KR102408738B1 - A water pipe system that can reliably provide water with a constant pressure to a building - Google Patents

Abstract

Disclosed is a water pipe system capable of providing water at a constant level of water pressure to a water supply source of a building regardless of a location where the water supply source is installed in a building. For this purpose, a water supply pipe connected to the water storage tank to provide a movement path for moving the water discharged from the water storage tank to the water supply point of the building, a pump unit including one or more pumps installed in the water supply line, and the water supply line connected to the water supply line to supply water Provided is a water piping system including a pressure tank for regulating water pressure in a pipeline, and a compressor connected to the pressure tank to supply a compressed gas to the pressure tank so that the internal pressure of the pressure tank is constantly and automatically maintained. According to the present invention, it is possible to continuously provide a certain level of water pressure even if the amount of water used in the water supply source of the building increases, and it is possible to provide sufficient water pressure regardless of the location of the water supply source in the building.

Description

A water pipe system that can stably provide water with a constant pressure to a building {A WATER PIPE SYSTEM THAT CAN RELIABLY PROVIDE WATER WITH A CONSTANT PRESSURE TO A BUILDING}

The present invention relates to a water pipe system capable of stably providing water with a constant water pressure to a building, and more particularly, to provide water at a constant level of water pressure to a water supply source of a building regardless of a location where the water supply source is installed in a building. It relates to a water pipe system that can be

In the fluid transfer piping system, each pressure tank is installed to prevent water shock caused by sudden changes in flow rate/flow rate in case of sudden stop of the pump or sudden valve closure, or to prevent damage to the piping system due to the expansion/contraction of piping water in the circulation piping system. Included water shock prevention equipment or pressure maintenance equipment (or expansion tank) is provided.

In such a pressure tank, incompressible fluid and compressible gas coexist, and when expansion/contraction or water shock occurs in the piping system, the incompressible fluid inside the pressure tank is discharged to the piping system using the compressible gas, or the incompressible fluid in the piping system is pressurized. By flowing into the tank, the high pressure generated in the piping system is relieved and low or negative pressure is prevented.

The capacity of the pressure tank is determined through the review of pipelines and flow analysis, and the amount of compressed gas required inside the pressure tank is also determined, but this compressed gas is not permanent, and some of it is consumed through leakage from the junction, Some are consumed by dissolving in an incompressible fluid. In addition, the volume of the compressible gas changes according to the pressure of the incompressible fluid in the piping system, which changes the level of the incompressible fluid inside the pressure tank.

The fluctuation of the water level in the pressure tank means the fluctuation of the reference pressure of the entire piping system. When the pressure rises, the equipment or piping in the piping system may be damaged. If the pressure in the piping system decreases to less than the saturated vapor pressure of the liquid, During recombination, the shock wave may damage equipment or piping. Therefore, in order to stably maintain the piping system, the pressure inside the pressure tank and the level of the incompressible fluid should be controlled so that it is always maintained in an appropriate range.

The water level control of the pressure tank is performed by receiving or exhausting compressed air or a compressible gas such as nitrogen in the pressure tank. That is, as shown in FIG. 1, a level transmitter (LT) or a level switch is installed in the pressure tank 10 connected to the piping system, and the water level of the pressure tank 10 in real time by the level transmitter LT or the level switch. is detected When the water level inside the pressure tank 10 rises, the control unit 30 opens the receiving valve S1 to receive the compressible gas from the gas supply device 20 such as an air compressor or a nitrogen generator into the pressure tank 10 to make it incompressible. The level of the incompressible fluid inside the pressure tank 10 is adjusted by lowering the level of the fluid to an appropriate level, and when the water level falls, the exhaust valve S2 is opened to exhaust the gas from the pressure tank 10 to the outside to raise the water level. is maintained in a preset appropriate range.

As described above, in the conventional water pipe system, an air compressor is used to accommodate the compressed air in the pressure tank. In particular, an oil-free air compressor is used in the water pipe system for water supply, and the oil-free air compressor has a characteristic that does not lubricate the friction part, and thus the pressure is usually 10 Bar or less.

