CN212513507U - Pressure sensor leakage testing device - Google Patents

Abstract

The utility model discloses a pressure sensor leakage testing device, which comprises a rack, a helium mass spectrometer and a helium source; a plurality of sensor testing stations are arranged on the mounting table surface of the rack, and an electric control cabinet and a vacuum pump cabinet are arranged below the mounting table surface; the sensor testing station is respectively connected with the helium mass spectrometer, the helium source and the vacuum pump cabinet through pipelines; the electric control cabinet is electrically connected with the sensor testing station, the vacuum pump cabinet, the helium mass spectrometer and the helium source. The pressure sensor to be detected is placed on the sensor detection station, the helium source injects helium into the sensor detection station, the vacuum pump cabinet vacuumizes the sensor detection station, so that pressure difference is formed on two sides of the pressure sensor to be detected, the helium mass spectrometer is used for detecting whether helium exists on the vacuumized side of the pressure sensor to be detected, and if helium exists, the situation that the pressure sensor to be detected leaks is indicated. The detection stations of the sensors are controlled by the electric control cabinet to detect at the same time, so that the detection efficiency of a factory is improved.

Description

Pressure sensor leakage testing device

Technical Field

The utility model relates to a sensor technical field, more specifically the utility model relates to a pressure sensor leak test device that says so.

Background

The pressure sensor is the most common sensor in industrial practice and is widely applied to a plurality of industries such as automobiles, transportation, intelligent buildings, mechanical equipment, automatic production control and the like. During the packaging process of the pressure sensor, the sealing performance of the packaging needs to be confirmed so as to prevent the pressure medium to be measured from leaking through the sensor body during the application process. During leakage test, the pressure medium interface of the sensor is mounted on the measurement interface of a standard helium mass spectrometer through a sealing thread or a sealing ring, so that a space sealed to the outside is formed between the pressure medium interface of the sensor and the measurement interface of the helium mass spectrometer. A vacuum pump arranged in the helium mass spectrometer can produce negative pressure through a measuring interface, so that the sealed space to the outside is in a negative pressure state. During the test, helium was "sprayed" around the outside of the sensor. If the sensor itself is not sealed, external helium gas can be drawn into the helium mass spectrometer due to the negative pressure conditions. If the helium mass spectrometer detects the helium element, the sensor is proved to be leaked; on the contrary, the sensor package proved to be good and no leakage occurred.

Along with the gradual improvement of the human cost, more and more enterprises begin to pay attention to the improvement of the production efficiency. In the current pressure sensor leakage test, a standard helium mass spectrometer is generally used, and the tested product is manually loaded to realize one-by-one test of single products. The single piece detection method has long product loading time and long testing time, so that the efficiency is low, and a leakage testing station becomes a bottleneck station in the whole pressure sensor manufacturing process. Meanwhile, a standard helium mass spectrometer manufacturer does not aim at the leakage test of the pressure sensor, develops a special batch automatic detection device or equipment with higher efficiency, and only uses the device or equipment for single-room detection.

Therefore, how to improve the efficiency of the pressure sensor leak test and realize batch test is an urgent problem to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a pressure sensor leak testing device, including rack, helium mass spectrometer and helium source; a plurality of sensor testing stations are arranged on the mounting table surface of the rack, and an electric control cabinet and a vacuum pump cabinet are arranged below the mounting table surface; the sensor testing station is respectively connected with the helium mass spectrometer, the helium source and the vacuum pump cabinet through pipelines; the electric control cabinet is electrically connected with the sensor testing station, the vacuum pump cabinet, the helium mass spectrometer and the helium source. The pressure sensor to be detected is placed on the sensor detection station, helium is injected into one side of the pressure sensor to be detected in the sensor detection station by the helium source, vacuumizing operation is carried out on the other side by the vacuum pump cabinet, so that pressure difference is formed on two sides of the pressure sensor to be detected, the helium mass spectrometer detects whether helium exists on the vacuumizing side of the pressure sensor to be detected, if yes, the condition that the pressure sensor to be detected has leakage is indicated, and if not, the performance of the pressure sensor to be detected is good. A plurality of sensor detection stations are simultaneously controlled through the electric control cabinet to detect a plurality of groups of pressure sensors to be detected, so that the detection efficiency of a factory is improved, and the batch production of the pressure sensors is facilitated.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a pressure sensor leak testing apparatus comprising: the system comprises a rack, a helium mass spectrometer and a helium source; a plurality of sensor testing stations are arranged on the mounting table surface of the rack, and an electric control cabinet and a vacuum pump cabinet are arranged below the mounting table surface; the sensor testing station is respectively connected with the helium mass spectrometer, the helium source and the vacuum pump cabinet through pipelines; the electric control cabinet is electrically connected with the sensor testing station, the vacuum pump cabinet, the helium mass spectrometer and the helium source.

