JP2009066635A - Underwater repair system and underwater repair method using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an underwater repair system realizing a specific constitution capable of performing a repair work by welding a backing plate to a repairing part in an inner wall of a pool even in a narrow spare, and preventing a blowout hole from generating in the welding part, and to provide an underwater repair method using the same. <P>SOLUTION: The underwater repair system includes: a backing plate supporting device 6 for disposing and supporting the backing plate 4 in the repairing part of the inner wall 2 of the pool; a plug fitting device 7 for fitting a sealing plug 5 to a gas vent hole 4a of the backing plate 4; an underwater welding device 8 for welding the circumferential part of the backing plate 4 in a gas atmosphere, while forming and moving the gas atmosphere so as to cover the local part of the backing plate 4 supported by the backing plate supporting device 6, thereafter welding the circumferential part of the sealing plug 5, while forming the gas atmosphere so as to cover the entire sealing plug 5 fitted to the gas vent hole 4a of the backing plate 4 with the plug fitting device 7; and a control device 10 for remotely operating the backing plate supporting device 6, plug fitting device 7, and underwater welding device 8. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fuel storage pool installed in, for example, a nuclear power plant or a spent fuel storage facility, and in particular, an underwater repair system for repairing by welding a contact plate to a repaired portion of an inner wall of the pool, and the same. It relates to underwater repair methods.

  For example, a fuel storage pool installed in a nuclear power plant or a spent fuel storage facility has a structure in which a concrete plate is lined with a line plate (metal plate). As a method of repairing the repaired portion of the inner wall of the pool, for example, there is a method in which all the fuel in the pool is transferred and the water in the pool is discharged, and then the worker enters the pool and performs repair work. Alternatively, for example, there is a method in which a radiation shielding facility for forming a work room is temporarily installed in a pool, and after water in the work room is replaced with gas, an operator enters the work room and performs repair work. These methods not only require equipment for storing fuel transferred from the pool, radiation shielding equipment, etc., but also increase the work time.

  Therefore, for example, a chamber having an opening on the side facing the pool inner wall, a chamber holding mechanism that presses the chamber against the pool inner wall with a predetermined pressure, and a gas injection mechanism that replaces water in the chamber with a gas such as argon. And an underwater welding apparatus in which a patch support mechanism, a welding torch, a welding torch moving mechanism, a filler material feeding mechanism, a monitoring mechanism, and the like are housed in the chamber have been proposed (see, for example, Patent Document 1). For example, when repairing by repairing a patch (patent plate) to the repaired portion of the pool inner wall, the patch support mechanism patches the repaired portion of the pool inner wall while forming a gas phase space in the chamber by the gas injection mechanism. The peripheral edge of this patch is welded with a welding torch.

Japanese Patent Laid-Open No. 3-146268

However, there are the following problems in the above-described prior art.
In other words, the underwater welding apparatus accommodates a patch support mechanism, a welding torch, a welding torch moving mechanism, a filler material feeding mechanism, a monitoring mechanism, and the like in the chamber (in other words, covering at least the entire contact plate). For example, it is difficult to use in a place (narrow part) where a structure is installed in the vicinity of the repaired part of the inner wall of the pool. In order to carry out the welding operation of the contact plate even in such a narrow part, for example, it is possible to employ a small underwater welding apparatus that performs welding while forming and moving a gas phase space so as to cover the local part of the contact plate. Conceivable. However, when this type of underwater welding equipment is used to weld the peripheral edge of the backing plate, water exists in the gap between the backing plate and the inner wall of the pool, and this water is heated by the welding heat and evaporates. There is a risk of holes. Therefore, although a method of forming a gas vent hole in the caul plate can be considered, in this case, it is necessary to attach a closing plug to the gas vent hole of the caul plate after welding the peripheral portion of the caul plate.

  The object of the present invention has been made based on the above matters, and the object of the present invention is to be able to carry out the repair work by repairing the repaired part of the pool inner wall by welding the contact plate even in the narrow part. It is to provide an underwater repair system capable of realizing such a configuration and thereby preventing a blow-out hole from being generated in a welded portion, and an underwater repair method using the same.

  In order to achieve the above object, the present invention provides an underwater repair system for repairing a repaired portion of a pool inner wall by welding a patch plate to the repaired portion of the pool inner wall. A caulking plate support device, a plug mounting device for attaching a closing plug to the vent hole of the caulking plate, and a gas phase space so as to cover a local part of the caulking plate supported by the caulking plate support device. And welding the peripheral edge portion of the contact plate in the gas phase space, and then forming the gas phase space so as to cover the entire closure plug attached to the vent hole of the contact plate with the plug mounting device However, an underwater welding apparatus that welds the peripheral edge of the closing plug, the support plate support apparatus, the plug mounting apparatus, and a control apparatus that remotely operates the underwater welding apparatus.

  In order to achieve the above object, the present invention provides a repair by remotely operating the contact plate support device, the underwater welding device, and the plug mounting device with a control device, and welding the contact plate to the repaired portion of the pool inner wall. An underwater repair method, wherein the pad plate supporting device supports the pad plate on a repaired portion of the inner wall of the pool and is supported by the pad plate supporting device by the underwater welding device. A procedure for welding a peripheral edge portion of the backing plate in the gas phase space while moving by forming a gas phase space so as to cover a local portion of the backing plate, and the plug mounting device to the repaired portion of the inner wall of the pool A procedure for attaching a closing plug to the vent hole of the attached caul plate, and a gas phase space is formed by the underwater welding apparatus so as to cover the entire closing plug attached to the vent hole of the caul plate. And a procedure for welding the periphery of the closing plug while.

  According to the present invention, a specific configuration is realized in which the repair work of repairing by welding the contact plate to the repaired portion of the inner wall of the pool can be performed even in the narrowed portion, and this causes a blowout hole in the welded portion. Can be prevented.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic diagram showing a part of the configuration of an embodiment of the underwater repair system of the present invention together with a fuel storage pool. Moreover, FIG. 2 is a perspective view showing the structure of the contact plate welded to the repaired portion of the pool inner wall.

  In FIG. 1, a fuel storage pool 1 has a structure in which a lining plate (metal plate) is lined on a concrete wall, and has a place (narrow portion) where a cooling water pipe 3 is provided in the vicinity of the pool inner wall 2. ing. The underwater repair system according to the present embodiment is configured to apply a patch plate 4 to a repaired portion of the pool inner wall 2 in such a narrow portion (for example, a defect generated in a joint 2a of a lining plate shown in FIGS. 7 to 11 described later). The purpose of the repair work is to repair by repairing a plate-shaped repair member.

  The backing plate 4 is made of the same metal material as that of the pool inner wall 2 (lining plate), and its peripheral portion has a slope formed on the front side (front side toward the paper surface in FIG. 2) in consideration of weldability. A route surface is formed at a portion (back side toward the paper surface in FIG. 2). In addition, the effect that the level | step difference of the contact plate 4 and the pool wall 2 is made smooth by forming a slope in the peripheral part of the contact plate 4 is also acquired.

  Further, for example, in order to prevent water in the gap between the contact plate 4 and the pool inner wall 2 from evaporating when the peripheral portion of the contact plate 4 is welded, a central portion of the contact plate 4 is formed. A gas vent hole 4a (specifically, a screw hole penetrating the contact plate 4) is formed, and a closing plug 5 that can be screwed into the gas vent hole 4a is prepared. The closing plug 5 is made of the same metal material as the contact plate 4 (in other words, the lining plate), and is formed at a screw portion 5a that is screwed into the vent 4a of the contact plate 4 and one end portion of the screw portion 5a. And a plate-like head portion 5b. In consideration of weldability, the peripheral portion of the head portion 5b of the closing plug 5 has a slope formed on the front side portion and a root surface formed on the back side portion.

