CN220304804U - Comprehensive detection platform for gas-liquid separator - Google Patents

Abstract

The utility model provides a comprehensive detection platform for a gas-liquid separator, which comprises a detection platform, wherein the detection platform comprises a fixing device for fixing the detected gas-liquid separator and a detection device for detection; the detection device comprises a first air flow pipeline, a second air flow pipeline, a third air flow pipeline and a fourth air flow pipeline, wherein the head end of the first air flow pipeline, the second air flow pipeline, the third air flow pipeline and the fourth air flow pipeline are connected with an air source; the first gas flow pipeline is sequentially connected with a two-position three-way electromagnetic reversing valve I, a vacuum generator, a pneumatic pressure maintaining valve I, a flowmeter and a gas outlet butt joint nozzle, wherein the gas outlet butt joint nozzle is used for butt joint with a gas outlet of a detected gas-liquid separator, and the first gas flow pipeline is also connected with a vacuum pressure gauge I positioned between the pneumatic pressure maintaining valve I and the flowmeter. The utility model relates to a special comprehensive detection platform for a gas-liquid separator, which can rapidly and accurately detect multiple performance indexes of the gas-liquid separator, improves detection efficiency and detection precision, and ensures that products meet the use requirements of customers.

Description

Comprehensive detection platform for gas-liquid separator

Technical Field

The utility model relates to the field of inspection equipment, in particular to a comprehensive detection platform for a gas-liquid separator.

Background

Corrosive liquid (such as electrolyte) is commonly contained in gas discharged in the production process of the new energy battery industry, and the corrosive gas-liquid mixture cannot be directly discharged and must be subjected to gas-liquid separation treatment by a gas-liquid separator. Because the gas-liquid separator is used for separating corrosive gas-liquid mixture, the requirements on vacuum tightness, vacuum flow and vacuum pressure drop are extremely high, and in order to ensure that the performance of the product meets the use requirements, the performance indexes must be detected, and the performance indexes are detected one by manpower, so that the detection efficiency is low and the detection precision is low.

Disclosure of Invention

The utility model provides a comprehensive detection platform for a gas-liquid separator, which solves the problems that the existing gas-liquid separator detects each property one by manpower, the detection efficiency is low and the detection precision is low.

The technical scheme of the utility model is realized as follows:

the comprehensive detection platform for the gas-liquid separator comprises a detection platform, wherein the detection platform comprises a fixing device for fixing the detected gas-liquid separator and a detection device for detection; the detection device comprises a first air flow pipeline, a second air flow pipeline, a third air flow pipeline and a fourth air flow pipeline, wherein the head end of the first air flow pipeline, the second air flow pipeline, the third air flow pipeline and the fourth air flow pipeline are connected with an air source; the first gas flow pipeline is sequentially connected with a two-position three-way electromagnetic reversing valve I, a vacuum generator, a pneumatic pressure maintaining valve I, a flowmeter and a gas outlet butt joint nozzle, wherein the gas outlet butt joint nozzle is used for butt joint with a gas outlet of a detected gas-liquid separator, and the first gas flow pipeline is also connected with a vacuum pressure gauge I positioned between the pneumatic pressure maintaining valve I and the flowmeter; the second air flow pipeline is connected with a control port of the pneumatic control pressure maintaining valve I after being connected with the two-position three-way electromagnetic reversing valve II; the device further comprises a fifth air flow pipeline, one end of the fifth air flow pipeline is connected with an air inlet butt joint mouth for butt joint with an air inlet of the detected gas-liquid separator, the other end of the fifth air flow pipeline is communicated with the atmosphere, the fifth air flow pipeline is connected with an air control pressure maintaining valve II and a speed regulating valve, and the fifth air flow pipeline is also connected with a vacuum pressure gauge II positioned between the air inlet butt joint mouth and the air control pressure maintaining valve II; the third air flow pipeline is connected with a control port of the pneumatic control pressure maintaining valve II after being connected with the two-position three-way electromagnetic reversing valve III; the fourth air flow pipeline is connected with the second three-way electromagnetic reversing valve IV and then connected with an upper cylinder butt joint nozzle and a lower cylinder butt joint nozzle in parallel; the two-position three-way electromagnetic directional valve I, the two-position three-way electromagnetic directional valve II, the two-position three-way electromagnetic directional valve III and the two-position three-way electromagnetic directional valve IV are respectively and electrically connected with a vacuum source button, a vacuum switch button, a vacuum flow button and a cylinder action button.

