KR200491289Y1 - Apparatus for testing connecting pipe blockage - Google Patents

Abstract

The present invention relates to a conduction performance test apparatus, the coupling coupling 110 and the connection coupler installed in the piping 5 of the reinforcement liquid automatic fire extinguishing facility connecting the reinforcement liquid container 1 and the injection nozzle 7 It is provided in the ring 110 and is provided in the inlet 115 through which water is injected for the conduction performance test of the piping 5 of the strengthening liquid automatic fire extinguishing facility and the connection coupling 110, and into the inlet 115 It includes a conduction performance test valve 120 for opening and closing the connection of the flow path for supplying the injected water to the injection nozzle 7 or the flow path for supplying the reinforcement liquid of the reinforcement liquid container 1 to the injection nozzle 7 do.
The present invention is advantageous in that it is easy to check the performance of the piping portion and the spray nozzle of the reinforcing liquid automatic fire extinguishing facility, and also to clean the inside of the piping portion and the spray nozzle of the reinforcing liquid auto fire extinguishing facility for a long time.

Description

Continuity performance tester {APPARATUS FOR TESTING CONNECTING PIPE BLOCKAGE}

The present invention relates to a conduction performance test apparatus, and more particularly, to a conduction performance test apparatus for confirming the performance of the piping portion and the spray nozzle of the automatic fire extinguishing equipment for strengthening liquid.

Most of the fires at the inlet cable connection of underground transmission are electrical fires caused by overcurrent, electrical short circuits, and breakdown, and the risk of combustion expansion is very high. Accordingly, it is impossible to extinguish and suppress a fire with a general water-based fire extinguishing facility. Therefore, in the event of a fire in the underground transmission cable, an automatic fire extinguishing facility is installed to extinguish the fire early.

As shown in FIG. 1, the automatic strengthening liquid extinguishing facility embeds the strengthening liquid container 1 filled with the strengthening liquid into the sliding liquid container container 3, and strengthens the liquid container through the piping part 5 ( 1) is connected to the injection nozzle (7), it is configured to discharge the reinforcement liquid to the inlet cable (L) through the piping portion (5) and the injection nozzle (7) when a fire signal occurs.

The reinforced liquid automatic fire extinguishing facility is performing a performance verification test as there is a risk of spreading to a large fire in the event of a fire due to impossibility of discharging the reinforced liquid in the event of a clogging of the piping and spray nozzle.

The method is to fill the test reinforcing liquid container with the same amount of water and nitrogen as the reinforcing material, and simulate a fire signal to check whether the test water and nitrogen in the reinforcing liquid container are actually discharged through the piping and spray nozzle. will be.

This inspection method is complicated in procedures such as bringing the test solution container to the site and installing it in the automatic solution extinguishing solution, and it takes a long time to install, and generates a high cost of about millions of won per test site. Therefore, instead of checking all of the automatic extinguishing facilities, we are currently performing performance verification tests at only one of several locations, once every five years as an excerpt.

In addition, the automatic fire extinguishing facility of the reinforcing solution is clogged by adhering foreign substances to the piping section and the spray nozzle over time, so in the case of a long-term non-operating automatic fire extinguishing facility, the clogging of the piping section and the spray nozzle occurs during the performance verification test There is.

Therefore, there is currently no method for verifying the performance of piping parts and spray nozzles of the long-term non-operation strengthening liquid automatic fire extinguishing facility.

The purpose of the present invention is to provide a conduction performance test device that is easy to check the performance of the piping part and spray nozzle of the reinforced liquid automatic fire extinguishing facility, and also can clean the inside of the piping part of the reinforced liquid automatic fire extinguishing facility and the spray nozzle. will be.

According to the features of the present invention for achieving the above object, the present invention is provided in the coupling coupling and the coupling coupling installed in the piping portion of the reinforcement liquid automatic fire extinguishing equipment connecting the reinforcement liquid container and the spray nozzle. For the conduction performance test of the pipe part of the automatic fire extinguishing system, the inlet for injecting water and the connection coupling, and for supplying water injected into the inlet through the injection nozzle, the reinforcing solution in the flow passage or the reinforcement container It includes a conduction performance test valve for opening and closing the connection of the flow path supplied to the injection nozzle.