  The underwater repair system attaches a stopper plug 5 to a stopper plate support device 6 (see FIG. 3 to be described later) that supports the stopper plate 4 by placing it on a repaired portion of the pool inner wall 2 and a vent hole 4a of the stopper plate 4. A plug mounting device 7 (see FIG. 4 to be described later) and a peripheral portion of the backing plate 4 are welded while forming and moving a gas phase space so as to cover a local portion of the backing plate 4, or a head portion of the closing plug 5 An underwater welding device 8 (see FIG. 1 and FIG. 5 to be described later) for welding the peripheral portion of the head portion 5b of the closing plug 5 while forming a gas phase space so as to cover the whole 5b, and installed on the operation floor 9 And a control device (control / monitoring panel) 10 for remotely operating the contact plate support device 6, the plug mounting device 7, and the underwater welding device 8. Further, a crane 11 for lowering the contact plate support device 6, the plug mounting device 7, and the underwater welding device 8 into the pool 1 is installed on the operation floor 9. Next, details of the contact plate support device 6, the plug mounting device 7, and the underwater welding device 8 will be described in order.

  FIG. 3 is a perspective view showing the overall structure of the contact plate support device 6.

  In FIG. 3, the contact plate support device 6 includes substantially plate-like side frames 12L and 12R, a main body fixing mechanism 13 provided on each of the side frames 12L and 12R (for example, four in total), A substantially plate-shaped center frame 14 disposed between the frames 12L and 12R and connected to the side frames 12L and 12R via a Y-axis direction moving mechanism, and a support provided to the center frame 14 via an X-axis direction moving mechanism. A frame 15 and a support plate support arm 16 that supports the support plate 4 and is provided on the support frame 15 so as to be rotatable in the Z-axis direction.

  The main body fixing mechanism 13 has an adsorption pad 13a and an ejector 13b, and the ejector 13b is supplied with water from a pump unit (not shown) on the operation floor 9 via a hose (not shown). Yes. The supply of water from the pump unit to the ejector 13 b is controlled by the control device 10. For example, when water is supplied to the ejector 13b, the ejector 13b ejects water to the front side of the side frames 12L and 12R (back side toward the paper surface in the drawing), thereby generating a negative pressure in the suction pad 13a. . As a result, the suction pad 13a is attracted to the pool inner wall 2, and the side frames 12L and 12R are fixed to the pool inner wall 2. On the other hand, for example, when the supply of water to the ejector 13b is stopped, the inside of the suction pad 13a becomes positive pressure, and the side frames 12L and 12R are detached from the pool inner wall 2. For example, when there is a step in the pool inner wall 2 between the plurality of main body fixing mechanisms 13, a plate or the like may be attached between the main body fixing mechanism 13 and the side frame 12L (or 12R).

  Although not shown in detail, the Y-axis direction moving mechanism has left and right hydraulic actuators provided on the side frames 12L and 12R. These left and right hydraulic actuators are driven by water supplied from a pump unit on the operation floor 9 via a hose (not shown), and the supply of water to the hydraulic actuator is controlled by the control device 10. (The same applies to other hydraulic actuators described later). For example, when the left and right hydraulic actuators are driven with the same operating amount, the center frame 14 is moved in the Y-axis direction while maintaining the posture with respect to the side frames 12L and 12R, while the left and right hydraulic actuators are operated differently. When driven by the amount, the center frame 14 is moved so as to be inclined with respect to the side frames 12L and 12R. Although not shown in detail, the X-axis direction moving mechanism has a hydraulic actuator, and the support frame 15 is moved in the X-axis direction with respect to the center frame 14 by driving the hydraulic actuator. Therefore, the control device 10 drives the above-described X-axis direction moving mechanism and Y-axis direction moving mechanism to move the position of the backing plate 4 supported by the backing plate support arm 16 (specifically, the repaired portion of the pool inner wall 2). The position of the abutting plate 4 in the X-axis direction and the Y-axis direction) is adjusted.

  At the tip of the contact plate support arm 16, a contact plate holding unit 17 for holding the contact plate 4 is detachably provided. The contact plate holding unit 17 includes a holding frame 18a having an opening in the center (see FIG. 7 described later, but may be formed in, for example, a substantially U-shaped plate shape), and the front side of the holding frame 18a (see FIG. An engagement portion 18b that is provided on the back side toward the middle sheet surface and can be fitted to the tip of the contact plate support arm 16 from the upper side (upper side in the drawing), and the upper and side sides of the holding frame 18a (in the drawing) For example, four holding plate holding mechanisms 19 (see FIG. 7) that hold the holding plate 4 provided on the back side of the holding frame 18a (front side in the drawing). And. The contact plate holding mechanism 19 has an adsorption pad and an ejector, and the ejector is supplied with water from a pump unit on the operation floor 9 via a hose (not shown). The supply of water from the pump unit to the ejector is controlled by the control device 10. For example, when water is supplied to the ejector, the ejector ejects water and generates a negative pressure in the suction pad. Accordingly, the suction pad sucks and holds the contact plate 4. On the other hand, for example, when the supply of water to the ejector is stopped, the inside of the suction pad becomes a positive pressure, and the suction pad releases the contact plate 4.

  At the front end side of the contact plate support arm 16, the contact plate pressing portion is located at the opening of the holding frame 18 a of the contact plate holding unit 17 and can contact the center portion of the contact plate 4 without interfering with the contact plate holding mechanism 19. 20 (see FIG. 7) is provided. In addition, the support frame 15 is provided with a contact plate pressing mechanism 21 (see FIG. 7) that rotates the contact plate support arm 16 in the Z-axis direction. The contact plate pressing mechanism 21 includes a hydraulic actuator 22, and the contact plate support arm 16 is rotated in the Z-axis direction with respect to the support frame 15 by driving the hydraulic actuator 22. Thereby, for example, the contact plate pressing portion 20 is brought into contact with the central portion of the contact plate 4 to press the contact plate 4 against the pool inner wall 2. Thereby, the base plate holding unit 17 can be removed so that a part of the peripheral edge of the base plate 4 can be welded.

  An operation cable (not shown) is connected to the contact plate holding unit 17. For example, when an operator on the operation floor 9 pulls the operation cable, the engagement portion 18 b of the contact plate holding unit 17 is applied. The plate support arm 16 is disengaged from the tip. Further, the contact plate holding unit 17 can be used even when it is detached from the contact plate support device 6, and can be used, for example, when recovering the contact plate 4 dropped into the pool 1.

  An illumination 23 that illuminates the contact plate 4 and a monitoring camera 24 that images the contact plate 4 from the Y-axis direction are provided at the center of the center frame 14, and the side frame 12R (or 12L) may have a contact plate. A surveillance camera (not shown) that images 4 from the X-axis direction is provided. An image of the monitoring camera 24 or the like is transmitted to the control device 10 via a signal line (not shown) and displayed on a monitoring monitor (not shown). As a result, the operator can visually check the position of the contact plate 4 and the like.

  A detector 26L having a contact 25, a detector moving mechanism 27L for moving the detector 26L in the X-axis direction, and a detection on the side frame 12L side (left side in the figure) from the contact plate support arm 16 in the center frame 14 And a detector moving mechanism 28L for moving the detector 26L in the Y-axis direction. The detector moving mechanism 27L includes a hydraulic actuator 29, and the detector 26L is moved in the X-axis direction with respect to the center frame 14 by driving the hydraulic actuator 29. The detector moving mechanism 28 </ b> L includes a hydraulic actuator 30, and the detector 26 </ b> L is moved in the Y-axis direction with respect to the center frame 14 by driving the hydraulic actuator 30. The detector 26L has a drive mechanism (not shown, for example, a mechanism driven using a spring or a hydraulic actuator) that moves the contact 25 in the Z-axis direction, and the contact 25 is placed on the contact plate 4 or the pool inner wall 2. The position of the contact 25 in the Z-axis direction when contacting each other is detected. The detection 26L outputs the detection value to the control device 10 via a signal line (not shown).

