KR20080105326A - System for testing of confidentially and method for testing thereof - Google Patents

Abstract

An airtightness test system and method are provided to perform an airtightness test according to a single system by increasing or reducing the internal pressure of test target product so as to decrease the test expense. An airtightness test system includes a pressurizing unit(22) for supplying the air to a test target through a first valve(24) under a predetermined condition, a depressurizing unit(34) for inhaling the air from the test target through a second value(32) under a predetermined condition to reduce the inner pressure of the test target, and a controller(40) for selectively opening/closing the first or second valve and driving the pressurizing unit or the depressurizing unit corresponding to the currently opened valve.

Description

Air tightness test system and test method thereof {SYSTEM FOR TESTING OF CONFIDENTIALLY AND METHOD FOR TESTING THEREOF}

1 is a block diagram of a gas tightness test system according to an embodiment of the present invention.

Figure 2 is a system configuration showing another structure employing a two-way valve in the air tightness test system configuration according to an embodiment of the present invention.

Figure 3 is a flow chart of a leak test method using a leak test system according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: air compressor 20: supply line

22: pressure regulator 24: pressure valve (first valve)

30: suction line 32: pressure reducing valve (second valve)

34: pressure reduction regulator 36: vacuum ejector

38: third valve 40: control module

42: mode switch

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an airtightness test, and more particularly, to an airtightness test system and a test method thereof capable of performing a plurality of airtightness test items through air pressurization and depressurization on a predetermined product.

Many mechanical and electrical / electronic products are provided with a large number of parts, and the parts are provided with a structure for maintaining airtightness to perform a smooth function of the product.

In particular, airtight structures are essential for connectors that electrically interconnect electrical and electronic devices. The connector is used as an essential part in a vehicle in which various control devices and electronic control devices are adopted in recent years.

However, if the airtightness of the connector itself is poor, moisture may penetrate due to moisture generation due to internal and external temperature differences, and may cause short circuits / short circuits, which may seriously affect driving safety of the vehicle.

Therefore, the confidentiality test should be conducted from the product development stage. Usually, the airtightness test is performed by checking whether the air is discharged to the outside of the connector in a state in which air is supplied into the product to be tested (in the present specification, the connector is described as an example and hereinafter referred to as a connector). Judgment to ensure confidentiality.

As one example, the waterproof test can determine whether the product is airtight. The waterproof test allows the connector to which the air supply line is connected to be locked in the tank. The air is supplied to the connector while the pressure is sequentially increased through the air supply line. At this time, if bubbles are generated in a predetermined portion of the connector submerged in the tank, it is determined that the airtightness is poor in the corresponding portions.

In this manner, the airtightness test is performed by supplying air into the connector. However, the airtightness test by the above air supply alone cannot obtain accurate results. For example, when the airtightness test is performed as the waterproof test, if there is a very small defect in which bubbles are difficult to occur in a predetermined portion of the connector or if the bubble generation state is so weak that the operator cannot easily confirm the bubble generation, The confidentiality of can be mistaken for being appropriate.

In recent years, a plurality of test items may be required for more accurate test results in addition to a single airtight test item by air supply. This creates the hassle of using other leak testing equipment.

Accordingly, an object of the present invention is to provide an airtightness test system and a test method thereof for more accurately performing the airtightness test.

Another object of the present invention is to easily apply a plurality of airtightness test items in one system.

According to a feature of the present invention for achieving the above object, the pressure means for supplying air to the product under test through a first valve according to a predetermined condition; Pressure reduction means for reducing the internal pressure of the product under test by sucking the air inside the product under test through a second valve according to a predetermined condition; And a control means for selectively opening / closing the first valve or the second valve for air supply and air intake, but for controlling driving the pressurizing means or the depressurizing means in which the valve which is currently open is located.

In the air suction operation, the vacuum ejection to always suck the air on the side of the product to be tested by the pressure difference with the air supplied from the air supply means, and the air in the air supply means only when the decompression means is in operation And a third valve opened to be supplied to the eject side.

Preferably, the vacuum ejector uses a venturi tube.

The control means opens only the first valve so that air is supplied only to the product under test when the pressure means is turned on. The control module opens only the second valve and the third valve so that air is sucked from the product under test to the vacuum ejection side when the pressure reducing means is turned on.

In addition, according to another feature of the invention, the first step of supplying air to the test target product through the pressurizing means by a predetermined pressure for a predetermined set time to confirm the airtight results; And, the second step of checking the airtightness results of the product under test while decompressing the inside of the product under test using a decompression means, wherein the first step and the second step is executed after any one step One step consists of executing in order.