Preferably, the electronic control cabinet comprises a control module, and the control module is electrically connected with the sensor testing station, the vacuum pump cabinet and the helium source.

Preferably, the sensor testing station comprises a gas injection chamber, a gas detection chamber, a cylinder control valve, a detection chamber control valve and a sealing gasket; the gas injection chamber is electrically connected with the control module through the cylinder and the cylinder control valve in sequence; the cylinder control valve and the detection chamber control valve are electrically connected with the control module; the gas detection chamber is connected with the vacuum pump cabinet and the helium mass spectrometer through pipelines by the detection chamber control valve; the gas injection chamber is driven by the cylinder to be matched and sealed with the gas detection chamber; the pressure sensor to be detected is placed at the joint of the gas injection chamber and the gas detection chamber in a matched mode, and the joint of the gas detection chamber where the pressure sensor to be detected is placed is provided with the sealing gasket.

Preferably, the helium source comprises a helium bottle, an inflation valve and a digital pressure gauge; the helium bottle is connected with the gas injection chamber through the inflation valve pipeline; the inflation valve is electrically connected with the control module; the digital pressure gauge is arranged between the helium bottle and the inflation valve.

Preferably, the vacuum pump cabinet comprises a vacuum pump, a pre-pumping valve and a digital vacuum meter; the vacuum pump is connected with the detection chamber control valve through the pre-pumping valve pipeline; the pre-pumping valve is electrically connected with the control module; the digital vacuum meter is installed between the vacuum pump and the pre-pumping valve.

Preferably, the helium mass spectrometer is also provided with a leak detection valve; the helium mass spectrometer is connected with the detection chamber control valve through the leak detection valve pipeline; the leak detection valve is electrically connected with the control module.

Preferably, the device further comprises a compressed air source, wherein the compressed air source comprises a compressed air bottle and a compressed air valve, and the compressed air bottle is connected with the gas detection chamber through a compressed air valve pipeline; the compressed air valve is electrically connected with the control module. After the test is finished, all the electromagnetic valves are closed, the compressed air valve is opened, helium possibly remaining in the gas detection chamber is removed, and the compressed air valve is closed after the test is finished, so that the test accuracy is guaranteed.

Preferably, the sensor testing stations are divided into a first testing area and a second testing area, and the first testing area and the second testing area alternately perform testing work. After the first test area is tested once, the same operation is carried out on the second test area, the leakage test of the second test area is carried out, the tested pressure sensor of the first test area is unloaded and reloaded while the test of the second test area is carried out, the leakage test of the first test area and the second test area is carried out by repeated circulating alternate operation, the standby time of the helium mass spectrometer is shortened, and the detection efficiency is improved.

Preferably, the cylinder control valve, the detection chamber control valve, the pre-pumping valve, the leak detection valve, the inflation valve and the compressed air valve are all solenoid valves.

According to the technical scheme, compared with the prior art, the utility model discloses a pressure sensor leakage testing device is provided with a plurality of sensor detection stations on the installation table surface of the device rack, divide into test first district and test second district, carry out the alternative detection, each group of sensor detection stations is provided with gas injection chamber and gas detection chamber, the sensor to be detected is placed between gas injection chamber and gas detection chamber, gas injection chamber and gas detection chamber lock under the effect of cylinder, form sealed mould, wherein the cylinder is controlled by the cylinder control valve that the control module electricity is connected in the automatically controlled rack to start; a vacuum pump cabinet and a compressed air source are arranged below the mounting table board, a vacuum pump in the vacuum pump cabinet is connected with a gas detection chamber through a pre-pumping valve, and the pre-pumping valve is controlled by a control module; a compressed air bottle of a compressed air source is connected with the gas detection chamber through a compressed air valve, and the compressed air valve is controlled by the control module; the gas injection chamber is connected with a helium source, a helium bottle is connected with the gas injection chamber through an inflation valve, and the inflation valve is controlled by the control module; the helium mass spectrometer is coupled to detect the presence of helium in the gas detection chamber. Through the point control of the electric control cabinet and the alternative detection work of the detection stations of the plurality of sensors, the working efficiency of the leakage detection of the pressure sensor is greatly improved, and the bottleneck of the batch production of the pressure sensor is favorably overcome.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic view of a connection structure of a pressure sensor leak testing device according to the present invention;

fig. 2 is a schematic circuit diagram of the pressure sensor leak testing device provided by the present invention.