  Similarly, on the side frame 12R side (right side in the figure) from the contact plate support arm 16 in the center frame 14, a detector 26R having a contact 25 and a detector moving mechanism 27R that moves the detector 26R in the X-axis direction. And a detector moving mechanism 28R that moves the detector 26R in the Y-axis direction. Since the detector 26R and the detector moving mechanisms 27R and 28R are the same as the detector 26L and the detector moving mechanisms 27L and 28L described above, description thereof is omitted.

  The control device 10 controls the position of the contact 25 of the detector 26L in the X-axis direction and the Y-axis direction by driving the detector moving mechanisms 27L and 28L, and the contact 25 input from the detector 26L in the Z-axis direction. The position is stored in association with the position in the X-axis direction and the Y-axis direction. Further, the position of the contact 25 of the detector 26R in the X-axis direction and the Y-axis direction is controlled by driving the detector moving mechanisms 27R and 28R, and the position of the contact 25 input from the detector 26R in the Z-axis direction is set to X. It is stored in association with the position in the axial direction and the Y-axis direction. And the difference of the Z-axis direction position of the contactor 25 contact | abutted to the contact plate 4 and the Z-axis direction position of the contactor 23 contact | abutted to the pool inner wall 2 is calculated, and the contact plate 4 memorize | stored beforehand from this difference By subtracting the thickness dimension, the gap dimension between the contact plate 4 and the pool inner wall 2 is calculated, and the calculated value is displayed on the monitor.

  FIG. 4 is a perspective view showing the overall structure of the plug mounting device 7.

  In FIG. 4, the plug mounting device 7 includes a substantially U-shaped plate-shaped main body frame 31, for example, four main body fixing mechanisms 32 provided on the main body frame 31, and an X-axis direction moving mechanism on the main body frame 31. And a plug support arm 35 that supports the closing plug 5 and is provided on the slide frame 33 via a Y-axis direction moving mechanism 34.

  The main body fixing mechanism 32 has a suction pad 32a and an ejector 32b, and the ejector 32b is supplied with water from a pump unit on the operation floor 9 via a hose (not shown). For example, when water is supplied to the ejector 32b, the ejector 32b ejects water and generates a negative pressure in the suction pad 32a. As a result, the suction pad 32 a is attracted to the pool inner wall 2, and the main body frame 31 is fixed to the pool inner wall 2. On the other hand, for example, when the supply of water to the ejector 32 b is stopped, the inside of the suction pad 32 a becomes a positive pressure, and the main body frame 31 is detached from the pool inner wall 2. For example, when there is a step in the pool inner wall 2 between the plurality of main body fixing mechanisms 32, a plate or the like may be attached between the main body fixing mechanism 32 and the main body frame 31.

  Although not shown in detail, the X-axis direction moving mechanism includes a hydraulic actuator, and the slide frame 31 is moved in the X-axis direction with respect to the main body frame 29 by driving the hydraulic actuator. The Y-axis direction moving mechanism 34 includes a hydraulic actuator 36, and the plug support arm 35 is moved relative to the slide frame 33 in the Y-axis direction by driving the hydraulic actuator 36. Therefore, the control device 10 drives the X-axis direction moving mechanism and the Y-axis direction moving mechanism 34 described above to drive the position of the closing plug 5 supported by the plug support arm 35 (specifically, the vent hole of the contact plate 4). The position of the closing plug 5 with respect to 4a in the X-axis direction and the Y-axis direction) is adjusted.

  The plug support arm 35 includes an arm start portion 35a provided on the slide frame 33 via a Y-axis direction moving mechanism 34, and a Z axis direction via a pivot stay 35b and a pair of connecting stays 35c. An arm rotating part 35d connected to the arm rotating part 35a, and a plug rotating part 35e provided at the tip of the arm rotating part 35d and holding a closing plug and rotatable about the Z-axis. Yes.

  The plug rotating portion 35e of the plug support arm 35 is formed with a recess (not shown) into which the head portion 5b of the closing plug 5 is fitted, and a plug supporting mechanism 37 capable of supporting the screw portion 5a of the closing plug 5. Is provided. The plug support mechanism 37 engages with the screw part 5a of the closing plug 5, and engages with the engaging part 37a loosely fitting the head part 5b of the closing plug 5 with the plug rotating part 35e. And a drive mechanism for moving in a substantially Y-axis direction. Although not shown in detail, this drive mechanism has a hydraulic actuator, and by driving this hydraulic actuator, the engaging portion 37a is moved to engage with or disengage from the head portion 5b of the closing plug 5. It has become. That is, for example, in a preparatory stage where the threaded portion 5a of the closing plug 5 is not screwed into the vent hole 4a of the backing plate 4, the engaging portion 37a is engaged with the threaded portion 5a of the closing plug 5 to close it. On the other hand, in the middle stage of the mounting situation where the screw part 5a of the closing plug 5 is screwed into the gas vent hole 4a of the stopper plate 4, for example, the engaging part 37a becomes an obstacle at the final stage. The joining portion 37a is separated from the screw portion 5a of the closing plug 5.

  A plug pressing mechanism that rotates the arm rotation portion 35d in the Z-axis direction via a rotation stay 35b is provided on the arm starting end portion 35a of the plug support arm 35. Although not shown in detail, the plug pressing mechanism has a hydraulic actuator, and by driving the hydraulic actuator, the arm rotating portion 35d is rotated in the Z-axis direction with respect to the arm starting end portion 35a. Thus, a force for pressing the closing plug 5 against the gas vent hole 4 a of the contact plate 4 or a force for pulling the closing plug 5 from the gas vent hole 4 a of the contact plate 4 is applied.

  A plug rotation mechanism 38 that rotates the plug rotation unit 35e is provided on the arm rotation unit 35d of the plug support arm 35. The plug rotation mechanism 38 has, for example, a pair of hydraulic actuators 39A and 39B provided in the arm rotation portion 35d. Then, for example, while applying the pressing force by the plug pressing mechanism described above, the hydraulic actuator 39A of the plug rotating mechanism 38 is driven to rotate the plug rotating portion 35e in the forward direction, whereby the closing plug 5 is moved to the gas of the contact plate 4. It can be attached to the hole 4a. On the other hand, for example, by applying the pulling force by the plug pressing mechanism, the hydraulic actuator 39B of the plug rotating mechanism 38 is driven to rotate the plug rotating portion 35e in the reverse direction, so that the closing plug 5 is degassed in the contact plate 4 It can be removed from 4a.

  The slide frame 33 is provided with an illumination 40 that illuminates the closing plug 5 and a monitoring camera 41 that images the closing plug 5 from the X-axis direction, and the closing plug 5 is attached to the arm rotating portion 35d of the plug support arm 35. A surveillance camera (not shown) that captures an image from the Y-axis direction is provided. An image of the monitoring camera 41 or the like is transmitted to the control device 10 via a signal line (not shown) and displayed on the monitoring monitor. As a result, the operator can visually check the position of the closing plug 5 and the installation work status.

  FIG. 5 is a perspective view showing the overall structure of the underwater welding apparatus 8, and FIG. 6 is a partially enlarged view showing the schematic structure inside the partition wall of the underwater welding apparatus 8.

  5 and 6, an underwater welding apparatus 8 (in this embodiment, a solid partition type underwater dry TIG welding apparatus) includes a substantially frame-shaped main body frame 42 and a lower side of the main body frame 42 (see FIG. A pair of seating frames 43L and 43R seated on the cooling water pipe 3, and are connected to the seating frames 43L and 43R, respectively, and come into contact with the inner wall 2 of the pool at a plurality of upper and lower locations. Are provided on the seating frames 43L and 43R and clamp mechanisms 45L and 45R for clamping the cooling water pipe 3, respectively.