The piping portion of the automatic liquid extinguishing facility includes a discharge pipe connected to the reinforcement liquid container and a supply pipe supplying the reinforcing liquid discharged to the discharge pipe to the injection nozzle, wherein the connection coupling comprises the discharge pipe and the It is installed in a position where the connection part of the supply pipe is separated.

The connection coupling forms a first flow path and forms a first connection portion connected to the discharge pipe and a second flow path on the same axis as the first flow path, and a second connection portion and the first flow path connected to the supply pipe And a third connection part forming a third flow passage perpendicularly crossing the second flow passage and having the injection port formed therein to connect the water injection pipe.

The conduction performance test valve is disposed at a position where the first flow path, the second flow path, and the third flow path intersect, and is located outside of the connection ball and the coupling coupling formed with a three-way flow path and connected to the rotation ball and the shaft. It includes a rotating operation unit for rotating the rotating ball so that the first to third passages selectively communicate.

A check valve is provided in the third flow path to prevent the reinforcement liquid from flowing back into the injection port when the reinforcement liquid is released.

The connection coupling is provided with a display unit for checking whether the conduction performance test valve is opened or closed.

Rotate the conduction performance test valve to connect a flow path to supply water injected into the injection port to the injection nozzle, connect a water injection pipe to the injection port, and supply water to the connection coupling through the water injection pipe. Supply, and check the water injection state of the spray nozzle.

It includes a water tank for injecting water into the inlet, the water pressure when injecting water from the water tank to the inlet is the same as the discharge pipe working pressure.

The conduction performance test is performed by checking the water injection state of the injection nozzle, and after the conduction performance test, the water injection pipe is removed from the inlet, and the conduction performance test valve is rotated to turn the conduction performance test valve to strengthen the liquid The flow path to supply the injection nozzle is connected.

A plurality of injection nozzles are installed toward the underground transmission inlet cable, and the piping portion of the automatic strengthening liquid is branched to a plurality of ends to be connected to the injection nozzles.

The present invention is installed in the piping of the automatic fire extinguishing equipment to connect the water injecting pipe to the inlet and rotate the rotating operation part of the conduction performance test valve to change the flow path to perform the conduction performance test of the piping and injection nozzle.

Therefore, it is easy and convenient to check the condition of the piping part and spray nozzle of the automatic fire extinguishing facility, and it is often possible to perform a performance test of the piping part and the spray nozzle when you want to inspect the piping part of the automatic fire extinguishing facility, and it is necessary for testing. Since the time required is short and the inspection cost is low, economical cost can be greatly reduced. This has the effect of increasing the safety of the incoming cable for underground transmission and thereby increasing the stability of the domestic power system.

1 is a block diagram showing a conventional strengthening liquid automatic fire extinguishing equipment.
Figure 2 is a schematic view showing an automatic fire extinguishing facility for strengthening solution to which the conduction performance test apparatus according to an embodiment of the present invention is applied.
Figure 3 is a front view showing a conduction performance test apparatus according to an embodiment of the present invention.
4 and 5 is an internal configuration showing a method of using the conduction performance test apparatus according to an embodiment of the present invention.
6 and 7 is an internal configuration showing a method of using the conduction performance test apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the conduction performance test apparatus of the present invention is installed in the piping part 5 of the automatic fire extinguishing facility for strengthening solution, and confirms the conduction state of the piping part 5 of the automatic fire extinguishing system for strengthening solution, and the spray nozzle ( Check the release performance of 7).

The piping part 5 of the automatic fire extinguishing facility connects the reinforcement liquid container 1 and the injection nozzle 7. The strengthening liquid container 1 is filled with a strengthening liquid as an extinguishing agent. A plurality of injection nozzles 7 are installed toward the underground transmission inlet cable L. The piping portion 5 of the automatic strengthening liquid is branched to a plurality of terminals at the end and is connected to the injection nozzles 7.

The conduction performance test apparatus 100 includes a connection coupling 110 and a conduction performance test valve 120.

The connection coupling 110 is installed in the piping 5 of the automatic fire extinguishing facility. The piping part 5 of the automatic liquid extinguishing facility is a supply pipe 5b for supplying the discharged pipe 5a connected to the reinforced liquid container 1 and the reinforced liquid discharged through the discharge pipe 5a to the injection nozzle 7 ).

