KR101344699B1 - Apparatus for inspecting pot assembly - Google Patents

Abstract

The present invention relates to a device for inspecting a leakage of a pot assembly. The purpose of the present invention is to provide a device for inspecting the leakage of the pot assembly by collecting helium particles leaked from the pot assembly after helium gas is injected into the pot assembly arranged in a vacuum chamber.

Description

Apparatus for inspecting pot assembly

The present invention relates to a port assay leak inspection apparatus, and in particular, helium gas is injected into a port assembly which is a component of an air spring in a vacuum chamber, and the helium particles leaked from the port assembly are collected and the corresponding port assembly is analyzed. The present invention relates to a port-assessment leak inspection device that can confirm whether or not the leakage of the gas.

In general, the vehicle suspension is installed between the vehicle body and the axle to absorb the vibration and impact energy transmitted from the road surface while the vehicle is running, to provide a function to suppress the damage of the vehicle body and improve the ride comfort of the vehicle.

Such a vehicle suspension device includes a suspension spring for mitigating an impact received from a road surface, and a shock absorber for suppressing free vibration of the suspension spring, and the suspension spring and the shock absorber have a complementary action to further improve ride comfort. Will be provided to

On the other hand, in recent years, the use of the air spring using the elasticity of the air and rubber in order to provide a more improved ride comfort is increasing.

The air spring is configured to absorb and mitigate shock by using compressed air injected into a bellows made of rubber material, and is used as an actual suspension device in combination with a port assembly and a shock absorber coupled to a vehicle body. ).

As such, the air struts constructed using the air springs maintain the internal pressure of the air springs at a constant level in order to maintain a proper garage and flexibly respond to changes in the situation while being stretched or compressed according to the impact or load change applied. Let's go.

1 is a cross-sectional view showing the structure of the upper end of the air spring.

The port assembly 10 is coupled to the upper end of the air spring, the air port 13 for injecting air into the air spring is provided.

The port assembly 10 includes an upper structure 11 coupled to a vehicle body side and a lower structure 12 coupled to an air spring, and the upper portion of the lower structure 12 into the upper structure 11. The upper structure 11 and the lower structure 12 are coupled through vulcanization in a state of being inserted at a predetermined depth.

As such, when the vulcanized adhesive portion 14 is formed between the upper structure 11 and the lower structure 12 to join the upper structure and the lower structure, the rubber is injected at an appropriate pressure and speed while maintaining the required temperature. If the temperature, pressure and speed conditions are not appropriate, a defect occurs in the vulcanized adhesive portion 14, which causes the air charged inside the air spring to leak to the outside.

Therefore, the inspection operation for the vulcanized adhesive part is carried out, but the vulcanized adhesive part is covered by the upper structure, so that visual inspection is not easy, and since there is no appropriate inspection device for performing the inspection work, it is completely dependent on manual work, so There was a problem that was difficult to implement.

The present invention has been made in view of the above problems, and an object of the present invention is to inject a helium gas into a port assembly disposed in a vacuum chamber, and then collect the helium particles leaking from the port assembly to collect the port assembly. The present invention provides a port assembly leak inspection device for inspecting whether a leak occurs.

Another object of the present invention is to provide a port assay leakage inspection apparatus that pressurizes the port assembly during the leakage inspection process of the port assembly and detects a load cell at this time to additionally check whether the vulcanized adhesive is defective.

