KR20080021421A - Fluid tightness test apparatus with integrated positive and negative pressurizer - Google Patents

Abstract

A fluid tightness test apparatus is provided to reduce test time and costs by performing fluid tightness tests for positive and negative pressure conditions with the same apparatus. A fluid tightness test apparatus comprises an air/fluid storage unit(3), an air supply/discharge unit(1), a flow control unit(2) and a pressure measuring unit(4). The air/fluid storage unit stores air in a first section and tested fluid in a second section. The air supply/discharge unit supplies or draws air to/from the first section of the air/fluid storage unit. The flow control unit controls flow rate of air entering between the air supply/discharge unit and the air/fluid storage unit. The pressure measuring unit measures pressure applied to a tested body connected to the second section of the air/fluid storage unit.

Description

Fluid tightness test apparatus with integrated positive and negative pressurizer

1 is a block diagram of a static-negative pressure integrated hermetic test apparatus according to an embodiment of the present invention for a hermetic test in a constant pressure condition.

Figure 2 is a block diagram of a positive-negative pressure integrated airtight test apparatus according to an embodiment of the present invention for the airtight test under the negative pressure condition.

Brief description of symbols for the main parts of the drawings

1: air supply means 1a: intake port

1b: outlet port 2: flow control means

3: air-fluid storage means 3a: sliding partition

4: pressure measuring means 5: test object

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a static-neutral integral tightness test apparatus, and more particularly, to a static-negative integral tightness test capable of performing a hermetic performance test when positive and negative pressures act on a valve or the like requiring airtightness. It is about a test device.

The final delivery of gas turbine engines or industrial equipment is delivered in the form of packaging, which is mainly designed to be exposed to the outside. Within the actuator in the packaging there is a container for storing fuel and oil, in which the supply system allows fluid to flow only during operation and must not leak out during storage.

However, when a sudden temperature change occurs inside the packaging exposed to the outside due to environmental changes, a pressure change occurs inside the container storing the fluid. In other words, the static pressure and negative pressure conditions are often generated in the device requiring the airtight characteristics according to environmental factors.

Therefore, in order to verify and manufacture a device that requires the airtight property under these conditions, a device that can simultaneously perform the airtight test under the positive and negative pressure conditions is required. In addition, a device capable of simultaneously conducting a leak test under both positive and negative pressure conditions is essential in order to investigate post-delivery failure and supplement product performance.

Leakage tests for devices requiring such leaks should be validated in environmental conditions as well as performance tests. Conventionally, the positive pressure and negative pressure conditions could not be implemented at the same time. Therefore, conventionally, the static pressure test rig should be implemented after the static pressure test rig is implemented, and the negative pressure test rig must be performed after the negative pressure test rig is implemented for the same specimen. Therefore, there is a problem that the test time and cost are excessively consumed, and accurate simulation is not performed when the positive pressure and the negative pressure simultaneously act.

In particular, in the case of various environmental conditions, where the positive and negative pressures can be generated in each environmental condition, the test time and the test device were repeated twice by connecting the positive pressure and the conforming test device for the same specific environmental conditions. There was a problem of excessive cost.

SUMMARY OF THE INVENTION An object of the present invention is to provide a positive-negative pressure integrated hermetic test apparatus capable of each of the hermetic tests under the positive pressure and the negative pressure conditions without replacing the test apparatus.

The present invention has a sliding partition inside the (i), the air is stored on the first side around the sliding partition and the test fluid is stored on the second side, the sliding partition is moved in accordance with the pressure of the air Air-fluid storage means; (Ii) air supply-discharge means for supplying or withdrawing air to the first side of said air-fluid storage means; (Iii) a flow control means fluidly connected between the air supply-discharge means and the air-fluid storage means and for controlling the flow rate of air entering and exiting between the air supply-discharge means and the air-fluid storage means ; And (iii) pressure measuring means for measuring a pressure applied to the test object fluidly connected to the second side of the air-fluid storage means.