The device comprises a 1-helium mass spectrometer, a 2-helium bottle, a 311-gas injection chamber, a 312-gas detection chamber, a 313-sealing gasket, a 314-cylinder, a 4-vacuum pump, a 5-compressed air bottle, a 6-pressure sensor to be detected, a 7-digital vacuum gauge and an 8-digital pressure gauge.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment of the utility model discloses pressure sensor leak testing device, include: the system comprises a rack, a helium mass spectrometer 1 and a helium source; a plurality of sensor testing stations are arranged on the mounting table surface of the rack, and an electric control cabinet and a vacuum pump cabinet are arranged below the mounting table surface;

the sensor testing station is respectively connected with the helium mass spectrometer 1, a helium source and a vacuum pump cabinet through pipelines; the electric control cabinet is electrically connected with the sensor testing station, the vacuum pump cabinet, the helium mass spectrometer 1 and the helium source.

In order to further optimize the technical scheme, the electronic control cabinet comprises a control module, and the control module is electrically connected with the sensor testing station, the vacuum pump cabinet and the helium source.

In order to further optimize the technical scheme, the sensor testing station comprises a gas injection chamber 311, a gas detection chamber 312, a gas cylinder 314, a gas cylinder control valve, a detection chamber control valve and a sealing gasket 313; the gas injection chamber 311 is electrically connected with the control module through the cylinder 314 and the cylinder control valve in sequence; the cylinder control valve and the detection chamber control valve are electrically connected with the control module; the cylinder control valves are used for respectively controlling the motion of each cylinder 314 and can also be matched with position switches to realize closed-loop control;

the gas detection chamber 312 is connected with a vacuum pump cabinet and a helium mass spectrometer 1 through pipelines by a detection chamber control valve;

the gas injection chamber 311 is driven by the cylinder 314 to be matched with the gas detection chamber 312 for sealing; the pressure sensor 6 to be detected is placed at the joint of the gas injection chamber 311 and the gas detection chamber 312, and a sealing gasket 313 is arranged at the interface of the gas detection chamber 312 where the pressure sensor 6 to be detected is placed. The sealing washer 313 makes the gas detection chamber 312 and the gas injection chamber 311 form an independent area after being matched, namely, the external space of the pressure sensor 6 to be detected is separated into two areas, the electric interface part of the two areas belongs to the area of the gas injection chamber 311, and the pressure interface part of the two areas belongs to the area of the gas detection chamber 312. The electrical interface end of the pressure sensor 6 to be detected is not sealed with the outside, and helium in the helium tank 2 can enter the inside of the pressure sensor 6 to be detected through the gas injection chamber 311; the pressure interface end of the pressure sensor 6 to be detected contacts the gas detection chamber 312, which is equivalent to a pressure medium cavity in an application environment, but helium gas cannot leak to the gas detection chamber 312 through the pressure interface due to the sealing structure in the pressure sensor.

In order to further optimize the technical scheme, the helium source comprises a helium bottle 2, an inflation valve and a digital pressure gauge 8; the helium bottle 2 is connected with the gas injection chamber 311 through a charging valve pipeline; the inflation valve is electrically connected with the control module; and the digital pressure gauge 8 is arranged between the helium bottle 2 and the inflation valve. The gas charging valves are used for specifically controlling the connection of the helium tank with each gas injection chamber 311, and the gas charging valves and the digital pressure gauge 8 are used for controlling and monitoring the output helium pressure of the helium tank 2, so that the consistency of measurement is ensured.

In order to further optimize the technical scheme, the helium mass spectrometer 1 is also provided with a leak detection valve; the helium mass spectrometer 1 is connected with a detection chamber control valve through a leak detection valve pipeline; the leak detection valve is electrically connected with the control module. The helium mass spectrometer 1 communicates with each gas detection chamber 312 through a solenoid valve, and detects the presence or absence of a helium component therein.

In order to further optimize the technical scheme, the vacuum pump cabinet comprises a vacuum pump 4, a pre-pumping valve and a digital vacuum meter 7; the vacuum pump 4 is connected with a control valve of the detection chamber through a pre-pumping valve pipeline; the pre-pumping valve is electrically connected with the control module; a digital vacuum gauge 7 is installed between the vacuum pump 4 and the pre-pump valve. The vacuum pump 4 is used for pumping air in the pipeline to provide a negative pressure environment close to vacuum for each gas detection chamber 312. The digital vacuum meter 7 is matched with the vacuum pump 4 and used for monitoring the negative pressure state of the pipeline, when the negative pressure reaches a fixed value, the pre-pumping valve is closed, and the leakage detection valve is opened.

