KR102289636B1 - Sealing inspection method and sealing inspection device of structure including flow path inside - Google Patents

Abstract

A sealing inspection method of a structure including a flow path therein is disclosed. The sealing inspection method of the structure including a flow path in the interior is a sealing inspection method of a structure including a flow path therein, and two openings in fluid communication with the flow path, which extend further in the longitudinal direction than the length of the prescribed standard of the flow path preparing an inlet and an outlet having extensions; After the adapter for pressure is in contact with the end surface of the extension part of the inlet, welding the circumference of the inner or outer end of the extension part, the adapter connection step for pressure; an outlet-side sealing step of inserting a barrier film having an inner diameter of the extension of the outlet or covering the outlet with a barrier film larger than the outer diameter of the outlet, and welding the periphery of the end of the extension of the outlet in contact with the barrier film; A sealing inspection step comprising pressing the flow path through the pressure adapter; and cutting and cutting the extended extension part after the sealing inspection step.

Description

Sealing inspection method and sealing inspection device for structures with flow path inside

The present invention relates to a sealing inspection method and a sealing inspection apparatus of a structure including a flow path therein, and more particularly, a sealing inspection method of a structure including a flow path inside, which can perform a sealing inspection without damage to a structure including a flow path inside, and It relates to an airtight inspection device.

A blanket shielding block used in a fusion device is a structure having a cooling flow path inside. This cooling path is formed by drilling from the outside of the blanket shielding material, and is made by blocking the outer surface by welding or the like. The structure manufactured in this way needs to be inspected for sealing the flow path.

This structure closes one of the two open openings and injects a high-pressure gas or liquid into the other to check whether it is sealed by maintaining the injected pressure for a certain period of time.

At this time, the outlet of the two openings must be tightly closed, and the high-pressure gas and liquid inlet must also be injected in a strongly sealed state. In order to strongly block the inlet and outlet, welding or strong bonding of sealing parts to the inlet and outlet of the flow path is required, and when the sealing part is detached after inspection, the inlet and outlet are damaged.

This blanket must have the performance to withstand the extreme environment in the fusion reactor, and at the same time have the exact required thickness.

There is a need for an inspection method that allows the structure manufactured to the required standard to maintain this standard even after the airtight inspection.

Therefore, the problem to be solved by the present invention is a sealing inspection method and sealing inspection apparatus for a structure including a flow path inside so that a loss of the specification of a flow path does not occur when a sealing part is removed after a sealing inspection of a structure including a flow path inside is to provide

The sealing inspection method of the structure having a flow path therein according to an embodiment of the present invention is a sealing inspection method of a structure including a flow path therein, and two openings in fluid communication with the flow path, the length of the specified standard of the flow path providing an inlet and an outlet having extensions that extend further in the longitudinal direction; After the adapter for pressure is in contact with the end surface of the extension part of the inlet, welding the circumference of the inner or outer end of the extension part, the adapter connection step for pressure; an outlet-side sealing step of inserting a barrier film having an inner diameter of the extension of the outlet or covering the outlet with a barrier film larger than the outer diameter of the outlet, and welding the periphery of the end of the extension of the outlet in contact with the barrier film; A sealing inspection step comprising pressing the flow path through the pressure adapter; and cutting and cutting the extended extension part after the sealing inspection step.

In one embodiment, when the outlet has first and second openings in a T-shape, and the first opening has an annular portion perpendicular inward from the end, the closing of the outlet may include: Inserting a first blocking film in the direction of the first opening to cover the inner surface of the ring-ring portion, welding the first blocking film and the end of the extension of the ring-ring portion, and a second blocking film having the size of the inner diameter of the extension of the second opening The method may include inserting or covering the second opening with a blocking film larger than an outer diameter of the extension of the second opening, and welding the periphery of the end of the extension of the second opening in contact with the second blocking film.

In one embodiment, after the extension portion of the ring-ring portion and the first blocking film are welded, the outer surface of the ring-ring portion is covered with a reinforcing plate, and the reinforcing plate and the first blocking film are screwed through the center hole of the ring-ring portion may include.

In one embodiment, the first blocking film may include, on one surface thereof, an embossed structure that can be fitted into the hole of the extension part of the annular part.

In one embodiment, the first blocking film may include a cylinder extending from the opposite surface not in contact with the annular portion and penetrating the second blocking film.