Among the valves respectively provided between the pressurizing means and the depressurizing means and the product under test, the pressurizing valve is opened only when the pressurizing means is in operation, and the decompression valve is opened only when the depressurizing means is in operation.

During operation of the decompression means, the air in the conduit is evacuated by the pressure difference between the air flowing into the vacuum ejector from the air supply means and the air communicating with the vacuum ejector and flowing through the conduit connected to the product under test. The pressure inside the product under test is reduced while being sucked into the furnace.

According to the present invention having such a configuration, it is possible to supply air to which the pressure increases in a predetermined step to the product to be tested, as well as to perform the airtightness test while reducing the pressure inside the product to be tested. Able to know. That is, not only the airtightness test by any one method, but the present embodiment can perform the airtightness test by independently performing air pressurization or decompression, and of course, by performing the two methods sequentially, a more accurate airtightness test is performed. can do.

Hereinafter, a gas tightness test system and a test method thereof according to the present invention will be described in detail with reference to a preferred embodiment shown in the accompanying drawings.

1 is a block diagram of a gas tightness test system according to a preferred embodiment of the present invention.

Referring to Fig. 1, an air compressor 10 as air supply means for compressing air is provided.

The supply line 20 is installed to perform the airtightness test using the air supplied from the air compressor 10.

The pressure regulator 22 is installed in the supply pipe 20 so as to be supplied to the connector 2 in the water tank 1 while increasing the air supplied from the air compressor 10 by a predetermined pressure. The pressure regulator 22 serves to supply air while the air is increased by a predetermined pressure for a predetermined time. A pressurizing valve (first valve) 24 is provided between the pressurizing regulator 22 and the connector 2 that opens only when the pressurizing regulator 22 is in operation (on).

In addition, a suction pipe passage 30 for sucking air to test the airtightness of the connector 2 is provided.

In other words, a supply line 20 and a suction line 30 are respectively provided between the air compressor 10 and the connector 2.

The suction pipe 30 is provided with a pressure reducing valve (second valve) 32, a pressure reducing regulator 34 and a vacuum ejector 36 sequentially from the connector 2 side as shown in the drawing. The vacuum ejector 36 sucks the air inside the connector 2 by the pressure difference with the air which is always supplied from the air compressor 10. The second valve 32 is opened only when the pressure reducing regulator 34 is in operation (on). That is, the first valve 24 is in a shut-off state when the pressure reducing regulator 34 is in operation, and the second valve 32 is in a shut-off state when the pressure regulator 22 is in operation. Therefore, the first valve 24 allows the air sucked from the connector 2 to flow along the suction pipe line 30 when the pressure reducing regulator 34 is operated, and to prevent the first valve 24 from flowing into the supply pipe 20. do. In addition, the second valve 32 prevents air from flowing to the suction pipe path 30 when air is supplied to the connector 2 according to the operation of the pressure regulator 22.

However, the vacuum ejector 36 may suck air in the suction pipe path 30 by a pumping action in a state in which the vacuum ejector 36 is simply connected to the suction pipe path 30.

In addition, as shown in FIG. 1, the first valve 24, which is a pressure valve, and the second valve 32, which is a pressure reducing valve, are not separately configured, and a predetermined control is provided at a point where the supply line and the suction line cross each other as shown in FIG. 2. In accordance with the operation, it is also possible to install the bidirectional valve 60 that opens in only one direction to selectively control the air flow. Even when the bidirectional valve 60 is employed, the same operation is performed according to the control operation as shown in FIG. 1, and thus the detailed description of FIG. 2 will be omitted.

Next, a third valve 38 is installed between the vacuum ejector 36 and the air compressor 10 to open only when the pressure reducing regulator 34 is in operation. The third valve 38 prevents air discharged from the air compressor 10 in the direction of the vacuum ejector 36 during the operation of the pressure regulator 22. That is, when the third valve 26 is in an open state, the pressure reducing regulator 34 is in an operating state, and air is always supplied from the air compressor 10 to the vacuum ejector 36 through the third valve 38. Say what it is. Therefore, when the pressure reducing regulator 34 is operated while the air is always supplied to the vacuum ejector 36 and the second valve 32 is opened, the pressure difference in the vacuum ejector 36 is in the suction pipe path 30. Air is sucked in the air flow direction flowing through the third valve 38 to flow.

Specifically, a venturi tube is used for the vacuum ejector 36 in the present embodiment. That is, the venturi tube is formed with a duct communicating with an inlet port 36a receiving air from the air compressor 10 and an outlet port 36b through which the air received through the inlet port 36a is discharged, and a predetermined portion of the duct. The suction pipe is configured to communicate with 36c. Therefore, when the third valve 38 is opened, air always flows through the duct in the air compressor 10, and when the second valve 32 is opened, air in the suction pipe path 30 connected to the connector 2 is opened. Is to suck the air inside the suction pipe line 30 by the pressure difference inside the venturi tube. As a result, the pressure inside the connector 2 is reduced.

