CN209247278U - A kind of fluidic medium valve tiny leakage test device - Google Patents

A kind of fluidic medium valve tiny leakage test device Download PDF

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Publication number
CN209247278U
CN209247278U CN201822158974.9U CN201822158974U CN209247278U CN 209247278 U CN209247278 U CN 209247278U CN 201822158974 U CN201822158974 U CN 201822158974U CN 209247278 U CN209247278 U CN 209247278U
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China
Prior art keywords
valve
module
tiny leakage
simulation
pressure
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CN201822158974.9U
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Chinese (zh)
Inventor
黄萍
罗伟
沈勇波
符帅
朱汉武
朱翠云
刘赛楠
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Research Institute of Nuclear Power Operation
China Nuclear Power Operation Technology Corp Ltd
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Research Institute of Nuclear Power Operation
China Nuclear Power Operation Technology Corp Ltd
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Abstract

The utility model belongs to equipment gas leak detection technology field, more particularly to a kind of fluidic medium valve tiny leakage test device, slip is accurately detected using the method that part is suppressed online, online test sensitivity valve seal performance effectively ensures maintenance of valve quality.It is characterized in that, it includes booster pump, pipeline modules, energy-storage module, simulation tiny leakage device, sensor module, acquisition control module and host computer;Booster pump is connect by pipeline modules with energy-storage module, and energy-storage module is connect with valve analogue body, simulation tiny leakage device and sensor module respectively by pipeline modules;Valve analogue body is connect with sensor module and simulation tiny leakage device respectively by pipeline modules;Control acquisition module is connect with booster pump, sensor module and simulation tiny leakage device respectively by cable;Host computer is connect by cable with control acquisition module.