The air supply-discharge means may be an air pump having a suction port for sucking air and a discharge port for discharging air. The flow control means is fluidly connected to the discharge port of the air pump when the airtight test of the test body under the constant pressure condition, and the inlet port of the air pump when the airtight test of the test body under the negative pressure condition Flow control means are fluidly connected.

The positive-negative pressure integrated airtight test apparatus having the above configuration can greatly reduce the test time and cost since the airtight test can be performed under the positive pressure and negative pressure conditions without replacing the test device.

Hereinafter, embodiments of the present invention shown in the accompanying drawings will be described in detail.

1 is a block diagram of a static-negative pressure integrated airtight test apparatus according to an embodiment of the present invention for the airtight test in the positive pressure condition, Figure 2 is a view of an embodiment of the present invention for the airtight test in the negative pressure condition It is a block diagram of a static negative pressure integrated hermetic test apparatus. 1 and 2, the static-negative pressure tightness test apparatus includes an air supply-discharge means 1, a flow regulating means 2, an air-fluid storage means 3, and a pressure measuring means 4. .

The air supply-discharge means 1 can be an air pump 1. The air pump 1 has a suction port 1a and a discharge port 1b, and sucks air from the suction port 1a to supply air of a predetermined pressure to the discharge port 1b. Referring to FIG. 1, the inlet port 1a of the air pump is opened to the atmosphere and the outlet port 1b is fluidly connected to the flow regulating means 2 to create a positive pressure condition. Thus, when the air pump 1 is operated, the air supplied from the air pump 1 enters the first storage space 3b of the air-fluid storage means via the flow regulating means 2.

Referring to FIG. 2, the inlet port 1a of the air pump is fluidly connected with the flow regulating means 2 to create a negative pressure condition, and the outlet port 1b of the air pump is open to the atmosphere. Therefore, when the air pump 1 is operated, the air of the first storage space 3b of the air-fluid storage means 3 is released and exits to the atmosphere. The suction port 1b and the discharge port 1b attached to the air pump 1 have the same diameter for the convenience of piping connection.

Although only the air pump 1 is illustrated as an air supply-discharge means 1 in FIG. 1, the protection scope of this invention is not limited to this. As the air supply-discharge means 1, an air pump 1 and a vacuum generator (not shown) can be used together. That is, after connecting the discharge port 1b of the air pump and the port of the vacuum generator to the flow control means 2, the air pump 1 is driven to create a positive pressure condition, and the vacuum generator is driven to create a negative pressure condition. can do. As such, the air supply-discharge means 1 can be used in any device having the function of selectively supplying or discharging air.

The flow regulating means 2 may be a flow regulating valve 2. The flow regulating valve 2 can be operated manually or automatically, and the flow rate through the valve 2 is controlled according to the closing amount. The flow regulating means 2 is fluidly connected to the air-fluid storage means 3. That is, the flow regulating means 2 is provided between the air supply-discharge means 1 and the air-fluid storage means 3.

The air-fluid storage means 3 may be an air-fluid storage tank 3. The air-fluid storage tank 3 has a sliding partition 3a which divides the internal space into the first space 3b and the second space 3c, and the sliding partition 3a keeps airtight inside the tank. Can slide Air is stored in the first space 3b around the sliding partition 3a, and the fluid to be tested (fluid under test) is stored in the second space 3c.

Since the sliding partition 3a must move while maintaining the airtightness of the air and the fluid under test stored in the first space 3b and the second space 3c, it should be made of a material having good adhesion and elasticity. Therefore, the sliding partition 3a may be made of a material containing rubber.

If air is supplied from the air supply-discharge means 1 through the flow regulating means 2, the sliding partition 3a moves to the right while the first space 3b of the air-fluid storage means expands, 2 Compress the fluid under test in space (3c).

The end of the second space 3c side of the air-fluid storage means is fluidly connected to the test object 5. A pressure measuring means 4 is provided between the second space side end portion and the test object 5. The pressure measuring means 4 can be a pressure gauge 94 and any system capable of measuring pressure can be used.

Hereinafter, the process of performing the airtight test on the test subject 5 under the positive pressure and the negative pressure conditions by the positive-negative pressure integrated airtight test apparatus having the above-described configuration will be described.

