CN1828230A - Flux measuring method based on negative resistance property and resistance flowmeter - Google Patents
Flux measuring method based on negative resistance property and resistance flowmeter Download PDFInfo
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- CN1828230A CN1828230A CN200610010794.5A CN200610010794A CN1828230A CN 1828230 A CN1828230 A CN 1828230A CN 200610010794 A CN200610010794 A CN 200610010794A CN 1828230 A CN1828230 A CN 1828230A
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Abstract
The disclosed measurement method comprises: measuring the resistance variation between two fixed points in flow field and opposite liquid average flow rate to scale and find out the relation V=f(R), then calculating the flow rate by Q=AV=Af(x). Wherein, the flowmeter comprises a flow rate sensor, a front-end amplification converter, a flow rate integrator, a display and record device, an interface circuit, and a power. This invention has well application in lots of fields.
Description
Technical field
The present invention relates to measure the method and the device of flow, particularly based on the flow-measuring method of negative resistance charactertistic and the resistive flowmeter that utilizes this method design by resistance between liquid two is fixed a point in the measurement flow field.
Background technology
Flowmeter is all widely used instrument of numerous areas such as oil, chemical industry, food, environmental protection, Fluid Transmission and Control.In oil, chemical industry, flow often is main observing and controlling parameter, and its accuracy of detection all has material impact to product quality, production safety.In Fluid Transmission and Control, flow is the supervisory system duty especially, and the evaluation system element is quiet, the major parameter of dynamic property, and the precision and the technical merit that improve flow measurement have important in theory meaning and practical value.
The flowmeter that is using at present is of a great variety, and measuring principle is different, and except volume type, quality formula are directly to measure the flow, most of flowmeters are to belong to indirect measurement.Multiply by the long-pending Q=AV of overflow section because flow equals mean flow rate, can when fluid flows,, just can utilize Q=AV=Af (x) measuring and calculating flow by measuring the physical quantity x relevant or the increment Delta x of this physical quantity with fluid mean flow rate V if V=f (x) is arranged.
According to the principle of above-mentioned indirect measurement, selecting different physical quantitys for use is that object has just formed different flowmeters.When getting x and being pressure differential deltap p is differential pressure flowmeter, as orifice-plate type, nozzle-type, venturi type, laminar flow flowmeter etc.; When the pulsed frequency of getting impeller is x, be exactly vane-wheel type flowmeter, as turbine meter, shunting rotor flowmeter etc.; During vortex frequency when getting x and being fluid turbulence, be exactly eddy-current flowmeter, as vortex shedding flow meter, vortex precession flowmeter etc.; If get ultrasound wave, be exactly ultrasonic flowmeter, Doppler flowmeter etc. during for x as frequency, mistiming by the parameter after the fluid reflection.Also have electromagnetic flowmeter, laser flowmeter etc. in addition.
The problem that the current flux meter exists, (1) interference flowing field changes fluidised form.Most flowmeters need be provided with orifice plate, turbine, restricting element in pipeline, produce the bigger pressure loss, interference flowing field, and measuring error is big.(2) dynamic responding speed is slow.Because the moving component inertia effects, majority can only be measured average discharge, can't react for the transient behavior flow.(3) on the high side.As laser type, ultrasonic type flowmeter, price is higher, uses restricted.
From the requirement of test, measure purpose from the measurement of simple static state average flow, turned to the measurement that requires dynamic instantaneous delivery simultaneously.Particularly in the Fluid Transmission and Control field, response speed is more and more faster, requirement to dynamic performance is more and more higher, the measurement level of dynamic instantaneous delivery now can not satisfy the working control requirement far away, and dynamically the measurement of instantaneous delivery has become the problem that the system for restricting control performance improves.
Goal of the invention
The objective of the invention is to study the interaction mechanism between working fluid mean flow rate V and the resistance R, find out the relation between the two, with the resistance R is the physical quantity x of indirect determination liquid mean flow rate, and propose a kind of new flow measurement theory and method thus, and design a kind of resistive flowmeter according to this theory and method.The present invention and methodological science are reasonable, install easy for installation; Interference flowing field not, the pressure loss is little; Movement-less part can be eliminated inertia effects to greatest extent, and dynamic property is good, can make things convenient for and measure dynamic instantaneous delivery accurately.