It includes a water tank 150 for supplying water to the coupling coupling 110, and supplies water to the supply pipe 5b through the coupling coupling 110 in the water tank 150. The conduction performance test is performed by checking the water injection state of the injection nozzle 7.

As shown in Figure 3, the coupling coupling 110 is installed in a position separated from the connection portion of the discharge pipe (5a) and the supply pipe (5b). Since the discharge pipe 5a is made of a stainless pipe and the supply pipe 5b is made of a flexible hose and connected to each other, the flexible hose connected to the stainless pipe is separated and a connection coupling 110 is installed therebetween.

The connection coupling 110 includes a first connection portion 111, a second connection portion 112 and a third connection portion 113.

The first connection part 111 is connected to the discharge pipe 5a, the second connection part 112 is connected to the supply pipe 5b, and the third connection part 113 is the first connection part 111 and the second connection part 112 And vertically. The injection port 115 is provided in the third connection portion. The injection port 115 is connected to a pipe 140 for water injection.

The first connection portion 111, the second connection portion 112, and the third connection portion 113 may be connected to the discharge pipe 5a, the supply pipe 5b, and the water injection pipe 140, respectively, in a screwed manner, Each connecting part is connected via a gasket to maintain airtightness of the connecting part.

The connection coupling 110 is provided with a conduction performance test valve 120. The conduction performance test valve 120 opens and closes the connection of a flow path for supplying water injected into the injection port 115 to the injection nozzle 7 or a flow path for supplying the reinforcement liquid in the reinforcement liquid container 1 to the injection nozzle 7 do.

As shown in FIG. 4, the first connection part 111 connected to the discharge pipe 5a is formed with a first flow path 111a, and the second connection part 112 connected with the supply pipe 5b is the first A second flow path 112a is formed on the coaxial line with the flow path 111a. The third connection part 113 is formed with a third flow path 113a that vertically intersects the first flow path 111a and the second flow path 112a. The end of the third flow path (113a) is an inlet 115, the inlet 115 is connected to the water injection pipe 140, the water for the conduction performance test of the piping portion 5 of the automatic liquid fire extinguishing equipment Is injected.

The conduction performance test valve 120 connects a flow path through which water injected into the injection port 115 by rotation is supplied to the injection nozzle 7. Connect the water injection pipe 140 to the injection port 115 and supply water to the connection coupling 110 through the water injection pipe 140 to check the water injection state of the injection nozzle 7 and to connect the piping It is possible to check the performance of (5) and the spray nozzle (7).

The conduction performance test valve 120 includes a rotating ball 121 and a rotating operation unit 122. The rotating ball 121 is disposed at a position where the first flow path 111a, the second flow path 112a, and the third flow path 113a cross, and a three-way flow path 121a is formed. The three-way flow path 121a connects the first flow path 111a and the second flow path 112a, or selectively connects the second flow path 112a and the third flow path 113a. In FIG. 4, the three-way flow path 121a of the rotating ball 121 connects the second flow path 112a and the third flow path 113a.

The rotating operation part 122 is located on the outside of the connection coupling 110 and is connected to the rotating ball 121 and the shaft (not shown) so that the first flow path 111a to the third flow path 113a selectively communicate with the rotating ball (121) is rotated.

As shown in FIG. 4, the three-way flow path 121a of the rotating ball 121 communicates the second flow path 112a and the third flow path 113a in a state in which the rotation operation part 122 faces the left direction. In the state where the second flow path 112a and the third flow path 113a are in communication, the first flow path 111a is shielded by the rotating ball 121 and is not communicated with the second flow path 112a and the third flow path 113a. Does not. Therefore, when water is injected into the third flow path 113a through the injection port 115, water moved from the third flow path 113a to the supply pipe 5b through the second flow path 112a is sprayed from the spray nozzle 7 do.

As shown in FIG. 5. The three-way flow path 121a of the rotating ball 121 communicates the first flow path 111a and the second flow path 112a while the rotation operation part 122 rotates 90 degrees in a counterclockwise direction and faces downward. In a state where the first flow path 111a and the second flow path 112a are in communication, the third flow path 113a is shielded by the rotating ball 121 and is not communicated with the first flow path 111a and the second flow path 112a. Does not. Therefore, when the reinforcing liquid is released, the reinforcing liquid is moved to the supply pipe 5b through the first flow path 111a and the second flow path 112a and is discharged from the spray nozzle 7.