Description

A kind of fluidic medium valve tiny leakage test device
Technical field
The utility model belongs to equipment liquid leakage detection technique field, and in particular to a kind of on-line automatic measurement liquid Jie Matter valve tiny leakage detection device.
Background technique
Valve plays fluid truncation, isolation and adjustment effect, the quality of sealing performance on system pipeline circuit and directly affects It to the safe and reliable of nuclear power station, runs to economic stability, in case of leaking, the complete of whole system pressure boundary will be destroyed Property, it threatens to the safety of nuclear power station.
Eliminating valve leak is to pay close attention to item in nuclear power station operation and maintenance work.Since technology is limited and nuclear power The particularity of factory's condition carries out disintegration grinding to valve when most domestic nuclear power station uses overhaul substantially at present, can not be timely Verify whether valve tightness is qualified, once test is unqualified, set state has to drop back, and seriously affects power plant and normally transports Row.
During nuclear power plant's planned outage, in order to ensure maintenance of valve quality, guarantee that overhaul machine late gate is reliable for operation, It needs to carry out special leak detection to valve, the repair quality of valve is detected with objective quantitative.This test method is adopted Slip is accurately detected with the method suppressed online, online test sensitivity valve seal performance effectively ensures maintenance of valve quality.
Utility model content
During nuclear power plant's planned outage, in order to ensure maintenance of valve quality, guarantee that overhaul machine late gate is reliable for operation, Special leak detection is carried out to valve by the utility model, the repair quality of valve is detected with objective quantitative.This The test method of utility model accurately detects slip using the method suppressed online, online test sensitivity valve seal performance, Effectively ensure maintenance of valve quality.
The utility model is realized in this way:
A kind of fluidic medium valve tiny leakage test device, including booster pump, pipeline modules, energy-storage module, simulation micro- are let out Leakage device, sensor module, acquisition control module and host computer;Booster pump is connect by pipeline modules with energy-storage module, energy storage Module is connect with valve analogue body, simulation tiny leakage device and sensor module respectively by pipeline modules;Valve analogue body is logical Pipeline modules are crossed to connect with sensor module and simulation tiny leakage device respectively;Control acquisition module by cable respectively with increasing Press pump, sensor module are connected with simulation tiny leakage device;Host computer is connect by cable with control acquisition module.
Pipeline modules as described above include connecting line and isolating valve, and wherein pipeline plays the role of each module of connection, Isolating valve plays exhaust and buffer action.
Energy-storage module as described above is accumulator, whole pre- inflation before access device, for maintaining in pipeline modules Pressure balance.
Sensor module as described above includes pressure sensor 1, pressure sensor 2 and pressure sensor 3;Pressure sensing Device 1 is used to monitor the pressure of liquid in pipeline modules, and pressure sensor 2 is used to monitor the pressure of preacceleration inflation in energy-storage module, pressure Force snesor 3 is used to monitor the pressure of valve valve chamber liquid.
Simulation tiny leakage device as described above includes beaker, electronic scale and isolating valve, for weighing the liquid of valve leak The quality of body.
Control acquisition module as described above is analog input card, for controlling pressurization after the operational order for receiving host computer Liquid quality in simulation tiny leakage module is simultaneously scaled liquid bulk by the open and close of pump, the reading for reading sensor module Product.
Host computer as described above is realized using PC machine, for sending instruction to control acquisition module, is realized for pressurization Liquid quality in simulation tiny leakage module is simultaneously scaled liquid volume by the open and close of pump, the reading for reading sensor module Operation.
A kind of fluidic medium valve tiny leakage test method utilizes intracapsular pressure and body by pressure drop test method Long-pending variable quantity calculates the tiny leakage amount of valve liquid medium:
Step 1: calibrated and calculated principle and method are as follows in laboratory:
The Ideal-Gas Equation are as follows:
PV=nRT (1)
4 variables in equation: P is the pressure of perfect gas, and V is the volume of perfect gas, and n indicates the amount of gaseous matter, T Indicate the thermodynamic temperature of perfect gas;1 constant: R is ideal gas constant;In the case where n, R, T are constant, i.e., gas is former Subnumber is constant, and PV is definite value;
Step 2: accumulator is shifted to an earlier date into precharge of gas to certain set-pressure P0, and it is encapsulated in No leakage in rubber pneumatic bag;
Then
PV=P0V0 (2)
P0For the preliminary filling set-pressure of gas in air bag;
V0Volume is adjusted for gas in air bag;
Step 3: after suppressing system fluid injection pressurization, in the case where suppressing system circuit itself there is no leaking, 3 energy storage Air bag can be extruded contraction in device, and the pressure of air bag is identical with the pressure of liquid in 4 chamber of test body;Test macro is passed through into increasing Press pump is pressurized to characterization test test pressure P1If the volume contraction of air bag is at V at this time1, then
P0V0=P1V1 (3)
Step 4: after isolating valve 1 turns off, isolating valve 5 is opened, goes out 4 chamber liquid medium of test body from 5 water clock of isolating valve Come, is collected with measuring cup 6, and weighed using electronic scale 7;P2The pressure of system after a period of time is leaked for test body 4, and it is corresponding Air bag volume then will increase V2;Then
P0V0=P2V2 (4)
Step 5: the leakage rate of 4 chamber indoor liquid of test body after setting Δ V as leakage a period of time is equal to during this The swell increment of air bag volume;
Then
By above formula (5) as long as it is found that obtaining the P under accumulator set-pressure0V0Value, so that it may pass through test valve at the scene Pressure drop after suppressing obtains the leakage rate of valve, and then obtains slip;Δ V value can be obtained by collecting leakage liquid and weighing , P1And P2By being obtained in measurement in lab test body pressure, then it can calculate and obtain P0V0Value;