Further, the fixing device comprises a positioning groove for positioning the detected gas-liquid separator, and a quick clamp connected to the periphery of the positioning groove for fixing the detected gas-liquid separator.

Further, the number of the quick clamp is two, and the air outlet butt joint mouth and the air inlet butt joint mouth are respectively and fixedly connected to the pressure heads of the quick clamp.

Further, the detection platform comprises a platform box body and a plurality of supporting legs fixed at the bottom of the platform box body.

Further, the novel air inlet pipe further comprises an air inlet main pipe, the air inlet main pipe is sequentially connected with a manual ball valve, a filtering and pressure reducing valve I, a manual valve I and a busbar according to the air inlet direction, the busbar is connected with the head ends of the first air flow pipeline, the second air flow pipeline and the third air flow pipeline, and the air inlet end of the fourth air flow pipeline is connected with the manual valve II and the filtering and pressure reducing valve II and then connected to the air outlet end of the manual ball valve.

Further, an air inlet end of the air inlet manifold is connected with an air compressor.

Further, the two-position three-way electromagnetic directional valve I, the two-position three-way electromagnetic directional valve II, the two-position three-way electromagnetic directional valve III and the third air receiving port of the two-position three-way electromagnetic directional valve IV are all communicated with the atmosphere.

Further, the flowmeter is an electronic flowmeter, and the vacuum pressure gauge I and the vacuum pressure gauge II are both electronic vacuum pressure gauges.

Further, the device also comprises a positive electrode wiring row and a negative electrode wiring row; the two wiring terminals of the flowmeter are respectively and electrically connected with the positive wiring row and the negative wiring row; the two wiring terminals of the vacuum pressure gauge I are respectively and electrically connected with the positive wiring row and the negative wiring row; the two wiring terminals of the vacuum pressure gauge II are respectively and electrically connected with the positive wiring row and the negative wiring row; one wiring terminal of the vacuum source button is electrically connected with the positive wiring bar, the other wiring terminal of the vacuum source button is electrically connected with one wiring terminal of the two-position three-way electromagnetic directional valve I, and the other wiring terminal of the two-position three-way electromagnetic directional valve I is electrically connected with the negative wiring bar; one wiring terminal of the vacuum switch button is electrically connected with the positive wiring bar, the other wiring terminal of the vacuum switch button is electrically connected with one wiring terminal of the two-position three-way electromagnetic reversing valve II, and the other wiring terminal of the two-position three-way electromagnetic reversing valve II is electrically connected with the negative wiring bar; one wiring end of the vacuum flow button is electrically connected with the positive wiring row, the other wiring end of the vacuum flow button is electrically connected with one wiring end of the two-position three-way electromagnetic reversing valve III, and the other wiring end of the two-position three-way electromagnetic reversing valve III is electrically connected with the negative wiring row; one wiring end of the cylinder action button is electrically connected with the positive wiring row, the other wiring end of the cylinder action button is electrically connected with one wiring end of the two-position three-way electromagnetic reversing valve IV, and the other wiring end of the two-position three-way electromagnetic reversing valve IV is electrically connected with the negative wiring row; the positive electrode wiring row and the negative electrode wiring row are respectively and electrically connected with the positive electrode output end and the negative electrode output end of the 24V switching power supply, and the input end of the 24V switching power supply is connected with a main switch with a fuse.

Further, the main switch with the fuse is connected with 220V mains supply.

The utility model has the beneficial effects that: the utility model relates to a special comprehensive detection platform for a gas-liquid separator, which can rapidly and accurately detect multiple performance indexes of the gas-liquid separator, improves detection efficiency and detection precision, and ensures that products meet the use requirements of customers.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a perspective view of another angle of the present utility model;

FIG. 3 is an enlarged view of a portion of the portion shown in FIG. 2C;

FIG. 4 is a connection diagram of the detection device;

FIG. 5 is a front view of a detected gas-liquid separator;

fig. 6 is a sectional view of fig. 5 taken along line D-D.