The connection coupling 110 is provided with a display unit (not shown) for checking whether the conduction performance test valve 120 is opened or closed. The display unit may be a character description such as 'open' or 'shield' at the position where the rotation manipulation unit 122 is rotated.

Here, 'open' refers to a state in which water injected into the injection port 115 can be supplied to the injection nozzle 7 in communication with the second flow path 112a and the third flow path 113a, and the 'shielding' means The first flow path 111a and the second flow path 112a may communicate to indicate a state in which the reinforcing liquid in the reinforcing liquid container 1 can be supplied to the injection nozzle 7. The conduction performance test valve 120 is kept in the 'open' state only when conducting the conduction performance test, and is normally kept in the 'shield' state.

The conduction performance test is performed while the conduction performance test valve 120 is open, and after the conduction performance test, the water injection pipe 140 is removed from the inlet 115, and the rotating operation part 122 is rotated to rotate the strengthening liquid container ( Maintain a shielding state in which the flow path for supplying the reinforcement liquid of 1) to the injection nozzle 7 is connected.

Meanwhile, as another embodiment, as shown in FIGS. 6 and 7, a check valve 130 is provided in the third flow path 113a to prevent the reinforcing liquid from flowing back into the inlet 115 when the reinforcing liquid is discharged. do.

The check valve 130 passes through the inlet 115, the water flowing into the third flow path 113a and is discharged from the first flow path 111a to flow back to the third flow path 113a. It serves to prevent it from being discharged into the furnace.

The check valve 130 is formed around an inner diameter on one side of the third flow path 113a and is disposed under the support 131 and the support 131 forming a smaller inner diameter than the inner diameter of the third flow path 113a in the center. It includes a buoy 133 that rises due to buoyancy during the countercurrent of the reinforcing liquid and is in close contact with the bottom surface of the support 131 to block the inner diameter of the support 131.

The bugu 133 extends from the center of the bugu 133 to the top and extends through the inner diameter of the support 131 and extends 133a and a straight-shaped locking portion protruding from both ends of the extension 133a ( 133b). The buoy 133 restricts the descending range of the bugu 133 by engaging the upper portion of the support 131 when the engaging portion 133b is lowered. Since the locking portion 133b is straight and the inner diameter of the support 131 is circular, even if the straight locking portion 133b descends and is caught on the upper surface of the support 131, between the inner diameter of the support 131 and the locking portion 133b Water may flow into the space and move to the second flow path 112a.

As shown in FIG. 6, when water is injected into the third flow path 113a through the injection port 115 while the second flow path 112a and the third flow path 113a are in communication, the buoy 133 is downward. By descending, the inner diameter of the support 131 is opened and water can be moved from the third flow path 113a to the supply pipe 5b through the second flow path 112a.

In addition, as shown in FIG. 7, when the reinforcing liquid is discharged into the first flow path 111a in a state where the first flow path 111a and the second flow path 112a are in communication, the reinforcing liquid is transferred to the third flow path 113a. Even if it flows back, the buoy 133 rises due to buoyancy, so that the reinforcing solution is not discharged to the inlet 115 by shielding the inner diameter of the support 131, and can be moved to the supply pipe 5b through the second flow path 112a. have.

In the case of FIG. 7, in the state of FIG. 6, the rotating ball 121 rotates clockwise so that the three-way flow path 121a of the rotating ball 121 includes a first flow path 111a, a second flow path 112a, and a third All of the flow paths 113a can be communicated. In this case, it is possible to prevent the check valve 130 from flowing back through the third flow path 113a to the inlet liquid 115.

For convenience of explanation, the case where the check valve 130 is applied has been described only in FIGS. 6 and 7. 4 and 5, a check valve may also be applied. The check valve shows an example in which a buoy rising by buoyancy is applied, but various examples can be adopted as long as it is a structure capable of preventing a reverse flow of the inlet of the reinforcement liquid.

Hereinafter, the operation of the present invention will be described.

The process of conduction performance test using the conduction performance test apparatus will be described.

