JPH0244038B2 - - Google Patents

Description

Detailed Description of the Invention [Technical Field of the Invention] The present invention relates to a control rod drive mechanism housing (hereinafter referred to as CRD) that supports the lower end of a control rod drive mechanism (hereinafter referred to as CRD) of a boiling water nuclear reactor and houses this CRD. It relates to a device that prevents the CRD housing and CRD from falling if the CRD housing (referred to as the CRD housing) breaks.

[Technical background of the invention]

A conventional example will be explained with reference to FIGS. 1 to 5. 20 in the figure is a nuclear reactor pressure vessel, and a reactor core 21 is accommodated in this reactor pressure vessel 20. Control rods 22 are inserted into and pulled out from below into this reactor core 21.
The control rod 22 is driven by the CRD 1. Each CRD 1 is inserted from below into a cylindrical CRD housing 2 having a flange 1A on the lower outer periphery and fixed to the bottom of the reactor pressure vessel 20. It is fixed to the CRD housing 2 by tightening bolts to the flange 2A. A plurality of support bars 3 are suspended below these drive mechanisms 1 via hanging rods 3A, and are arranged in a substantially horizontal direction. A pair of drive mechanism fall prevention grids 4 are arranged parallel to each other on top of these support bars 3. These grids 4 are strip-shaped and are arranged with the width direction facing approximately vertically, so that in the unlikely event that the bolts fixing between the flanges 1A and 2A break or the CRD housing 2
Even if the CRD 1 were to break and fall, the two grids 4, 4 support the CRD 1 from below to prevent the CRD 1 from falling. The two grids 4, 4 of each set are spaced narrower than the diameter of the lower end of the CRD 1.
1, and multiple sets of vertical support fittings 5, 6.
It is positioned by The upper support fitting 5 is
As shown in FIG. 3, the L-shaped pieces 8, 8 are raised from both sides of the bottom plate 7, and the lower end of each L-shaped piece 8 is shaped to straddle the two grids 4, 4. The upper horizontal plate part of the piece 8 has a semicircular recess 9, and the recesses 9, 9 of both L-shaped pieces 8, 8 are fitted into the lower outer periphery of the two adjacent CRDs 1, 1. 1
I try to suppress the fluctuation of the. In addition, the bottom plate part 7
A bolt insertion hole 10 is bored in the center of the hole.

The lower support fitting 6 is formed by bending a plate material into a substantially U-shape so as to straddle the lower edges of the two grids 4, 4, and has a bolt insertion hole 11 in the center thereof.

Thus, one tightening bolt 12 is inserted into the bolt insertion holes 10 and 11 of the upper and lower support fittings 5 and 6, and by screwing and tightening the nut 13,
The two grids 4, 4 are positioned and fixed.

Also, flange 2A of CRD housing 2...
When viewed on a plan view, they are arranged vertically and horizontally as shown in Figure 5, with lateral restraints 16 interposed between adjacent flanges 2A, 2A.
It is designed to prevent the CRD housing 2 from swinging. In addition, 17 in the figure is a restraint beam fixed to the reactor pedestal, and a lateral restraint 16 is also interposed between this beam 17 and the housing flange 2A located at the end. The acting lateral load is received by the reactor pedestal via the restraint beam 17. Therefore, the shaking of the housing 2 when an earthquake occurs, etc.
These lateral restraints 16... and restraint beams 17 suppress the movement, and as a result, the CRD 1 is configured to be prevented from swinging.

[Problems with background technology]

By the way, during regular inspections of nuclear reactors, grid 4
After removing all..., pull apart both flanges 1A and 2A, pull out CRD 1 downward, and inspect. After inspection, the CRD 1 must be fixed to the CRD housing 2 again, and then the grid 4 must be repositioned and fixed, but all of this work will be done in a high radiation area, so it must be done as quickly as possible. It is desirable to be able to do so.

In addition, when removing grid 4..., first remove nut 1.
This can be done by loosening the bolts 3 and removing the tightening bolts 12, and then removing the upper and lower support fittings 5 and 6 from the grid 4. It is the most difficult and time-consuming process. This is because the two integrated L-shaped pieces 8, 8 are fitted to the lower outer circumferences of the two adjacent CRDs 1, 1 at the same time, and the upper support bracket 5 cannot be attached or removed. Therefore, there were problems in that inspection work took longer and the amount of radiation exposure for workers increased. Additionally, due to the difficulty of the work, a large number of workers were required, and periodic inspections required a long time, resulting in a reduction in the operating rate of the reactor.

In addition, the conventional one has a complicated structure and
Since the horizontal support of the CRD housing 2 is insufficient, the lateral restraints 16 must be provided as described above to provide horizontal support, resulting in an extremely complicated structure.

[Purpose of the invention]

To provide a CRD housing support device which can easily and quickly attach and detach a CRD, can reliably prevent horizontal vibration of the CRD housing, and has a simple structure.