However, recently, when water is transported over long distances, such as in the Middle East, or when water is transported to a place with a high drop, the pressure of the pump is operated with a high-pressure system such as 40Bar, 60Bar, or 80Bar, so the pressure tanks installed in these piping systems are also It is operated at high pressure, and the air compressor or gas receiving device accommodated therein must also be operated at high pressure. In particular, an oil-free compressor must be used for sanitary reasons in the piping system that transports drinking water, such as tap water. However, since such a high-pressure oil-free air compressor is not produced, an oil injection compressor (such as oil in the friction part of the compressor) is required to match the capacity. A type of compressor with liquid lubrication) is used and the method of removing oil from the compressed gas is used, but since the oil component is not completely removed, it is impossible to ensure hygiene that does not contain oil components in the high-pressure liquid transport piping system. exist.

In addition, since high-pressure oil-free air compressors are not being produced, a number of 10-bar capacity air compressors must be connected and used to match the corresponding capacity. There is a problem in that the cost is greatly increased and energy consumption is excessive.

Republic of Korea Patent Registration No. 10-1673495 (Notice on Nov. 7, 2016) Republic of Korea Patent Publication No. 10-2020-0111983 (published on October 5, 2020) Republic of Korea Patent Registration No. 10-0300305 (published on Oct. 27, 2001) Republic of Korea Patent Registration No. 10-1392847 (Notice on May 27, 2014)

Accordingly, it is an object of the present invention to provide a water piping system capable of stably maintaining the internal pressure of a pressure tank so as to continuously provide sufficient water pressure to a water supply source regardless of the location where the water supply source of the building is installed and the amount of water used. .

In order to achieve the object of the present invention described above, in one embodiment of the present invention, a water supply pipe connected to a water storage tank and providing a movement path for moving water discharged from the water storage tank to a water supply point of a building, and one installed in the water supply pipe A pump unit including the above pump, a pressure tank connected to the water supply line to control the water pressure in the water supply line, and a pressure tank connected to the pressure tank to automatically maintain a constant internal pressure of the pressure tank. It provides a water pipe system including a compressor for supplying it.

According to the present invention, since the internal pressure of the pressure tank installed to solve the water gap in the water supply pipe can be automatically adjusted using a compressor, a certain level of water pressure can be continuously provided even if the amount of water used in the water supply source of the building increases. It can provide sufficient water pressure regardless of the location of the building water supply source.

In addition, according to the present invention, water having a suitable water pressure for each location of the building can be provided to the low-rise and high-rise parts of the building by using a single compressor operated at a high pressure.

In addition, since the present invention uses a single compressor instead of using separate compressors for the low-rise and high-rise parts of the building, it is possible to increase the efficiency of the installation space.

1 is a block diagram showing a conventional water pipe system.
2 is a configuration diagram for explaining an embodiment of a water pipe system according to the present invention.
3 is a configuration diagram for explaining another embodiment of the water pipe system according to the present invention.
Figure 4 is a perspective view showing a check valve installed in the compression tank according to the present invention.

Hereinafter, a water pipe system (hereinafter, abbreviated as 'water pipe system') capable of providing water of suitable water pressure for each location of a building according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram for explaining an embodiment of a water pipe system according to the present invention.

Referring to FIG. 2 , the water piping system according to the present invention includes a water supply pipe 100 providing a passage for water movement between a water storage tank 600 and a building water supply source, and moving water from the water storage tank 600 to a building water supply source. It includes a pump unit 200 , a pressure tank 300 for adjusting the water pressure in the water supply pipe 100 , and a compressor 400 providing compressed gas to the pressure tank 300 .

Hereinafter, each component will be described in more detail with reference to the drawings.

Referring to FIG. 2 , the water pipe system according to the present invention includes a water supply pipe 100 .

The water supply pipe 100 is connected to the water storage tank 600 , and provides a function of moving the water discharged from the water storage tank 600 to the water supply point of the building.

One end of this water supply pipe 100 is connected to the water storage tank 600 , and the other end opposite to the one end is connected to a faucet or a water meter in a building through a branch pipe.

3 is a configuration diagram for explaining another embodiment of the water pipe system according to the present invention.

The water supply pipe 100 according to the present invention consists of a single water supply pipe installed in a building such as an apartment with the same water fee, or a high-rise pipe 110 and a low-rise pipe ( 120) can be configured.

The high-rise pipeline 110 is connected to the water storage tank 600 , and provides a function of moving water discharged from the water storage tank 600 to a high-rise part of the building. In addition, one end of the high-rise conduit 110 is connected to the water storage tank 600, and the other end opposite to the one end is connected to a high-rise faucet or water meter through a branch pipe.

