KR102015257B1 - Hydrostatic test method of electro chamber module using in ballast water management system - Google Patents

Abstract

The present invention relates to a water pressure test method of an electro-chamber module used in a ship ballast water treatment system which reliably seals an electro-chamber module used in water within a short period of time by a small number of processes to check whether a water leakage of a weld occurs in a water pressure required by marine equipment. According to the present invention, the water pressure test method comprises: a step (S1) of coupling bolts (13) to a plurality of tap holes (12) formed on an upper surface of an electro-chamber module (100); a step (S2) of coupling a side watertight member (200), a first watertight member (400), a second watertight member (500), and a third watertight member (600); a step (S3) of coupling an upper watertight member (300) after injecting water into the electro-chamber module (100); and a step (S4) of checking a change of a water pressure gauge (507) under a certain water pressure.

Description

Hydrostatic test method of electro chamber module using in ballast water management system

The present invention relates to a hydrostatic pressure test method for an electrochamber module used in a ballast water treatment system. The electrochamber module used in water can be reliably sealed in a short time in a small process and leaks in a weld portion at hydraulic pressure requiring marine equipment. The present invention relates to a hydraulic test method of an electrochamber module used in a ballast water treatment system capable of confirming whether or not such a light is generated.

Ballast water is seawater that is filled in tanks installed at the bottom or left and right of the ship to maintain the center of gravity of the ship as it is in service. When the cargo is loaded, the seawater that is loaded is discarded, and when the cargo is unloaded, the seawater is put back in to take the center of gravity of the ship. This allows the center of gravity of the ship to be balanced. If ballast water is discharged into the sea without any problem, ballast water is a major cause of various ecosystem disturbances and water pollution.

The International Maritime Organization (IMO) has mandated the installation of Ballast Water Management System (BWMS) in order to prevent such marine ecosystem destruction, disturbance and environmental pollution.

BWMS is a facility that removes or sterilizes aquatic organisms and microorganisms in ballast water. In case of sterilization by electrolysis, electro chamber module is equipped with electrolysis device. ) Will be provided.

Since the electrochamber module is a device used in water, it should be manufactured to withstand leakage without pressure or water pressure corresponding to the depth of use. As a test method, conventionally, the end or the plan of all the conduits of the electrochamber module is planned. Since the gasket is sealed through the branch and the opening, the hydraulic test is performed, and thus, the process according to the hydraulic test is cumbersome and time consuming.

Therefore, there is a need for a method capable of efficiently conducting a hydraulic test while reliably closing the electrochamber module in a short time with a small process.

Korean Patent Registration No. 1895419

The present invention has been made to solve the above problems, an object of the present invention is to seal the electrochamber module used in the water quickly and securely in a small process in a short time whether the leakage of the weld portion occurs at the water pressure required for marine equipment It is to provide a hydraulic test method of the electrochamber module used in the ballast water treatment system that can determine whether or not.

In order to achieve the above object, the hydraulic pressure test method of the electrochamber module used in the ballast water treatment system according to the present invention includes the step of coupling the bolt to a plurality of tab holes formed in the upper surface of the electrochamber module (S1) and ; After the step S1, the side watertight members are fastened to both flange portions of the electrochamber module using bolts and nuts, respectively, and the first watertight jig is provided at each end of the pipe pipe portion provided at one side of the electrochamber module. Couple to the first watertight jig to one end of the pipe pipe portion provided on the other side upper portion of the electrochamber module, and coupled to the second watertight jig to the other end, and is provided on the other side lower portion of the electrochamber module Coupling the first watertight jig to one end of the pipe pipe part and the third watertight jig to the other end (S2); After the step (S2), after injecting water into the electro-chamber module through the opening formed on the upper surface of the electro-chamber module, cover the opening with an upper watertight member and fasten the nut to the bolt to open the opening of the electro-chamber module. Sealing step (S3); After the step S3, water is further injected into the electrochamber module until the predetermined water pressure is reached through the third watertight jig, and the second chamber is left for a predetermined time under a constant water pressure. It includes a step (S4) to confirm the change of the hydraulic pressure gauge mounted on the watertight jig.