First, with reference to FIG. 1, the process of performing the airtight test of the test subject 5 in a positive pressure condition is demonstrated. When the air pump 1 is operated, air enters the first space 3b of the air-fluid storage means via the flow regulating means 2. As the air pressure increases, the sliding partition 3a is pushed to the right to compress the fluid under test in the second space 3c. At this time, the fluid to be used and the fluid to be tested 5 should be the same fluid. Then, the fluid under test flows into the airtight space of the test object 5 and exerts a positive pressure on the airtight space of the test object 5. The measurer watches the pressure measuring means 4 and adjusts the opening and closing amount of the flow regulating means 2 so that the pressure value meets the airtight test requirement of the test object 5. When the pressure value reaches a predetermined value, a static pressure is applied to the test object 5 in a state where the predetermined pressure is maintained by closing the flow adjusting means 2 completely. At this time, the airtight test is performed by confirming whether the fluid under test leaks out where the airtight of the test object 5 is required.

Now, with reference to Figure 2 will be described the process of performing the airtight test of the test subject 5 under negative pressure conditions. When the air pump 1 is operated, the air in the first space 3b of the air-fluid storage means escapes to the atmosphere through the flow regulating means 2. As the pressure of the first space 3b decreases, the sliding partition 3a moves to the left to expand the second space 3c. Then, the fluids under test in the airtight space of the test object 5 enter the second space 3c of the air-fluid storage means and apply negative pressure to the airtight space of the test object 5. The measurer watches the pressure measuring means 4 and adjusts the opening and closing amount of the flow regulating means 2 so that the pressure value meets the airtight test requirement of the test object 5. When the pressure value reaches a predetermined value, a negative pressure is applied to the test object 5 while the flow control means 2 is completely closed while the proper pressure is maintained. At this time, the airtight test is performed by confirming whether the fluid under test leaks out where the airtight of the test object 5 is required.

As described above, since the airtight test can be performed on the test object 5 under the positive pressure and negative pressure conditions using the same airtight test device, the test time and the cost can be greatly reduced. In addition, accurate testing under environmental conditions is possible. It also ensures the confidentiality of products in industrial packaging and facilitates cause analysis for fault investigations.

In the above, a process in which the airtight test of the test object 5 is manually performed by the measurer has been described, but all of the above airtight tests can be performed automatically. For example, the air pump 1 and the vacuum generator can be selectively connected to the flow regulating means 2 as the air supply means, the electromagnetic flow regulating valve is used as the flow regulating means 2, and the pressure measuring means By using the pressure sensors as (4) and using a programmable controller capable of controlling them, the airtight test in the positive and negative pressure conditions can also be performed electronically.

The positive-negative pressure integrated airtight test apparatus of the present invention can be easily tested at the positive pressure and negative pressure conditions using the same airtight test device, thereby greatly reducing the test time and cost.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (5)

An air-fluid storage means having a sliding partition therein, storing air on a first side about the sliding partition, and storing a test fluid on a second side, and moving the sliding partition according to the pressure of the air; ; Air supply-discharge means for supplying or withdrawing air to the first side of the air-fluid storage means; Flow regulating means fluidly connected between said air supply-discharge means and said air-fluid storage means, and regulating the flow rate of air entering and exiting between said air supply-discharge means and said air-fluid storage means; And And a pressure measuring means for measuring a pressure applied to the test object fluidly connected to the second side of the air-fluid storage means. According to claim 1, Wherein said air supply-discharge means is an air pump having a suction port for sucking air and a discharge port for discharging air. The method of claim 2, The flow control means is fluidly connected to the discharge port of the air pump when the airtight test of the test body under the constant pressure condition, and the inlet port of the air pump when the airtight test of the test body under the negative pressure condition A static-negative pressure tight test apparatus in which flow control means are fluidly connected. According to claim 1, The sliding compartment is a positive-negative pressure tightness test apparatus made of a material containing a rubber. According to claim 1, And said pressure measuring means is fluidly connected between said air-fluid storage means and said test subject.

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