JP4473806B2 - Replacement method of low-pressure water injection piping - Google Patents

Description

  The present invention relates to a method for replacing a low-pressure water injection system pipe constituting a part of low-pressure water injection system equipment.

  FIG. 9 is a diagram showing a schematic configuration of a boiling water reactor, and a core shroud 3 is attached to a core support plate 2 provided in the reactor pressure vessel 1, and the above-mentioned core is contained in the core shroud 3. A large number of fuel assemblies 5 are disposed and supported between the support plate 1 and the upper lattice plate 4. A jet pump 6 for circulating the coolant is disposed between the core shroud 3 and the inner wall surface of the reactor pressure vessel 1.

  By the way, in the boiling water reactor, at the height position corresponding to the upper lattice plate 4, the cooling water for submerging the core in the low pressure water injection mode at the time of the reactor coolant loss accident is supplied to the reactor pressure vessel. A low-pressure water injection system coupling 7, which is a pipe joint leading from one container wall to the core shroud 3, is provided.

FIG. 10 is an enlarged perspective view of the low-pressure water injection system coupling 7 part, and FIG. 11 is a longitudinal sectional view of the reactor pressure vessel side flange welded in the low-pressure water injection nozzle safe end 8 of the reactor pressure vessel 1. A bellows assembly 11 constituting a low-pressure water injection system coupling is interposed between the neck 9 and the shroud side flange neck 10 fixed to the core shroud 3, and the reactor pressure vessel side flange neck 9 is provided by the bellows assembly 11. And the shroud side flange neck 10 are connected. The bellows assembly 11 has sleeves 12 having spherical surfaces at both ends of the outer periphery, and both ends of the sleeve 12 are fitted and inserted into flanged rings 13a and 13b, respectively. The sleeve 12 is connected to both rings 13a and 13b. The bellows 14 is covered with protective outer cylinders 15 and 15 attached to the rings 13a and 13b, respectively. Then, the flange surface of one ring 13a and the flange surface formed at the end of the reactor pressure vessel side flange neck 9 are brought into contact with each other to engage the clamp 16 that can be divided vertically, and the other ring 13b The flange surface and the flange surface of the shroud side flange neck 10 are brought into contact with each other to engage the clamp 17 that can be divided into upper and lower parts, so that both ends of the bellows assembly 11 are connected to the reactor pressure vessel side flange neck 9 and the shroud side flange neck 10. It is connected to.
By the way, the reactor pressure vessel wall and the core shroud wall cause relative displacement from the cold body during normal operation and low pressure water injection operation due to the difference in thermal expansion coefficient of the material. Therefore, by engaging the spherical surface formed on the sleeve 12 with the inner surfaces of the flanged rings 13a and 13b as described above, it can be rotated and moved in all directions, and the relative displacement can be absorbed. It is. In addition, by providing the bellows 14, leakage of cooling water from the joint portion is prevented, and absorption of relative displacement is easily performed.

  The low-pressure water injection system is a separate loop for each of the three low-pressure water injection pumps. The system starts operation with a low reactor water level or drywell pressure high signal, and the water in the suppression pool is injected directly into the core shroud. The core is cooled by being submerged to about 2/3 of the height of the core.

  The installation of the low-pressure water injection system coupling and the like during the construction of the plant is performed by placing an operator in the annulus and aligning the core with the core of the reactor pressure vessel side flange neck 9 attached to the low-pressure water injection nozzle safe end 8 in advance. The flange neck 10 on the shroud side is attached to the core shroud 3 by welding via a ring 18, and then the thermal shield 19 is attached to the core side end of the flange neck on the core shroud side, and the cover plate 20 is attached to the baffle plate 21. Welding.

  Also, when the bellows assembly is inserted between the flange of the reactor pressure vessel side flange neck and the flange of the reactor core shroud side flange neck and attached with a clamp, the work of the operator entering the annulus is increased. Yes.

  As described above, the installation of the low-pressure water injection system coupling at the time of construction involves many welding work locations in the furnace, and many operations are performed by workers entering the annulus.