In an embodiment, the cylinder may include an opening in a side surface of the cylinder between the first blocking film and the second blocking film.

In one embodiment, a welding groove for the pressure adapter or the extension portion may be included at a welding position of the extension portion of the pressure adapter and the inlet.

In one embodiment, a welding groove may be included in the blocking film or the extension portion at a welding position of the extension portion of the blocking film and the outlet.

In one embodiment, the structure may be a blanket shield block for a fusion reactor.

In accordance with an embodiment of the present invention, there is provided an apparatus for inspecting sealing of a structure including a flow path therein, comprising: a flow path in the interior; and a closed inspection device without loss of dimensions of a structure having an inlet and an outlet in fluid communication with the flow path, the device comprising: an extension extending in a longitudinal direction more than a predetermined length of the inlet and the outlet; a pressing adapter welded around the inner or outer end of the extension in contact with the end face of the extension of the inlet; and a blocking film inserted into the inner diameter of the outlet or covering the outer diameter of the outlet, and welded to the circumference of the end of the extension of the outlet.

In one embodiment, when the outlet has first and second openings in a T-shape, wherein the first opening has an annular portion perpendicular inwardly from the distal end, the device may be configured to move in a direction of the first opening from the second opening a first blocking film inserted into and covering the inner surface of the round-rim and welded to the circumference of the end of the extension of the round-rim; and a second blocking film inserted into the inner diameter of the second opening or covering the outer diameter of the second opening and welded to the periphery of the end of the extension of the second opening.

In one embodiment, it may further include a reinforcing plate that covers the outer surface of the ring-ring portion and screwed with the first blocking film through the central hole of the extension portion of the ring-rim portion.

In one embodiment, the first blocking film may include, on one surface thereof, an embossed structure that can be fitted into the hole of the extension part of the annular part.

In one embodiment, the first blocking film may further include a cylinder extending from the opposite surface not in contact with the annular portion and penetrating the second blocking film.

In an embodiment, the cylinder may include an opening in a side surface of the cylinder between the first blocking film and the second blocking film.

In one embodiment, a welding groove for the pressure adapter or the extension portion may be included at a welding position of the extension portion of the pressure adapter and the inlet.

In one embodiment, a welding groove may be included in the blocking film or the extension portion at a welding position of the extension portion of the blocking film and the outlet.

In one embodiment, the structure may be a blanket shield block for a fusion reactor.

According to the sealing inspection method and the sealing inspection apparatus of the structure including the flow path inside according to the present invention, the loss of the specification of the flow path does not occur, and accordingly, the structure such as the blanket shield block for a nuclear fusion reactor is also maintained without deformation or damage, There is an advantage in that the problem of discarding the structure does not occur due to the deformation or damage of the structure in the sealing inspection process, so that it is possible to prevent the problem of wasted manpower according to the increase of the cost for the production of the structure and the reproduction of the structure.

1 is a flow chart showing the sequence of the sealing inspection method of the structure including the flow path inside according to an embodiment of the present invention.
2A to 2E are perspective views illustrating an embodiment of each step of FIG. 1 .
3A is a cross-sectional perspective view illustrating a flow path in which an outlet is extended in a T-shape.
3B to 3D are cross-sectional perspective views illustrating a process of an outlet-side sealing step in a flow path in which the outlet is extended in a T-shape.
4 is a cross-sectional perspective view showing another embodiment of the sealing inspection of the T-shaped flow path.

Hereinafter, with reference to the accompanying drawings, a sealing inspection method and sealing inspection apparatus of a structure including a flow path inside according to an embodiment of the present invention will be described in detail. Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals have been used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged than the actual size for clarity of the present invention.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a flow chart showing the sequence of the sealing inspection method of the structure including the flow path inside according to an embodiment of the present invention.

Referring to FIG. 1 , the sealing inspection method of the structure including the flow path therein without loss of the specification according to an embodiment of the present invention includes the steps of preparing an inlet and an outlet having an extension that is longer than the length of a predetermined standard in the longitudinal direction (S110); After contacting the adapter for pressure with the end surface of the extension of the inlet, welding the inner or outer end of the extension portion around the adapter for pressure (S120); an outlet-side sealing step (S130) of inserting a blocking film of the size of the inner diameter of the extension of the outlet or covering the outlet with a barrier greater than the outer diameter of the outlet, and welding the periphery of the end of the extension of the outlet in contact with the barrier; A sealing inspection step (S140), which includes pressing the flow path through the pressure adapter; and after the sealing inspection step, cutting and cutting the extended extension part (S150).