In a preferred embodiment, the side watertight member is provided with a plurality of through holes corresponding to the coupling holes formed in the flange portion, the first O-ring is installed on one surface, and the upper watertight member covers and seals the opening of the electrochamber module. As a plurality of through holes are formed so that the bolt penetrates to the outside, and a second O-ring is installed on one surface.

In addition, as a preferred embodiment, the first watertight jig has a threaded rod of a predetermined length having a male thread formed on the outside, a clamp nut formed with a female threaded thread and fastened to the screwed rod, and a plurality of metals inserted into the screwed rod. Including a ring and a rubber ring which is inserted between the screw rod and disposed between the metal ring, and inserting the portion where the rubber ring is placed into the pipe of the pipe pipe portion, and tightening the clamp nut, the pipe pipe portion The rubber ring inserted into the pipeline expands to close the pipeline.

In addition, as a preferred embodiment, the second watertight jig has a screw rod having a predetermined length having a flow path through which water flows and a male thread formed on the outside, and a clamp nut that is formed with a female thread and fastened to the screw rod. A plurality of metal rings inserted into the screw rod, a rubber ring inserted into the screw rod and disposed between the metal rings, a nipple installed on one side of the screw rod and communicating with a flow path of the screw rod; A bushing having a groove to be interposed between the metal ring and the clamp nut and inserted into the screw rod of the portion where the nipple is installed, a hydraulic pressure gauge coupled to the nipple, and connected to the hydraulic pressure gauge. And a valve capable of discharging or blocking water in the electrochamber module to the outside, and a portion where the rubber ring is disposed, When the clamp nut is tightened after the other end is inserted into the pipe, the rubber ring inserted into the pipe of the other end of the pipe pipe part expands to close the pipe pipe part and check the hydraulic pressure in the electrochamber module through the hydraulic pressure gauge. It is possible to discharge the water in the electrochamber module through the valve to the outside.

In addition, as a preferred embodiment, the third watertight jig has a screw rod having a predetermined length having a flow path through which water flows and a male thread formed on the outside, and a clamp nut which is formed with a female thread and fastened to the screw rod. A plurality of metal rings inserted into the screw rod, a rubber ring inserted into the screw rod and disposed between the metal rings, a nipple installed on one side of the screw rod and communicating with a flow path of the screw rod; A hose between the metal ring and the clamp nut and inserted into a screw rod of a portion where the nipple is installed, the bushing having a groove portion so that the nipple may be interposed, and a hose coupled to the nipple and connected to a hose portion supplied with water. Including the connector, the rubber ring is inserted into the other end of the pipe pipe portion of the pipe and then tightening the clamp nut the pipe Is a rubber ring is inserted into the expanded pipe portion of the other end of the channel is closed, the conduit pipe portion of the pipe and connected to the host unit through the hose connector is capable of flowing into the electroporation chamber modules water.

According to the present invention, the electrochamber module used in the water can be reliably sealed in a short time in a small process, and it is possible to check whether or not leakage occurs in the welded part at the water pressure required for marine equipment. Whether or not can be judged efficiently.

