capacitance C
X2One end, second resistance R
2One end and first operational amplifier A
1(AD817) positive input is connected, first resistance R
1An end, first capacitor C
1An end and first operational amplifier A
1(AD817) inverting input is connected, second resistance R
2The other end, first capacitor C
1The other end, the 3rd resistance R
3An end be connected the 3rd resistance R
3Other end ground connection, the 3rd coupling capacitance C
X3One end, the 5th resistance R
5One end and second operational amplifier A
2(AD817) positive input is connected, the 4th resistance R
4An end, second capacitor C
2An end and second operational amplifier A
2(AD817) inverting input is connected, the 5th resistance R
5The other end, second capacitor C
2The other end, the 6th resistance R
6An end be connected the 6th resistance R
6Other end ground connection, the 4th coupling capacitance C
X4One end, the 8th resistance R
8One end and the 3rd operational amplifier A
3(AD817) positive input is connected, the 7th resistance R
7An end, the 3rd capacitor C
3An end and the 3rd operational amplifier A
3(AD817) inverting input is connected, the 8th resistance R
8The other end, the 3rd capacitor C
3The other end, the 9th resistance R
9An end be connected the 9th resistance R
9Other end ground connection, first operational amplifier A
1(AD817) output terminal, first resistance R
1The other end be connected second operational amplifier A with the positive input of the first instrumentation amplifier Y1 (INA111)
2(AD817) output terminal, the 4th resistance R
4The other end and the first instrumentation amplifier Y
1(INA111) reverse input end, the second instrumentation amplifier Y
2(INA111) positive input is connected, the 3rd operational amplifier A
3(AD817) output terminal, the 7th resistance R
7The other end be connected the output terminal of the first instrumentation amplifier Y1 (INA111) and the first multiplier M with the reverse input end of the second instrumentation amplifier Y2 (INA111)
1(AD734) a input end is connected, the output terminal of the second instrumentation amplifier Y2 (INA111) and the second multiplier M
2(AD734) a input end is connected, the ac-excited source 7 and the first multiplier M
1(AD734) another input end, the second multiplier M
2(AD734) another input end is connected, the first multiplier M
1(AD734) output terminal is through the tenth resistance R
10With the 4th capacitor C
4An end, the 12 resistance R
12An end, four-operational amplifier A
4(AD817) reverse input end is connected, four-operational amplifier A
4(AD817) positive input is through the 16 resistance R
16Ground connection, four-operational amplifier A
4(AD817) output terminal is through the 14 resistance R
14With the 6th capacitor C
6An end be connected the 6th capacitor C
6Other end ground connection, the second multiplier M
2(AD734) output terminal is through the 11 resistance R
11With the 5th capacitor C
5An end, the 13 resistance R
13An end, the 5th operational amplifier A
5(AD817) reverse input end is connected, the 5th operational amplifier A
5(AD817) positive input is through the 17 resistance R
17Ground connection, the 5th operational amplifier A
5(AD817) output terminal is through the 15 resistance R
15With the 7th capacitor C
7An end be connected the 7th capacitor C
7Other end ground connection.
The step of passage aisle rate of flow of fluid flow-measuring method is following:
1) excitation frequency that ac-excited source 7 is set is f, and output voltage is U<sub TranNum=" 169 ">In</sub>, under this pumping signal effect, five electrode non-contact electric conductivity sensors form an alternating current path, equivalent electrical circuit resulting impedance<maths TranNum=" 170 " num=" 0001 "><[CDATA [<math><mrow><mi>Z</mi><mo>=</mo><mfrac><mn>1</mn><mrow><mi>j</mi><mn>2</mn><mi>π</mi><msub><mi>Fc</mi><mrow><mi>x</mi><mn>1</mn></mrow></msub></mrow></mfrac><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>1</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>2</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>3</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>4</mn></mrow></msub><mo>+</mo><mfrac><mn>1</mn><mrow><mi>j</mi><mn>2</mn><mi>π</mi><msub><mi>Fc</mi><mrow><mi>x</mi><mn>5</mn></mrow></msub></mrow></mfrac><mo>,</mo></mrow></math>]]></maths>The first current potential output terminal V<sub TranNum=" 171 ">1</sub>Potential value<maths TranNum=" 172 " num=" 0002 "><[CDATA [<math><mrow><msub><mi>V</mi><mn>1</mn></msub><mo>=</mo><mfrac><mrow><msub><mi>R</mi><mrow><mi>x</mi><mn>2</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>3</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>4</mn></mrow></msub><mo>+</mo><mfrac><mn>1</mn><mrow><mi>j</mi><mn>2</mn><mi>π</mi><msub><mi>Fc</mi><mrow><mi>x</mi><mn>5</mn></mrow></msub></mrow></mfrac></mrow><mi>Z</mi></mfrac><mo>,</mo></mrow></math>]]></maths>The second current potential output terminal V<sub TranNum=" 173 ">2</sub>Potential value<maths TranNum=" 174 " num=" 0003 "><[CDATA [<math><mrow><msub><mi>V</mi><mn>2</mn></msub><mo>=</mo><mfrac><mrow><msub><mi>R</mi><mrow><mi>x</mi><mn>3</mn></mrow></msub><mo>+</mo><msub><mi>R</mi><mrow><mi>x</mi><mn>4</mn></mrow></msub><mo>+</mo><mfrac><mn>1</mn><mrow><mi>j</mi><mn>2</mn><mi>π</mi><msub><mi>Fc</mi><mrow><mi>x</mi><mn>5</mn></mrow></msub></mrow></mfrac></mrow><mi>Z</mi></mfrac><mo>,</mo></mrow></math>]]></maths>The 