In the figure: a-gas-liquid separator comprehensive detection platform, 11-first air flow pipeline, 12-two-position three-way electromagnetic directional valve I, 13-vacuum generator, 14-pneumatic control pressure maintaining valve I, 15-flowmeter, 16-gas outlet butt joint mouth, 17-vacuum pressure gauge I, 18-vacuum source button, 21-second air flow pipeline, 22-two-position three-way electromagnetic directional valve II, 23-vacuum switch button, 31-third air flow pipeline, 32-two-position three-way electromagnetic directional valve III, 33-vacuum flow button, 41-fourth air flow pipeline, 42-second position three-way electromagnetic directional valve IV, 43-upper cylinder butt joint mouth, 44-lower cylinder butt joint mouth, 45-cylinder action button, 46-hand valve II, 47-filtration pressure reducing valve II, 51-fifth air flow pipeline, 52-air inlet butt joint mouth, 53-air control pressure maintaining valve II, 54-speed regulating valve, 55-vacuum pressure gauge II, 6-detection table, 61-positioning groove, 62-quick clamp, 63-platform box, 64-support leg, 71-air inlet header pipe, 72-manual ball valve, 73-filtration pressure reducing valve I, 74-hand valve I, 75-bus bar, 76-air compressor, 81-positive electrode wiring row, 82-negative electrode wiring row, 83-24V switch power supply, 84-main switch, B-air-liquid separator, 91-cylinder, 92-upper separation chamber, 93-lower liquid storage chamber, 94-separation core, 95-upper cylinder, 96-taper plug, 97-drain valve, 98-lower cylinder, 99-rod body, 911-gas-liquid separator air inlet, 912-gas-liquid separator air outlet.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, a comprehensive detection platform a of a gas-liquid separator comprises a detection platform 6, wherein the detection platform 6 comprises a fixing device for fixing the detected gas-liquid separator B and a detection device for detection; the detection device comprises a first airflow pipeline 11, a second airflow pipeline 21, a third airflow pipeline 31 and a fourth airflow pipeline 41, wherein the head end of the first airflow pipeline 11 is connected with an air source; the first air flow pipeline 11 is sequentially connected with a two-position three-way electromagnetic reversing valve I12, a vacuum generator 13, an air control pressure maintaining valve I14, a flowmeter 15 and an air outlet butt joint nozzle 16, wherein the air outlet butt joint nozzle 16 is used for butt joint with an air outlet of a detected air-liquid separator B, and the first air flow pipeline 11 is also connected with a vacuum pressure gauge I17 positioned between the air control pressure maintaining valve I14 and the flowmeter 15; the second air flow pipeline 21 is connected with a two-position three-way electromagnetic reversing valve II22 and then is connected with a control port of a pneumatic control pressure maintaining valve I14; the device further comprises a fifth air flow pipeline 51, one end of the fifth air flow pipeline 51 is connected with an air inlet butt joint mouth 52 for butt joint with an air inlet of the detected gas-liquid separator B, the other end of the fifth air flow pipeline 51 is communicated with the atmosphere, the fifth air flow pipeline 51 is connected with an air control pressure maintaining valve II53 and a speed regulating valve 54, and the fifth air flow pipeline 51 is also connected with a vacuum pressure gauge II55 positioned between the air inlet butt joint mouth 52 and the air control pressure maintaining valve II 53; the third air flow pipeline 31 is connected with a control port of the pneumatic control pressure maintaining valve II53 after being connected with the two-position three-way electromagnetic directional valve III 32; the fourth air flow pipeline 41 is connected with a second three-way electromagnetic directional valve IV42 and then connected with an upper cylinder butt joint nozzle 43 and a lower cylinder butt joint nozzle 44 in parallel; the two-position three-way electromagnetic directional valve I12, the two-position three-way electromagnetic directional valve II22, the two-position three-way electromagnetic directional valve III32 and the two-position three-way electromagnetic directional valve IV42 are respectively and electrically connected with a vacuum source button 18, a vacuum switch button 23, a vacuum flow button 33 and a cylinder action button 45.