The sealing inspection method of the structure including the flow path therein according to an embodiment of the present invention may be applied to, for example, a T-shaped flow path having a straight flow path and a bent or branched area without a bent or branched area.

Tightness inspection in straight flow passages

2A to 2E are perspective views illustrating an embodiment of each step of FIG. 1 .

2A shows the state of the step S110. One side of the flow path 110 forms an inlet 111 , the opposite side of the inlet 111 of the flow path 110 forms an outlet 112 , and a flow path 110 at each of the inlet 111 and the outlet 112 . Extension parts 121 and 122 that extend further in the longitudinal direction than the length of the prescribed standard are provided. For example, the first extension 121 may be provided at the inlet 111 side, and the second extension 122 may be provided at the outlet 112 side. The first extension 121 and the second extension 122 are the connection points of the inlet 111 and the outlet 112 when connecting independent pipes to the inlet 111 and the outlet 112 of the flow path 110 . Since it can be easily broken in the flow path 110 , it is preferable to be integrally formed with the inlet 111 and the outlet 112 of the flow path 110 .

2B shows the state of the step S120. In order to connect the adapter for pressurization, the adapter for pressurization 130 is first prepared. For example, the adapter for pressurization 130 includes the fluid transfer pipe 131 and the first flange portion provided at one end of the fluid transfer pipe 131 . (132). Then, the adapter 130 for pressure is connected to the first extension 121 of the inlet 111, and at this time, the end surface of the fluid transfer pipe 131 of the adapter 130 for pressure is connected to the first extension. After being in contact with the end surface of (121), the circumference of the inner or outer end of the first extension part 121 is welded. For example, as shown in FIG. 2B , the circumference of the inner end of the first extension part 121 may be welded.

2C shows the state of the step S130. In order to seal the outlet side, the blocking film 140 is first prepared. The blocking film 140 has the same size as the inner diameter of the second extension 122 of the outlet 112 or is larger than the outer diameter of the second extension 122 . can have a diameter. For example, the blocking film 140 may be provided to have a diameter greater than the outer diameter of the second extension part 122 . The blocking film 140 having a larger diameter than the outer diameter of the second extension portion 122 covers the outlet 112 by covering the end of the second extension portion 122 , and the second of the outlet 112 in contact with the blocking film 140 . The blocking film 140 is fixed by welding the periphery of the end of the extension 122 , that is, welding the periphery of the end of the second extension 122 from the outside of the second extension 122 .

2D shows the state of step 140 above. For the sealing test, the flow path is pressurized through the pressure adapter 130 . At this time, a high-pressure fluid is injected into the flow path to pressurize the flow path. To this end, the first flange portion 132 of the adapter 130 for pressurization is connected to a pipe of a device for supplying a high-pressure fluid in a flange-joining manner, so that the high-pressure fluid is supplied to the flow path 110 through the adapter 130 for pressurization. ) can be injected into the As such, when the high-pressure fluid is supplied from the inside of the flow path 110, that is, from the inlet 111 to the outlet 112, the high-pressure fluid is fixed to the second extension 122 of the outlet 112. The blocking film 140 is pressed, and at this time, it is detected whether there is a leak of fluid around the end of the second extension 122 of the outlet 112 to perform a sealing test.

2E shows the state of the 150 step. After the sealing inspection is completed, the first extension 121 of the inlet 111 and the second extension 122 of the outlet 112 are cut and cut from the inlet 111 and the outlet 112 of the flow path 110 . is removed At this time, since only the first extension part 121 and the second extension part 122 extending more than the entire length of the flow path 110 are cut and removed, the overall size of the flow path 110 is maintained.

Sealing inspection in T-shaped flow path

3A is a cross-sectional perspective view illustrating a flow path in which an outlet extends in a T-shape, and FIGS. 3B to 3D are cross-sectional perspective views illustrating a process of an outlet sealing step in a flow path in which an outlet is extended in a T-shape.