The high-rise conduit 110 may cover 40 to 60% of the total number of floors of the building, but is not limited thereto. For example, the high-rise conduit 110 may be installed in a building to cover the 13th to 19th to 30th floors when the building has 30 floors.

In other words, in the case of a 30-story building, the high-rise pipeline 110 provides a passage through which water to be used for each floor is moved from the 13th to the 19th to the 30th floors.

On the other hand, the low-rise conduit 120 is connected to the water storage tank 600 and provides a movement path for moving the water discharged from the water storage tank 600 to the lower part of the building. One end of such a low-level conduit 120 is connected to the water storage tank 600, and the other end opposite to the one end is connected to a faucet or a water meter of the lower level.

In addition, the low-rise conduit 120 may be in charge of 40 to 60% of the total number of floors of the building, but is not limited thereto. For example, the low-rise conduit 120 may be installed in the building to cover the first to the 12th to 18th floors when the building has 30 floors.

In other words, in the case of a 30-story building, the low-rise conduit 120 provides a movement path through which water to be used for each floor is moved from the 1st floor to the 12th to 18th floors.

Referring to FIG. 2 , the water pipe system according to the present invention includes a pump unit 200 .

The pump unit 200 includes one or more pumps 202 , 204 , and 206 installed in the water supply pipe 100 , and provides a function of moving the water discharged from the water storage tank 600 to the water supply point of the building.

The number of pumps included in the pump unit 200 is not particularly limited because it may change according to the number of floors of the building. For example, the pump unit 200 may be composed of two to five pumps. In this case, the first pump 202 is a lead pump that starts operation at the time of initial operation, and the remaining pumps 202 and 204 are leg pumps that start operation when the capacity of the lead pump is insufficient.

As a specific aspect, the pump unit 200 according to the present invention may include a first pump unit 210 and a second pump unit 210 as shown in FIG. 3 .

The first pump unit 210 includes one or more pumps 212 , 214 , 216 installed in the high-rise pipeline 110 , and provides a function of moving the water discharged from the water storage tank 600 to the water supply point of the high-rise part of the building.

The number of pumps included in the first pump unit 210 is not particularly limited because it may change according to the number of floors of the building. For example, when the building has 30 floors, the first pump unit 210 may include 3 to 5 pumps.

The pump constituting the first pump unit 210 pressurizes the water at a pressure of about 12 bar or the like in order to transport the water stored in the water storage tank 600 to a long distance along the high-rise pipeline 110 .

On the other hand, the second pump unit 220 includes one or more pumps 222 and 224 installed in the low-rise conduit 120, and provides a function of moving the water discharged from the water storage tank 600 to the water supply point of the lower level of the building.

The number of pumps included in the second pump unit 220 is not particularly limited because it may change according to the number of floors of the building. For example, when the building has 30 floors, the second pump unit 220 may include two to three pumps.

The pump constituting the second pump unit 220 pressurizes the water at a pressure of about 8 bar or the like in order to transport the water stored in the water storage tank 600 to a long distance along the low-rise conduit 120 .

Figure 4 is a perspective view showing a check valve installed in the compression tank according to the present invention.

Referring to FIG. 2 , the water pipe system according to the present invention includes a pressure tank 300 .

The pressure tank 300 is connected to the water supply line 100 to adjust the water pressure in the water supply line 100 , and the water moving along the water supply line 100 using a compressed gas provided from the outside has a certain level of water pressure. provide pressure to maintain

The pressure tank 300 maintains the internal pressure at a constant level through the compressed gas provided from the compressor 400 so that water of a constant pressure is supplied to the water supply source regardless of the location of the water supply source connected to the water supply pipe 100 . function is provided.

Referring to FIG. 3 , the pressure tank 300 according to the present invention may include a first pressure tank 302 and a second pressure tank 304 .

The first pressure tank 302 is connected to the high-rise pipe line 110 to control the water pressure in the high-rise pipe line 110, and the water moving along the high-rise pipe line 110 by using a compressed gas provided from the outside is at a certain level. provide pressure to maintain the water pressure of

As a specific aspect, the first pressure tank 302 according to the present invention includes a jacket (not shown), a housing (not shown), a check valve 310, and a pressing means 320, and optionally a drain It is configured to further include a valve (not shown).