Summary of the invention
Flow-measuring method based on negative resistance charactertistic, it is characterized in that, the mean flow rate of the liquid of changes in resistance amount and correspondence between liquid two is fixed a point in the measurement flow field, by demarcating, that finds out the resistance R of different liquids and mean flow rate V concerns V=f (R), and then calculate flow by Q=AV=Af (x), and the liquid variable resistor R that utilizes desire to measure to be made of fluid to be measured between two set in the pipeline of its flow electrodes measures flow, and concrete grammar is:
(1) establish two electrodes in desire is measured the pipeline of its flow, electrode directly contacts with liquid, when forming the liquid resistance of a numerical value behind the full of liquid in the pipe between two electrodes with the variation of liquid mean flow rate,
(2) keep liquid in pipe static, measure two interelectrode initial liquid resistance R
0,
(3) change the liquid in pipe mean flow rate, get V successively
1, V
2, V
3Vn measures corresponding resistance R
1R
2R
3Rn,
(4) adopt the existing above-mentioned data of known computer curve fitting routine processes, get the funtcional relationship V=f (R) between outflow and resistance,
(5) the long-pending A of measuring channel overflow section,
(6) relational expression that step (4), (5) are drawn and data input stream amount integrating instrument, store stand-by,
(7) flow integrator is according to the different liquids resistance stored and the funtcional relationship V=f (R) of mean flow rate, and according to Q=AV=Af (x) relation, utilizes its default existing known calculation procedure, the calculating fluid flow,
(8) by the real-time displayed record flow value of on-line monitoring programmed control display instrument in the flow integrator, but and query history record.
Resistive flowmeter based on negative resistance charactertistic of the present invention is characterized in that, includes:
(1) flow sensor of bulk resistor variable quantity,
(2) be used for transfer resistance signal and the preposition amplification converter that amplifies,
(3) utilize different liquids resistance and voltage signal to concern V=f (R), and, utilize its default existing known calculation procedure according to Q=AV=Af (x) relation, the flow integrator of calculated flow rate,
(4) demonstration of displayed record flow value, registering instrument,
(5) with flow signal output, for the I/O interface circuit of controlling use automatically,
(6) power supply,
Flow sensing body (4) two ends are dismountable syndeton, and endoporus passes through for liquid, are respectively equipped with the electrode (2) of surveying resistance variations between two fixed points at endoporus, and sensor connects with preposition magnification changer is electric; Preposition magnification changer connects with flow integrator is electric; Flow integrator connects with display instrument is electric; Flow integrator and flow signal output I/O electric connection of interface; Power supply respectively with flow sensor, preposition magnification changer, flow integrator, and Flow Measurement Display Meter is electric connects.
According to theoretical analysis and experimental verification, the resistance in the flow field between two fixed points can reduce along with the increase of mean flow rate, and we are referred to as " negative resistance charactertistic ".When fluid certain, when external condition is constant, exist to determine between the two funtcional relationship.As long as can set up this funtcional relationship V=f (R), just can be by formula Q=AV=Af (R) flow.This is the theoretical foundation of resistive flowmeter, and the present invention proposes flow-measuring method and the resistive flowmeter based on negative resistance charactertistic in view of the above.
The theoretical foundation of measurement method of flow of the present invention is to have the funtcional relationship of determining between resistance between liquid flow field two fixed points and the mean flow rate.When mean flow rate is zero, an original value R is arranged
0, this resistance can change when mean flow rate increases, and has the funtcional relationship of determining between mean flow rate and the resistance, we select resistance R as the reference physical quantity, set up funtcional relationship V=f (R), just can indirect determination mean flow rate V, and then calculate by Q=AV=Af (R) and to obtain flow.Various liquid V is different with the funtcional relationship of R, should demarcate respectively in the measuring and calculating.The calibration result of various different liquids is designated as f corresponding to different funtcional relationships
1(R), f
2(R), f
3(R) ..., be stored in the flow integrator standby.