1a to 1c is a photograph showing the electrochamber module used in the ballast water treatment system to which the hydraulic test method of the present invention is applied,
2 is a block diagram schematically illustrating a hydraulic test method of an electrochamber module according to the present invention;
3A is a photograph showing a process of coupling bolts to a plurality of tab holes formed on an upper surface of an electrochamber module, and FIG. 3B is a photograph showing a state where bolts are coupled to an upper surface of an electrochamber module.
4A is a photograph showing a side watertight member of the present invention, and FIG. 4B is a photograph showing a state where the side watertight member is fastened to the flange portion of the electrochamber module using a bolt and a nut.
Figure 5a is a photograph showing a first watertight jig of the present invention, Figure 5b is a photograph for explaining the operation relationship of the first watertight jig, Figure 5c is the end of the pipe pipe portion provided on one side upper portion of the electrochamber module 1 is a picture showing the state of combined watertight jig,
Figure 6a is a photograph showing a second watertight jig of the present invention, Figure 6b is a photograph showing a state in which the first watertight jig and the second watertight jig coupled to the end of the pipe pipe portion provided on the other side of the electrochamber module,
Figure 7a is a photograph showing a third watertight jig of the present invention, Figure 7b is a photograph showing a flow path formed on the screw rods of the second watertight jig and the third watertight jig, Figure 7c is provided on the lower side of the other side of the electrochamber module It is a photograph showing a state in which the third watertight jig is coupled to the end of the pipe tube,
8A and 8B are photographs illustrating a process of introducing water into the electrochamber module.
Figure 9a is a photograph showing the upper watertight member of the present invention, Figure 9b is a photograph showing a process of covering the upper watertight member and fastening the nut to the opening of the electrochamber module,
10A is a photograph illustrating a process of injecting water into the electrochamber module until a predetermined water pressure is reached through the third watertight jig.
10B is a photograph showing a process of confirming whether the hydraulic chamber mounted on the second watertight jig is changed while the electrochamber module is left for a certain time under a constant water pressure state.
10C is a photograph showing a process of discharging water from the electrochamber module.

The present invention relates to a hydraulic test method of the electrochamber module 100 for inspecting whether an electrochamber module used in a ballast water treatment system (BWMS) is leaked at a welded part or the like under a constant hydraulic pressure. will be.

First, referring to Figures 1a to 1c will be described the structure of the electrochamber module 100 used in the ballast water treatment system.

In the electrochamber module 100 to which the present invention is applied, a plurality of openings 11 are formed at an upper portion of the electrochamber module 100, and a plurality of tab holes 12 are formed at an upper surface around the opening 11. . A screw thread is formed inside the tab hole 12 to fasten the bolt 13.

In addition, both sides of the electrochamber module 100 are provided with a flange portion 20 in communication with the internal space. As shown in FIG. 1C, the flange portion 20 communicates with the inside of the electrochamber module 100 through the hollow portion 21, and a plurality of coupling holes 22 penetrate through the circumferential direction.

In addition, upper and lower sides of the electrochamber module 100 are provided with pipe pipes 31, 32, 33, and 34, which communicate with the internal space, respectively.

In order to completely seal the electrochamber module 100, the opening part 11, the flange part 20, and the pipe pipe parts 31, 32, 33, and 34 must all be securely sealed. Using the watertight member 200, the upper watertight member 300, and the first to the third watertight jig (400, 500, 600) and securely sealed the electrochamber module 100 through the method described later, and then the hydraulic test Do this.

Hereinafter, with reference to the accompanying drawings and photos will be described in detail the pressure test method of the electrochamber module according to the present invention.

In the hydraulic test method according to the present invention, as shown in FIG. 2, a step (S1) of joining the bolts 13 to the plurality of tab holes 12 formed in the upper surface of the electrochamber module 100, the side watertight member ( 200), the first watertight jig 400, the second watertight jig 500, the step of combining the third watertight jig 600 (S2), after the water is injected into the electrochamber module 100, the upper watertight member Coupling (300) (S3), and the step (S4) of confirming the change in the water pressure gauge 507 under a constant water pressure.

The step S1 is a step of coupling the bolt 13 to the tab hole 12 formed in the upper surface of the electrochamber module 100 as can be seen in Figures 3a and 3b. The bolt 13 is to be prepared around the opening 11 in order to fasten the upper watertight member 300 for sealing the opening 11 to the upper surface of the electrochamber module 100.

In the step S2, after the step S1, the side watertight members 200 are fastened to both flange portions 20 of the electrochamber module 100 using bolts B1 and nuts N1, respectively. The first watertight jig 400 is coupled to both ends of each of the pipe pipe parts 31 and 32 provided on one side up and down of the electrochamber module 100, and the pipe provided on the other side of the electrochamber module 100. The first watertight jig 400 is coupled to one end 33A of the pipe part 33, and the second watertight jig 500 is coupled to the other end 33B, and the other side lower portion of the electrochamber module 100 is provided. Coupling the first watertight jig 400 to one end 34A of the pipe pipe part 34 provided at the same time, and the third watertight jig 600 to the other end 34B (S2).