  However, when replacing the reactor internals after operating the reactor for a long period of time, the location where the low-pressure water injection system coupling is installed is expected to be close to the reactor core, resulting in a high radiation dose environment. As in the construction, there is a problem that it is difficult for the worker to enter the annulus and attach the low-pressure water injection system coupling because the radiation dose is high. Moreover, the method at the time of construction has problems such as a large amount of welding work in the furnace and the possibility of a long construction period.

  In view of these points, the present invention reduces the amount of work performed by an operator entering the annulus part as much as possible when replacing the reactor internals after operating the reactor for a predetermined period of time. The purpose is to obtain a method for replacing low-pressure water injection pipes that can be reduced and the construction period can be shortened.

In order to achieve the above object, the present invention connects a low-pressure water injection nozzle provided in a reactor pressure vessel and a core shroud so that cooling water is injected into the reactor pressure vessel in the event of a reactor coolant loss event. After cutting off the existing low pressure water injection system coupling and removing the existing core shroud, a new core shroud with a shroud side flange neck installed in the factory was installed in the reactor pressure vessel, and the new core shroud The bellows assembly that constitutes the low-pressure water injection system coupling is carried between the shroud-side flange neck attached to the reactor and the reactor pressure vessel-side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel. And the reactor pressure vessel side flange neck and the shroud side flange neck through the bellows assembly. In the method of replacing low-pressure water injection pipes, the core of the reactor pressure vessel side flange neck or the core of the reactor shroud side flange neck and the core of the reactor pressure vessel side flange neck and the core shroud The amount of misalignment with the core of the side flange neck is remotely measured, and a mechanism for absorbing the misalignment is provided between the reactor pressure vessel side flange neck or the core shroud side flange neck and the bellows assembly. It is a feature.
The present invention also provides a low-pressure water injection system cup in which a low-pressure water injection nozzle provided in a reactor pressure vessel and a core shroud are connected so that cooling water is injected into the reactor pressure vessel in the event of a reactor cooling water loss accident. After cutting through the ring and removing the existing core shroud, a new core shroud with a shroud-side flange neck installed in the factory was installed in the reactor pressure vessel, and the shroud attached to the new core shroud The bellows assembly that constitutes the low-pressure water injection system coupling is carried between the side flange neck and the reactor pressure vessel-side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel. The reactor pressure vessel side flange neck and the shroud side flange neck are fastened together via a solid body. In the method of replacing the low-pressure water injection pipe characterized by the above, the flange surface of the reactor pressure vessel side flange neck and the core surface of the reactor shroud side flange neck with respect to the core of the reactor pressure vessel side flange neck or the core of the core shroud side flange neck A mechanism is provided for remotely measuring the amount of inclination of the flange surface of the reactor and absorbing the amount of inclination of the flange surface between the reactor pressure vessel side flange neck or the core shroud side flange neck and the bellows assembly. It is what.
Furthermore, the present invention provides a low-pressure water injection system cup in which a low-pressure water injection nozzle provided in a reactor pressure vessel and a core shroud are connected to inject cooling water into the reactor pressure vessel in the event of a reactor cooling water loss accident. After cutting through the ring and removing the existing core shroud, a new core shroud with a flange neck short tube part installed in the factory was installed in the reactor pressure vessel and attached to the new core shroud. A low-pressure water injection system coupling is formed between the flange portion attached to the shroud-side flange neck short pipe portion and the reactor pressure vessel-side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel. A bellows assembly is carried in, and through the bellows assembly, the reactor pressure vessel side flange neck and shroud side frame are loaded. In the method of replacing low-pressure water injection pipes characterized in that the ginecks are fastened together, the short pipe part of the core shroud side flange neck, which is a part of the new low-pressure water injection system equipment, is renewed based on the core of the core shroud in advance. It is attached to a core shroud, and the core shroud to which this short tube portion is attached is installed in the reactor, and the core of the reactor pressure vessel side flange neck or the core of the short tube portion of the core shroud side flange neck is used as a reference. A misalignment amount between the core of the reactor pressure vessel side flange neck and the core of the short tube portion of the core shroud side flange neck is remotely measured.