Next, the control module unit 40 is configured to control the on / off operation of the pressure regulator 22 and the pressure reduction regulator 34. The control module unit 40 selectively drives either the pressure regulator 22 or the pressure reduction regulator 34 in accordance with the test mode, or drives the pressure regulator 22 or the pressure reduction regulator 34 in order. To control. For this purpose, the mode switch 42 is provided. In addition, the control module 40 controls the setting of the pressure level and the time interval when supplying air from the air compressor 10. In addition, the control module 40 performs opening / closing of the first to third valves 24, 32, 38 according to the driving states of the pressure regulator 22 and the pressure reduction regulator 34. That is, when the pressure regulator 22 operates, the first valve 22 is opened, and the second and third valves 24 and 32 are blocked. In operation of the pressure reducing regulator 34, the first valve 22 is shut off, and the second and third valves 24 and 32 are opened. And a display window 44 for displaying information necessary for the test mode.

On the other hand, the connector 2 should be locked in the water tank 1 with water of a predetermined capacity. At this time, the water capacity should be the capacity that the connector 2 can be completely locked. And the connector 2 should be of a structure that is completely coupled to one end of the supply / suction pipe. That is, when the air is provided inside the connector 2 or when the air is sucked in the connector 2, if the connection part other than the connector 2 itself is defective, the airtightness test cannot be performed normally.

Next, the process of performing the airtightness test using the airtightness test system according to the present invention having the configuration as described above will be described in detail.

First, the test mode is selected by operating the mode switch 42 of the control module unit 40 (S100). The operation of the mode switch 42 may cause only one of the pressure regulator 22 and the pressure reduction regulator 34 to be driven, but in this embodiment, the pressure regulator 22 and the pressure reduction regulator 34 are selected to be driven in order. do. Also set the pressure level and time interval. For example, 0.1kgf / cm ² increased 30 seconds (sec) at a pressure by the 0.1kgf / cm ² interval, and to reach the final 2kgf / cm ^2, it can be made to conduct a test time of about 15 minutes total have. Of course, different pressures and times may be provided depending on the test object.

According to the test mode setting, supplying air to the connector 2 to perform the airtightness test will be described first (S102). When the test mode is set by the mode switch 42, the control module unit 40 drives the pressure regulator 22 on, and opens the first valve 24 (S104). At this time, the second valve 32 and the third valve 38 should be blocked.

When the pressure regulator 22 is driven, air is supplied to the pressure regulator 22 from the air compressor 10 which is always in operation (S106).

Then, the pressure regulator 22 is 2.0kgf / cm, the final pressure while increasing the pressure by 0.1kgf / cm ² every 30 seconds interval from the conditions set in the control module 40, the first 0.1kgf / cm ² pressure If air is supplied up to ² , air is supplied to the connector 2 in the water tank 1 through the first valve 24 according to the time condition and the pressure condition (S108). At this time, since the second valve 30 is in a blocked state, the air supplied through the supply line 20 is supplied only to the connector 2 and not to the suction line 30. In addition, since the third valve 38 is also in a blocked state, it is not supplied to the vacuum ejector 36 side.

As such, when air is supplied to the connector 2 through the first valve 24, in operation 110, the operator determines whether the connector 2 is airtight. The airtightness determination is determined by whether bubbles are generated outside the connector 2. That is, if bubbles are generated as a result of the determination of step 110, it is determined that the connector airtightness is poor (S126). On the other hand, if bubbles do not occur, it is determined that the confidentiality state is maintained (S128).

At this time, the air supply is supplied to the connector 2 for a predetermined time interval at the set initial pressure, and if there is no abnormality, the order in which the air, which is increased by a predetermined pressure, is supplied again to the connector 2 is repeated until the predetermined final pressure. Thus, if bubbles are generated at any pressure stage, the operator can know the pressure conditions that the connector 2 can withstand.

Next, after vacuuming the inside of the connector 2, it is judged whether or not water is permeated into the inside of the connector 2 to determine whether it is airtight.

To this end, the mode switch 42 for performing such a test is selected by the operator (S112). At this time, in addition to the mode switch 42 is directly selected by the operator, when the pressure regulator 22 is completed, the pressure reducing regulator 34 is automatically driven by the control module unit 40 to continue the airtightness test. Of course. In this case, the opening and closing of the valve located in the pipeline are also controlled.