In order to further optimize the above technical solution, the gas detection chamber 312 is connected with the vacuum pump 4 or the helium mass spectrometer through a detection chamber control valve respectively. When the pre-pumping valve is opened, the gas detection chamber 312 is connected with the vacuum pump 4; when the leak detection valve is open, the gas detection chamber 312 is connected to the helium mass spectrometer 1.

In order to further optimize the technical scheme, the device further comprises a compressed air source, wherein the compressed air source comprises a compressed air bottle 5 and a compressed air valve, and the compressed air bottle 5 is connected with the gas detection chamber 312 through a compressed air valve pipeline; the compressed air valve is electrically connected with the control module.

In order to further optimize the technical scheme, the sensor testing stations are divided into a first testing area and a second testing area, and the first testing area and the second testing area alternately perform testing work.

The operation method of the pressure sensor leakage testing device comprises the following specific processes:

s1: dividing a sensor testing station on a testing table into a first testing area and a second testing area, electrifying the equipment, and keeping all electromagnetic valves closed; firstly, selecting a test area for detection;

s2: the gas detection chamber 312 of each sensor test station is fixed on the test table board, during testing, the pressure interface of the pressure sensor 6 to be tested faces downwards, the electrical interface faces upwards, the pressure interface is placed on the sealing ring 313 of the gas detection chamber 312, and the control module arranged in the electric control cabinet and fixed on the left side of the lower part of the test table board controls the cylinder 314 through the cylinder control valve and drives the gas injection chamber 311 to move downwards to be matched with the gas detection chamber 312;

s3: the control module controls the charging valve to be opened, and helium is injected into the gas injection chamber 311 at the same time;

s4: the control module controls the pre-pumping valve to be opened and controls the detection chamber control valve to be opened simultaneously, and the vacuum pump 4 arranged in the vacuum pump cabinet and fixed on the right side of the lower part of the test table top is used for pumping air out of the gas detection chamber 312, so that the gas detection chamber 312 is in a vacuum negative pressure state;

s5: the control module controls the pre-pumping valve to be closed, controls the leak detection valve to be opened, and then detects whether helium exists through the helium mass spectrometer 1; if the helium element is detected, indicating that helium exists in the gas detection chamber 312, and further indicating that a leakage point exists in the internal package of the pressure sensor 6 to be detected; otherwise, the packaging is good and no leakage is caused;

s6: after the test is finished, all the electromagnetic valves are closed, the compressed air valve is opened, helium possibly remaining in the gas detection chamber 312 is removed, and the compressed air valve is closed after the test is finished;

s7: selecting the test two area to repeat the operations from S2 to S6, and the test one area and the test two area are operated alternately.

In order to further optimize the technical scheme, when the leakage rate is high in batch measurement of the pressure sensor 6 to be detected, a test program is adjusted, firstly, negative pressure is sequentially pumped to the gas detection chamber 312 of the sensor test station, and then, the helium mass spectrometer 1 is used for sequentially detecting the leakage of the sensor test station, so that the sensor test station with a poor detection result is accurately identified.

Examples

The device is provided with six groups of sensor testing stations which are divided into a first testing area and a second testing area, wherein the first area cylinder control valve comprises cylinder control valves 15-17, the inflation valve comprises inflation valves 21-23, the compressed air valve comprises compressed air valves 27-29, and the detection chamber control valve comprises detection chamber control valves 33-35; the two-zone cylinder control valves comprise cylinder control valves 18-20, the charge valves comprise charge valves 24-26, the compressed air valves comprise compressed air valves 30-32, and the detection chamber control valves comprise detection chamber control valves 36-38; the pre-pumping valves comprise pre-pumping valves 41-42; the leakage detection valve comprises leakage detection valves 11-12; all the control valves are electromagnetic valves, all the control valves are connected with and controlled by a control module, and the control module adopts a programmable controller FP 7.

A digital pressure gauge 8 is arranged between the gas charging valves 21-26 of the six groups of sensor testing stations and a main line connected with the helium tank; a digital vacuum meter 7 is arranged between the general lines connecting the vacuum pump 4 and the pre-pumping valves 41-42.

The vacuum pump 4 is divided into two paths through the electromagnetic valve 9 and the digital vacuum meter 7, and is respectively connected with the detection chamber control valves 33 to 35 and the leak detection valve 12 of the first testing area through the pre-pumping valve 41, and is connected with the detection chamber control valves 36 to 38 and the leak detection valve 11 of the second testing area through the pre-pumping valve 42; the leak detection valve 11 and the leak detection valve 12 are both connected with the helium mass spectrometer 1. The electromagnetic valve 43 is the master control switch of the negative pressure pumping pipeline of the vacuum pump 4 and is normally kept open during the test process.