  The posture adjustment mechanism 44L (or 44R, hereinafter, the same correspondence in parentheses in this paragraph) is connected to the seating frame 43L (or 43L), and a pair of roller arms 46a extending in the vertical direction, and the roller arms 46a The roller 46b is rotatably supported at both ends. Then, the upper and lower rollers 46 b abut against the pool inner wall 2, so that the posture of the main body frame 42 is parallel to the pool inner wall 2. The clamp mechanism 45L (or 45R, hereinafter the same in parentheses in this paragraph) includes a gripping arm 47a that is rotatably provided on the seating frame 43L (or 43L), and a pneumatic pressure that rotates the gripping arm 47a. And an actuator 47b. The pneumatic actuator 47b is driven by air supplied from the operation floor 9 via a hose, and the air supply to the pneumatic actuator 47b is controlled by the control device 10 (note that other empty air described later is used). The same applies to pressure actuators). Then, the gripping arm 47a is rotated by the driving of the pneumatic actuator 47b, and the cooling water pipe 3 is clamped. As a result, the main body frame 42 is fixed to the cooling water pipe 3 while keeping the posture of the main body frame 42 parallel to the pool inner wall 2.

  The underwater welding device 8 is disposed within the frame of the main body frame 42, and is disposed within the frame of the main body frame 42, the first slide portion 48 provided on the main body frame 42 via the X-axis direction moving mechanism, A second slide portion 49 provided on one slide portion 48 via a Y-axis direction moving mechanism, a welding unit 50 provided on the second slide portion 49 via a first Z-axis direction moving mechanism, and a main body frame 42 A wire box 51 for accommodating a welding wire (melting material) disposed in the frame and a power source box 52 disposed in the frame of the main body frame 42.

  The X axis direction moving mechanism is not shown in detail, but is driven by an electric actuator (specifically, an electric signal output from the control device 10 through a signal line. The same applies to other electric actuators described later. The first slide portion is moved in the X-axis direction with respect to the main body frame 42 by driving the electric actuator. Although the details of the Y-axis direction moving mechanism are not shown, the Y-axis direction moving mechanism has an electric actuator, and by driving the electric actuator, the second slide portion 49 is moved in the Y-axis direction with respect to the first slide portion 48. . Although not shown in detail, the first Z-axis direction moving mechanism has an electric actuator, and the electric actuator is driven to move the welding unit 50 in the Z-axis direction with respect to the second slide portion 49. Therefore, the control device 10 drives the first Z-axis direction moving mechanism described above to press a partition wall 53 of a welding unit 50 described later against the contact plate 4 or the pool inner wall 2, and the X-axis direction moving mechanism and the Y-axis described above. By driving the direction moving mechanism, the welding unit 50 is moved in the X-axis direction and the Y-axis direction.

  The welding unit 50 is opposed to the casing 54 disposed between the main body frame 42 (and the cooling water pipe 3) and the pool inner wall 2, and the pool inner wall 2 on the lower side (lower side in FIG. 5) of the casing 54. And an annular partition wall 53 for forming a gas phase space so as to cover the local part of the contact plate 4 and the entire closure plug 5. The partition wall 53 is composed of a carbon felt that is formed at the distal end portion and has elasticity and less frictional force, and a sponge that is formed at the proximal end portion and has elasticity and low permeability compared to the carbon felt.

  An opening communicating with the inside of the partition wall 53 is formed in the casing 54, and a welding torch 55, a wire nozzle 56, an illumination 57, and a monitoring camera 58 are accommodated in the vicinity of the opening (see FIG. 6). .

  The wire box 51 is provided with a wire supply mechanism that supplies a welding wire to the wire nozzle 56 of the welding unit 50 via a hose 59 or the like. Although not shown in detail, the welding wire supply mechanism has an electric actuator. By driving the electric actuator, the welding wire is supplied to the wire nozzle 56 and led to the vicinity of the tip of the welding torch 55.

  The wire box 51 is supplied with an inert gas or the like (more specifically, at least one of inert gas and dry air can be selected) from the operation floor 9 via a hose. An inert gas or the like is supplied from the wire box 51 through the like, and the inert gas or the like is ejected into the partition wall 53. In addition, the inert gas or the like is supplied also into the casing 54 through a hose that is different from the hose that supplies the inert gas or the like to the wire box 51. Thus, a gas phase space can be formed inside the partition wall 53 in a state where the partition wall 53 is pressed against the pool inner wall 2, and the peripheral edge of the contact plate 4 and the head portion 5 b of the closing plug 5 in the partition wall 53. The peripheral edge can be welded with a welding torch 55. The controller 10 controls the pressure and flow rate of the inert gas and the pressure and flow rate of the dry air, respectively.

  Further, since it corresponds to the welding direction (in this embodiment, two directions of the X-axis direction and the Y-axis direction) in which the peripheral edge portion of the backing plate 4 and the peripheral edge portion of the head portion 5b of the closing plug 5 are welded, A wire position switching mechanism for switching the position of the wire nozzle 56 is provided. Although not shown in detail, the wire position switching mechanism includes a pneumatic actuator, and the position of the wire nozzle 56 with respect to the welding torch 55 (in other words, the welding wire supply position) is switched by driving the pneumatic actuator. That is, for example, when welding in the X-axis direction, the supply position of the welding wire to the welding torch 55 is switched to the left position shown in FIG. 6, while when welding in the Y-axis direction, for example, the upper side shown in FIG. Switch to the position.

  The monitoring camera 58 images the inside of the partition wall 53 (including the pool inner wall 2, the contact plate 4, the closing plug 5, or the welding torch 55) including the position of the wire nozzle 56, and the image is transmitted via a signal line. It is transmitted to the control device 10 and displayed on the monitoring monitor. In addition, a filter cover opening / closing mechanism (not shown) for reducing light is provided in front of the monitoring camera 58 so that strong light is emitted not only at the preparation stage, interruption stage and end stage of welding work. The situation during welding work can be imaged.

  The welding torch 55 is of an arc welding type having, for example, an arc electrode (tungsten electrode), and a second Z-axis direction moving mechanism for moving the welding torch 55 in the Z-axis direction is provided. Although not shown in detail, the second Z-axis direction moving mechanism has an electric actuator. By driving the electric actuator, the welding torch 55 is moved in the Z-axis direction with respect to the casing 54.

  For example, when performing arc voltage control (AVC: Arc Voltage Control) for the purpose of keeping the arc length constant in arc welding, the control device 10 compares the detected value of the arc voltage with a preset reference voltage, In response to this, the second Z-axis direction moving mechanism is driven to control the position of the welding torch 55 in the Z-axis direction, and the supply speed of the welding wire by the wire supply mechanism is controlled.

  For example, when the control device 10 detects the gap size between the contact plate 4 and the pool inner wall 2, the above-described second Z-axis direction moving mechanism (and the above-described X-axis direction moving mechanism, Y-axis direction moving mechanism, and the like). ) To bring the welding torch 55 into contact with the contact plate 4 and the pool inner wall 2. At this time, the second Z-axis direction moving mechanism (and the above-described X-axis direction moving mechanism and Y-axis are used by utilizing the phenomenon of electrical conduction when the welding torch 55 comes into contact with the contact plate 4 or the pool inner wall 2. Direction movement mechanism etc.) is automatically stopped. And the control apparatus 10 calculates the position of the Z-axis direction of the welding torch 55 when making it contact | abut each to the contact plate 4 and the pool inner wall 2, and the position of the Z-axis direction of this welding torch 55 is set to X-axis direction and It is stored in association with the position in the Y-axis direction. Then, the difference between the Z-axis direction position of the welding torch 55 in contact with the contact plate 4 and the Z-axis direction position of the welding torch 55 in contact with the pool inner wall 2 is calculated, and the contact plate 4 stored in advance from this difference. By subtracting the thickness dimension, the gap dimension between the contact plate 4 and the pool inner wall 2 is calculated, and the calculated value is displayed on the monitor.