As shown in FIG. 3A , in the case of a T-shaped flow path, the outlet 212 of the flow path 210 has a T-shaped first opening 2121 and a second opening 2122, and the first opening 2121 is It may have an annular portion 2123 perpendicular to the inside from the end. In addition, the ring-ring portion 2123 includes a third extension portion 221 extending in the central direction of the ring-ring portion 2123 , and the second opening 2122 has a fourth extension equal to the diameter of the second opening 2122 . part 222 may be included. The closing step (S130) of the outlet side of the flow path 210 proceeds as described below, which will be described with reference to FIG. 3 .

Since the inlet 211 side of the T-shaped flow path is the same as the pressure adapter connection step S120 described with reference to FIG. 2A in the description of the sealing inspection process in the straight flow path described above, a detailed description thereof will be omitted.

Referring to FIG. 3B , first, the first blocking film 231 is inserted from the second opening 2122 to the first opening 2121 to cover the inner surface of the annular part 2123 , and the first blocking film 231 is inserted. And the circumference of the end of the third extension 221 of the ring-rim portion 2123 is welded. That is, the circumference of the end of the inner surface of the third extension portion 221 of the ring-ring portion 2123 in contact with the first blocking film 231 is welded.

Referring to FIG. 3C , the second opening 2122 is covered with a second blocking layer 232 . For example, the second blocking film 232 may be provided to have a diameter equal to or greater than the outer diameter of the fourth extension 222 of the second opening 2122 . there is. When the diameter of the second blocking film 232 is the same as the inner diameter of the fourth extension 222 , the second blocking film 232 may be inserted into the fourth extension 222 to cover the second opening 2122 . and when the diameter of the second blocking film 232 is larger than the outer diameter of the fourth extension part 222 , the second blocking film 232 may cover the end of the fourth extension part 222 to cover the second opening 2122 . there is. For example, a second opening 2122 contacting the second blocking film 232 by inserting the second blocking film 232 having the same diameter as the inner diameter of the fourth extension 222 into the fourth extension 222 . The second blocking film 232 may be fixed by welding the periphery of the end of the fourth extension part 222 .

Referring to FIG. 3D , after the first blocking film 231 is welded to the ring-shaped part 2123 , the reinforcing plate 240 is coupled thereto for more robust sealing. That is, the outer surface of the ring-ring portion 2123 is covered with the reinforcing plate 240 , and the reinforcing plate 240 and the first blocking film 231 are screwed through the center hole of the ring-ring portion 2123 . The screw may be coupled to the first blocking film 231 through the central hole of the reinforcing plate 240 and the annular portion 2123 . In the process of (c), when the first opening 2121 is closed only with the first blocking film 231 , when the high pressure pressure is injected into the flow path 210 , the annulus 2123 becomes convex by the high pressure and Since deformation of the same circular ring portion 2123 may occur, the reinforcing plate 240 may be coupled to prevent this.

Meanwhile, the first blocking film 231 shown in FIGS. 3A to 3D may have an embossed structure 2311 that can be fitted into the center hole of the third extension part 221 of the ring-shaped part 2123 . In this case, as the embossed structure 2311 is fitted into the center hole of the third extension 221 of the ring-shaped portion 2123 , the first blocking film 231 may be more strongly coupled and more tightly sealed. When the embossed structure 2311 is fitted in the center hole of the third extension 221 of the ring-ring 2123, the periphery of the end of the third extension 221 of the ring-ring 2123 in contact with the embossed structure is welded to the first 1 The blocking layer 231 may be fixed.

After sealing the outlet 212 in this way, when the high-pressure fluid is supplied from the inlet 211 communicating with the outlet 212 in the direction of the outlet 212, the high-pressure fluid is supplied to the first blocking film 231 of the outlet 212 and The second blocking film 232 is pressed, and at this time, a sealing test is performed by detecting whether there is a fluid leak in the first opening 2121 and the second opening 2122 of the outlet 212 .

4 is a view showing another embodiment of the sealing inspection of the T-shaped flow path.