Port assay leakage inspection apparatus of the present invention to achieve the object as described above and to perform the problem for eliminating the conventional drawback frame 100; A shielding plate 220 installed in the frame 100 to provide a space in which the port assembly 10 to be inspected is placed, which is in close contact with the open side end 10a of the port assembly and seals the port assembly; A gas injection port 211 coupled with the air port 13 provided in the port assembly to form a flow path through which helium gas is injected, and a collection port providing a discharge flow path for collecting helium particles leaking from the port assembly ( 212 and a lower chamber unit 200 having a vacuum port 213 for discharging internal air; The upper chamber unit is installed in the frame 100 so as to be positioned in the vertical upper portion of the lower chamber unit 200, the lower chamber unit 200 is coupled to the lower chamber unit 200 while descending by the operation of the lifting means 600 ( 300); It is disposed inside the upper chamber unit 300, and has a support end 311 for supporting the upper chamber unit 300 to prevent free fall of the upper chamber unit 300, and the lifting means 600 and A pressurizing member 310 connected to and lowering by the elevating means 600 to press the port assembly placed in the vacuum chamber; A spring installed on the connection rod 312 extending vertically from the pressing member 310 to press the upper chamber unit 300 so that the upper chamber unit 300 is coupled to the lower chamber unit 200 at a predetermined pressure ( 340); A load cell 330 which detects a load when the port assembly is pressed by the pressing member 310; A rubber bellows 350 installed to surround the spring 340 to prevent external exposure of the spring 340; The vacuum pump 400 is connected to the vacuum port 213 of the lower chamber unit 200 to forcibly discharge the internal air of the vacuum chamber formed by the combination of the upper chamber unit 300 and the lower chamber unit 200 to the outside. ; And a leak detector 500 installed at the frame 100 and connected to the collection port 212 of the lower chamber unit 200 to collect and detect helium particles leaking from the port assembly. .

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In addition, coupled to the connecting rod 312 extending upwardly from the pressing member 310, coupled to the lifting means 600, coupled to a plurality of guide posts 120 installed perpendicular to the frame 100 A support member 320 for supporting the lifting and lowering of the upper chamber unit 300 and the pressing member 310 may be further included.

On the other hand, the lifting means 600, the screw jack 610 installed in the frame 100; And a servo motor 620 installed in the frame 100 and connected to the screw jack 610 to drive the screw jack 610.

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On the other hand, the plurality of helium detectors 230 are disposed to be located close to the vulcanized adhesive portion of the port assembly, the plurality of helium detectors 230 are installed in the lower chamber unit 200 to have a circular array structure spaced apart from each other by a predetermined distance around the port assembly It may be further included.

According to the present invention having the above characteristics, there is an effect that can easily and accurately perform the leak inspection operation for the port assay.

In addition, by carrying out the load test in parallel, there is an effect that it is possible to more accurately detect the defect of the vulcanized adhesive portion.

1 is a cross-sectional view showing the upper structure of the air spring,
Figure 2 is a front view showing the structure of the port assay leakage inspection apparatus according to a preferred embodiment of the present invention,
Figure 3 is a side view showing the structure of the port assay leakage inspection apparatus according to a preferred embodiment of the present invention,
Figure 4 is a plan view showing the structure of the port assay leakage inspection apparatus according to an embodiment of the present invention,
5 is a detailed view showing the structure of a lower chamber unit according to the present invention;
6 is a detailed view showing the installation structure of the upper chamber unit according to the present invention;
7 is a detailed view showing a state in which the helium detector is installed in the lower chamber unit,
8 is a process chart showing the progress of the leak inspection operation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

2 is a front view showing the structure of the port assay leakage inspection apparatus according to a preferred embodiment of the present invention, Figure 3 is a side view showing a structure of the port assay leakage inspection apparatus according to a preferred embodiment of the present invention, Figure 4 Shows a plan view showing the structure of the port assay leakage inspection apparatus according to a preferred embodiment of the present invention.

The port assay leakage inspection apparatus of the present invention injects helium gas into the port assembly disposed in the vacuum chamber, and collects and detects helium particles leaking from the port assembly to check whether the vulcanized adhesive leaks. The frame 100, the lower chamber unit 200, the upper chamber unit 300, the vacuum pump 400, and the leak detector 500 are provided.

The frame 100 is a structure that forms the basic structure of the port assay leakage inspection apparatus, and assembling a plurality of aluminum profiles to form a frame 100 having a three-dimensional structure, using such a frame 100 The lower chamber unit 200, the upper chamber unit 300 and the vacuum pump 400 and the leak detector 500 is installed.

Meanwhile, a plurality of casters 110 are installed at the lower end of the frame 100 to easily move the inspection apparatus.

Figure 5 shows a detailed view showing the structure of the lower chamber unit according to the present invention.

The lower chamber unit 200 is installed in the frame 100 to provide a space in which the port assembly 10 to be inspected is placed.