That is, the step (S2) is a specially manufactured side watertight member 200, the first watertight jig 400, the second watertight jig 500, to reliably seal the electrochamber module 100 in a simple manner, The third watertight jig 600 is coupled to both ends of the flange portion 20 and the pipe pipe portions 31, 32, 33, and 34 of the electrochamber module 100.

On the other hand, the step (S2) may be a method of first joining the side watertight member 200, and then sequentially joining the first to third watertight jig (400, 500, 600), the first to third The watertight jig (400, 500, 600) may be combined first, and then the method of coupling the side watertight member 200 may be adopted. In other words, in the step (S2) of the present invention, the coupling order of the side watertight member 200, the first watertight jig 400, the second watertight jig 500, and the third watertight jig 600 may be variously changed. have.

First, the side watertight member 200 of the present invention will be described. As shown in FIG. 4A, the side watertight member 200 has a through hole corresponding to the coupling hole 22 formed in the flange portion 20. 201) is formed in the plural along the circumferential direction, the first O-ring 202 is provided on one surface. The first O-ring 202 may be formed of a known O-ring configuration.

Therefore, as shown in FIG. 4B, the through hole 201 of the side watertight member 200 corresponds to the coupling hole 22 of the flange portion 20, and then passes through the bolt B1 to the nut N1. When fastened, the first o-ring 202 is in close contact with the outer surface of the flange portion 20 to seal the flange portion 20 securely.

As shown in FIG. 5A, the first watertight jig 400 of the present invention has a predetermined length of a threaded rod 401 having a male thread formed therein, and a clamp nut having a female thread formed therein and fastened to the screwed rod 401 ( 402, a plurality of metal rings 403 fitted to the screw rod 401, and a rubber ring 404 inserted between the screw rods 401 and disposed between the metal rings 403. do. In addition, the first watertight jig 400 is formed between the clamp nut 402 and the metal ring 403 is a cylindrical bushing 406 of a metal material larger than the metal ring 403 and rubber ring 404 It is preferred that the nut is fixedly coupled to the rubber ring 404 end portion.

Referring to FIG. 5B, the operation relationship of the first watertight jig 400 and the coupling structure of the pipe pipes 31, 32, 33, and 34 will be described. The rubber ring 404 of the first watertight jig 400 will be described. Is inserted into the conduit at the end of the pipe portion 31, 32, 33, 34, and then tighten the clamp nut 402 in Figure 5b while moving the clamp nut 402 on the screw rod 401 Push the bushing 406 and the metal ring 403 in the direction indicated to inflate the rubber ring 404 in the direction shown in FIG. 5B. As a result, the rubber ring 404 inserted into the pipe of the pipe pipes 31, 32, 33, 34 expands to reliably close the pipe of the pipe pipes 31, 32, 33, 34.

FIG. 5C shows a state in which the first watertight jig 400 is coupled to the end of the pipe pipe part 31 by the above method. In the present invention, the pipe water pipe part 31 is operated by simply operating the first watertight jig 400 specially manufactured. The pipeline itself can be surely closed.

As shown in FIG. 6A, the second watertight jig 500 of the present invention has a flow path 501A through which water can flow (see FIG. 7B), and a thread rod having a predetermined length having a male thread formed on the outside thereof (see FIG. 7B). 501, a clamp nut 502 formed with a female thread, and fastened to the screw rod 501, a plurality of metal rings 503 fitted to the screw rod 501, and the screw rod 501. A rubber ring 504 interposed between the metal ring 503 and a nipple 505 installed at one side of the screw rod 501 and communicating with a flow path 501A of the screw rod 501; And a groove 506A between the metal ring 503 and the clamp nut 502 to be inserted into the screw rod 501 of the portion where the nipple 505 is installed, so that the nipple 505 can be interposed therebetween. A bushing 506, a hydraulic pressure gauge 507 coupled to the nipple 505, and connected to the hydraulic pressure gauge 507 to supply water in the electrochamber module 100. It includes a valve 508 that can be discharged or shut off to the outside.