Referring to FIG. 4 , as another embodiment of the sealing test of the T-shaped flow path, the outlet 212 in the T-shaped flow path may be used as an inlet for injecting a high-pressure fluid. In this case, a cylinder 250 extending from the opposite surface of the first blocking film 231 not in contact with the annular portion 2123 and penetrating the second blocking film 232 may be provided, and the first blocking film 231 and An opening 252 corresponding to the inlet 211 of the flow path 210 may be provided on a side surface of the cylinder 250 between the second blocking layers 232 . The cylinder 250 may serve as the adapter 130 for pressurization mentioned in the description of sealing inspection in a straight flow path. To this end, a second flange portion 251 may be provided at an end of the cylinder 250 penetrating through the second blocking film 232 .

Meanwhile, welding grooves 121a , 122a , 231a , and 232a may be formed in the welding portion during the sealing inspection process in the linear flow path and the sealing inspection process in the T-shaped flow path described above.

That is, in the sealing test in the straight flow path, the first to the adapter 130 or the first extension 121 for pressure at the welding position of the adapter 130 and the first extension 121 of the inlet 111 for pressure. After the welding groove (121a) is formed, welding may be made in the first welding groove (121a), and at the welding position of the blocking film 140 and the second extension part 122 of the outlet 112, the blocking film 140 or After forming the second welding groove 122a in the second extension portion 122, welding may be performed in the second welding groove 122a.

In the sealing test in the T-shaped flow path, the first blocking membrane 231 or the third extended part ( 231 ) or the third extended part ( After the third welding groove 231a is formed in the 221 , welding may be performed in the third welding groove 231a , and the second blocking film 232 and the second opening 2122 of the outlet 212 have a fourth After the fourth welding groove 232a is formed in the second blocking film 232 or the fourth extended portion 222 at the welding position of the extended portion 222 , welding may be performed within the fourth welding groove 232a.

As described above, if the welding grooves 121a, 122a, 231a, 232a are formed at each welding position and then welded, welding is facilitated, and the problem of welding being released by the pressure of the high-pressure fluid injected can be prevented.

After the sealing inspection is completed through the sealing inspection method of the structure including the flow path described above, each of the extension parts 121, 122, 221, 222 is cut and cut, but only the extension parts 121, 122, 221, 222 Since it is cut and removed, the loss of the specification of the flow path 110 does not occur, and accordingly, the structure is also maintained without deformation or damage. There is an advantage in that it is possible to prevent the problem of wasting manpower according to an increase in the cost required for the production and the reproduction of the structure.

The structure subject to the sealing inspection method of the structure including the flow path therein is capable of sealing inspection of the structures of various shapes and structures including the flow path therein. As an example, the structure may be a blanket shielding block for a fusion reactor, and the blanket shielding block for a fusion reactor is sealed and inspected through the sealing inspection method of the structure including a flow path inside the fusion reactor even after the sealing test. standard can be maintained.

On the other hand, in order to implement the sealing inspection method of the structure having a flow path therein without loss of these specifications, the sealing inspection apparatus of the structure including the flow path is used inside.

Sealing inspection apparatus according to an embodiment of the present invention, the flow path therein; and a closed inspection device without loss of dimensions of a structure having an inlet and an outlet in fluid communication with the flow path, the device comprising: an extension extending in a longitudinal direction more than a predetermined length of the inlet and the outlet; a pressing adapter welded around the inner or outer end of the extension in contact with the end face of the extension of the inlet; and a blocking film inserted into the inner diameter of the outlet or covering the outer diameter of the outlet, and welded to the circumference of the end of the extension of the outlet.

The extension portion may be the first to second extension portions 122 illustrated in FIG. 2 , the pressure adapter may be the pressure adapter 130 illustrated in FIG. 2 , and the blocking film may be the pressure adapter 130 illustrated in FIG. 2 . It may be a blocking film 140 . The first to second extensions 122 , the pressure adapter 130 , and the blocking film 140 have been described in detail in the description of the sealing inspection method of the structure including the flow path therein, so detailed descriptions of each will be omitted.

On the other hand, when the outlet has first and second openings in a T-shape, and the first opening has an annular portion perpendicular inward from the end, the sealing inspection device is inserted from the second opening in the direction of the first opening a first blocking film covering the inner surface of the ring-ring portion and welding the first blocking film and the end of the extended portion of the ring-ring portion; and a second blocking film inserted into the inner diameter of the second opening or covering the outer diameter of the second opening and welded to the periphery of the end of the extension of the second opening.