Step 6: because accumulator is in different preliminary filling air pressure P0Under, the corresponding pressure drop of identical leakage rate is different, need to be by big It measures examination and obtains P of the accumulator under different preliminary filling atmospheric pressure states0V0Value, and carry out the error of the test datas such as environment temperature Amendment, while determining the OK range for the test pressure test that different preliminary filling air pressures can carry out.
The beneficial effects of the utility model are:
The utility model proposes that a kind of precise measurement is small mainly for defect of the existing technology, for nuclear power plant's valve The measuring and calculation method of leakage is suppressed during stoppage in transit under the premise of valve is not dismantled, do not disintegrate, and tests online valve The tiny leakage of door obtains relevant featuring parameters, accurately analyzes valve performance state, carries out state performance to the valve after maintenance It verifies again, effectively avoids human-equation error.
Detailed description of the invention
Fig. 1 is a kind of system construction drawing of fluidic medium valve tiny leakage test device of the utility model;
Fig. 2 is that a kind of pressure of fluidic medium valve tiny leakage test device of the utility model is forced into P1State afterwards Schematic diagram;
Fig. 3 is that a kind of pressure of fluidic medium valve tiny leakage test device of the utility model is depressurized to P2State afterwards Schematic diagram.
Specific embodiment
The utility model is described further with reference to the accompanying drawings and examples.
As shown in Figure 1, a kind of fluidic medium valve tiny leakage test device, including booster pump, pipeline modules, energy storage mould Block, simulation tiny leakage device, sensor module, acquisition control module and host computer.Booster pump passes through pipeline modules and energy storage mould Block connection, energy-storage module are connect with valve analogue body, simulation tiny leakage device and sensor module respectively by pipeline modules.Valve Door analogue body is connect with sensor module and simulation tiny leakage device respectively by pipeline modules.Control acquisition module passes through cable Line is connect with booster pump, sensor module and simulation tiny leakage device respectively.Host computer passes through cable and control acquisition module Connection.
The pipeline modules include connecting line and isolating valve, and wherein pipeline plays the role of each module of connection, isolation Valve plays exhaust and buffer action.
The energy-storage module is accumulator, whole pre- inflation before access device, for maintaining the pressure in pipeline modules Balance.
The sensor module includes pressure sensor 1, pressure sensor 2 and pressure sensor 3.Pressure sensor 1 For monitoring the pressure of liquid in pipeline modules, pressure sensor 2 is used to monitor the pressure of preacceleration inflation in energy-storage module, and pressure passes Sensor 3 is used to monitor the pressure of valve valve chamber liquid.
The simulation tiny leakage device includes beaker, electronic scale and isolating valve, for weighing the liquid of valve leak Quality.
The control acquisition module is analog input card, for controlling booster pump after the operational order for receiving host computer It opens and closes, read the reading of sensor module and liquid quality in simulation tiny leakage module is scaled liquid volume.
The host computer is realized using PC machine, for sending instruction to control acquisition module, is realized for booster pump It opens and closes, read the reading of sensor module and liquid quality in simulation tiny leakage module is scaled to the behaviour of liquid volume Make.
As shown in Figures 2 and 3, a kind of fluidic medium valve tiny leakage test method is utilized by pressure drop test method Intracapsular pressure and the variable quantity of volume calculate the tiny leakage amount of valve liquid medium:
Step 1: calibrated and calculated principle and method are as follows in laboratory:
The Ideal-Gas Equation are as follows:
PV=nRT (1)
4 variables in equation: P is the pressure of perfect gas, and V is the volume of perfect gas, and n indicates the amount of gaseous matter, T Indicate the thermodynamic temperature of perfect gas;1 constant: R is ideal gas constant.In the case where n, R, T are constant, i.e., gas is former Subnumber is constant, and PV is definite value.
Step 2: accumulator is shifted to an earlier date into precharge of gas to certain set-pressure P0, and it is encapsulated in No leakage in rubber pneumatic bag.
Then
PV=P0V0 (2)
P0For the preliminary filling set-pressure of gas in air bag;
V0Volume is adjusted for gas in air bag;
Step 3: after suppressing system fluid injection pressurization, in the case where suppressing system circuit itself there is no leaking, 3 energy storage Air bag can be extruded contraction in device, and the pressure of air bag is identical with the pressure of liquid in 4 chamber of test body (i.e. valve valve chamber).It will survey Test system is pressurized to characterization test test pressure P by booster pump1If the volume contraction of air bag is at V at this time1, then
P0V0=P1V1 (3)
Step 4: after isolating valve 1 turns off, isolating valve 5 is opened, goes out 4 chamber liquid medium of test body from 5 water clock of isolating valve Come, is collected with measuring cup 6, and weighed using electronic scale 7.P2The pressure of system after a period of time is leaked for test body 4, and it is corresponding Air bag volume then will increase V2.Then
P0V0=P2V2 (4)
Step 5: the leakage rate of liquid in fluid chamber is tested after setting Δ V as leakage a period of time, should be equal to during this The swell increment of air bag volume.
Then
By above formula (5) as long as it is found that obtaining the P under accumulator set-pressure0V0Value, so that it may pass through test valve at the scene Pressure drop after suppressing obtains the leakage rate of valve, and then obtains slip.Δ V value can be obtained by collecting leakage liquid and weighing , P1And P2It can then calculate by being obtained in measurement in lab test body pressure and obtain P0V0Value.
Step 6: because accumulator is in different preliminary filling air pressure P0Under, the corresponding pressure drop of identical leakage rate is different, need to be by big It measures examination and obtains P of the accumulator under different preliminary filling atmospheric pressure states0V0Value, and carry out the error of the test datas such as environment temperature Amendment, while determining the OK range for the test pressure test that different preliminary filling air pressures can carry out.
It is explained in detail above in conjunction with implementation method of the embodiment to utility model, but utility model is not limited to Embodiment is stated, within the knowledge of a person skilled in the art, the utility model aims can also not departed from Under the premise of various changes can be made.The content being not described in detail in the utility model specification can use the prior art.