Referring to the operation relationship of the second watertight jig 500 and the coupling structure at the other end 33B of the pipe pipe part 33, the site where the rubber ring 504 is disposed is the other of the pipe pipe part 33. When the clamp nut 502 is tightened after being inserted into the conduit of the end 33B, the clamp nut 502 pushes the bushing 506 and the metal ring 503 while moving on the screw rod 501. The rubber ring 504 is inflated. At this time, since the groove portion 506A is formed in the bushing 506, even if the nipple 505 is installed in the screw rod 501, the bushing 506 is extended by the groove portion 506A in the longitudinal direction of the screw rod 501. By moving to the metal ring 503 can be pushed in the screw rod 501.

As a result, as described above, the rubber ring 504 of the second watertight jig 500 inserted into the pipe of the other end 33B of the pipe pipe 33 is expanded to close the pipe of the pipe pipe 33. The hydraulic pressure gauge 507 which can check the water pressure in the electrochamber module 100 is installed in the pipe pipe part 33 while making it. (See Figure 6b)

As shown in FIG. 7A, the third watertight jig 600 of the present invention has a flow path 601A through which water can flow (see FIG. 7B), and a thread rod having a predetermined length having a male thread formed on the outside thereof (see FIG. 7B). 601, a clamp nut 602 formed with a female thread and fastened to the screw rod 601, a plurality of metal rings 603 inserted into the screw rod 601, and the screw rod 601. A rubber ring 604 inserted between the metal rings 603, a nipple 605 installed at one side of the screw rod 601, and communicating with a flow path of the screw rod 601, and the metal Bushing 606 having a groove 606A between the ring 603 and the clamp nut 602 to be inserted into the threaded rod 601 of the portion where the nipple 605 is installed, so that the nipple 605 can be interposed. And a hose connector 607 that is coupled to the nipple 605 and may be connected to a hose part 610 to which water is supplied.

Referring to the operation relationship of the third watertight jig 600 and the coupling structure at the other end portion 34B of the pipe pipe portion 34, the site where the rubber ring 604 is disposed is the other of the pipe pipe portion 34. When the clamp nut 602 is tightened after being inserted into the conduit of the end 34B, the bushing 606 moves as the clamp nut 602 moves on the screw rod 601 similarly to the second watertight jig 500. ) And the metal ring 603 to expand the rubber ring 604. At this time, the groove 606A is formed in the bushing 606 similarly to the second watertight jig 500, so even if the nipple 605 is installed on the threaded rod 601, the bushing 606A is provided. The 606 moves in the longitudinal direction of the screw rod 601 to push the metal ring 603 off the screw rod 601.

As a result, as described above, the rubber ring 604 of the third watertight jig 600 inserted into the pipe of the other end 34B of the pipe pipe 34 is expanded to open the other pipe of the pipe pipe 34. Close it. (See Figure 7c)

In addition, the hose part 610 may be connected to the hose connector 607 of the third watertight jig 600 so that water supplied through the hose part 610 may be introduced into the electrochamber module 100. The hose 610 is preferably provided with a known open and close valve such as a ball valve.

 As described above, the flange of the electrochamber module 100 through the side watertight member 200, the first watertight jig 400, the second watertight jig 500, and the third watertight jig 600 in step S2. 20 and the both ends of the pipe pipe parts 31, 32, 33, 34, respectively, and then sealed in step (S3) to the inside of the electrochamber module 100 through the opening 11 of the electrochamber module 100. After inserting the hose (H) and injecting water (see FIGS. 8A and 8B), the opening 11 is covered with the upper watertight member 300 and the nut N2 is fastened to the bolt 13 to the electrophoresis. The opening 11 of the chamber module 100 is sealed. (See Figures 9A and 9B)

The upper watertight member 300 of the present invention covers and seals the opening 11 of the electrochamber module 100. As shown in FIG. 9A, a through hole is formed so that the bolt 13 penetrates through an outer edge thereof. A plurality of 301 is formed and a second O-ring 302 is installed on one surface. The second O-ring 302 may be formed of a known O-ring configuration.