As shown in FIG. 2, the conduction performance test apparatus 100 is installed in the piping 5 of the reinforcing liquid automatic fire extinguishing facility connecting the reinforcing liquid container 1 and the injection nozzle 7. Normally, the conduction performance test apparatus 100 forms a flow path for supplying the strengthening liquid of the strengthening liquid container 1 to the spray nozzle 7. 5 or 7, the flow path for supplying the reinforcing liquid of the reinforcing liquid container 1 to the injection nozzle 7, that is, the first flow path 111a and the second flow path 112a is maintained. do.

It is supplied through the first flow path (111a) and the second flow path (112a) to the supply pipe (5b) through the first flow path (111a) and the second flow path (112a) upon discharge of the reinforced liquid due to the fire, through the injection nozzle (7) connected to the supply pipe (5b) This is to allow the fire to be extinguished early by the release of the reinforcing liquid.

In addition, when performing the conduction performance test, connect the water injection pipe 140 to the inlet 115, and rotate the rotating operation part 122 of the conduction performance test valve 120 to rotate the water injected into the inlet 115. The conduction performance test valve 120 is opened so that the flow path supplied to the injection nozzle 7 is connected to the second flow path 112a and the third flow path 113a.

Next, by supplying water to the injection port 115 through the pipe 140 for water injection, it checks whether the piping 5 of the strengthening liquid automatic fire extinguishing system is conducting and the water injection state of the injection nozzle 7. In the embodiment, the number of injection nozzles 7 is 6 to 9 to check the water injection state of each injection nozzle.

At this time, the water tank 150 connected to the pipe 140 for water injection is tested in a state filled with water using a water supply vehicle 160, and water pressure is injected when water is injected into the inlet 115 from the water tank 150. Silver discharge pipe (5a) should be the same as the operating pressure. In the embodiment, when water is injected from the water tank 150 into the injection port 115, the water pressure is 10 kgf / cm 3 which is the same as the discharge pipe working pressure. Accurate conduction performance test is possible when water is injected into the injection port 115 in the same manner as the discharge piping 5a.

As a result of the conduction test, if the conduction state of the piping 5 and the spray nozzle 7 of the automatic fire extinguishing system is judged to be defective, the piping part 5 and the spray nozzle 7 are separated and cleaned, if necessary, replaced and replaced again. Conduct a conduction performance test.

When the inspection of the piping portion 5 and the injection nozzle 7 is completed through the conduction performance test, the conduction performance test valve 120 is returned to its original state. The flow path for supplying the reinforcing liquid of the reinforcing liquid container 1 to the injection nozzle 7 is reconnected by rotating the rotating operation part 122 of the conduction performance test valve 120 in the reverse direction to rotate the rotating ball 121 in the reverse direction. To make. Next, the water injection pipe 140 is removed from the injection port 115.

In a state in which the flow path for supplying the reinforcement liquid of the reinforcement liquid container 1 to the injection nozzle 7 is reconnected, the conduction performance test apparatus 100 is a check valve (3) connected to the third flow path 113a connected to the injection port 115. 130) is installed to prevent the reinforcement liquid from flowing back into the inlet 115 of the conduction performance test valve 120 when the reinforcement liquid is discharged.

The above-described conduction performance test apparatus is connected to the pipe 140 for water injection to the injection port 115 in a state installed in the piping portion 5 of the automatic fire extinguishing facility and rotates the rotation operation portion 122 of the conduction performance test valve 120 By rotating the rotating ball 121 and changing the flow path, the conduction performance test of the piping 5 and the spray nozzle 7 can be conveniently performed. This provides lower cost and convenience of work compared to the existing conduction performance test method.

In addition, the conduction performance test device can perform the performance test of the piping part 5 and the spraying nozzle 7 from time to time to check the piping part 5 of the automatic fire extinguishing facility, and the time required for the test is per location It is less than 10 minutes, and the inspection cost is about 30,000 won, which can significantly reduce both time and economic costs. This means that conduction performance tests can be conducted at all locations of automatic fire extinguishing facilities.

In addition, since the conduction performance test device tests the conduction performance by injecting water, cleaning of the inside of the piping part of the automatic fire extinguishing equipment and the spray nozzle for a long period of non-operation in the process of discharging water to the spray nozzle through the piping part is a certain part. It has the advantage of being.

Accordingly, it is possible to increase the safety of the incoming cable for underground transmission, and eventually to increase the stability of the domestic power system.

This embodiment is also applicable to fire extinguishing equipment and other equipment with piping and nozzles.