  In addition, when the control device 10 detects, for example, the weld thickness of the welded portion in which the peripheral edge portion of the contact plate 4 or the peripheral edge portion of the closing plug is welded, the above-described second Z-axis direction moving mechanism (and the above-described X-axis direction). The moving mechanism and the Y-axis direction moving mechanism are driven to bring the welding torch 55 into contact with the toe of the welded portion. At this time, the second Z-axis direction moving mechanism (and the above-described X-axis direction moving mechanism and Y-axis direction moving mechanism, etc.) is utilized by utilizing an event that is electrically conducted when the welding torch 55 contacts the welded portion. Is automatically stopped. Then, the control device 10 calculates and stores the positions of the welding torch 55 in the X-axis direction, the Y-axis direction, and the Z-axis direction when brought into contact with the toes of the welded portion. The weld thickness of the welded portion is calculated based on the position of the welding torch 55 in contact with the toe of the welded portion, and the calculated value is displayed on the monitoring monitor.

  In the above description, the wire nozzle 56 of the underwater welding apparatus 8 constitutes a gas supply means for supplying gas to the inside of the partition wall described in the claims, and a melt material for supplying a filler material in the vicinity of the welding torch. The material supply means is configured. Further, the X-axis direction moving mechanism, the first slide part, the Y-axis direction moving mechanism, the second slide part, and the first Z-axis direction moving mechanism of the underwater welding apparatus 8 are the first welding movements that move the welding unit. Configure the mechanism. The second Z-axis direction moving mechanism of the underwater welding apparatus 8 constitutes a second welding moving mechanism that moves the welding torch.

  Next, an underwater repair method using the underwater repair system of this embodiment will be described with reference to FIGS. This underwater repair method is broadly divided into a contact plate arranging step, a contact plate temporary attachment step, a contact plate welding step, a closing plug attaching step, and a closing plug welding step.

(1) Placing plate placement process (see FIG. 7)
The operator first confirms on the operation floor 9 that there is no abnormality in the appearance of the backing plate 4. In addition, it is preferable to match the shape of the installation surface (back surface) of the backing plate 4 with the repaired portion of the pool inner wall 2. Further, the thickness dimension of the contact plate 4 is measured, and the measured value is input to the control device 10 and stored.

  Then, the control device 10 drives the contact plate holding mechanism 19 of the contact plate holding unit 17 attached to the distal end portion of the contact plate support arm 16 of the contact plate support device 6 so that the suction pad of the contact plate holding mechanism 19 is applied. The plate 4 is sucked and held. Thereafter, the operator lowers the contact plate support device 6 into the pool 1 with the crane 11 and arranges the contact plate 4 held by the contact plate support device 6 on the repaired portion of the pool inner wall 2. Then, the main body fixing mechanism 13 of the backing plate support device 6 is driven by the control device 10, and the suction pad 13 a of the main body fixing mechanism 13 is attracted to the pool inner wall 2 to fix the backing plate support device 6. At this time, the operator confirms the pressure in the suction pad 13a with a pressure gauge (not shown) connected to the main body fixing mechanism 13 via a hose (not shown). It is confirmed whether or not the adsorption pad 13a is adsorbed on the pool inner wall 2.

  Then, the operator confirms the position of the contact plate 4 from the image of the monitoring camera 24 of the contact plate support device 6 displayed on the monitor monitor, and if necessary, the control device 10 uses the X axis of the contact plate support device 6. The direction moving mechanism and the Y-axis direction moving mechanism are driven to move the contact plate support arm 16 to adjust the positions of the contact plate 4 in the X-axis direction and the Y-axis direction. Then, the control device 10 drives the contact plate pressing mechanism 21 of the contact plate support device 6 to rotate the contact plate support arm 16 so that the contact plate pressing portion 20 is brought into contact with the central portion of the contact plate 4. 4 is pressed against the pool inner wall 2. Then, after confirming the state in which the contact plate 4 is pressed against the pool inner wall 2 by a monitoring monitor, the worker removes the contact plate holding unit 17 from the contact plate support device 6 and collects it.

  For example, the detector 10 moves the detector moving mechanisms 27L, 28L or 27R, 28R by the control device 10 with the intention of detecting the gap size between the backing plate 4 and the pool inner wall 2 at a plurality of locations including the four corners of the backing plate 4. The position in the X-axis direction and the Y-axis direction of the detector 26L or 26R is controlled by driving, and the Z-axis direction position when the contactor 25 of the detector 26L or 26R abuts against the contact plate 4 or the pool inner wall 2 is determined. To detect. The control device 10 calculates the clearance dimension between the contact plate 4 and the pool inner wall 2 based on the detection result and the thickness dimension of the contact plate 4 stored in advance, and displays the calculated value on the monitor monitor. Thereby, an operator confirms whether it is in the condition where the gap dimension of the contact plate 4 and the pool inner wall 2 is large, and cannot be welded, for example.

(2) Temporary attachment process of the backing plate (see FIG. 8)
The operator lowers the underwater welding device 8 into the pool 1 with the crane 11 and seats the underwater welding device 8 on the cooling water pipe 3. At this time, in order to minimize the intrusion of water into the welding unit 50 of the underwater welding apparatus 8, dry air is supplied into the casing 54 of the welding unit 50 and the partition wall of the welding unit 50 through the wire nozzle 56 and the like. 53 is supplied with dry air. Further, the operator confirms the position of the welding unit 50 from the video of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor, and adjusts the arrangement of the underwater welding apparatus 8. Thereafter, the clamp mechanism 45L, 45R of the underwater welding device 8 is driven by the control device 10 so that the gripping arm 47a clamps the cooling water pipe 3 and fixes the underwater welding device 8.

  Then, the control device 10 drives the first Z-axis direction moving mechanism of the underwater welding device 8 to press the partition wall 53 of the welding unit 50 against the contact plate 4 or the pool inner wall 2. As a result, the partition wall 53 is filled with dry air, and a gas phase space is formed. Then, the control unit 10 switches the dry air supplied to the welding unit 50 (specifically, the partition wall 53 and the casing 54) to an inert gas, and then drives the X-axis direction moving mechanism, the Y-axis direction moving mechanism, and the like. While moving the welding unit 50, a plurality of locations on the peripheral edge of the contact plate 4 in the partition wall 53 are welded with the welding torch 55, and the contact plate 4 is temporarily attached. Further, the operator confirms whether or not there is any abnormality in the weld bead welded to the peripheral portion of the backing plate 4 by the video of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor.

(3) Patch plate welding process (see FIG. 9)
After the inert gas supplied to the welding unit 50 of the underwater welding device 8 is switched to dry air, the clamp mechanism 45L, 45R of the underwater welding device 8 is driven by the control device 10 to release the clamping of the gripping arm 47a. The welding device 8 is once detached from the repaired portion of the pool inner wall 2. Thereafter, the main body fixing mechanism 13 of the backing plate support device 6 is stopped by the control device 10 and the backing plate support device 6 is recovered. Then, in the same procedure as described above, the underwater welding device 8 is fixed to the cooling water pipe 3 again, and the partition wall 53 of the welding unit 50 is pressed against the contact plate 4 or the pool inner wall.

  Then, for example, the control device 10 uses the X-axis direction moving mechanism and the Y-axis of the underwater welding device 8 with the intention of detecting the gap size between the backing plate 4 and the pool inner wall at a plurality of locations including the four corners of the backing plate 4. The direction moving mechanism is driven to control the positions of the welding torch 55 in the X-axis direction and the Y-axis direction, and the second Z-axis direction moving mechanism (and the first Z-axis direction moving mechanism) is driven to apply the contact plate 4. Further, the Z-axis direction position of the welding torch 55 when it is brought into contact with the pool inner wall 2 is calculated. The control device 10 calculates the clearance dimension between the backing plate 4 and the pool inner wall 2 based on the calculated values and the thickness dimension of the backing plate 4 stored in advance, and displays the computed value on the monitor monitor. Thereby, an operator confirms whether it is in the condition where the gap dimension of the contact plate 4 and the pool inner wall 2 is large, and cannot be welded, for example.