Therefore, as shown in FIG. 9B, the bolt 13 is passed through the through hole 301 of the upper watertight member 300 to cover the opening 11 with the upper watertight member 300, and then to the nut N2. When fastened, the second O-ring 302 is in close contact with the upper surface of the electrochamber module 100 around the opening 11, thereby tightly sealing the opening 11.

Subsequently, in step S4 after step S3, water is additionally injected into the electrochamber module 100 until the predetermined water pressure is reached through the third watertight jig 600.

In other words, as shown in FIG. 10A, the hose part 610 is connected to the hose connector 607 of the third watertight jig 600 to supply water supplied from the hose part 610 to the third watertight jig 600. Further injection into the electrochamber module 100 through the flow path 601A and the pipe pipe 34.

At this time, since the valve 508 of the second watertight jig 500 is blocked, the water pressure inside the electrochamber module 100 continuously increases as water is continuously injected. As shown in FIG. 10B, when the water pressure of the pressure gauge 507 reaches a predetermined water pressure, the valve (not shown) installed in the hose 610 is blocked to stop the water supply.

Thereafter, the electrochamber module 100 is left for a predetermined time under a constant water pressure state to check whether the hydraulic pressure gauge 507 mounted to the second watertight jig 500 is changed. If the water pressure decreases, it indicates that a leak occurs somewhere in the electrochamber module 100, so that the appearance of the electrochamber module 100 is closely inspected to check for defects.

When the step (S4) is completed, first open the valve 508 to discharge the water under a certain pressure state inside the electrochamber module 100 to the outside through the hose 508A (see Fig. 10c), The upper watertight member 300 is separated to discharge all of the water inside the electrochamber module 100 using a pump or the like, or the first watertight jig 400 installed at the pipe 34 is separated to discharge water. . Subsequently, when the side watertight member 200, the upper watertight member 300, and the first to third watertight jigs 400, 500, and 600 coupled to the electrochamber module 100 are separated, the hydraulic test according to the present invention is performed. Is done.

Although the preferred embodiment of the present invention has been described above, it will be apparent to those skilled in the art that various modifications can be made without departing from the scope of the technical idea. Accordingly, the above description does not limit the scope of the invention as defined by the following claims.

100: electrochamber module, 10: chamber, 11: opening,
12: tapped hole, 13: bolt, 20: flange portion,
21: hollow part, 22: coupling hole,
31, 32, 33, 34: pipe pipe,
200: side watertight member, 201: through hole, 202: first O-ring,
300: upper watertight member, 301: through hole, 302: second O-ring,
400: first watertight jig, 500: second watertight jig, 600: third watertight jig,
401, 501, 601: screw rod, 402, 502, 602: clamp nut,
403, 503, 603: metal ring, 404, 504, 604: rubber ring,
505, 605: nipple, 506, 606: bushing, 507: hydraulic pressure gauge,
508: valve, 607: hose connector, 610: hose part,
B1: Bolt, N1, N2: Nut

Claims (1)