The fixing device comprises a positioning groove 61 for positioning the detected gas-liquid separator B and a quick clamp 62 connected to the periphery of the positioning groove for fixing the detected gas-liquid separator B. The number of the quick tongs 62 is two, and the air outlet butt joint mouth and the air inlet butt joint mouth are respectively and fixedly connected to the pressure heads of the quick tongs.

The detection table 6 comprises a platform box 63 and a plurality of support legs 64 fixed at the bottom of the platform box 63.

As a further embodiment, the air intake system further comprises an air intake manifold 71, wherein the air intake manifold 71 is sequentially connected with a manual ball valve 72, a filter pressure reducing valve I73, a manual valve I74 and a bus bar 75 according to the air intake direction, the bus bar 75 is connected with the head ends of the first air flow pipeline 11, the second air flow pipeline 21 and the third air flow pipeline 31, and the air intake end of the fourth air flow pipeline 41 is connected with a manual valve II46 and a filter pressure reducing valve II47 and then connected to the air outlet end of the manual ball valve 72. The intake end of the intake manifold 71 is connected to an air compressor 76.

And the third air inlets of the two-position three-way electromagnetic directional valve I12, the two-position three-way electromagnetic directional valve II22, the two-position three-way electromagnetic directional valve III32 and the two-position three-way electromagnetic directional valve IV42 are all communicated with the atmosphere.

The flowmeter 15 is an electronic flowmeter, and the vacuum pressure gauge I17 and the vacuum pressure gauge II65 are both electronic vacuum pressure gauges.

As a further embodiment, positive electrode tab row 81 and negative electrode tab row 82 are also included; the two terminals of the flowmeter 15 are respectively electrically connected with the positive electrode wiring row 81 and the negative electrode wiring row 82; the two wiring terminals of the vacuum pressure gauge I17 are respectively and electrically connected with the positive electrode wiring row 81 and the negative electrode wiring row 82; the two wiring terminals of the vacuum pressure gauge II65 are respectively electrically connected with the positive electrode wiring row 81 and the negative electrode wiring row 82; one terminal of the vacuum source button 18 is electrically connected with the positive electrode wiring row 81, the other terminal of the vacuum source button 18 is electrically connected with one terminal of the two-position three-way electromagnetic directional valve I12, and the other terminal of the two-position three-way electromagnetic directional valve I12 is electrically connected with the negative electrode wiring row 82; one terminal of the vacuum switch button 23 is electrically connected with the positive electrode wiring row 81, the other terminal of the vacuum switch button 81 is electrically connected with one terminal of the two-position three-way electromagnetic directional valve II22, and the other terminal of the two-position three-way electromagnetic directional valve II22 is electrically connected with the negative electrode wiring row 82; one terminal of the vacuum flow button 33 is electrically connected with the positive electrode wiring row 81, the other terminal of the vacuum flow button 33 is electrically connected with one terminal of the two-position three-way electromagnetic directional valve III32, and the other terminal of the two-position three-way electromagnetic directional valve III32 is electrically connected with the negative electrode wiring row 82; one terminal of the cylinder action button 45 is electrically connected with the positive electrode wiring row 81, the other terminal of the cylinder action button 45 is electrically connected with one terminal of the two-position three-way electromagnetic directional valve IV42, and the other terminal of the two-position three-way electromagnetic directional valve IV42 is electrically connected with the negative electrode wiring row 81; the positive electrode wiring row 81 and the negative electrode wiring row 82 are respectively electrically connected with a positive electrode output end and a negative electrode output end of the 24V switching power supply 83, and an input end of the 24V switching power supply 83 is connected with a main switch 84 with a fuse. The main fused switch 84 is connected to 220V mains.