The lower chamber unit 200 has a space S in which the port assembly is accommodated, and is formed in a structure in which an upper end portion is opened so that an upper portion of the space S is opened.

In addition, the lower chamber unit 200 is formed with a gas injection port 211 is coupled to the air port 13 of the port assembly to form a flow path for helium gas is injected, is connected to the leak detector 500 is a port assembly The collection port 212 is formed to guide the helium particles leaking from the Say to the leak detector 500, is connected to the vacuum pump 400 is formed by the combination of the lower chamber unit 200 and the upper chamber unit 300 A vacuum port 213 (shown in FIG. 3) is formed to discharge air in the vacuum chamber to the outside.

In addition, the inner bottom of the lower chamber unit 200 is provided with a shielding plate 220 that is in close contact with the open side end portion 10a of the port assembly 10 to seal the inside of the port assembly, the shielding plate 220 It is preferable that it consists of rubber | gum or a synthetic pad which has silver elasticity.

Figure 6 shows a detailed view showing the installation structure of the upper chamber unit according to the present invention.

The upper chamber unit 300 is coupled to the lower chamber unit 200 to form a vacuum chamber, and is installed in the frame 100 to be positioned vertically above the lower chamber unit 200.

The upper chamber unit 300 is lowered by the operation of the elevating means 600 to form a vacuum chamber by being combined with the lower chamber unit 200, the lower chamber unit 200 is raised by the operation of the elevating means 600 ) Will open the upper end.

On the other hand, the upper chamber unit 300 is connected to the lifting means 600 via the pressing member 310 and the support member 320 to be described later.

The elevating means 600 is installed on the upper end of the frame 100 to elevate the upper chamber unit 300 and the pressing member 310, it is composed of a screw jack 610 and the servo motor 620. In this case, the screw jack 610 and the servomotor 620 are well known techniques, so detailed description thereof will be omitted.

The pressing member 310 is disposed inside the upper chamber unit 300 and presses the port assembly while descending by the elevating means 600.

The pressing member 310 is provided with a support end 311 for supporting the inner upper surface of the upper chamber unit 300 in order to prevent free fall of the upper chamber unit 300.

Meanwhile, the connection structure of the pressing member 310 and the elevating means 600 will be described in more detail. The upper end of the pressing member 310 is provided with a connecting rod 312 extending upward while penetrating the upper chamber unit 300. The connection rod 312 is coupled to the support member 320 which is coupled to the guide post 120 provided in the frame 100 and moves up and down, and the support member 320 is connected to the screw jack 610. It is configured to move up and down by driving the screw jack 610.

In this case, a load cell 330 is installed on the upper surface of the support member 320 to detect a load when the port assembly is pressed by the pressing member 310, and an upper chamber unit 300 is connected to the connection rod 312. A spring 340 for pressurizing the upper chamber unit 300 to be coupled to the lower chamber unit 200 by pressure is installed, and prevents the external exposure of the spring 340 to prevent contamination of the spring 340 and the inspection work process Rubber bellows 350 for preventing the worker's body or work tools from being caught between the winding of the spring 340 is installed.

2 and 3, the vacuum pump 400 is installed in the frame 100, and is connected to the vacuum port 213 of the lower chamber unit 200 through a hose to external air in the vacuum chamber. By forcibly discharging, the vacuum atmosphere is formed inside the vacuum chamber.

The leak detector 500 is installed in the frame 100 and is connected to a collection port 212 and a hose of the lower chamber unit 200 to collect helium particles leaking from the port assembly. The total leakage of helium particles is detected.

The leak detector 500 is composed of a helium detector, and since the helium detector is a well-known technique, a detailed description of the principle of the leak detector 500 will be omitted.

On the other hand, when it is confirmed that there is a leak from the vulcanized adhesive portion inside the lower chamber unit 200, a plurality of helium detector 230 for detecting the leaked portion may be further installed.

Figure 7 shows a detailed view showing a state in which the helium detector is installed in the lower chamber unit according to the present invention.

The plurality of helium detectors 230 are disposed in the lower chamber unit 200 to be located in close proximity to the vulcanized adhesive portion 14 of the port assembly 10 placed in the lower chamber unit 200, and the port assembly 10. It is installed to have a circular array structure spaced apart from each other at a predetermined interval.