  Then, for example, with the intention of performing first layer welding (first layer welding) on the peripheral edge of the backing plate 4, the operator uses a video image of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. While confirming the position of 55, the controller 10 drives the X-axis direction moving mechanism and the Y-axis direction moving mechanism to move the welding torch 55 from the welding start position to the welding end position along the welding line, and passes through the welding. The points are stored in the control device 10 (teaching work). Thereafter, the welding torch 55 in a state where no welding arc is generated is moved based on the welding passing point stored in the control device 10 and is checked in advance. Then, the dry air supplied to the welding unit 50 is switched to an inert gas, and the first layer welding is performed on the peripheral portion of the contact plate 4.

  Thereafter, the operator confirms whether there is no abnormality in the first layer weld bead welded to the peripheral portion of the backing plate 4 by the video of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. Further, the inert gas supplied to the welding unit 50 of the underwater welding apparatus 8 is switched to dry air in the same procedure as described above, and the underwater welding apparatus 8 is once detached from the repaired portion of the pool inner wall 2. Thereafter, the underwater camera (not shown) is lowered from the operation floor 9 into the pool 1, and it is confirmed whether or not there is any abnormality in the first layer weld bead welded to the peripheral edge of the backing plate 4 by the image of the underwater camera. Then, in the same procedure as described above, the underwater welding device 8 is fixed to the cooling water pipe 3 again, and the partition wall 53 of the welding unit 50 is pressed against the contact plate 4 or the pool inner wall.

  Then, for example, with the intention of performing lamination welding (second layer welding) on the peripheral edge portion of the contact plate 4, the operator uses a video image of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. The X-axis direction moving mechanism and the Y-axis direction moving mechanism are driven by the control device 10 while checking the position of the welding position, and the welding torch 55 is moved from the welding start position to the welding end position along the weld line, and the welding passing point Is stored in the control device 10 (teaching work). Thereafter, the welding torch 55 in a state where no welding arc is generated is moved based on the welding passing point stored in the control device 10 and is checked in advance. Then, the dry air supplied to the welding unit 50 is switched to an inert gas, and lamination welding is performed on the peripheral portion of the contact plate 4.

  Thereafter, the operator confirms whether or not there is any abnormality in the laminated weld bead welded to the peripheral portion of the backing plate 4 by the image of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. Then, when all the welding operations at the peripheral edge of the backing plate 4 are completed (in the above description, the case up to the second layer welding has been described as an example, but the procedure similar to the above is repeated to perform the third layer welding and the subsequent steps. The inert gas supplied to the welding unit 50 of the underwater welding apparatus 8 is switched to dry air.

  For example, the control device 10 drives the X-axis direction moving mechanism and the Y-axis direction moving mechanism of the underwater welding device 8 with the intention of detecting the gutter thickness of the laminated welded portion welded to the peripheral edge portion of the backing plate 4. The position of the welding torch 55 in the X-axis direction and the Y-axis direction is controlled, and the second Z-axis direction moving mechanism (and the first Z-axis direction moving mechanism) is driven to contact the toe of the laminated welded portion. The position of the welding torch 55 when contacted is calculated. The control device 10 calculates the gutter thickness of the laminated welded portion based on these calculated values, and displays the calculated value on the monitor monitor. Thereby, an operator confirms whether the gutter thickness of the lamination | stacking welding part welded to the peripheral part of the contact plate 4 is appropriate. Thereafter, the underwater welding device 8 is once detached from the repaired portion of the pool inner wall 2 in the same procedure as described above.

(4) Closing plug installation process (see Fig. 10)
On the operation floor 9, the worker holds the closing plug 5 on the plug rotating portion 35 e of the plug support arm 35 of the plug mounting device 7. Thereafter, the plug attachment device 7 is lowered into the pool 1 by the crane 11, and the closing plug 5 held by the plug attachment device 6 is arranged in the gas vent hole 4 a of the contact plate 4. Then, the main body fixing mechanism 32 of the plug attachment device 7 is driven by the control device 10, and the suction pad 32 a of the main body fixation mechanism 32 is attracted to the pool inner wall 2 to fix the plug attachment device 7. At this time, the operator confirms the pressure in the suction pad 32a by using a pressure gauge (not shown) connected to the main body fixing mechanism 32 via a hose (not shown). It is confirmed whether or not the adsorption pad 32a is adsorbed to the pool inner wall 2.

  Then, the operator confirms the position of the closing plug 5 from the video of the monitoring camera 41 of the plug mounting device 7 displayed on the monitoring monitor, and moves the plug mounting device 7 in the X-axis direction by the control device 10 as necessary. The mechanism and the Y-axis direction moving mechanism 34 are driven to move the plug support arm 35 to adjust the position of the closing plug 5 in the X-axis direction and the Y-axis direction. Then, the control device 10 drives the plug pressing mechanism of the plug mounting device 7 to rotate the arm rotating portion 35 d of the plug support arm 35, thereby pressing the closing plug 5 against the gas vent hole 4 of the abutting plate 4. The operator confirms the state in which the closing plug 5 is pressed against the vent hole 4a of the contact plate 4 by the image of the monitoring camera 41 of the plug mounting device 7 displayed on the monitoring monitor. Thereafter, the control device 10 drives the plug rotating mechanism 38 of the plug mounting device 7 to rotate the plug rotating portion 35 e, and the screw portion 5 a of the closing plug 5 is screwed into the gas vent hole 4 a of the contact plate 4. At this time, the operator confirms the mounting state of the closing plug 5 from the video of the monitoring camera 41 of the plug mounting device 7 displayed on the monitoring monitor, and when the mounting state is in the middle stage, the engagement of the plug support mechanism 37 is performed. The part 37 a is detached from the screw part 5 a of the closing plug 5. Then, after attaching the closing plug 5 to the vent hole 4 a of the contact plate 4, the main body fixing mechanism 32 of the plug attachment device 7 is stopped by the control device 10, and the plug attachment device 7 is recovered.

(5) Closing plug welding process (see FIGS. 11 and 12)
In the same procedure as described above, the underwater welding device 8 is fixed to the cooling water pipe 3 again, and the partition wall 53 of the welding unit 50 is pressed against the contact plate 4. Then, for example, with the intention of performing first layer welding (first layer welding) on the peripheral edge of the head portion 5b of the closing plug 5, the operator uses the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. While confirming the position of the welding torch 55 from the image, the controller 10 drives the X-axis direction moving mechanism and the Y-axis direction moving mechanism to move the welding torch 55 from the welding start position to the welding end position along the welding line. Then, the welding passing point is stored in the control device 10 (teaching operation). Thereafter, the welding torch 55 in a state where no welding arc is generated is moved based on the welding passing point stored in the control device 10 and is checked in advance. Then, the dry air supplied to the welding unit 50 is switched to an inert gas, and the first layer welding is performed on the peripheral portion of the head portion 5 b of the closing plug 5.

  Thereafter, the operator confirms whether there is no abnormality in the first layer weld bead welded to the peripheral edge portion of the head portion 5b of the closing plug 5 by the image of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. To do. Further, the inert gas supplied to the welding unit 50 of the underwater welding apparatus 8 is switched to dry air in the same procedure as described above, and the underwater welding apparatus 8 is once detached from the repaired portion of the pool inner wall 2. Thereafter, the underwater camera is lowered into the pool 1 from the operation floor 9, and it is confirmed whether there is any abnormality in the first layer weld bead welded to the peripheral portion of the head portion 5b of the closing plug 5 by the image of the underwater camera. Then, in the same procedure as described above, the underwater welding apparatus 8 is fixed to the cooling water pipe 3 again, and the partition wall 53 of the welding unit 50 is pressed against the contact plate 4.

  Then, for example, with the intention of performing lamination welding (second layer welding) on the peripheral edge of the head portion 5b of the closing plug 5, the operator can view the video of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. While confirming the position of the welding torch 55, the controller 10 drives the X-axis direction moving mechanism and the Y-axis direction moving mechanism to move the welding torch 55 from the welding start position to the welding end position along the welding line, The welding passing point is stored in the control device 10 (teaching operation). Thereafter, the welding torch 55 in a state where no welding arc is generated is moved based on the welding passing point stored in the control device 10 and is checked in advance. Then, the dry air supplied to the welding unit 50 is switched to an inert gas, and lamination welding is performed on the peripheral portion of the head portion 5 b of the closing plug 5.

