KR20130118679A - A pressure control device for gas drop test and leakage test - Google Patents

Abstract

PURPOSE: A pressure control device for a pipe seal test is provided to rapidly and simply perform the seal test of the vertical pipe or underground pipe of the building to be constructed, thereby shortening the work process and finely controlling the minute amount of seal test pressure in a manual manner. CONSTITUTION: A pressure control device for a pipe seal test includes a pressure measuring unit (40), a pressing device (20), and a minute pressure controller (30). The pressure measuring unit is installed in the end portion of the connection line (10) of a pneumatic pipe (1). The pressuring device is branched and installed to the connection line. The minute pressure controller includes a pressure/backpressure member (32) and a minute pressure control button (31). The pressure/backpressure member is formed to have a ball shape. The minute pressure control button is installed on the front portion of the pressure/backpressure member.

Description

Pressure control device for pipe tightness test {a pressure control device for gas drop test and leakage test}

The present invention relates to a pressure regulating device for a gas tightness test, and more particularly, the airtightness test of a pipe connected to a standing pipe exposed to the wall of a building or to a pipe installed on the wall or floor of a basement or a building is easily connected. It can be carried out, and relates to a pressure or discharge control device for the pressure of the pipe tightness test that can easily implement the fine pressure control.

In general, city gas, water, heating water, and firefighting water supplied to each consumer form a pipeline in the form of granular piping installed in a basement or a floor of a building such as an apartment or a building. It consists of a structure in which a plurality of pipes are connected to each other.

In addition, the pipe line is a plumbing operation for supplying the city gas, water supply, heating and fire water, etc., and a pressure tightness test is carried out to check the gas leak or leakage of the constructed pipe.

In this case, in order to perform a pressure tightness test of the pipe, a pressure measuring means is installed at one end of the pneumatic pipe and an inert gas such as air, carbon dioxide, or nitrogen is injected from the other end of the pneumatic pipe, or the one end of the pneumatic pipe is pressed. Finish with shut-off valve or prefabricated cap for pressure test, pressurize by injecting inert gas from the other end of pneumatic pipe, and use pressure measuring means to closely check whether internal pressure is deteriorated or leaked after a certain time. To do so.

In other words, the above pipe pressure tightness test is a test for checking whether there is a leak after injecting pressurized air, carbon dioxide, or inert gas such as nitrogen into the pneumatic pipe, and the gas leakage phenomenon should not occur in the pressure range of the specified tightness test. The pressure tightness test is to be carried out by connecting a pressurization device and a pressure measuring means (electronic manometer, magnetic pressure recorder, etc.) to the pneumatic pipe in order.

On the other hand, in the case of low-pressure pipes for city gas, the gas tight test pressure should not cause gas leakage at a pressure of 1.1 times the maximum working pressure or 8.4 kPa or more, and in the case of an electronic manometer widely used as a pressure measuring means. The pressure range for low pressure measurement is set to 0 to 1,000 H ₂ O (= 9.81 kPa), and the pressure range for medium and low pressure measurements is 0 to 2 kgf / cm ² (= 196.1 kPa).

Therefore, if the pressure is exceeded 9.81 kPa to the electronic manometer set for low pressure measurement, the pressure measurement sensor of the electronic manometer will not only cause failure due to overpressure, but also rupture or crack in the low pressure pipe fittings or accessories. Leaks occur, so it must be pressurized to 8.4 kPa or more and 9.81 kPa or less, which is the airtight test pressure range for the pressure to be measured.

As described above, the conventional pipe pressure tightness test not only delays work time in that the pressurizing device and the pressure measuring means are separately installed in the pneumatic pipe 1, but also the low pressure when pressurizing the overpressure tightness test pressure to the low pressure pipe. This may cause gas leakage, rupture, or breakdown of the digital pressure gauge.

In addition, since there is no dedicated confidentiality test pressure control device, it is impossible to establish a systematic and standardized confidentiality test work procedure. Therefore, there is a high probability of the occurrence of safety accidents due to human error such as arbitrary work of the worker. There is no problem.

The present invention has been made to solve the above problems, an object of the present invention is to provide a pressure control device for a gas tight test that can easily implement the fine pressure control and ensure the reliability of the pressure control.

Pressure control device for the gas tightness test according to the present invention for achieving the above object is branched to the pressure measuring means 40 and the connection line 10 is installed at one end of the connection line 10 of the pneumatic pipe (1) Composed of a pressurizing device 20 and a fine pressure control device 30 is installed, the fine pressure control device 30 is a ball-shaped pressing / back pressure member 32 and all of the pressing / back pressure member (32) It is formed of a fine pressure control button 31 is installed. In addition, the pressurizing device 20 is characterized in that the hand pump or other pneumatic generator (inert gas cylinder, compressor, blower, etc.) consisting of the cylinder 21 and the piston 22.