In addition, it may further include a reinforcing plate covering the outer surface of the round-rim portion and screwed with the reinforcing plate and the first blocking film through the center hole of the round-ring portion.

In addition, the first blocking film may include, on one surface thereof, an embossed structure that can be fitted into the hole of the extension part of the annular part.

In addition, it may include a cylinder extending from the opposite surface of the first blocking film not in contact with the annular portion and penetrating the second blocking film.

Also, the cylinder may include an opening in a side surface of the cylinder between the first blocking film and the second blocking film.

In addition, a welding groove for the pressure adapter or the extension portion may be included at a welding position of the extension portion of the pressure adapter and the inlet.

In addition, a welding groove may be included in the blocking membrane or the extended portion at a welding position of the blocking membrane and the extension of the outlet.

The first blocking film, the second blocking film, the reinforcing plate, the embossed structure, the cylinder, the opening, and the welding grooves are the first blocking film 231 , the second blocking film 232 , and the reinforcement plate shown in FIG. 3 . 240, the embossed structure 2311, the cylinder 250, the opening 252 and the welding grooves (121a, 122a, 231a, 232a) may be. The first blocking film 231 , the second blocking film 232 , the reinforcing plate 240 , the embossed structure 2311 , the cylinder 250 , the opening 252 , and the welding grooves 121a , 122a , 231a , and 232a are formed inside. Since it has been described in detail in the description of the sealing inspection method of the structure including the flow path, a detailed description of each will be omitted.

If the sealing inspection device of the structure including the flow path is used inside according to an embodiment of the present invention, the loss of the specification of the flow path does not occur, and accordingly, the structure is also maintained without deformation or damage. The sealing inspection method of the structure including the flow path can be carried out to prevent the problem of the structure being discarded due to deformation or damage, thereby preventing the increase in the cost of production of the structure and the wasting of manpower due to the reproduction of the structure. can

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (18)