The present invention has disclosed the best embodiments in the drawings and specifications. Here, although specific terms are used, they are used for the purpose of describing the present invention only, and are not used to limit the scope of the present invention described in the meaning limitation or the claims. Therefore, the present invention will be understood by those of ordinary skill in the art that various modifications and other equivalent embodiments are possible. Therefore, the true technical scope of the present invention should be determined by the technical spirit of the appended claims.

1: Reinforced liquid container 3: Sliding reinforced liquid container set
5: piping 5a: discharge piping
5b: Supply piping 7: Spray nozzle
L: underground transmission inlet cable 100; Conduction performance test device
110: coupling coupling 111: first connection
111a: 1st flow path 112: 2nd connection part
112a: second passage 113: third connection
113a: Third passage 115: Inlet
120: conduction performance test valve 121: rotating ball
121a: three-way flow path 122: rotating operation unit
130: check valve 131: support
133: bugu 133a: extension
133b: engaging portion 140: water injection pipe
150: water tank 160: water supply vehicle

Claims (10)

A coupling coupling installed in a piping portion of an automatic fire extinguishing facility for connecting a reinforcement liquid container and a spray nozzle;
An injection port provided in the connection coupling and into which water is injected for conduction performance test of the piping portion of the automatic fire extinguishing facility; And
And a conduction performance test valve which is provided in the connection coupling and opens and closes a connection of a flow path for supplying water injected into the injection port to the injection nozzle or a flow path for supplying the reinforcement liquid in the reinforcement liquid container to the injection nozzle. ,
The piping portion of the automatic liquid extinguishing facility includes a discharge pipe connected to the reinforcing liquid container and a supply pipe supplying the reinforcing liquid discharged to the discharge pipe to the injection nozzle, wherein the connection coupling comprises the discharge pipe and the It is installed in a position where the connection part of the supply pipe is separated.
The connection coupling forms a first flow path and a first connection portion connected to the discharge pipe, a second connection portion formed on the coaxial line with the first flow path and connected to the supply pipe and the first connection portion A third flow path forming a third flow path perpendicularly intersecting the flow path and the second flow path, and including a third connection portion through which the injection port is formed to connect the water injection pipe,
A check valve is provided in the third flow path to prevent the reinforcement liquid from flowing back into the injection port when the reinforcement liquid is released,
The check valve includes a support having an inner diameter in the center, and a sub-sphere disposed under the support to open and close the inner diameter,
The buoy includes an extension portion extending from the center to the top and penetrating the inner diameter of the support, and a locking portion protruding in a straight line from both ends of the extension portion,
The locking portion is a conduction performance test device characterized in that the hook is lowered by the supply of water through the third flow path is caught on the upper surface of the support. delete delete The method according to claim 1,
The conduction performance test valve
A rotating ball disposed at a position where the first flow path, the second flow path, and the third flow path intersect and has a three-way flow path; And
A rotary manipulation unit located on the outside of the connection coupling and axially connected to the rotary ball to rotate the rotary ball such that the first to third flow channels selectively communicate;
Conductivity performance test apparatus comprising a. delete The method according to claim 1,
The connection coupling is a conduction performance test device, characterized in that the display unit for checking whether the conduction performance test valve is opened or closed. The method according to claim 1,
Rotating the conduction performance test valve to connect the flow path to supply water injected into the injection port to the injection nozzle,
A connection performance test apparatus characterized by confirming a water injection state of the injection nozzle by connecting a water injection pipe to the injection port and supplying water to the connection coupling through the water injection pipe. The method according to claim 7,
It includes a water tank for injecting water into the inlet,
When the water is injected from the water tank to the inlet, the water pressure is the conduction performance test apparatus, characterized in that the same as the discharge pipe operating pressure. The method according to claim 7,
The conduction performance test is performed by checking the water injection state of the spray nozzle, and after the conduction performance test, the water injection pipe is removed from the inlet,
The conduction performance test apparatus characterized in that the flow path for supplying the strengthening liquid of the strengthening liquid container to the injection nozzle is connected by rotating the conduction performance test valve. The method according to claim 1,
A plurality of injection nozzles are installed toward the underground transmission inlet cable,
Conductive performance test device, characterized in that the piping portion of the automatic strengthening liquid is branched to a plurality of ends and connected to the injection nozzles.

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