In addition, the pressurizing device 20 and the micro-pressure control device 30 is installed in each branch line 10 or installed in the connection line 10, characterized in that the branch is installed through the three-way valve 50 is installed. do.

As described above, the present invention enables a quick and simple airtight test of a standing pipe or underground buried pipe of a building to be constructed, so that the work process can be shortened and a small amount of airtight test pressure can be finely controlled by a manual method. .

In addition, by establishing a systematic and standardized pressure tightness test procedure using a dedicated tightness test pressure control device, external reliability of pipe tightness test can be secured by improving work efficiency and preventing safety accidents caused by human error. Can be.

1 is a block diagram of a pressure adjusting device for a gas tight seal test according to an embodiment of the present invention.
Figure 2 is a block diagram of a pressure control device for a pipe tightness test provided with a three-way valve according to an embodiment of the present invention.

Exemplary embodiments will now be described with reference to the accompanying drawings to help understand the technical means for achieving the above object and effects thereof.

First, referring to FIG. 1, the present invention relates to a pressure control device for a pipe tightness test, and finishes at one end of the pneumatic pipe 1 with a shutoff valve or a prefabricated cap for pressure test, and the other side of the pneumatic pipe 1. The intermediate valve (2) is installed at the end, and the front end of the intermediate valve (2) is inserted into the end of one side (11) of the connection line (10), such as a pneumatic hose, and is connected and mounted by a fixing member such as a hose band. Branching the pressure measuring means 40 and the connection line 10 at the other end 12 of the (10) is provided with a pressure device 20 and a fine pressure control device 30 is formed.

The pressurization device 20 is a pneumatic generator that pressurizes by injecting inert gas such as air, carbon dioxide, or nitrogen into the pneumatic pipe 1 through the connection line 10, and in the case of the pneumatic pipe 1 being a low pressure short-range pipe, a cylinder ( 21) and a piston 22, a hand pump is used. In the case of a medium pressure or low pressure long distance pipe, an inert gas bomb, a compressor, a blower, and the like are pressurized.

In the case of low-pressure pipes for city gas, the airtight test pressure should not occur gas leakage at a pressure of 1.1 times the maximum working pressure or more than 8.4 kPa, and an electronic manometer, which is a digital pressure gauge widely used as the pressure measuring means 40, manometer), the low pressure measurement manometer is 0 ~ 1,000 H ₂ O (= 9.81 kPa), and the medium / low pressure measurement 0 ~ 2 kgf / cm ² (= 196.1 kPa) If pressure exceeding 9.81 kPa is applied to the pressure sensor, the pressure sensor will not only fail due to overpressure, but also gas leaks due to rupture or cracks in the low pressure pipe fittings and fittings. It should be pressurized from 8.4 kPa or more to 9.81 kPa or less.

In the embodiments of FIGS. 1 and 2, the main functions and names of the electronic manometer used as the pressure measuring means 40 are as follows. The display unit 41 displays the pressure measurement value on the LCD display window.The measurement time setting button 42 sets the measurement time at intervals of 1 to 60 minutes at the time of initial value and final value measurement. Set the absolute zero (0) ignoring the weak change, the power button 44 is set to turn the power on when the button is pressed for 2 seconds, the power is turned off by pressing the button again in the ON state, the setting mode button 45 is low -Low / medium pressure-high pressure The measuring pressure sensor changes to low pressure.

The pressure measuring means 40 closely measures whether the internal pressure of the pneumatic pipe 1 is lowered or there is a gas leak using a digital manometer, a magnetic manometer, a magnetic pressure recorder, or the like.

The micro-pressure control device 30 is formed of a pressure-sensitive back / back pressure member 32 and the pressure-sensitive control button 31 is installed on all of the pressure / back pressure member 32, Figures 1, 2 of the present invention In the embodiment, the pressing / back pressure member 32 has a hollow ball shape having one elasticity, and a pressure reducing control button 31 is formed on one side and a hole is formed on the other side, so that the micro pressure control button 31 is manually operated. By operating the gas in a very small amount of pneumatic pipe (1) to the outside at high speed or by pressing the back / back pressure member 32 by hand to carry out the pressure operation to send the gas to the pneumatic pipe (1) It will function to control the size of the emissions.

In addition, the pressurizing device 20 and the micro pressure regulating device 30 are branched to the connection line 10, respectively, and the first and second valves 51a at the front end of the pressurizing device 20 and the micro pressure adjusting device 30, respectively. and b) to selectively block the flow of inert gas such as air, carbon dioxide, and nitrogen, and the valves 51a and b use a shutoff valve such as a cock or a ball valve.