3rd current potential output terminal V<sub TranNum=" 175 ">3</sub>Potential value<img TranNum="176" file="BDA0000089492590000054.GIF" he="175" img-content="drawing" img-format="GIF" inline="yes" orientation="portrait" wi="414"/>The second fluid equivalent resistance R<sub TranNum=" 177 ">X2</sub>The voltage drop at two ends<img TranNum="178" file="BDA0000089492590000055.GIF" he="107" img-content="drawing" img-format="GIF" inline="yes" orientation="portrait" wi="461"/>Three-fluid equivalent resistance R<sub TranNum=" 179 ">X3</sub>The voltage drop at two ends<img TranNum="180" file="BDA0000089492590000056.GIF" he="107" img-content="drawing" img-format="GIF" inline="yes" orientation="portrait" wi="464"/>Wherein, first fluid equivalent resistance R<sub TranNum=" 181 ">X1</sub>Be the equivalent resistance of first electrode and the second interelectrode fluid, the second fluid equivalent resistance R<sub TranNum=" 182 ">X2</sub>Be the equivalent resistance of the fluid between second electrode and third electrode, three-fluid equivalent resistance R<sub TranNum=" 183 ">X3</sub>Be the equivalent resistance of third electrode and the 4th interelectrode fluid, the 4th fluid equivalent resistance R<sub TranNum=" 184 ">X4</sub>Be the equivalent resistance of the 4th electrode and the 5th interelectrode fluid, the first coupling capacitance C<sub TranNum=" 185 ">X1</sub>Be the coupling capacitance that first electrode 2, isolated pipe 1 and pipeline inner fluid form, the second coupling capacitance C<sub TranNum=" 186 ">X2</sub>The coupling capacitance that to be second electrode 3, isolated pipe 1 form with the pipeline inner fluid, the 3rd coupling capacitance C<sub TranNum=" 187 ">X3</sub>Be the coupling capacitance that third electrode 4, isolated pipe 1 and pipeline inner fluid form, the 4th coupling capacitance C<sub TranNum=" 188 ">X4</sub>The coupling capacitance that to be the 4th electrode 5, isolated pipe 1 form with the pipeline inner fluid, the 5th coupling capacitance C<sub TranNum=" 189 ">X5</sub>Be the 5th electrode 6, isolated pipe 1 and the formed coupling capacitance of pipeline inner fluid;
2) amplitude modulation demodulation circuit 8 is by the first current potential output terminal V
1With the second current potential output terminal V
2Obtain the second fluid equivalent resistance R
X2The voltage drop U at two ends
01, by the second current potential output terminal V
2With the 3rd current potential output terminal V
3Obtain three-fluid equivalent resistance R
X3The voltage drop U at two ends
02, and, obtain first voltage U with its demodulation respectively, amplification
1With second voltage U
2
3) first voltage U
1, second voltage U
2In microcomputer, adopt following formula calculation flow rate flow by data collecting module collected, utilize earlier
Obtain transit time τ
o, through v
Cp=L/ τ
oCalculate rate of flow of fluid v
Cp, and and then acquisition fluid flow Q=v
CpA, wherein, L is the spacing between upstream sensor and downstream sensor, A is that cross-section of pipeline is long-pending.
Utilized the heterogeneous body conductive fluid on the horizontal glass pipeline to the utility model in mentioned apparatus and method carried out preliminary test; Verified the feasibility of the utility model; Wherein horizontal glass pipeline internal diameter is 3.90mm; External diameter is 6.20mm, and test(ing) medium is the non-homogeneous mixed solution of water and milk.Test findings shows: utilize apparatus and method mentioned in the utility model, can realize flow rate of fluid in the pipeline, flow measurement, and can obtain measurement result preferably.
Claims (2)
1. a passage aisle rate of flow of fluid flow measurement device is characterized in that comprising isolated pipe (1), first electrode (2), second electrode (3), third electrode (4), the 4th electrode (5), the 5th electrode (6), ac-excited source (7), amplitude modulation demodulation circuit (8), data acquisition module (9), microcomputer (10); Isolated pipe (1) outside is provided with first electrode (2), second electrode (3), third electrode (4), the 4th electrode (5), the 5th electrode (6) in order; First electrode (2) links to each other with ac-excited source (7); Second electrode (3), third electrode (4), the 4th electrode (5) link to each other with amplitude modulation demodulation circuit (8) respectively; Amplitude modulation demodulation circuit (8), data acquisition module (9), microcomputer (10) link to each other in order, the 5th electrode (6) ground connection; Constitute five electrode non-contact electric conductivity sensors by first electrode (2), second electrode (3), third electrode (4), the 4th electrode (5) and the 5th electrode (6); First electrode (2) is as exciting electrode; The 5th electrode (6) is a ground-electrode; Second electrode (3), third electrode (4) and the 4th electrode (5) are the output terminal of five electrode non-contact electric conductivity sensors; Constitute the upstream electrical derivative sensor by isolated pipe (1), second electrode (3) and third electrode (4), constitute the downstream electrical derivative sensor by isolated pipe (1), third electrode (4) and the 4th electrode (5).