The jacket is provided with an outlet communicating with the high-rise conduit 110, and water is accommodated therein, and is made of an elastic material such as rubber so that it can be contracted and expanded. This jacket fills water through the high-rise pipe line 110 as the first pump unit 210 operates, and pressurizes the water moving along the high-rise pipe line 110 through contraction to maintain a certain level of water pressure. to provide.

The housing is installed on the outside of the jacket so that a space for accommodating the compressed gas is formed between the housing and the jacket, and a gas inlet communicating with the compressor 400 is provided. Such a housing provides a sealed space so that the compressed gas provided from the compressor 400 does not escape through the gas inlet.

In addition, the housing adjusts the pressure applied to the jacket by adjusting the amount of compressed gas accommodated therein. To this end, the housing may be provided with a pressure sensor that generates a pressure signal by sensing internal pressure and provides the pressure signal to the control panel.

When the compressor 400 is operated under the control of the control panel, the first pressure tank 302 increases the internal pressure with the compressed gas provided from the compressor 400, and when the internal pressure of the housing is gradually increased and the accumulating pressure is completed to a specified value, The compressor 400 is stopped under the control of the control panel. At this time, the control panel analyzes the pressure signal provided from the pressure sensor to determine the stop time of the compressor 400 , and controls the compressor 400 to stop the compressor 400 .

Then, when the internal pressure of the housing decreases to the restart set point, the control panel restarts the compressor 400 . At this time, the control panel analyzes the pressure signal provided from the pressure sensor to determine the restart time of the compressor 400 , and controls the compressor 400 to operate the compressor 400 .

Subsequently, when the internal pressure of the housing reaches the stop set point, the control panel controls the compressor 400 to stop the compressor 400 . At this time, the control panel analyzes the pressure signal provided from the pressure sensor to determine the stopping point of the compressor 400 , and controls the compressor 400 to stop the compressor 400 .

The check valve 310 is installed at the gas inlet, and controls the inflow of the compressed gas supplied to the housing. The check valve 310 opens the inlet when a physical pressure is applied to the inlet from the outside, and closes the inlet when the action of the physical pressure is resolved. At this time, the check valve 310 of the first pressure tank 302 and the compressor 400 are connected by a hose or a pipe.

The pressing means 320 is installed at the inlet of the check valve 310 as shown in FIG. 4 , and is a check valve such that the compressed gas provided from the compressor 400 is supplied to the housing through the inlet of the check valve 310 . It serves to continuously open the inlet of the 310.

More specifically, the pressing means 320 includes an assembly pipe 322 having a spiral portion formed on its inner circumferential surface so as to be assembled to the spiral portion formed in the inlet of the check valve 310, and a support plate 324 installed at the rear end of the assembly pipe 322, And it is connected to the front surface of the support plate 324 and is formed with a length longer than the assembly pipe 322 so as to protrude to the tip of the assembly pipe 322 and is interpolated into the inlet of the check valve 310. Including a pressing rod 326 can be configured.

The assembly pipe 322 may be formed in a tubular or annular structure in which a hollow is formed and the front and rear ends are opened, and the check valve 310 through clockwise rotation or counterclockwise rotation depending on the structure of the spiral part. It can be assembled at the inlet of

The support plate 324 connects the assembly tube 322 and the pressing rod 326 so that the pressing rod 326 can be installed at the center of the rear end of the assembly tube 322, and a plurality of pressurized gases can pass therethrough. It may be formed in a disk structure with through-holes, or may be formed in a cross-shaped or X-shaped structure.

The drain valve is installed in the housing of the first pressure tank 302, and provides a function of discharging moisture formed when the gas is compressed in the housing to the outside of the housing.

On the other hand, the above-described second pressure tank 304 is connected to the low-rise pipe line 120 to adjust the water pressure in the low-level pipe line 120, and the water moving along the low layer pipe line 120 using a compressed gas provided from the outside. A pressure is provided to maintain this constant level of water pressure.

As a specific aspect, the second pressure tank 304 according to the present invention includes a second jacket (not shown), a second housing (not shown), a second check valve (not shown), and a second pressing means ( not shown), and optionally further comprising a second drain valve (not shown).