  Thereafter, the operator confirms whether or not there is any abnormality in the laminated weld bead welded to the peripheral portion of the head portion 5b of the closing plug 5 by the video of the monitoring camera 58 of the underwater welding apparatus 8 displayed on the monitoring monitor. . Then, when all the welding operations at the peripheral edge of the head portion 5b of the closing plug 5 are completed (in the above description, the case up to the second layer welding has been described as an example, but the same procedure as described above is repeated for the third layer. The inert gas supplied to the welding unit 50 of the underwater welding apparatus 8 is switched to dry air.

  For example, the control device 10 uses the X-axis direction moving mechanism and the Y-axis direction of the underwater welding device 8 with the intention of detecting the gutter thickness of the laminated welded portion welded to the peripheral portion of the head portion 5b of the closing plug 5. The movement mechanism is driven to control the positions of the welding torch 55 in the X-axis direction and the Y-axis direction, the second Z-axis direction movement mechanism (and the first Z-axis direction movement mechanism) is driven, and The position of the welding torch 55 when contacting the toe is calculated. The control device 10 calculates the gutter thickness of the laminated welded portion based on these calculated values, and displays the calculated value on the monitor monitor. Thereby, an operator confirms whether the gutter thickness of the lamination | stacking welding part welded to the peripheral part of the head part 5b of the closing plug 5 is appropriate. Thereafter, the underwater welding apparatus 8 is recovered in the same procedure as described above.

  As described above, in the present embodiment, a specific configuration is realized in which the repair work of repairing by welding the contact plate 4 to the repaired portion of the pool inner wall 2 can be performed even in the narrow portion, thereby It is possible to prevent an ejection hole from being generated in the welded portion. Further, it is not necessary to transfer the fuel in the pool 1, temporarily install a radiation shielding facility in the pool 1, or drain a large amount of water, and the working time can be shortened. Further, since the repair work of the pool inner wall 2 is carried out by remotely operating the contact plate support device 6, the underwater welding device 7, and the plug mounting device 8, there is no need for the operator to enter the pool 1, and the operator's exposure Reduction can be achieved.

  Further, in the present embodiment, the partition wall 53 is formed of a carbon felt that is formed at the distal end portion and has elasticity and less frictional force, and a sponge that is formed at the proximal end portion and has elasticity and lower permeability than the carbon felt. It consists of and. Thereby, for example, in the case where the repaired portion of the pool inner wall 2 is directly welded and repaired (in other words, the pressing amount of the partition wall 53 is reduced to the extent that the backing plate 4 is not provided, and the carbon felt from the carbon felt forming the partition wall 53 is reduced. Even when gas leakage is likely to occur), the gas phase space in the partition wall 53 can be maintained.

  In the above embodiment, the partition wall 53 of the underwater welding apparatus 8 has been described as being fixed to the casing 54 as an example, but the present invention is not limited to this. That is, for example, it may be provided so as to be inclined via a known gimbal mechanism (not shown) to reduce gas leakage from the partition wall 53.

  Moreover, in the said one Embodiment, although the case where the underwater welding apparatus 7 provided the welding torch 55 of the arc welding system was demonstrated as an example, it is not restricted to this. That is, instead of this, for example, a laser welding type welding torch having a condenser lens or the like may be provided. In this case, the same effect as described above can be obtained.

  In the above-described embodiment, the underwater welding apparatus 8 has been described with respect to the case where the clamp mechanisms 45L and 45R are provided as means for fixing the main body frame 42 to the cooling water pipe 3, but the present invention is not limited thereto. I can't. That is, for example, a mechanism that is disposed between the pool inner wall 2 and the cooling water pipe 3 and applies a pressing force to the pool inner wall 2 and the cooling water pipe 3 may be provided. Moreover, you may provide the main body fixing mechanism which has an adsorption | suction pad and an ejector, for example. Moreover, in the said one Embodiment, although demonstrated taking the case of repairing by welding the contact plate 4 to the repaired part of the pool inner wall 2 which is a narrow part, it is not restricted to this, The pool which is not a narrow part Needless to say, the present invention may be applied when repairing the repaired portion of the inner wall 2.

It is the schematic showing a part of structure of one Embodiment of the underwater repair system of this invention with a fuel storage pool. It is a perspective view showing the structure of the patch plate in one Embodiment of the underwater repair system of this invention. It is a perspective view showing the whole structure of the backing plate support device which constitutes one embodiment of the underwater repair system of the present invention. It is a perspective view showing the whole structure of the plug attachment apparatus which comprises one Embodiment of the underwater repair system of this invention. It is a perspective view showing the whole structure of the underwater welding apparatus which constitutes one embodiment of the underwater repair system of the present invention. It is the elements on larger scale showing the schematic structure in the partition of the underwater welding apparatus in FIG. It is a perspective view for demonstrating the arrangement | positioning process of the patch plate in one Embodiment of the underwater repair system of this invention. It is a perspective view for demonstrating the temporary attachment process of the patch plate in one Embodiment of the underwater repair system of this invention. It is a perspective view for demonstrating the welding process of the patch plate in one Embodiment of the underwater repair system of this invention. It is a perspective view for demonstrating the attachment process of the closure plug in one Embodiment of the underwater repair system of this invention. It is a perspective view for demonstrating the welding process of the closure plug in one Embodiment of the underwater repair system of this invention. It is the elements on larger scale showing the inside of the partition of the underwater welding apparatus in FIG.

Explanation of symbols

2 pool inner wall 4 contact plate 4a gas vent hole 5 closing plug 5a screw portion 5b head portion 6 contact plate support device 7 plug mounting device 8 underwater welding device 10 control device 16 contact plate support arm 17 contact plate holding unit 19 contact plate holding mechanism 20 Contact plate pressing portion 25 Contact 26L, 26R Detector 27L, 27R Detector moving mechanism 28L, 28R Detector moving mechanism 35 Plug support arm 38 Plug rotating mechanism 43L, 43R Seating frame 44L, 44R Posture adjusting mechanism 45L, 45R Clamp Mechanism 48 First slide part 49 Second slide part 50 Welding unit 53 Bulkhead 55 Welding torch 56 Wire nozzle

Claims (13)