As a sealing inspection method of a structure comprising two openings in fluid communication with the flow passages (110, 210) and the flow passages (110, 210) therein,
preparing inlets (111, 211) and outlets (112, 212) having extensions (121, 122, 221, 222) that extend further in the longitudinal direction than the predetermined length of the flow paths (110, 210);
Adapting the adapter 130 for pressure to the end surface of the extension 121 of the inlet 111 and then welding the circumference of the inner or outer end of the extension 121 to the adapter connection step for pressure;
The blocking films 140, 231, 232 having the size of the inner diameter of the extensions 122, 221, 222 of the outlets 112, 212 are inserted, or the blocking films 140, 231, which are larger than the outer diameter of the outlets 112, 212. 232) covering the outlets 112, 212, and welding around the ends of the extensions 122, 221, 222 of the outlets 112, 212 in contact with the blocking films 140, 231, 232, the outlet side sealing step;
A sealing inspection step, comprising pressing the flow path (110, 210) through the pressure adapter (130); and
After the sealing inspection step, comprising cutting and cutting the extended extension (121, 122, 221, 222),
When the outlet 212 has first and second openings 2121 and 2122 in a T-shape, and the first opening 2121 has an annular portion 2123 perpendicular to the inside from the end,
The outlet side sealing step,
A first blocking film 231 is inserted from the second opening 2122 in the direction of the first opening 2121 to cover the inner surface of the annular part 2123, and the first blocking film 231 and the ring Welding the circumference of the end of the extension 221 of the rim 2123,
The second blocking film 232 having the size of the inner diameter of the extension 222 of the second opening 2122 is inserted, or the second blocking film 232 is larger than the outer diameter of the extension 222 of the second opening 2122 . Covering the second opening 2122 with a , and welding the periphery of the end of the extension portion 222 of the second opening 2122 in contact with the second blocking film 232 ,
A method of sealing inspection of structures with flow passages inside without loss of specifications. delete According to claim 1,
After the extension part 221 of the ring-shaped part 2123 and the first blocking film 231 are welded,
Covering the outer surface of the ring-ring portion 2123 with the reinforcing plate 240, and screwing the reinforcing plate 240 and the first blocking film 231 through the center hole of the ring-ring portion 2123 ,
Method of sealing inspection of structures with flow passages inside. According to claim 1,
The first blocking film 231 includes, on one surface thereof, an embossed structure 2311 that can be fitted into the hole of the extension part 221 of the annular part 2123,
Method of sealing inspection of structures with flow passages inside. According to claim 1,
and a cylinder 250 extending from an opposite surface of the first blocking film 231 that is not in contact with the annular portion 2123 and penetrating the second blocking film 232 ,
Method of sealing inspection of structures with flow passages inside. 6. The method of claim 5,
wherein the cylinder (250) includes an opening (252) in a side surface of the cylinder (250) between the first blocking film (231) and the second blocking film (232);
Method of sealing inspection of structures with flow passages inside. According to claim 1,
Including a welding groove (121a) in the adapter 130 or the extension portion 121 for the pressure at the welding position of the adapter 130 and the extension portion 121 of the inlet 111 for the pressure,
Method of sealing inspection of structures with flow passages inside. According to claim 1,
The blocking films 140, 231, 232 or the extensions 122, 221, 222 are located at the welding positions of the blocking films 140, 231, 232 and the extensions 122, 221, 222 of the outlets 112, 212. ), including grooves for welding (122a, 231a, 232a),
Method of sealing inspection of structures with flow passages inside. According to claim 1,
The structure is characterized in that it is a blanket shielding block for a nuclear fusion reactor,
Method of sealing inspection of structures with flow passages inside. flow passages (110, 210) therein; And as a closed inspection device without loss of dimensions of the structure having inlets (111, 211) and outlets (112, 212) in fluid communication with the flow passages (110, 210),
The device is
The inlets (111, 211) and the outlets (112, 212) extending more in the longitudinal direction than the length of the standard (121, 122, 221, 222);
an adapter 130 for pressing that is welded around the inner or outer end of the extension 121 in contact with the end surface of the extension 121 of the inlet 111; and
The blocking film 140 is inserted into the inner diameter of the outlets 112 and 212 or covers the outer diameters of the outlets 112 and 212, and is welded around the ends of the extensions 122 and 222 of the outlets 112 and 212, 231, 232);
When the outlet 212 has first and second openings 2121 and 2122 in a T-shape, and the first opening 2121 has an annular portion 2123 perpendicular to the inside from the end,
The device is
The first blocking film is inserted from the second opening 2122 in the direction of the first opening 2121 to cover the inner surface of the ring-ring portion 2123 and welded to the circumference of the end of the extension portion 221 of the ring-ring portion 2123 . (231); and
A second blocking film 232 inserted into the inner diameter of the second opening 2122 or covering the outer diameter of the second opening 2122 and welded to the circumference of the end of the extension part 222 of the second opening 2122 . comprising,
Airtight inspection device for structures with flow paths inside. delete 11. The method of claim 10,
Covering the outer surface of the ring-ring portion 2123 and further comprising a reinforcing plate 240 screwed with the first blocking film 231 through the center hole of the extension portion 221 of the ring-ring portion 2123,
Airtight inspection device for structures with flow passages inside. 11. The method of claim 10,
The first blocking film 231 includes, on one surface thereof, an embossed structure 2311 that can be fitted into the hole of the extension part 221 of the annular part 2123,
Airtight inspection device for structures with flow passages inside. 11. The method of claim 10,
Further comprising a cylinder 250 extending from the opposite surface of the first blocking film 231 not in contact with the annular portion 2123 and penetrating the second blocking film 232,
Airtight inspection device for structures with flow passages inside. 15. The method of claim 14,
wherein the cylinder (250) includes an opening (252) in a side surface of the cylinder (250) between the first blocking film (231) and the second blocking film (232);
Airtight inspection device for structures with flow passages inside. 11. The method of claim 10,
Containing a welding groove (121a) in the adapter 130 or the extension portion 121 for the pressure at the welding position of the adapter 130 and the extension portion 121 of the inlet 111 for the pressure,
Airtight inspection device for structures with flow passages inside. 11. The method of claim 10,
The blocking films 140 , 231 , 232 or the extensions 122 , 221 and 222 are located at the welding positions of the blocking films 140 , 231 , 232 and the extensions 122 , 221 , 222 of the outlets 112 and 212 . ), including grooves for welding (122a, 231a, 232a),
Airtight inspection device for structures with flow passages inside. 11. The method of claim 10,
The structure is characterized in that it is a blanket shielding block for a nuclear fusion reactor,
Airtight inspection device for structures with flow passages inside.

Images