In the present invention, flow sensor is also referred to as flow transmitter, and its effect is to be resistance or the voltage relevant with resistance variations, the parts of current signal with the mean flow rate conversion of signals.Preposition amplification converter is used to amplify, the output signal of transform stream quantity sensor, makes it to be handled by flow integrator easily.Flow integrator is used to receive preposition amplification output signal, draws flow signal after computing, the processing.Display instrument is used for the form table output of numerical value such as flow, total flow, average discharge with the perception of people's energy, as indicator indication, LED demonstration and printer prints output etc.Flow signal output has various ways such as voltage, electric current, uses for instrument for automatic control or upper level control computer.
Characteristics of the present invention, the liquid resistance in (1) needs measurement flow field between any two point of fixity also converts thereof into signals such as the voltage relevant with resistance, electric current, just can obtain the flow of liquid, so method is simple, sensor construction is also very simple, intensity is good.The present invention also can be used for the highly pressurised liquid flow measurement except that being used for the normal pressure liquid flow measurement, as water jet cutting, pure water hydraulics transmission etc.(2) the present invention becomes voltage or current signal with changes in resistance by electric bridge or other circuit conversion, and the output of end product is designed to digital quantity or analog quantity is all very convenient, and the choice is big, applied range.(3) sensor of the present invention can interference flowing field, does not have the pressure loss, can also measure and be with corrosive liquid, as the flow of water, acid, aqueous slkali etc.(4) movement-less part of the present invention, response is fast, and dynamic perfromance is good, except that measuring the average discharge, more can be used for the on-line measurement of dynamic instantaneous delivery, and this point is significant for fields such as Fluid Transmission and Control system, fine chemistry industries.
The present invention can be widely used in conduction or micro conductive liquid, as the flow measurement of water or various acid, alkali, salt solusion, in the pure water hydraulics transmission, the flow measurement of acid, aqueous slkali in environmental protection water treatment system, the chemical industry, production run control aspect automatically can be widely used.Application prospect is good.
Below in conjunction with the drawings and the specific embodiments the present invention is further explained.
Description of drawings
Fig. 1 is a structured flowchart of the present invention
Fig. 2 is the electric schematic diagram of sensor of the present invention
Fig. 3 has the sensor construction synoptic diagram of ring electrode for the present invention
Fig. 4 has the sensor construction synoptic diagram of needle electrode for the present invention
Fig. 5 is the preposition amplification converter electrical schematic diagram of partial pressure type
Fig. 6 is the preposition amplification converter electrical schematic diagram of bridge-type
Fig. 7 is the flow integrator structured flowchart
Fig. 8 is a flow measurement connection diagram of the present invention
Fig. 9 is flow measurement of the present invention, control linkage synoptic diagram
Embodiment
Flow-measuring method and resistive flowmeter based on negative resistance charactertistic
1, based on the flow-measuring method of negative resistance charactertistic
In the flow field, measure changes in resistance between liquid two fixed points, concern V=f (R) by what the resistance R of different liquids and mean flow rate V were found out in demarcation, by preposition magnification changer, flow integrator process information, obtain flow information and show that at display instrument concrete grammar is
(1) desire is measured two electrodes of the interior series connection of pipeline of its flow, and electrode directly contacts with liquid, forms the liquid resistance that numerical value becomes with mean flow rate in managing behind the full of liquid between two electrodes,
(2) flowmeter is demarcated, at first kept liquid in pipe static, measure the initial liquid resistance R of two interpolars
0Change the liquid in pipe mean flow rate, get V successively
1, V
2, V
3Vn measures corresponding resistance R
1, R
2, R
3Rn,
(3) adopt the existing above-mentioned data of known computer programs process, the funtcional relationship V=f (R) between outflow and resistance, and it is stand-by to be stored in flow integrator,
(4) the long-pending A of measuring channel overflow section,
(5) relational expression that step (4), (5) are drawn and data input stream amount integrating instrument utilize its default existing known calculation procedure (for example), calculate Q=Af (R), obtain fluid flow,
(6) show the present flow rate value in real time by the on-line monitoring programmed control display instrument in the integrating instrument, but and the query history record,
(7) will export after the flow signal conversion, for control use automatically.