  When exchanging the reactor internals after operating the reactor for a long period of time, the work performed by workers entering the annulus is reduced as much as possible to reduce worker exposure and shorten the construction period. Can be achieved.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

(First embodiment)
When the nuclear reactor is operated for a predetermined period, it is necessary to replace the internal structure of the reactor such as replacement of the core shroud. When the reactor internals are replaced, the reactor pressure vessel 1 is first chemically cleaned so that the operator can install new low-pressure water injection system equipment by entering the reactor pressure vessel 1. Alternatively, after decontamination by mechanical cleaning, the welded portion of the shroud side flange neck 10 and the shroud 3 shown in FIG. 10 is cut in water by a remote cutting device, and the low pressure water injection nozzle safe end 8 and the reactor pressure vessel side flange neck 9 is cut in the air by a remote cutting device, and the low pressure water injection nozzle provided in the reactor pressure vessel and the core shroud 3 are connected to inject cooling water into the pressure vessel in the event of a loss of reactor cooling water. The low pressure water injection system coupling 7 to be removed is removed.

  Thereafter, the flange neck 9 on the reactor pressure vessel side, which is a part of the new low-pressure water injection system equipment, is attached to the reactor pressure vessel low-pressure water injection nozzle safe end 8 with reference to the core of the reactor pressure vessel. At this time, the projecting length of the reactor pressure vessel side flange neck 9 from the inner wall of the pressure vessel is the same as that during construction.

  On the other hand, the shroud side flange neck 10 which is a part of the new low-pressure water injection system equipment is subjected to the thermal stress at the time of water injection at the factory in the same manner as the existing structure with respect to the core of the new core shroud 3 in advance. It attaches via the ring 18 so that it may ease, and also attaches the thermal shield 19, the baffle plate 21, and the cover plate 20, and is completed as an apparatus. Then, the core shroud 3 to which the shroud side flange neck 10 or the like is attached is installed in the furnace in the same manner as the known shroud replacement method. This state is shown in the lower half of FIG.

  After the shroud 3 is installed, water is poured into the annulus part to the middle ring of the core shroud 3 and the entire circumference of the annulus part is placed near the low-pressure water injection system coupling installation direction or above the jet pump provided in the annulus part. Install a shielding plate. In addition, a work scaffold (not shown) that is also used for installing a water supply sparger and a core spray system pipe is installed on the core shroud 3. Then, a bellows assembly 11 is carried by remote control between the reactor pressure vessel side flange neck 9 and the core shroud side flange neck 10, and both ends of the bellows assembly 11 are connected to the reactor pressure vessel side flange neck 9. And connected to the core shroud side flange neck 10.

In this case, prior to the loading of the bellows assembly 11, the measuring device is remotely operated from the scaffold on the shroud 3, and the core of the reactor pressure vessel side flange neck 9 or the core shroud is used by using the measuring device. The misalignment amount j between the reactor pressure vessel side flange neck 9 and the core shroud side flange neck 10 is measured with reference to the core of the side flange neck 10, and the left and right mounting flanges 22a, 22b are offset from each other based on the measurement data. A centered eccentric ring 22 is manufactured at the factory, and the eccentric ring 22 is clamped to the flange of the reactor pressure vessel side flanged ring 13a of the bellows assembly 11 or the flanged ring 13b of the core shroud side. Install at the factory using. FIG. 1 shows a structure in which an eccentric ring 22 is attached to the flange of a flanged ring 13b on the core shroud side. Figure 2 is a perspective view of the clamp 23, vertically bisected semicircular clamp members 23a on the inner peripheral surface having a circumferential groove 23a ₁ of the ladder-shaped, consists 23a, the upper and lower clamp members 23a The flanges that are fastened to each other in the circumferential groove 23a ₁ are engaged, and the upper and lower clamp members 23a are fastened to each other by the bolts 23b and nuts 23c, thereby joining the adjacent flanges together.