According to the plurality of helium detectors 230, the helium detector 230 in the position close to the leak portion is higher than the other helium detectors, so that the helium level is higher than that of the other helium detectors. The site can be identified.

By using the port assay leakage inspection device configured as described above to explain the process of performing the leakage inspection operation for the single port assay product, through this to clarify the effect of the force assay leakage inspection device according to the present invention do.

8 is a flowchart showing the progress of the leak inspection operation.

First, the upper chamber unit 300 is raised to open the upper end of the lower chamber unit 200. Of course, the raising of the upper chamber unit 300 is made by the operation of the lifting means (600).

As such, when the upper chamber unit 300 is raised to open the upper end of the lower chamber unit 200, the port assembly 10 to be inspected is disposed in the lower chamber unit 200, and at this time, the port assembly ( The port assembly is arranged such that the open end 10a of 10) is in close contact with the shielding plate 220 located on the inner bottom of the lower chamber unit 200.

Since the support member 320 is lowered by the operation of the lifting means 600 to lower the pressing member 310 and the upper chamber unit 300, the lowering of the pressing member 310 and the upper chamber unit 300. In the process, the upper chamber unit 300 is first combined with the lower chamber unit 200 to form a vacuum chamber.

Thus, when the vacuum chamber is formed by the combination of the upper chamber unit 300 and the lower chamber unit 200, the upper chamber unit 300 is combined with the lower chamber unit 200, so that further lowering is impossible, The pressing member 310 is lowered by the operation of the lifting means 600, the port assembly 10 is pressed by the lowering of the pressing member (310).

Meanwhile, when the pressing member 310 moves as described above, the spring 340 is compressed to pressurize the upper chamber unit 300 with a greater force, and the supporting member 320 when pressing the port assembly by the pressing member 310. The load cell 330 installed in the load cell 330 detects the load generated between the pressing member 310 and the port assembly 10.

On the other hand, the load detected in the load cell 330 shows a different tendency depending on the state of the vulcanized adhesive portion. In other words, when the pressure member 310 is moved at the same distance and the port assembly is pressurized, the load value is increased in the port assembly having the vulcanized adhesive portion which is formed more abnormally than the normal port vulcanized adhesive portion and does not achieve a perfect adhesion state. It tends to be measured low.

Therefore, through the experiment under the same conditions as the inspection work in advance, the load generated during the pressurization of the port assembly having a normal vulcanized adhesive portion is measured, and it is possible to additionally determine whether the vulcanized adhesive portion is normal based on this load value. Therefore, the inspection using helium gas and the inspection using the load value can be performed in parallel to increase the reliability of the inspection work.

On the other hand, when the port assembly is pressurized by the pressing member 310, the open side end of the port assembly is in close contact with the shielding plate 220, and the air port of the port assembly is connected to the gas injection port 211. The tightness prevents helium gas from leaking from unintended areas.

Thereafter, the air inside the vacuum chamber is discharged to the outside by the operation of the vacuum pump 400 to form a vacuum atmosphere inside the vacuum chamber, and the helium gas supplier (not shown) connected to the gas injection port 211 is operated to Helium gas is injected into the port assay. As the helium gas supplier, a container in which helium gas is stored may be used, or a separate dedicated gas supply facility may be used.

As described above, in injecting helium gas into the port assembly, it is preferable to inject helium gas into a low pressure and a high pressure, and to check whether the helium gas is leaked.

This is because when the helium gas is injected at a high pressure into the port assembly, the vulcanized adhesive portion is squeezed between the upper structure and the lower structure due to the internal pressure of the port assembly, so that leakage may not occur even when the vulcanized adhesive portion is defective. have.

Therefore, it is preferable to inject the helium gas at a low pressure (2.0 Bar to 3.0 Bar) for leak test, and to inject the helium gas at a high pressure (9.0 Bar to 10.0 Bar) for leak test again.