2, based on the resistive flowmeter of negative resistance charactertistic
According to said method design discharge sensor.Flow sensing body (4) two ends be screw thread (6) or flange (8) so that be connected with fluid pipeline (10), normally the tested pipeline diameter hour adopts and is threaded, the tested pipeline diameter adopts flange to connect (8) when big.Endoporus passes through for liquid, is fixed with two electrodes (2) of surveying resistance variations between two fixed points in endoporus respectively, and circular ring electrode (9) diameter of bore is identical with the sensor diameter of bore and concentric, is 25 millimeters, the desirable 10-50 millimeter of common two interelectrode distances.Electrode also can be for circular (9), needle-like or column (7) etc., and is best with the circular ring electrode effect, as Fig. 3, Fig. 4.Electrode (2) is electrically connected to preposition magnification changer by extension line (3), is provided with insulating trip (5) the sensor preposition magnification changer of connecting between electrode and the sensor body, and preposition magnification changer connects with flow integrator is electric; Flow integrator connects with display instrument is electric, and power supply is for complete machine provides energy, power supply respectively with flow sensor, preposition magnification changer, flow integrator, and Flow Measurement Display Meter is electric connects.Preposition magnification changer is used for resistance signal being converted to voltage signal and amplifying, flow signal output can be various ways such as voltage, electric current, flow integrator is used to receive the signal of preposition magnification changer, and the resistance R of utilization storage different liquids and the funtcional relationship V=f (R) of mean flow rate V, according to the pre-set programs calculated flow rate, and do to export after the convertible processing.Demonstration, registering instrument and power supply, the electric connection of flow integrator provide flow signal output in the device of use.Sensor structurally is independently, and power supply, preposition amplification converter, flow integrator, display recorder are done as a whole, places in main frame (1) case.Also can external expansion display recorder.
Preposition amplification converter can adopt various ways in the present embodiment, can adopt the preposition amplification converter of partial pressure type, as Fig. 5.The preposition switching amplifier of partial pressure type is by fixed resistance R
0, liquid variable resistor R, power supply, integrated operational amplifier circuit form, the liquid variable resistor is made up of two potential electrode and fluid to be measured, the output signal of amplifier is taken from the voltage u at liquid variable resistor two ends.If supply voltage is constant U,, can get by the electrotechnics theory because the input resistance of integrated operational amplifier circuit is very big:
U is also doing corresponding the variation when R changes along with the liquid mean flow rate, has comprised the information that mean flow rate changes among the u.
Present embodiment also can adopt the preposition amplification converter of bridge-type, by three fixed resistance R
0The liquid variable resistor R that constitutes with fluid to be measured has formed an electric bridge, and electrical principle as shown in Figure 6.The output of amplifier is taken as the voltage of a, b point-to-point transmission, can be obtained by electrotechnical principle equally:
When changing, resistance R can obtain a variable signal u equally.Compare with the preposition amplification converter of partial pressure type, the preposition amplification converter antijamming capability of bridge-type is strong, and measuring accuracy is higher, belongs to preferred forms.Opinion is taked above-mentioned that a kind of form, and preposition amplification converter all must possess following feature,
(1) has by fixed resistance R
0Bleeder circuit or the bridge circuit formed with liquid variable resistor R.
(2) has the amplifying circuit of forming by integrated operational amplifier.
(3) adopting AC power is bleeder circuit or bridge diagram power supply.