The working principle of the utility model is as follows:

before explaining the working principle, the structure of the detected gas-liquid separator B is first to be solved, as shown in fig. 5 and 6, the detected gas-liquid separator B includes a cylinder 91, the cylinder 91 is divided into an upper separation chamber 92 and a lower liquid storage chamber 93, the upper separation chamber 92 includes a separation core 94, the upper separation chamber 92 and the lower liquid storage chamber 93 are communicated and blocked by an upper cylinder 95 driving a conical plug 96 at the lower end of a rod body 99 to move up and down, the lower part of the cylinder 91 includes a liquid discharge valve 97 for controlling liquid discharge, and the liquid discharge valve 97 is controlled to be opened and closed by a lower cylinder 98.

When the gas-liquid separator B is used, the upper air cylinder 95 drives the taper plug 96 to be at the highest position, the upper separation chamber 92 is communicated with the lower liquid storage chamber 93, the lower air cylinder 98 controls the liquid discharge valve 97 to be closed, corrosive gas-liquid mixture in the new energy battery industry enters from the gas-liquid separator air inlet 911, gas and liquid are separated in the upper separation chamber 92, separated gas is discharged from the gas-liquid separator air outlet 912, separated liquid flows into the lower liquid storage chamber 93 from the upper separation chamber 92 and is accumulated in the lower liquid storage chamber 93, when liquid discharge is needed, the upper air cylinder 95 drives the taper plug 96 to move downwards, the upper separation chamber 92 and the lower liquid storage chamber 93 are blocked, the upper separation chamber 92 continues to work, the liquid discharge valve 97 is opened through the lower air cylinder 98, so that the liquid in the lower liquid storage chamber 93 is discharged, the gas-liquid separation process is not required to be interrupted, after the liquid discharge is completed, the lower air cylinder is controlled to be closed, the upper air cylinder 95 is controlled to drive the taper plug 96 to move upwards, and the upper separation chamber 92 is communicated with the lower liquid storage chamber 93, and the gas-liquid separation work is continued.

When the liquid discharge valve is required to be closed during detection, the upper separation chamber is communicated with the lower liquid storage chamber, the sealing performance of the whole upper separation chamber and the whole lower liquid storage chamber and the cone plug move downwards, and when the upper separation chamber is blocked by the lower liquid storage chamber, the sealing performance and the flow of the upper separation chamber meet the requirements.

1. Opening a manual ball valve, adjusting the pressure of a filtering reducing valve I and a filtering reducing valve II, opening the hand valve I and the hand valve II, opening a master switch with a fuse, installing a detected gas-liquid separator in a positioning groove, fixing the detected gas-liquid separator through a quick clamp, simultaneously enabling an air outlet butt joint mouth and an air inlet butt joint mouth to be respectively connected with an air outlet of the gas-liquid separator and an air inlet of the gas-liquid separator, enabling an upper cylinder butt joint mouth to be connected with an air port of an upper cylinder, enabling the upper cylinder to drive a cone plug to move upwards, enabling an upper separation chamber to be communicated with a lower liquid storage chamber, enabling a lower cylinder butt joint mouth to be connected with an air port of a lower cylinder, and enabling the lower cylinder to drive a liquid discharge valve to be closed;

2. closing a vacuum switch button and a vacuum source button, opening a pneumatic control pressure maintaining valve I, starting vacuumizing the gas-liquid separator by a vacuum generator, disconnecting the vacuum switch button and the vacuum source button when the vacuum degree reaches above-92 KPa, closing the pneumatic control pressure maintaining valve I, and performing pressure resistance test for 1 minute to see whether the leakage quantity meets the requirement;

3. closing a vacuum switch button, opening a vacuum source button, opening an air suction port of a vacuum generator to be in air, opening the vacuum source button after vacuum breaking and pressure relief, closing the vacuum source button again, vacuumizing the gas-liquid separator again, opening the vacuum switch button and the vacuum source button when the vacuum degree reaches-80 to-85 KPa, closing a pneumatic control pressure maintaining valve I, performing an integral vacuum airtight pressure maintaining test, maintaining the pressure for 3.5 minutes, checking whether the leakage quantity meets the requirement or not, simultaneously observing the pressure difference between a vacuum pressure gauge I and a vacuum pressure gauge II at two ends of an air inlet and an air outlet, and recording the pressure drop;