The cylinder control valves 15-20 are respectively connected with a cylinder 314, are all connected with a control module and are controlled by the control module, and the cylinder 314 drives the gas injection chamber 311 to move downwards so as to realize die assembly with the gas detection chamber 312; the inflation valves 21-26 are respectively connected between the helium tank 2 and each gas injection chamber 311; the compressed air valves 27 to 32 are respectively connected between the compressed air tank 6 and each gas detection chamber 312; one end of each of the detection chamber control valves 33-35 is respectively connected with the three gas detection chambers 312 of the first test area, and the other end is connected with the pre-pumping valve 41 and the leak detection valve 12; compressed air valves 36-38 are connected at one end to the three gas detection chambers 312 of test zone two, respectively, and at the other end to pre-pump valve 42 and leak detection valve 11.

The utility model discloses a pressure sensor is leak test in batches, has solved the low problem of pressure sensor leak test efficiency among the batch production. Compared with the original manual testing mode, the mode of automatically loading the tested workpiece and automatically testing is adopted, so that the testing time is greatly shortened, and the leakage test is not a bottleneck station in the manufacturing process any more. Meanwhile, the pressure monitoring function, the vacuum monitoring function and the residual helium gas removing function are integrated, and the misjudgment condition is effectively prevented.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. A pressure sensor leak test apparatus, comprising: the system comprises a rack, a helium mass spectrometer (1) and a helium source; a plurality of sensor testing stations are arranged on the mounting table surface of the rack, and an electric control cabinet and a vacuum pump cabinet are arranged below the mounting table surface;

the sensor testing station is respectively connected with the helium mass spectrometer (1), the helium source and the vacuum pump cabinet through pipelines; the electric control cabinet is electrically connected with the sensor testing station, the vacuum pump cabinet, the helium mass spectrometer (1) and the helium source.

2. The pressure sensor leak test apparatus of claim 1, wherein the electronic control cabinet includes a control module that electrically connects the sensor test station, the vacuum pump cabinet, and the helium source.

3. A pressure sensor leak test apparatus according to claim 2, wherein the sensor test station comprises a gas injection chamber (311), a gas detection chamber (312), a gas cylinder (314), a gas cylinder control valve, a detection chamber control valve and a sealing gasket (313); the gas injection chamber (311) is electrically connected with the control module sequentially through the cylinder (314) and the cylinder control valve; the cylinder control valve and the detection chamber control valve are electrically connected with the control module;

the gas detection chamber (312) is connected with the vacuum pump cabinet and the helium mass spectrometer (1) through pipelines of the detection chamber control valve;

the gas injection chamber (311) is driven by the cylinder (314) to be matched and sealed with the gas detection chamber (312); the pressure sensor (6) to be detected is placed at the joint of the gas injection chamber (311) and the gas detection chamber (312) in a mold closing manner, and the sealing washer (313) is arranged at the joint of the gas detection chamber (312) where the pressure sensor (6) to be detected is placed.

4. A pressure sensor leak testing device according to claim 3, characterized in that the helium source comprises a helium tank (2), a gas filling valve and a digital pressure gauge (8); the helium bottle (2) is connected with the gas injection chamber (311) through the inflation valve pipeline; the inflation valve is electrically connected with the control module; the digital pressure gauge (8) is arranged between the helium bottle (2) and the inflation valve.

5. A pressure sensor leak test device according to claim 3, characterized in that the vacuum pump cabinet comprises a vacuum pump (4), a pre-pump valve and a digital vacuum gauge (7); the vacuum pump (4) is connected with the detection chamber control valve through the pre-pumping valve pipeline; the pre-pumping valve is electrically connected with the control module; the digital vacuum meter (7) is arranged between the vacuum pump (4) and the pre-pumping valve.

6. A pressure sensor leak testing arrangement according to claim 3, characterized in that the helium mass spectrometer (1) is further provided with a leak detection valve; the helium mass spectrometer (1) is connected with the detection chamber control valve through the leak detection valve pipeline; the leak detection valve is electrically connected with the control module.

7. A pressure sensor leak testing device according to claim 3, characterized in that the device further comprises a compressed air source, the compressed air source comprises a compressed air bottle (5) and a compressed air valve, the compressed air bottle (5) is connected with the gas detection chamber (312) through the compressed air valve pipeline; the compressed air valve is electrically connected with the control module.

8. The pressure sensor leak test apparatus according to claim 1, wherein the plurality of sensor test stations are divided into a first test area and a second test area, and the first test area and the second test area alternately perform test operations.

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