Therefore, the bellows assembly 11 to which the eccentric ring 22 is mounted in the factory as described above is carried in between the reactor pressure vessel side flange neck 9 and the core shroud side flange neck 10 by remote control, and the reactor. The flange 9a of the pressure vessel side flange neck 9 and the flange of the reactor pressure vessel side flanged ring 13a of the bellows assembly 11 are fastened by a clamp 16 similar to the clamp 23, and the eccentric ring 22 on the core shroud side. The mounting flange 22b and the flange 10a of the core shroud side flange neck 10 are mechanically fastened by a clamp 17 similar to the clamp 23. 3 and 4 show a state in which the bellows assembly 11 is assembled in a furnace.

Thus, the installation of the shroud side flange neck 10 to the core shroud, the installation of the thermal shield 19 to the shroud side flange neck, and the installation of the baffle plate 21 and the cover plate 20 that were carried out in the existing reactor at the site were performed at the factory. Therefore, the amount of work in the furnace can be reduced. In addition, since there is no work performed by the worker entering the annulus section and the number of attachment points of the low-pressure water injection system components to the shroud in the furnace is reduced, reduction of the exposure of the worker is expected. In addition, since some of the work that has been carried out in the existing furnace is carried out in the factory, the construction period in the furnace can be shortened.
(Second Embodiment)
By the way, in the above-described embodiment, the case where misalignment has occurred between the reactor pressure vessel side flange neck 9 and the core shroud side flange neck 10 has been described. However, the reactor is operated by a measuring device operated by remote control. When the inclination is measured between the flange surface of the pressure vessel side flange neck 9 and the flange surface of the core shroud side flange neck 10, the left and right mounting flanges 22a of the eccentric ring 22 are based on the measurement data. An eccentric ring 22 in which the flange surface 22b1 of at least one of the mounting flanges 22b is inclined is attached to the bellows assembly 11 at the factory, and the bellows assembly 11 to which the eccentric ring 22 is attached is the reactor. It is carried in between the pressure vessel side flange neck 9 and the core shroud side flange neck 10 by remote control. Similar to the embodiment, the flange 9a and the tongue of the reactor pressure vessel flange neck 9 - a flange of the reactor pressure vessel side flanged ring 13a of's assembly 11 is fastened by the same clamp 16 and clamp 23, Further, the mounting flange 21 b on the core shroud side of the eccentric ring 22 and the flange 10 a of the core shroud side flange neck 10 are mechanically fastened by a clamp 17 similar to the clamp 23. FIG. 5 shows a state in which the bellows assembly 11 is assembled in a furnace. In this case, the same effect as that of the first embodiment is obtained.

(Third embodiment)
In the first and second embodiments, the eccentric ring 22 is attached to the bellows assembly 11, and the bellows assembly 11 to which the eccentric ring 22 is attached is connected to the reactor pressure vessel side. Although what was carried in and carried out by remote operation between the flange neck 9 and the core shroud side flange neck 10 was shown, the core and core of the reactor pressure vessel side flange neck 9 were measured by the measuring device operated by remote operation. When misalignment or inclination is measured between the shroud side flange neck 10 and the core of the shroud side flange neck 10, the reactor pressure vessel side and the core shroud side flange constituting the bellows assembly 11 based on the measurement data. At least one flange of the attached rings 13a and 13b is manufactured at the factory so as to have an eccentricity or an inclined surface, and the bellows assembly 11 is formed as described in the above embodiment. Loading and linking by remote control between the reactor pressure vessel flange neck 9 and the core shroud flange neck 10 as. 6 and 7, the bellows assembly 11 manufactured by decentering or inclining the flange 13 b on the core shroud side constituting the bellows assembly 11 at the factory is connected to the reactor pressure vessel side flange neck 9. The state which carried in and connected by remote control between the core shroud side flange neck 10 is shown.

(Fourth embodiment)
In the first and second embodiments, the eccentric ring 22 is attached to the bellows assembly 11, and the bellows assembly 11 to which the eccentric ring 22 is attached is connected to the reactor pressure vessel side. Although what was carried in and carried out by remote operation between the flange neck 9 and the core shroud side flange neck 10 was shown, for example, several eccentric rings are attached to the reactor pressure vessel side of the bellows assembly 11 and It can also be incorporated into at least one of the core shroud side.