The effect of flow integrator in the present invention is to receive the signal that preposition amplification is sent here, draws flow signal after computing, processing.The signal of gained is divided into two-way, and one the road drives Displaying Meter, directly reading.Use for the Displaying Meter or the Other Instruments of control or external expansion automatically by the output of multichannel external interface on another road.Output signal has two kinds of digital signal and simulating signals, can freely select for use.The core of flow integrator is a single-chip microcomputer, and Fig. 6 is a flow integrator structured flowchart.Signal u from preposition switching amplifier
1By (I/O) interface, after mould/number (A/D) conversion, enter single-chip microcomputer, carry out computing according to the program of prior setting, the flow signal one tunnel that draws is sent into Displaying Meter, and directly video data reads for the user of service.Another road is through I/O interface output, and output quantity has two kinds of digital signal and simulating signals, can select for use according to actual conditions.Output interface is provided with a plurality of, uses when can be simultaneously controlling automatically for different instrument for automatic controls or upper level control computer, also can be in order to drive the secondary instrument of expansions such as printer, oscillograph.Data on flows is stored in the single-chip microcomputer, can take for inquiry at any time.
Demonstration, registering instrument are with numerical value such as flow, total flow, average discharges, with the form table output of people's energy perception, as indicator indication, light emitting diode (LED), LCD (LCD) demonstration or printer prints output etc.
Resistance-type flowmeter utilizes working fluid resistance to increase the characteristic that reduces with the liquid mean flow rate and measures, and the flow signal that flowmeter is obtained is divided into two-way output, and one the tunnel connects Displaying Meter, is directly read by operating personnel.Can there be various ways outputs such as voltage, electric current, frequency on another road as required, uses for automatic control system.Hence one can see that, and resistance-type flowmeter not only can be used as conventional flowmeter and uses, and more can be used as a link of robot control system(RCS), realizes that to relating to flow or the various production runes relevant with flow closed loops control automatically.
Fig. 8 is the connection diagram in the time of only need doing flow measurement.Sensor string is connected pipeline into the desire measurement of discharge, directly read the flow of liquid in pipe by operating personnel, or preserve for future referencely automatically, the flow signal output interface free time need not.In the time of only need knowing flow value, such connection gets final product.
Fig. 9 is flow measurement, control linkage synoptic diagram.With the signal of actual flow, send into comparison operation unit through output interface, with given flow signal relatively after, draw deviate, amplify the back and drive volume pump or operation valve generation corresponding action, increase or reduce flow, thereby reach the purpose of Control Flow by dynamical element.
Claims (5)
1, based on the flow-measuring method of negative resistance charactertistic, it is characterized in that, the mean flow rate of the liquid of changes in resistance amount and correspondence between liquid two is fixed a point in the measurement flow field, by demarcating, that finds out the resistance R of different liquids and mean flow rate V concerns V=f (R), and then calculate flow by Q=AV=Af (x), and the liquid variable resistor R that utilizes desire to measure to be made of fluid to be measured between two set in the pipeline of its flow electrodes measures flow, and concrete grammar is:
(1) establish two electrodes in desire is measured the pipeline of its flow, electrode directly contacts with liquid, when forming the liquid resistance of a numerical value with the variation of liquid mean flow rate behind the full of liquid in the pipe between two electrodes;
(2) keep liquid in pipe static, measure two interelectrode initial liquid resistance R
0,
(3) change the liquid in pipe mean flow rate, get V successively
1, V
2, V
3Vn measures corresponding resistance R
1R
2R
3Rn,
(4) adopt the existing above-mentioned data of known computer curve fitting routine processes, get the funtcional relationship V=f (R) between outflow and resistance,
(5) the long-pending A of measuring channel overflow section,
(6) relational expression that step (4), (5) are drawn and data input stream amount integrating instrument, store stand-by,
(7) flow integrator is according to the different liquids resistance stored and the funtcional relationship V=f (R) of mean flow rate, and according to Q=AV=Af (x) relation, utilizes its default existing known calculation procedure, the calculating fluid flow,
(8) by the real-time displayed record flow value of on-line monitoring programmed control display instrument in the flow integrator, but and query history record.