4. closing a vacuum switch button, opening a vacuum source button, opening the vacuum switch button after vacuum breaking and pressure relief, respectively butting an upper cylinder butting nozzle and a lower cylinder butting nozzle with two interfaces of the upper cylinder and the lower cylinder, repeatedly closing and opening a cylinder action button, simultaneously acting the upper cylinder and the lower cylinder, and detecting whether the reciprocating action of the cylinders is normal;

5. closing an air cylinder action button, wherein an upper air cylinder drives a conical plug to move downwards, an upper separation chamber and a lower liquid storage chamber are blocked, a lower air cylinder opens a liquid discharge valve, the lower liquid storage chamber is communicated with the atmosphere, a vacuum switch button and a vacuum source button are closed, a pneumatic control pressure maintaining valve I is opened, a vacuum generator starts vacuumizing the gas-liquid separator, when the vacuum degree reaches-80 to-85 KPa, the vacuum switch button and the vacuum source button are disconnected, the pneumatic control pressure maintaining valve I is closed, a vacuum airtight pressure maintaining test of the upper separation chamber is performed, the pressure maintaining is performed for 3.5 minutes, and whether the leakage quantity meets the requirement is judged;

6. closing a vacuum switch button, opening a vacuum source button, breaking vacuum and releasing pressure, then closing a vacuum flow button, the vacuum switch button and the vacuum source button, opening a pneumatic control pressure maintaining valve II, connecting an air inlet of a gas-liquid separator with the atmosphere through a speed regulating valve, regulating the speed regulating valve, controlling the numerical value of a vacuum pressure gauge II to be-82+/-0.2 KPa, and testing whether the vacuum flow meets the requirement.

The utility model relates to a special comprehensive detection platform for a gas-liquid separator, which can rapidly and accurately detect multiple performance indexes of the gas-liquid separator, improves detection efficiency and detection precision, and ensures that products meet the use requirements of customers.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. Comprehensive detection platform for gas-liquid separator, and is characterized in that:

the device comprises a detection table, wherein the detection table comprises a fixing device for fixing a detected gas-liquid separator and a detection device for detection;

the detection device comprises a first air flow pipeline, a second air flow pipeline, a third air flow pipeline and a fourth air flow pipeline, wherein the head end of the first air flow pipeline, the second air flow pipeline, the third air flow pipeline and the fourth air flow pipeline are connected with an air source;

the first gas flow pipeline is sequentially connected with a two-position three-way electromagnetic reversing valve I, a vacuum generator, a pneumatic pressure maintaining valve I, a flowmeter and a gas outlet butt joint nozzle, wherein the gas outlet butt joint nozzle is used for butt joint with a gas outlet of a detected gas-liquid separator, and the first gas flow pipeline is also connected with a vacuum pressure gauge I positioned between the pneumatic pressure maintaining valve I and the flowmeter;

the second air flow pipeline is connected with a control port of the pneumatic control pressure maintaining valve I after being connected with the two-position three-way electromagnetic reversing valve II;

the device further comprises a fifth air flow pipeline, one end of the fifth air flow pipeline is connected with an air inlet butt joint mouth for butt joint with an air inlet of the detected gas-liquid separator, the other end of the fifth air flow pipeline is communicated with the atmosphere, the fifth air flow pipeline is connected with an air control pressure maintaining valve II and a speed regulating valve, and the fifth air flow pipeline is also connected with a vacuum pressure gauge II positioned between the air inlet butt joint mouth and the air control pressure maintaining valve II;

the third air flow pipeline is connected with a control port of the pneumatic control pressure maintaining valve II after being connected with the two-position three-way electromagnetic reversing valve III;

the fourth air flow pipeline is connected with the second three-way electromagnetic reversing valve IV and then connected with an upper cylinder butt joint nozzle and a lower cylinder butt joint nozzle in parallel;

the two-position three-way electromagnetic directional valve I, the two-position three-way electromagnetic directional valve II, the two-position three-way electromagnetic directional valve III and the two-position three-way electromagnetic directional valve IV are respectively and electrically connected with a vacuum source button, a vacuum switch button, a vacuum flow button and a cylinder action button.