(Fifth embodiment)
FIG. 8 is a view showing a fifth embodiment of the present invention, in which the short tube portion 10b of the core shroud side flange neck 10 is preliminarily connected to a new core shroud 3 through a ring 18 with the core of the core shroud 3 as a reference. The core shroud 3 to which the short pipe portion 10b of the flange neck is attached is installed in the furnace according to a known shroud installation method. Thereafter, a work scaffold (not shown) is installed below the intermediate ring inside the shroud 3 before the upper lattice plate 4 is attached. The core of the reactor pressure vessel side flange neck 9 and the core of the reactor shroud side flange neck 10 and the core of the reactor shroud side flange neck 10 are used as a reference. The misalignment amount and inclination between the parts 10b are measured remotely using a measuring device. Therefore, an eccentric flange 10c having a flange surface that is eccentric or inclined based on the measurement data obtained by the measurement device is attached from the inside of the shroud 3 to the reactor pressure vessel side of the short pipe portion 10b. Thereafter, the thermal shield 19 is attached to the opposite side of the short pipe portion 10 b, and the cover plate 20 is attached to the baffle plate 21. The bellows assembly 11 having the same specifications as that of the existing pressure vessel side flange neck 9 and the core shroud side flange neck 10 is remotely installed from the working scaffold or operating floor in which the upper part of the shroud 3 is installed. Carry in and mechanically fasten with clamps.

  Thus, in this embodiment, the effect is reduced because the number of installation work in the furnace is increased as compared with each of the above-mentioned embodiments, but the construction period is shortened and the exposure dose is compared with the installation method and structure at the time of construction. Can be reduced.

Operation | movement explanatory drawing of the 1st Embodiment of this invention. The perspective view of a clamp. The perspective view which shows the state which incorporated the bellows assembly by 1st Embodiment. FIG. 4 is a longitudinal side view corresponding to FIG. 3. The figure which shows the 2nd Embodiment of this invention. The figure which shows the 3rd Embodiment of this invention. The figure which shows the modification of the 3rd Embodiment of this invention. The figure which shows the 5th Embodiment of this invention. The figure which shows a nuclear reactor internal schematic structure. The expansion perspective view of the conventional low-pressure water injection system coupling 7 part. The longitudinal cross-sectional view of the connection part of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reactor pressure vessel 3 Core shroud 4 Upper lattice board 7 Low pressure injection system coupling 8 Low pressure injection nozzle safe end 9 Reactor pressure vessel side flange neck 10 Core shroud side flange neck 10b Short pipe part 11 Bellows assembly 13a, 13b Flange Ring 14 with bellows 15 Protective outer cylinder 16, 17 Clamp 18 Ring 19 Thermal shield 20 Cover plate 21 Baffle plate 22 Eccentric ring 23 Clamp

Claims (7)