In the hydraulic test method of the electrochamber module 100 used in the ballast water treatment system,
Coupling the bolts (13) to the plurality of tab holes (12) formed in the upper surface of the electrochamber module (S1);
After the step S1, the side watertight members 200 are fastened to the two flange portions 20 of the electrochamber module 100 using bolts B1 and nuts N1, respectively, and the electrochamber module 100 is closed. Coupling the first water-tight jig 400 to each end of the pipe pipe portion (31, 32) provided at one side of the upper and lower sides of), one end of the pipe pipe portion 33 provided on the other side of the electrochamber module 100 Coupling the first watertight jig 400 to the portion 33A and the second watertight jig 500 to the other end 33B, the pipe pipe portion provided on the other side lower portion of the electrochamber module 100 ( Coupling the first watertight jig 400 to one end 34A of the 34 and the third watertight jig 600 to the other end 34B (S2);
After injecting water into the electrochamber module 100 through the opening 11 formed on the upper surface of the electrochamber module 100 after the step S2, the opening 11 is formed by the upper watertight member 300. Covering () and fastening the nut (N2) to the bolt (13) to seal the opening (11) of the electrochamber module (100) (S3);
After the step S3, water is further injected into the inside of the electrochamber module 100 until the predetermined water pressure is reached through the third watertight jig 600, and the electrochamber module 100 is under a predetermined water pressure. Step (S4) to check whether the hydraulic pressure gauge (507) mounted on the second watertight jig (500) is left for a predetermined time; Including,
The side watertight member 200 is provided with a plurality of through holes 201 corresponding to the coupling hole 22 formed in the flange portion 20, and the first O-ring 202 is installed on one surface,
The upper watertight member 300 covers and seals the opening 11 of the electrochamber module 100, and a plurality of through holes 301 are formed to penetrate the bolt 13 on the outside thereof. 2 O-ring 302 is installed,
The first watertight jig 400 is a screw rod 401 of a predetermined length formed with a male thread on the outside, a clamp nut 402 formed with a female thread and fastened to the screw rod 401, and the screw rod 401 The rubber ring 404 includes a plurality of metal rings 403 inserted into the plurality of metal rings 403 and a rubber ring 404 inserted between the screw rods 401 and disposed between the metal rings 403. Rubber inserted into the pipe of the pipe parts 31, 32, 33, 34 is inserted into the pipe of the pipe parts 31, 32, 33, 34, and then tightening the clamp nut 402. Ring 404 is expanded to close the conduit of the pipe conduits 31, 32, 33, 34,
The second watertight jig 500 has a screw rod 501 having a predetermined length having a male thread formed therein and a male thread formed therein and a female thread formed therein and fastened to the screw rod 501. A clamp nut 502, a plurality of metal rings 503 fitted to the screw rod 501, and a rubber ring 504 inserted between the screw rods 501 and disposed between the metal rings 503. ), A nipple 505 installed at one side of the screw rod 501 and communicating with a flow path of the screw rod 501, and between the metal ring 503 and the clamp nut 502 and the nipple 505. The bushing 506 is inserted into the screw rod 501 of the installation portion, but has a groove 506A so that the nipple 505 can be interposed therebetween, and the hydraulic pressure gauge 507 coupled to the nipple 505. And a valve 508 connected to the hydraulic pressure gauge 507 and configured to discharge or shut off water in the electrochamber module 100 to the outside. Including, the rubber ring 504 is inserted into the other end portion 33B of the pipe pipe portion 33 is inserted into the pipe, and then tighten the clamp nut 502 the other end of the pipe pipe portion 33 ( 33B) the rubber ring 504 inserted into the pipeline is expanded to close the pipeline of the pipe tube 33 and check the hydraulic pressure in the electrochamber module 100 through the hydraulic gauge 507.
The third watertight jig 600 has a screw rod 601 of a predetermined length having a male thread formed therein and a male thread formed therein and a female thread formed therein and fastened to the screw rod 601. A clamp nut 602, a plurality of metal rings 603 inserted into the screw rod 601, and a rubber ring 604 inserted between the metal rods 603 and inserted into the screw rod 601. ), A nipple 605 installed at one side of the screw rod 601 and communicating with a flow path of the screw rod 601, and between the metal ring 603 and the clamp nut 602 while being the nipple 605. The bushing 606, which is inserted into the screw rod 601 of the portion to be installed, has a groove 606A so that the nipple 605 can be interposed, and a hose part coupled to the nipple 605 and supplied with water. Including the hose connector (607) that can be connected to the 610, the other end portion 34B of the pipe pipe portion 34 is the portion where the rubber ring 604 is disposed When the clamp nut 602 is tightened after being inserted into the furnace, the rubber ring 604 inserted into the other end 34B of the pipe pipe part 34 expands to close the pipe pipe part 34. Hydraulic test method of the electrochamber module used in the ballast water treatment system, characterized in that connected to the hose portion 610 through the hose connector 607 can be introduced into the electrochamber module 100. .

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