2. a kind of passage aisle rate of flow of fluid flow measurement device according to claim 1 is characterized in that described amplitude modulation demodulation circuit (8) is: the second coupling capacitance (C x2 ) end, the second resistance (R 2 ) end and the first operational amplifier (A 1 ) positive input be connected, the first resistance (R 1 ) an end, the first electric capacity (C 1 ) an end and the first operational amplifier (A 1 ) inverting input be connected, the second resistance (R 2 ) other end, the first electric capacity (C 1 ) other end, the 3rd resistance (R 3 ) an end be connected, the 3rd resistance (R 3 ) other end ground connection, the 3rd coupling capacitance (C x3 ) end, the 5th resistance (R 5 ) end and the second operational amplifier (A 2 ) positive input be connected, the 4th resistance (R 4 ) an end, the second electric capacity (C 2 ) an end and the second operational amplifier (A 2 ) inverting input be connected, the 5th resistance (R 5 ) other end, the second electric capacity (C 2 ) other end, the 6th resistance (R 6 ) an end be connected, the 6th resistance (R 6 ) other end ground connection, the 4th coupling capacitance (C x4 ) end, the 8th resistance (R 8 ) end and the 3rd operational amplifier (A 3 ) positive input be connected, the 7th resistance (R 7 ) an end, the 3rd electric capacity (C 3 ) an end and the 3rd operational amplifier (A 3 ) inverting input be connected, the 8th resistance (R 8 ) other end, the 3rd electric capacity (C 3 ) other end, the 9th resistance (R 9 ) an end be connected, the 9th resistance (R 9 ) other end ground connection, the first operational amplifier (A 1 ) output, the first resistance (R 1 ) the other end and the first instrumentation amplifier (Y 1 ) positive input be connected, the second operational amplifier (A 2 ) output, the 4th resistance (R 4 ) the other end and the first instrumentation amplifier (Y 1 ) reverse input end, the second instrumentation amplifier (Y 2 ) positive input be connected, the 3rd operational amplifier (A 3 ) output, the 7th resistance (R 7 ) the other end and the second instrumentation amplifier (Y 2 ) reverse input end be connected, the first instrumentation amplifier (Y 1 ) output and the first multiplier (M 1 ) an input be connected, the second instrumentation amplifier (Y 2 ) output and the second multiplier (M 2 ) an input be connected, ac-excited source (7) and the first multiplier (M 1 ) another input, the second multiplier (M 2 ) another input be connected, the first multiplier (M 1 ) output by the tenth resistance (R 10 ) and the 4th electric capacity (C 4 ) an end, the 12 resistance (R 12 ) an end, four-operational amplifier (A 4 ) reverse input end be connected, four-operational amplifier (A 4 ) positive input by the 16 resistance (R 16 ) ground connection, four-operational amplifier (A 4 ) output by the 14 resistance (R 14 ) and the 6th electric capacity (C 6 ) an end be connected, the 6th electric capacity (C 6 ) other end ground connection, the second multiplier (M 2 ) output by the 11 resistance (R 11 ) and the 5th electric capacity (C 5 ) an end, the 13 resistance (R 13 ) an end, the 5th operational amplifier (A 5 ) reverse input end be connected, the 5th operational amplifier (A 5 ) positive input by the 17 resistance (R 17 ) ground connection, the 5th operational amplifier (A 5 ) output by the 15 resistance (R 15 ) and the 7th electric capacity (C 7 ) an end be connected, the 7th electric capacity (C 7 ) other end ground connection.
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| CN2011203343081U CN202204828U (en) | 2011-09-07 | 2011-09-07 | Device for measuring flow velocity and flow rate of fluid in small channel |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102360025A (en) * | 2011-09-07 | 2012-02-22 | 浙江大学 | Device and method for measuring flow velocity and flow quantity of fluid in small flow passage |
| CN105259366A (en) * | 2015-10-30 | 2016-01-20 | 武汉工程大学 | Measuring device and method for seepage flow velocity |
| CN109084856A (en) * | 2018-07-19 | 2018-12-25 | 中国神华能源股份有限公司 | The flow determining method of open circulation water system |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102360025A (en) * | 2011-09-07 | 2012-02-22 | 浙江大学 | Device and method for measuring flow velocity and flow quantity of fluid in small flow passage |
| CN105259366A (en) * | 2015-10-30 | 2016-01-20 | 武汉工程大学 | Measuring device and method for seepage flow velocity |
| CN109084856A (en) * | 2018-07-19 | 2018-12-25 | 中国神华能源股份有限公司 | The flow determining method of open circulation water system |
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