Connect the low-pressure water injection nozzle provided in the reactor pressure vessel and the core shroud, and cut through the low-pressure water injection system coupling that injects cooling water into the reactor pressure vessel in the event of a reactor water loss accident. In addition, after removing the existing core shroud, a new core shroud with a shroud side flange neck installed in the factory is installed in the reactor pressure vessel, and the shroud side flange neck attached to the new core shroud, A bellows assembly constituting a low-pressure water injection system coupling is carried between the reactor pressure vessel side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel, and the atoms are connected via the bellows assembly. Low pressure characterized by fastening the furnace pressure vessel side flange neck and the shroud side flange neck together A replacement method of water injection system piping,
Remotely measure the amount of misalignment between the core of the reactor pressure vessel side flange neck and the core of the reactor shroud side flange neck with respect to the core of the reactor pressure vessel side flange neck or the core of the core shroud side flange neck, and you characterized in that a mechanism of absorbing the misalignment between the reactor pressure vessel flange neck or core shroud flange neck and the bellows assembly, low douche method replacement of water piping. Connect the low-pressure water injection nozzle provided in the reactor pressure vessel and the core shroud, and cut through the low-pressure water injection system coupling that injects cooling water into the reactor pressure vessel in the event of a reactor water loss accident. In addition, after removing the existing core shroud, a new core shroud with a shroud side flange neck installed in the factory is installed in the reactor pressure vessel, and the shroud side flange neck attached to the new core shroud, A bellows assembly constituting a low-pressure water injection system coupling is carried between the reactor pressure vessel side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel, and the atoms are connected via the bellows assembly. Low pressure characterized by fastening the furnace pressure vessel side flange neck and the shroud side flange neck together A replacement method of water injection system piping,
Using the core of the reactor pressure vessel side flange neck or the core of the core shroud side flange neck as a reference, the amount of inclination of the flange surface of the reactor pressure vessel side flange neck and the flange surface of the core shroud side flange neck is measured remotely, wherein it characterized in that a mechanism for absorbing the inclination of the flange surface, low douche method replacement of water piping between the reactor pressure vessel flange neck or core shroud flange neck and bellows assembly. The mechanism for absorbing the misalignment between the core of the reactor pressure vessel side flange neck and the core of the core shroud side flange neck or the inclination amount of the flange surface is based on the measurement data of the misalignment amount or the inclination amount of the flange surface. The low-pressure water injection system according to claim 1 or 2 , wherein the low-pressure water injection system is an eccentric ring that is attached to a flange on a reactor pressure vessel side or a core shroud side of the bellows assembly that is eccentric or has an inclined flange surface. How to replace piping. A mechanism for absorbing the misalignment between the core of the reactor pressure vessel side flange neck and the core of the core shroud side flange neck or the inclination of the flange surface is provided on the reactor pressure vessel side or core shroud side of the bellows assembly. The replacement of the low-pressure water injection pipe according to claim 1 or 2 , wherein the flange is eccentric or based on the measurement data of the misalignment amount or the inclination amount of the flange surface. Method. A mechanism for absorbing the misalignment between the core of the reactor pressure vessel side flange neck and the core of the core shroud side flange neck or the amount of inclination of the flange surface is provided at least on the reactor pressure vessel side and core shroud side of the bellows assembly. The replacement of the low-pressure water injection pipe according to claim 1 or 2 , wherein the replacement is an eccentric ring that is provided on one side and can be eccentric based on measurement data of the misalignment amount or the inclination amount of the flange surface. Method. Connect the low-pressure water injection nozzle provided in the reactor pressure vessel and the core shroud, and cut through the low-pressure water injection system coupling that injects cooling water into the reactor pressure vessel in the event of a reactor water loss accident. In addition, after removing the existing core shroud, a new core shroud in which the flange neck short pipe portion is installed in the factory is installed in the reactor pressure vessel, and the shroud side flange neck short pipe attached to the new core shroud is installed. The bellows assembly that constitutes the low-pressure water injection system coupling is carried in between the flange part attached to the part and the reactor pressure vessel side flange neck attached to the low-pressure water injection nozzle provided in the reactor pressure vessel. The reactor pressure vessel side flange neck and the shroud side flange neck are connected to each other through the bellows assembly. A replacement method of low-pressure water injection system piping, characterized in that the binding,
Can you attach to a new core shroud relative to the center of the pre-core shroud short pipe section of which is a part of a new low-pressure water injection system equipment core shroud flange neck, the core shroud the short tube portion is attached Installed in the reactor, the core of the reactor pressure vessel side flange neck or the core of the short tube portion of the core shroud side flange neck is used as a reference, and the short tube portion of the reactor pressure vessel side flange neck and the core shroud side flange neck of you, characterized in that to measure remotely misalignment amount between the core, low douche method replacement of water piping. As a mechanism to absorb the misalignment of the short tube section of the reactor pressure vessel side flange neck and the core shroud side flange neck and the inclination of the flange surface, the eccentric flange that is eccentric based on the measurement data is used as the core of the core shroud side flange neck. The method for replacing a low-pressure water injection pipe according to claim 6 , wherein the short pipe part is attached to the reactor pressure vessel side from the inside of the core shroud, and then a thermal shield is attached to the opposite side of the short pipe part.

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