2, based on the resistive flowmeter of negative resistance charactertistic, it is characterized in that, include:
(1) flow sensor of tracer liquid resistance change,
(2) the preposition amplification converter that is used for the transfer resistance signal and amplifies,
(3) utilize different liquids resistance and liquid mean flow rate funtcional relationship V=f (R), and, utilize its default existing known calculation procedure according to Q=AV=Af (x) relation, the flow integrator of calculated flow rate,
(4) demonstration of displayed record flow value, registering instrument,
(5) with flow signal output, for the I/O interface circuit of controlling use automatically,
(6) power supply,
Flow sensing body (4) two ends are dismountable syndeton, and endoporus passes through for liquid, are respectively equipped with 2 electrodes (2) of surveying resistance variations between two fixed points at endoporus, and sensor connects with preposition magnification changer is electric; Preposition magnification changer connects with flow integrator is electric; Flow integrator connects with display instrument is electric; Flow integrator and flow signal output I/O electric connection of interface; Power supply respectively with flow sensor, preposition magnification changer, flow integrator, and Flow Measurement Display Meter is electric connects.
3, the resistive flowmeter based on negative resistance charactertistic as claimed in claim 2 is characterized in that, has by fixed resistance R in the circuit of preposition amplification converter
0Bleeder circuit or bridge circuit that the liquid variable resistor R that changes with the liquid mean flow rate with numerical value is formed.
4, the resistive flowmeter based on negative resistance charactertistic as claimed in claim 2 is characterized in that, flow sensor is provided with 2 electrodes (2), is electrically connected to preposition magnification changer by extension line (3), and electrode is circular (9), needle-like or column (7).
5, the resistive flowmeter based on negative resistance charactertistic as claimed in claim 3 is characterized in that, dismountable syndeton connects (8) for be threaded (6) or flange.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102435238A (en) * | 2011-11-02 | 2012-05-02 | 中国计量学院 | Bridge type flow measuring method and device for conducting liquid flow measurement |
CN105424098A (en) * | 2015-11-13 | 2016-03-23 | 李文艺 | Volumetric flowmeter |
CN107131905A (en) * | 2016-02-26 | 2017-09-05 | 高准公司 | Detect two or more gauge assemblies |
CN114636039A (en) * | 2022-05-17 | 2022-06-17 | 浙江大学 | Self-sensing intelligent electric melting pipe fitting, flow and leakage detection system and method |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102445245B (en) * | 2011-11-02 | 2012-12-05 | 刘铁军 | Flow rate measurement device based on bridge-type flow rate measurement and electromagnetic flow rate measurement |
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CH529401A (en) * | 1970-09-02 | 1972-10-15 | Lacoray Sa | A method for monitoring a liquid flow and a flow monitor for carrying out the same |
GB1491207A (en) * | 1973-11-12 | 1977-11-09 | Atomic Energy Authority Uk | Sensors for monitoring the electrical conductivity of electrically conductive fluids |
GB1512235A (en) * | 1975-05-13 | 1978-05-24 | Zizine J | Electronic flow gauge |
NZ210240A (en) * | 1984-11-19 | 1989-04-26 | Allflex Int | Milk flow measure and teat cup removal |
CN2036660U (en) * | 1988-07-30 | 1989-04-26 | 昆明钢铁厂 | Hot-wire type flowmeter |
CN2287723Y (en) * | 1997-01-29 | 1998-08-12 | 中国原子能科学研究院 | Low-speed fluid flow velocity monitor |
CN2627470Y (en) * | 2003-07-04 | 2004-07-21 | 苏州三星电子有限公司 | Water level detecting device for ice-making machine of refrigerator |
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2006
- 2006-04-06 CN CNB2006100107945A patent/CN100427893C/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102435238A (en) * | 2011-11-02 | 2012-05-02 | 中国计量学院 | Bridge type flow measuring method and device for conducting liquid flow measurement |
CN105424098A (en) * | 2015-11-13 | 2016-03-23 | 李文艺 | Volumetric flowmeter |
CN107131905A (en) * | 2016-02-26 | 2017-09-05 | 高准公司 | Detect two or more gauge assemblies |
CN114636039A (en) * | 2022-05-17 | 2022-06-17 | 浙江大学 | Self-sensing intelligent electric melting pipe fitting, flow and leakage detection system and method |
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