On the other hand, if there is a defect in the vulcanized adhesive portion of the port assembly into which the helium gas is injected, the helium gas leaks through the defective portion and is discharged into the vacuum chamber, and the helium gas discharged into the vacuum chamber is collected in the collection port ( The leak detector 500 is introduced into the leak detector 500 through 212, and the leak detector 500 detects the total leak amount of the collected helium particles to determine the size of a defect of the corresponding port assembly.

As described above, the port assay leakage inspection apparatus according to the present invention injects helium gas into the port assembly disposed in the vacuum chamber, and performs leakage inspection by collecting helium particles leaking from the port assay. Compared to the inspection method of the test method, it is possible to further increase the speed or reliability of the inspection work.

On the other hand, if the leak test results for the port assembly, it is determined that the corresponding port assembly is defective, additional work to find a specific leakage site may be performed.

The additional inspection operation injects helium gas into the port assembly while the upper chamber unit 300 is raised, and at this time, a relatively high detection value among the plurality of helium detectors 230 installed in the lower chamber unit 200. By finding the helium detector 230, which indicates the defect, the site where the defect is generated, and the related measures are performed.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Description of the Related Art
10: Port Assay 100: Frame
120: guide post 200: lower chamber unit
211: gas injection port 212: capture port
(213): vacuum port 220: shield plate
230: helium detector 300: upper chamber unit
(310): pressure member 311: support end
312: connecting rod 320: support member
330: load cell 340: spring
350: Rubber Bellows 400: Vacuum Pump
500: leak detector 600: lifting means
(610): screw jack 620: servo motor

Claims (6)

A frame 100;
A shielding plate 220 installed in the frame 100 to provide a space in which the port assembly 10 to be inspected is placed, which is in close contact with the open side end 10a of the port assembly and seals the port assembly; A gas injection port 211 coupled with the air port 13 provided in the port assembly to form a flow path through which helium gas is injected, and a collection port providing a discharge flow path for collecting helium particles leaking from the port assembly ( 212 and a lower chamber unit 200 having a vacuum port 213 for discharging internal air;
The upper chamber unit is installed in the frame 100 so as to be positioned in the vertical upper portion of the lower chamber unit 200, the lower chamber unit 200 is coupled to the lower chamber unit 200 while descending by the operation of the lifting means 600 ( 300);
It is disposed inside the upper chamber unit 300, and has a support end 311 for supporting the upper chamber unit 300 to prevent free fall of the upper chamber unit 300, and the lifting means 600 and A pressurizing member 310 connected to and lowering by the elevating means 600 to press the port assembly placed in the vacuum chamber;
A spring installed on the connection rod 312 extending vertically from the pressing member 310 to press the upper chamber unit 300 so that the upper chamber unit 300 is coupled to the lower chamber unit 200 at a predetermined pressure ( 340);
A load cell 330 which detects a load when the port assembly is pressed by the pressing member 310;
A rubber bellows 350 installed to surround the spring 340 to prevent external exposure of the spring 340;
The vacuum pump 400 is connected to the vacuum port 213 of the lower chamber unit 200 to forcibly discharge the internal air of the vacuum chamber formed by the combination of the upper chamber unit 300 and the lower chamber unit 200 to the outside. ; And
The port is installed on the frame 100, connected to the collection port 212 of the lower chamber unit 200, characterized in that the port consisting of a leak detector 500 for collecting and detecting helium particles leaking from the port assembly Assay leak tester. delete The method according to claim 1,
Coupled with a connecting rod 312 extending upwardly from the pressing member 310, coupled with the lifting means 600, coupled to a plurality of guide posts 120 installed perpendicular to the frame 100, the upper Port assembly leak test device, characterized in that further comprising a support member 320 for supporting the lifting and lowering of the chamber unit 300 and the pressing member (310). The method of claim 1, wherein the lifting means 600,
A screw jack 610 installed on the frame 100; And
Port assay leakage inspection apparatus is installed on the frame 100 and connected to the screw jack 610 is composed of a servo motor 620 for driving the screw jack 610. delete The method according to claim 1,
A plurality of helium detectors 230 are disposed to be located in close proximity to the vulcanized adhesive portion of the port assembly, and are installed in the lower chamber unit 200 to have a circular arrangement structure spaced apart from each other by a predetermined distance around the port assembly. Port assay leak inspection apparatus comprising a.

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