The second jacket is provided with an outlet communicating with the low-rise conduit 120, and water is accommodated therein, and is made of an elastic material such as rubber so that it can be contracted and expanded. This second jacket fills water through the low-rise pipe line 120 as the second pump unit 220 operates, and allows the water moving along the low-rise pipe line 120 through contraction to maintain a certain level of water pressure. provide pressure.

The second housing is installed outside the second jacket so that a space for accommodating the compressed gas is formed between the second housing and the second jacket, and a gas inlet communicating with the compressor 400 is provided. The second housing provides a sealed space so that the compressed gas provided from the compressor 400 does not escape through the second gas inlet. In addition, the second housing adjusts the pressure applied to the second jacket by adjusting the amount of compressed gas accommodated therein.

The second housing may be provided with a pressure sensor that generates a pressure signal by sensing internal pressure and provides the pressure signal to the control panel. At this time, the control panel controls the operation of the compressor so that the pressure inside the second pressure tank is adjusted like the above-described first pressure tank.

The second check valve is installed at the second gas inlet, and controls the inflow of the compressed gas supplied to the second housing. This second check valve opens the inlet when a physical pressure is applied to the inlet from the outside, and closes the inlet when the action of the physical pressure is resolved. At this time, the second check valve of the second pressure tank 304 and the compressor 400 are connected by a hose or a pipe.

The second pressing means is installed at the inlet of the second check valve, and the inlet of the second check valve is continuously opened so that the compressed gas provided from the compressor 400 is supplied to the second housing through the inlet of the second check valve. perform the role of

More specifically, the second pressing means includes a second assembly pipe having a spiral portion formed on an inner circumferential surface so as to be assembled to the spiral portion formed in the inlet of the second check valve, a second support plate installed at the rear end of the second assembly tube, and the second support plate It is connected to the front surface of the second assembly pipe is formed to have a longer length than the second assembly pipe so as to protrude to the tip of the second assembly pipe may be configured to include a second pressing rod that is interpolated into the inlet of the second check valve.

The second assembly pipe may be formed in a tubular or annular structure in which a hollow is formed and the front and rear ends are open, and the inlet of the second check valve through clockwise rotation or counterclockwise rotation depending on the structure of the spiral part. can be assembled on

The second support plate connects the second assembly tube and the second pressing rod so that the second pressing rod can be installed at the center of the rear end of the second assembly tube, and a disk having a plurality of through-holes to allow compressed gas to pass therethrough. It may be formed in a structure or may be formed in a cross-shaped or cross-shaped structure.

The second drain valve is installed in the housing of the second pressure tank 304, and provides a function of discharging moisture formed when the gas is compressed in the housing to the outside of the housing.

2 and 3 , the water pipe system according to the present invention includes a compressor 400 .

The compressor 400 is connected to the pressure tank 300 , and supplies compressed gas to the pressure tank 300 so that the internal pressure of the pressure tank 300 is automatically maintained constant.

When the compressor 400 is installed in a low-rise building, it provides a level of compressed gas required for the low-rise building.

In addition, when the compressor 400 is installed in a high-rise building, it provides a required level of compressed gas to the high-rise part of the high-rise building. At this time, since water having a water pressure higher than the required level of water pressure is supplied to the lower part of the high-rise building through the water supply pipe 100, the water pressure is reduced to the required level through the pressure reducing valve installed in the water meter connected to the water supply pipe 100. lowers it

Referring to FIG. 3 , the compressor 400 according to the present invention may be connected to the first pressure tank 302 and the second pressure tank 304 . At this time, the compressor 400 supplies the required level of compressed gas to the first pressure tank 302 to the first pressure tank 302 and the second pressure tank 304 .

In other words, the compressor 400 supplies the first pressure tank 302 and the second pressure tank 304 with a higher level of compressed gas than the level required for the second pressure tank 304 to be suitable for maintaining the water pressure of the high-rise pipeline 110 . ) are provided for each. At this time, the working pressure (pressing pressure) of the compressor 400 is preferably 11 to 20 Bar.

Nitrogen gas or air may be used as a compressed gas provided by the compressor 400 to the first pressure tank 302 and the second pressure tank 304 . To this end, the compressor 400 is provided with a nitrogen generator at the rear end may be configured to supply nitrogen instead of air.

The water pipe system according to the present invention may further include a gas supply control valve (not shown).

The gas supply control valve is installed in the pipeline between the compressor 400 and the first pressure tank 302 and between the compressor 400 and the second pressure tank 304, and the compressed gas is supplied to the pressure tank. It provides the ability to control things.