It is an underwater repair system that repairs by welding a patch plate to the repaired part of the pool inner wall,
A backing plate support device for arranging and supporting the backing plate on the repaired portion of the inner wall of the pool;
A plug attaching device for attaching a closing plug to the vent hole of the contact plate;
While forming and moving a gas phase space so as to cover a local portion of the pad plate supported by the pad plate supporting device, a peripheral portion of the pad plate in the gas phase space is welded, and then the plug mounting device An underwater welding apparatus that welds the peripheral edge of the closing plug while forming a gas phase space so as to cover the entire closing plug attached to the vent hole of the abutting plate,
An underwater repair system comprising: the backing plate support device, the plug attachment device, and a control device for remotely operating the underwater welding device.   2. The underwater repair system according to claim 1, wherein the backing plate support device is detachably attached to a main body and has a backing plate holding mechanism capable of holding the backing plate, and the backing plate holding mechanism. A contact plate pressing portion capable of contacting the central portion of the contact plate so as not to interfere with the contact plate, and a contact plate pressing mechanism for pressing the contact plate against the inner wall of the pool by the contact plate pressing portion. Underwater repair system.   2. The underwater repair system according to claim 1, wherein the contact plate support device is provided so as to be movable by a detector moving mechanism, and the contact member is brought into contact with the contact plate and the inner wall of the pool, respectively. A detector for detecting a position; and the control device calculates a gap dimension between the pad and the pool inner wall based on a detection result of the detector and a thickness dimension of the pad stored in advance. An underwater repair system characterized by comprising a gap calculation means.   2. The underwater repair system according to claim 1, wherein the closing plug has a threaded portion that can be screwed into a gas vent hole of the contact plate, and the plug mounting device connects the stop plug to the gas release hole of the contact plate. An underwater repair system comprising: a plug pressing mechanism that presses against a plug; and a plug rotating mechanism that rotates the closing plug.   The underwater repair system according to claim 1, wherein the underwater welding apparatus includes a seating frame for seating a main body on a structure provided in the vicinity of the inner wall of the pool, a plurality of the underwater welding devices connected to the seating frame, An underwater repair system comprising: an attitude adjustment mechanism that adjusts the attitude of the main body with respect to the inner wall of the pool by abutting at a location; and a clamp mechanism that is provided on the seating frame and clamps the structure.   2. The underwater repair system according to claim 1, wherein the underwater welding apparatus supplies gas to a partition for forming a gas phase space so as to cover a local part of the contact plate and the entire closure plug, and the inside of the partition. A welding unit comprising a gas supply means, a welding torch for welding the peripheral edge of the contact plate and the peripheral edge of the closing plug in the partition, and a filler supply means for supplying a filler material in the vicinity of the welding torch And a first welding moving mechanism for moving the welding unit.   The underwater repair system according to claim 6, wherein a welding unit of the underwater welding apparatus corresponds to a welding direction in which a peripheral edge portion of the contact plate and a peripheral edge portion of the closing plug are welded, and the filler material for the welding torch is An underwater repair system comprising a filler material position switching mechanism for switching a supply position.   The underwater repair system according to claim 6, wherein the welding unit of the underwater welding apparatus includes a second welding movement mechanism that moves the welding torch, and the control device includes the first and second welding movement mechanisms. The position of the welding torch when the welding torch is brought into contact with the contact plate and the pool inner wall by drive control is calculated, and the contact plate is based on the calculated value and the thickness dimension of the contact plate stored in advance. An underwater repair system comprising a second gap calculating means for calculating a gap dimension between the inner wall and the pool inner wall.   The underwater repair system according to claim 6, wherein the welding unit of the underwater welding apparatus includes a second welding movement mechanism that moves the welding torch, and the control device includes the first and second welding movement mechanisms. Welded portion calculation means for calculating the position of the welding torch when the welding torch is brought into contact with the toe of the welded portion by drive control and calculating the thickness of the welded portion based on the calculated values. Underwater repair system characterized by that. It is an underwater repair method in which a contact plate support device, an underwater welding device, and a plug mounting device are remotely operated to weld and repair a contact plate on a repaired portion of a pool inner wall,
A procedure for placing and supporting the backing plate on the repaired portion of the inner wall of the pool by the backing plate support device;
A step of welding the peripheral portion of the backing plate in the gas phase space while moving and forming the gas phase space so as to cover the local portion of the backing plate supported by the backing plate support device by the underwater welding device; ,
A procedure for attaching a closing plug to a vent hole of the backing plate attached to the repaired portion of the inner wall of the pool by the plug attaching device;
A step of welding the peripheral edge portion of the closing plug while forming a gas phase space so as to cover the whole of the closing plug attached to the vent hole of the contact plate by the underwater welding device. How to repair underwater. It is an underwater repair method in which a contact plate support device, an underwater welding device, and a plug mounting device are remotely operated to weld and repair a contact plate on a repaired portion of a pool inner wall,
A procedure for placing and supporting the backing plate on the repaired portion of the inner wall of the pool by the backing plate support device;
The position of the contact when the contact of the contact plate support device is brought into contact with the contact plate supported by the contact plate support device and the inner wall of the pool is detected, and the detection result and stored in advance A procedure for calculating a clearance dimension between the contact plate and the pool inner wall based on a thickness dimension of the contact plate by a first clearance calculating means;
A step of welding the peripheral portion of the backing plate in the gas phase space while moving and forming the gas phase space so as to cover the local portion of the backing plate supported by the backing plate support device by the underwater welding device; ,
A procedure for attaching a closing plug to a vent hole of the backing plate attached to the repaired portion of the inner wall of the pool by the plug attaching device;
A step of welding the peripheral edge portion of the closing plug while forming a gas phase space so as to cover the whole of the closing plug attached to the vent hole of the contact plate by the underwater welding device. How to repair underwater. It is an underwater repair method in which a contact plate support device, an underwater welding device, and a plug mounting device are remotely operated to weld and repair a contact plate on a repaired portion of a pool inner wall,
A procedure for placing and supporting the backing plate on the repaired portion of the inner wall of the pool by the backing plate support device;
The position of the contact when the contact of the contact plate support device is brought into contact with the contact plate supported by the contact plate support device and the inner wall of the pool is detected, and the detection result and stored in advance A procedure for calculating a clearance dimension between the contact plate and the pool inner wall based on a thickness dimension of the contact plate by a first clearance calculating means;
The underwater welding apparatus welds a plurality of locations on the peripheral edge of the backing plate in the gas phase space while moving and forming a gas phase space so as to cover a local portion of the backing plate supported by the backing plate support device. And the steps to
The position of the welding torch when the welding torch of the underwater welding device is brought into contact with the contact plate temporarily attached to the repaired portion of the pool inner wall and the pool inner wall, and the calculated value and stored in advance A procedure for calculating a clearance dimension between the contact plate and the pool inner wall by a second clearance calculation means based on the thickness dimension of the applied contact plate;
The entire periphery of the pad plate in the gas phase space is moved by forming and moving the gas phase space so as to cover the local part of the pad plate temporarily attached to the repaired portion of the pool inner wall by the underwater welding apparatus. The procedure of welding,
A procedure for attaching a closing plug to a vent hole of the backing plate attached to the repaired portion of the inner wall of the pool by the plug attaching device;
A step of welding the peripheral edge portion of the closing plug while forming a gas phase space so as to cover the whole of the closing plug attached to the vent hole of the contact plate by the underwater welding device. How to repair underwater. It is an underwater repair method in which a contact plate support device, an underwater welding device, and a plug mounting device are remotely operated to weld and repair a contact plate on a repaired portion of a pool inner wall,
A procedure for placing and supporting the backing plate on the repaired portion of the inner wall of the pool by the backing plate support device;
The position of the contact when the contact of the contact plate support device is brought into contact with the contact plate supported by the contact plate support device and the inner wall of the pool is detected, and the detection result and stored in advance A procedure for calculating a clearance dimension between the contact plate and the pool inner wall based on a thickness dimension of the contact plate by a first clearance calculating means;
The underwater welding apparatus welds a plurality of locations on the peripheral edge of the backing plate in the gas phase space while moving and forming a gas phase space so as to cover a local portion of the backing plate supported by the backing plate support device. And the steps to
The position of the welding torch when the welding torch of the underwater welding device is brought into contact with the contact plate temporarily attached to the repaired portion of the pool inner wall and the pool inner wall, and the calculated value and stored in advance A procedure for calculating a clearance dimension between the contact plate and the pool inner wall by a second clearance calculation means based on the thickness dimension of the applied contact plate;
The entire periphery of the pad plate in the gas phase space is moved by forming and moving the gas phase space so as to cover the local part of the pad plate temporarily attached to the repaired portion of the pool inner wall by the underwater welding apparatus. The procedure of welding,
A position of the welding torch when the welding torch of the underwater welding apparatus is brought into contact with the toe of the welded portion where the peripheral edge of the contact plate is welded is calculated, and the weld node is calculated based on the calculated values. A procedure for calculating the thickness by the weld calculation means;
A procedure for attaching a closing plug to a vent hole of the backing plate attached to the repaired portion of the inner wall of the pool by the plug attaching device;
A step of welding the peripheral edge of the closing plug while forming a gas phase space so as to cover the whole of the closing plug attached to the vent hole of the contact plate by the underwater welding device;
A position of the welding torch when the welding torch of the underwater welding apparatus is brought into contact with the toe of the welded portion where the peripheral edge of the closing plug is welded is calculated, and the weld node is A submerged repair method comprising: calculating a thickness by a welded part calculating means.

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