Claims (7)

1. a kind of fluidic medium valve tiny leakage test device, it is characterised in that: it includes booster pump, pipeline modules, energy storage mould Block, simulation tiny leakage device, sensor module, acquisition control module and host computer;Booster pump passes through pipeline modules and energy storage mould Block connection, energy-storage module are connect with valve analogue body, simulation tiny leakage device and sensor module respectively by pipeline modules;Valve Door analogue body is connect with sensor module and simulation tiny leakage device respectively by pipeline modules;Control acquisition module passes through cable Line is connect with booster pump, sensor module and simulation tiny leakage device respectively;Host computer passes through cable and control acquisition module Connection.
2. fluidic medium valve tiny leakage test device according to claim 1, it is characterised in that: the pipeline modules Including connecting line and isolating valve, wherein pipeline plays the role of each module of connection, and isolating valve plays exhaust and buffer action.
3. fluidic medium valve tiny leakage test device according to claim 1, it is characterised in that: the energy-storage module For accumulator, whole pre- inflation before access device, for maintaining the pressure balance in pipeline modules.
4. fluidic medium valve tiny leakage test device according to claim 1, it is characterised in that: the sensor die Block includes pressure sensor 1, pressure sensor 2 and pressure sensor 3;Pressure sensor 1 is for monitoring liquid in pipeline modules Pressure, pressure sensor 2 is used to monitor the pressure of preacceleration inflation in energy-storage module, and pressure sensor 3 is for monitoring valve valve chamber The pressure of liquid.
5. fluidic medium valve tiny leakage test device according to claim 1, it is characterised in that: the simulation is micro- to let out Leakage device includes beaker, electronic scale and isolating valve, the quality of the liquid for weighing valve leak.
6. fluidic medium valve tiny leakage test device according to claim 5, it is characterised in that: the control acquisition Module is analog input card, for controlling the open and close of booster pump after the operational order for receiving host computer, reading sensor Liquid quality in simulation tiny leakage module is simultaneously scaled liquid volume by the reading of module.
7. fluidic medium valve tiny leakage test device according to claim 6, it is characterised in that: the host computer is adopted It is realized with PC machine, for sending instruction to control acquisition module, realizes the open and close for booster pump, reads sensor die The reading of block and the operation that liquid quality in simulation tiny leakage module is scaled to liquid volume.
CN201822158974.9U 2018-12-21 2018-12-21 A kind of fluidic medium valve tiny leakage test device Active CN209247278U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201822158974.9U CN209247278U (en) 2018-12-21 2018-12-21 A kind of fluidic medium valve tiny leakage test device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201822158974.9U CN209247278U (en) 2018-12-21 2018-12-21 A kind of fluidic medium valve tiny leakage test device

Publications (1)

Publication Number Publication Date
CN209247278U true CN209247278U (en) 2019-08-13

Family

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Application Number Title Priority Date Filing Date
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Country Status (1)

Country Link
CN (1) CN209247278U (en)

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