2. The integrated gas-liquid separator detection platform of claim 1, wherein: the fixing device comprises a positioning groove for positioning the detected gas-liquid separator and a quick clamp connected to the peripheral side of the positioning groove for fixing the detected gas-liquid separator.

3. The integrated gas-liquid separator detection platform of claim 2, wherein: the two quick clamps are provided, and the air outlet butt joint mouth and the air inlet butt joint mouth are respectively and fixedly connected to the pressure heads of the quick clamps.

4. The integrated gas-liquid separator detection platform of claim 3, wherein: the detection platform comprises a platform box body and a plurality of supporting legs fixed at the bottom of the platform box body.

5. The integrated gas-liquid separator detection platform of claim 1, wherein: the device comprises a first air flow pipeline, a second air flow pipeline, a third air flow pipeline, a fourth air flow pipeline, a hand valve II and a filter pressure reducing valve II, wherein the hand valve I, the hand valve I and a busbar are sequentially connected to the air inlet manifold according to the air inlet direction, the busbar is connected with the head ends of the first air flow pipeline, the second air flow pipeline and the third air flow pipeline, and the air inlet end of the fourth air flow pipeline is connected with the hand valve II and the filter pressure reducing valve II and then connected to the air outlet end of the hand valve.

6. The integrated gas-liquid separator detection platform of claim 5, wherein: and the air inlet end of the air inlet main pipe is connected with an air compressor.

7. The integrated gas-liquid separator detection platform of claim 1, wherein: the two-position three-way electromagnetic directional valve I, the two-position three-way electromagnetic directional valve II, the two-position three-way electromagnetic directional valve III and the third air receiving port of the two-position three-way electromagnetic directional valve IV are all communicated with the atmosphere.

8. The integrated gas-liquid separator detection platform of claim 1, wherein: the flowmeter is an electronic flowmeter, and the vacuum pressure gauge I and the vacuum pressure gauge II are both electronic vacuum pressure gauges.

9. The integrated gas-liquid separator detection platform of claim 8, wherein:

the device also comprises an anode wiring row and a cathode wiring row;

the two wiring terminals of the flowmeter are respectively and electrically connected with the positive wiring row and the negative wiring row;

the two wiring terminals of the vacuum pressure gauge I are respectively and electrically connected with the positive wiring row and the negative wiring row;

the two wiring terminals of the vacuum pressure gauge II are respectively and electrically connected with the positive wiring row and the negative wiring row;

one wiring terminal of the vacuum source button is electrically connected with the positive wiring bar, the other wiring terminal of the vacuum source button is electrically connected with one wiring terminal of the two-position three-way electromagnetic directional valve I, and the other wiring terminal of the two-position three-way electromagnetic directional valve I is electrically connected with the negative wiring bar;

one wiring terminal of the vacuum switch button is electrically connected with the positive wiring bar, the other wiring terminal of the vacuum switch button is electrically connected with one wiring terminal of the two-position three-way electromagnetic reversing valve II, and the other wiring terminal of the two-position three-way electromagnetic reversing valve II is electrically connected with the negative wiring bar;

one wiring end of the vacuum flow button is electrically connected with the positive wiring row, the other wiring end of the vacuum flow button is electrically connected with one wiring end of the two-position three-way electromagnetic reversing valve III, and the other wiring end of the two-position three-way electromagnetic reversing valve III is electrically connected with the negative wiring row;

one wiring end of the cylinder action button is electrically connected with the positive wiring row, the other wiring end of the cylinder action button is electrically connected with one wiring end of the two-position three-way electromagnetic reversing valve IV, and the other wiring end of the two-position three-way electromagnetic reversing valve IV is electrically connected with the negative wiring row;

the positive electrode wiring row and the negative electrode wiring row are respectively and electrically connected with the positive electrode output end and the negative electrode output end of the 24V switching power supply, and the input end of the 24V switching power supply is connected with a main switch with a fuse.

10. The integrated gas-liquid separator detection platform of claim 9, wherein: the main switch with the fuse is connected with 220V mains supply.