The gas supply control valve may be configured to open and close only for a certain period of time so that an appropriate amount of compressed gas is accommodated in the pressure tank. It is also possible to control the pressure tank to be filled with a certain amount (or pressure) of compressed gas.

Referring to FIG. 3 , the water pipe system according to the present invention may further include a regulator 500 .

The regulator 500 is installed between the compressor 400 and the second pressure tank 304, and reduces the pressure of the compressed gas supplied from the compressor 400 to be suitable for the lower part of the building. For example, the regulator 500 depressurizes the internal pressure of the second pressure tank 304 by the compressed gas provided to the second pressure tank 304 to maintain a level of 6 to 10 Bar.

To this end, the regulator 500 may be installed at the outlet of the compressor 400 connected to the second pressure tank 304, or may be installed in a pipeline connecting the regulator 500 and the second pressure tank 304, , it may be installed at the inlet of the second pressure tank 304 connected to the compressor 400 .

The water pipe system according to the present invention may further include a pressure intensifier (not shown).

The pressure intensifier is installed between the pressure tank 300 and the compressor 400 , and serves to increase the pressure of the compressed gas supplied from the compressor 400 to the pressure tank 300 .

In this pressure intensifier, when the operating pressure (pressurization pressure) of the compressor 400 is insufficient to be used in a building in which the water pipe system of the present invention is installed, the air pressure of the compressed gas supplied from the compressor 400 to the pressure tank 300 is increased. boosts it For example, the pressure intensifier increases the air pressure of the compressed gas supplied from the compressor 400 to about two times the air pressure of the compressed gas.

To this end, the pressure intensifier may be installed at the outlet of the compressor 400 connected to the pressure tank 300 , or may be installed in a pipe connecting the pressure tank 300 and the compressor 400 , and the compressor 400 and It may be installed at the inlet of the connected pressure tank 300 .

Although described above with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the following claims. You will understand that you can.

100: water supply pipe 110: high-rise pipe
120: low-rise pipeline 200: pump unit
210: first pump unit 220: second pump unit
300: pressure tank 302: first pressure tank
304: second pressure tank 310: check valve
320: pressing means 322: assembly pipe
324: support plate 326: press bar
400: compressor 500: regulator
600: water tank

Claims (7)

A high-rise conduit connected to the water storage tank to provide a movement path for moving water discharged from the water storage tank to a water supply source in a high-rise part of a building, and a low-rise building connected to the water storage tank to provide a movement path for moving the water discharged from the water storage tank to the water supply source in the lower part of the building water supply conduit consisting of conduit;
a pump unit including a first pump unit including one or more pumps installed in the high-rise conduit, and a second pump unit including one or more pumps installed in the low-rise conduit;
a pressure tank including a first pressure tank connected to the high-rise pipeline to control water pressure in the high-rise pipeline, and a second pressure tank connected to the low-rise pipeline to adjust the water pressure in the low-rise pipeline;
a compressor connected to the first pressure tank and the second pressure tank to supply a compressed gas having a pressure set to 11 to 20 Bar based on the first pressure tank to the first pressure tank and the second pressure tank; and
A regulator installed between the compressor and the second pressure tank to reduce the air pressure of the compressed gas supplied from the compressor so that the internal pressure of the second pressure tank maintains a level of 6 to 10 Bar,
The first pressure tank
A jacket that is provided with an outlet communicating with the high-rise pipeline and made of rubber so that water can be accommodated and contracted and expanded;
a housing installed outside the jacket to form a space for accommodating the compressed gas between the jacket and the housing provided with a gas inlet communicating with the compressor;
a check valve installed in the gas inlet, and
An assembly pipe having a spiral portion formed on the inner circumferential surface so as to be installed at the inlet of the check valve and assembled to the spiral portion formed at the inlet of the check valve so as to continuously open the inlet of the check valve, and installed at the rear end of the assembly pipe, the compressed gas A support plate formed in a disc structure having a plurality of through-holes to pass through, or formed in a cross or X-shaped structure, and connected to the front surface of the support plate and formed to a length longer than the assembly tube to protrude from the tip of the assembly tube, the check A water piping system comprising a pressing means including a pressing rod interpolated into the inlet of the valve. delete delete delete delete delete delete

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