Referring to Figure 2, the pressurizing device 20 and the fine pressure control device 30 is installed in the connection line 10, but the embodiment is installed through the three-way valve 50 is installed, the three-way valve By the 50 to selectively block the gas flow of the pressurizing device 20 and the micro-pressure control device 30, an additional shut-off valve is not essential, but pressurizing the first and second valves (51a, b) Installed at the front end of the device 20 and the micro-pressure regulator 30 to improve the airtightness by blocking the flow of the fluid in a double.

Referring to the method of the pressure tightness test using the structure of the present invention based on the embodiment of Figure 2 as follows.

One end of the low pressure pneumatic pipe 1 is closed with a shutoff valve or a test pressure cap, and an intermediate valve 2 is installed at the other end of the pneumatic pipe 1 to provide the intermediate valve 2 ) All of the intermediate valve (2) is connected to the connecting line (11) by mounting with a fixing member such as a lake band, so that the pressurizing device (20) and the micro pressure regulating device (30) are connected to the connecting line (10). Connect and fix the pressure control device for airtight test branched through. The three-way valve 50 is operated to smoothly flow the fluid between the pressurizing device 20 and the pneumatic pipe 1, and then pressurizes the inert gas into the pneumatic pipe 1 through the pressurizing device 20 to pressurize the pressure. Using the electronic manometer as the measuring means 40, after increasing the internal pressure of the pneumatic pipe 1 so that the measurement value of the display part 41 of the electronic manometer is 8.4 kPa or more, close the intermediate valve 2 and the electronic manometer Check that the measured value does not decrease.

In order to finely adjust the internal pressure of the pneumatic pipe 1 so that the pressure measurement value of the electronic manometer is within the airtight test range, that is, 8.4 kPa or more and 9.81 kPa or less, the micro pressure regulator 30 and the pneumatic pipe 1 Operate the three-way valve 50 so that the fluid flows smoothly between the two, and then manually operate the micro pressure control button 31 when the internal pressure of the pneumatic pipe 1 exceeds the set upper limit pressure (ie, 9.81 kPa). The gas in the pneumatic pipe 1 is discharged to the outside through the pressing / back pressure member 32 at a very high speed to lower the pressure. If the internal pressure of the pneumatic pipe 1 is less than the set lower limit pressure (ie, 8.4 kPa), the pressurizing operation is carried out by holding the provisional / back pressure member 32 by hand to move the gas through the pneumatic pressure control button 31. The gas is sent to 1) and the gas is stopped when the pressure reaches the set lower limit pressure (ie 8.4 kPa).

When the measured value of the electronic manometer is lowered, apply soapy water (or leak detection liquid, etc.) to the area where the leakage of the pneumatic pipe (1) is expected to be leaked, repair it, and perform the airtight test again in the same manner as before. If the measured value of the electronic manometer is not lowered for more than a predetermined time, the tightness test is regarded as a pass.

This makes it easy to implement fine pressure control of the pneumatic pipe 1 so that the internal pressure of the pneumatic pipe 1 for airtight test fits within the prescribed airtight test pressure range, and to ensure the reliability of pressure control. An adjustment device can be provided.

1: pneumatic piping 2: intermediate valve
10: connection line 11: intermediate valve connection line
12: pressure measuring means connecting line 20: pressurization device
21: cylinder 22: piston
30: fine pressure control device 31: fine pressure control button
32: pressing / back pressure member 40: pressure measuring means
41: LCD 42: Measurement time setting button
43: Zero adjustment button 44: Power button
45: setting mode button 50: three-way valve 51a, b: first and second valve

Claims (5)

A pressure measuring means 40 installed at an end of the connection line 10 of the pneumatic pipe 1; Pressure control device for the gas tightness test characterized in that it consists of a pressurizing device 20 and the fine pressure control device 30 is installed branched to the connection line 10.
The pressure control device of claim 1, further comprising: a pressing / back pressure member (32) in the form of a ball; Pressure regulating device for the gas tightness test characterized in that it is formed of a fine pressure adjustment button 31 installed on all of the temporary / back pressure member (32)
According to claim 1, wherein the pressurizing device 20 is a pressure control device for the gas tightness test, characterized in that the hand pump consisting of the cylinder 21 and the piston 22.
According to claim 1, Pressurizing device 20 and the fine pressure control device 30 is a pressure control device for the gas tightness test, characterized in that each branched to the connection line (10).
According to claim 1, wherein the pressurizing device 20 and the fine pressure control device 30 is installed in the connection line 10, the pressure control device for the pipe tightness test, characterized in that branched through the three-way valve (50).

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