Once the mode is switched as described above, the control module unit 40 stops the pressure regulator 22 and drives the pressure reduction regulator 34. In addition, the first valve 24 in the open state is shut off, and the second valve 32 and the third valve 38 installed in the suction pipe 30 are opened.

Since the air compressor 10 is continuously driven once the third valve 38 is opened, air is supplied from the air compressor 10 to the vacuum ejector 36 through the third valve 38. The supplied air passes through the inlet 36a and the outlet 36b of the vacuum ejector 36 (S114).

At this time, since the pressure reducing regulator 34 is in a driving state and the second valve 32 is also open (S116), the air in the suction pipe path 30 is discharged by the pressure difference inside the vacuum ejector 36. It is sucked in the air flow direction flowing through the three valve (38). Of course, since the first valve 24 is blocked, the air sucked from the connector 2 flows only to the suction pipe path 30 without flowing to the supply pipe 20 side. As a result, the pressure inside the connector 1 is gradually reduced by the air suction (S118).

The pressure decompression is continuously performed during the air suction operation performed up to the pressure condition set by the control module 40, for example, a vacuum state (S120).

And the airtightness test judgment by air suction is made after the connector 2 is disassembled. In other words, the connector 2 is disassembled by the worker (S122), and it is determined whether or not the airtightness by checking whether there is water in the connector (S124). If there is water, the connector 2 determines that the confidentiality is poor (S126), and in the opposite case, it is determined that the confidentiality is normal (S128).

Here, the worker may inspect the inside of the connector 2 while performing the air suction process at a predetermined pressure. It can then be determined that the connector 2 is not hermetically maintained under any pressure. For example, suppose that there is no water inside the connector (2), starting from the initial pressure until 0.5 kgf / cm ² pressure, but there is water under 0.6 kgf / cm ² pressure, the connector (2) has a pressure limit It can be seen that 0.6kgf / cm ² . Through this airtightness test, a pressure limit can be known for each connector 2, and a connector having a pressure limit corresponding to a suitable location can be used.

 As described above, the present invention described in the above embodiment can perform the airtightness test by sequentially performing pressure and pressure reduction on the test target product.

As described above, it has been described with reference to the illustrated embodiment of the present invention, but this is only exemplary, and those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention It will be apparent that other variations, modifications and equivalents are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described in detail above, according to the airtightness test system and the test method thereof, the airtightness test is performed by pressurizing the pressure inside the product according to the air supply or by reducing the pressure inside the product through air suction. Since the process can be performed by one system, it is possible to reduce the configuration cost compared to the conventional airtight test was performed by a separate configuration.

In addition, the trend that requires multiple items for the confidentiality test also has the effect of being able to actively deal with a simple configuration.

Claims (7)

Pressurizing means for supplying air to the product under test through a first valve according to a predetermined condition; Decompression means for sucking the air inside the product under test through a second valve according to a predetermined condition to reduce the internal pressure of the product under test; And, And control means for selectively opening / closing the first valve or the second valve for air supply and air intake, and driving the pressurizing means or the depressurizing means in which the valve which is currently open is located. Air tightness test system. The method of claim 1, A vacuum ejector which sucks air on the side of the product to be tested by a pressure difference with air supplied from an air supply means during the air suction operation; And a third valve which is opened so that air is supplied to the vacuum eject side from the air supply means only when the decompression means is in operation. The method of claim 2, The vacuum ejector is a gas tightness test system, characterized in that the venturi tube. The method according to claim 1 or 2, The control means, Only the first valve is opened so that air is supplied only to the product under test when the pressurization means is turned on, And the second valve and the third valve are controlled to be opened so that air is sucked from the product under test to the vacuum ejection side when the decompression means is turned on. A first step of supplying air, which is increased by a predetermined pressure, for a predetermined set time to a test target product through a pressurizing means to check the airtight result; And, After depressurizing the inside of the product under test using a decompression means, a second step of checking the airtight result of the product under test, The first and second steps are airtightness testing method characterized in that it is configured to be executed after any one step and the other step is executed in sequence. The method of claim 5, Among the valves provided between the pressurizing means and the decompression means and the product under test, the pressurizing valve is opened only when the pressurizing means is in operation, and the pressure reducing valve is opened only when the depressurizing means is in operation. Test Methods. The method of claim 5, During operation of the decompression means, the air in the conduit is evacuated by the pressure difference between the air flowing into the vacuum ejector from the air supply means and the air communicating with the vacuum ejector and flowing through the conduit connected to the product under test. Airtightness test method characterized in that for reducing the pressure inside the product under test while being sucked into.

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