[Summary of the invention]

The present invention includes a plurality of hanger rods arranged around each CRD housing, the upper end of which is attached to the support beam, and a hanger rod that fits from below into the lower end of the CRD housed in each of the CRD housings. The support member is detachably attached to the lower ends of the plurality of hanger rods arranged around the housing, and the side surfaces of adjacent hanger rods are in contact with each other. Therefore, when attaching or detaching the CRD, it is necessary to
Only the support member fitted to the CRD needs to be removed, making it possible to easily and quickly attach and detach the CRD. Further, since adjacent support members are in contact with each other, it is possible to prevent the CRD housing from swinging in the horizontal direction, and the structure is simple.

[Embodiments of the invention]

A first embodiment of the present invention will be described with reference to FIGS. 6 to 8. In the figure, 101 is a reactor pressure vessel, and inside this reactor pressure vessel 101 there is a reactor core 1.
02 is accommodated. And this core 102
Control rods 103 are inserted into or pulled out from below. Also, 104...
is a CRD housing. These CRD housings 104... have a cylindrical shape, and the reactor pressure vessel 10
It is provided to penetrate the bottom of 1. And, inside these CRD housings 104... there are CRD10
5... are inserted, and the control rods 103... are inserted into or withdrawn from the reactor core 102 by these CRDs 105.... A flange 106 is formed at the lower end of the CRD housing 104. Also, above
A flange 107 is also formed at the lower end of the CRD 105.... The flanges 106 of the CRD housings 104 and the flanges 107 of the CRDs 105 are abutted against each other, and the bolts 108 are abutted against each other.
It is fixed by. In addition, CRD105...
The lower part of the flange 107 is formed as a small diameter part 107a, and the upper part is formed as a large diameter part 107b having a larger diameter than this small diameter part 107a. and,
These CRD105... and CRD housing 10
The lower end portions of 4 are supported by a CRD housing support device. This support device will be explained below. 109 is a support beam, both ends of which are supported by reactor pedestals (not shown);
CRD housing 104... is arranged between.
A large number of hanger rods 110 project downward from the support beam 109. These hanger rods 110... are CRD
A plurality of pieces, for example two pieces, are provided for each housing 104. These two hanger rods 110... are connected to the CRD housing 10.
4 are placed at positions facing each other at 180° with respect to the center. The direction in which these two hanger rods 110 are connected, that is, the direction in which the two hanger rods 110 are arranged, is orthogonal to each other in adjacent CRD housings 104, and the rods are provided correspondingly to each CRD housing 104. CRD with attached hanger rod 110...
It is configured so as not to interfere with the hanger rods 110 of the housings 104. And each
Support members 111 are provided corresponding to the CRDs 105, respectively. This support member 1
11... has a substantially octagonal planar shape. Note that the planar shape of these support members 111 is not a regular octagon, but is formed into an elongated octagon having a major axis _L1 and a minor axis _L2 . And this major axis
L ₁ and short axis L ₂ are configured such that the sum of these lengths is equal to twice the distance between the centers of the CRD housings 104 arranged in a lattice pattern. Fitting holes 112 are formed in the centers of these support members 111. These support members 111... are connected to the CRD 105... from below.
The CRD10 is fitted into the fitting hole 112...
The small diameter part 107a of the flange 107 of 5... is tightly fitted, and the peripheral edge of this fitting hole 112... is the large diameter part 107.
It is configured to fit into the lower edge of the CRD 105 and support the CRDs 105 from below. Further, attachment holes 113 are formed at both ends of the support members 111 in the longitudinal direction, respectively. The lower ends of two hanger rods 110 provided for each CRD housing 104 are inserted into these mounting holes 113. and,
Nuts 114... are screwed into the lower ends of these hanger rods 110...
4 are tightened to push up the support members 111, and the CRDs 105 are supported from below by these support members 111 and hanger rods 110. And each CRD
Two hanger rods 110 are provided corresponding to the housings 104, and the directions in which they are arranged are adjacent to each other.
Since the CRD housings 104 are configured to be shifted by 90 degrees from each other, these support members 111
... are also arranged so that their major axes _L1 directions are orthogonal to each other. And this major axis L ₁
Since the sum of the length and the short axis _L2 is equal to twice the distance between the centers of the CRD housings 104..., the mutually adjacent support members 111... The side surfaces of the CRD housings 104 are configured to abut each other to prevent the CRD housings 104 from shaking in the horizontal direction. Note that the support members 111 attached to the CRDs 105 disposed on the outermost periphery are reactor pedestals (not shown).
It is fixed to the wall etc. In the first embodiment of the present invention constructed as described above, the nuts 114 at the lower end of the hanger rod 110 are removed, and the support members 111...
By pulling out the CRD 105 downward, only one CRD 105 can be attached or detached regardless of the adjacent CRD 105, making the work easier and faster. Also,
Since the adjacent support members 111 are in contact with each other, the movement of the lower ends of the CRD housings 104 in the horizontal direction is restrained.
Horizontal deflection of the lower end of the housing 104 can be reliably prevented. Furthermore, this structure is simple, as the support member 111 fitted to the lower end of the CRD 105 is directly attached to the hanger rod 110.

Further, in this first embodiment, the support member 1
11... have an elongated octagonal shape, and the arrangement directions are shifted by 90 degrees from each other, so the four support members 11...
The gap surrounded by the oblique sides of CRD housings 104 becomes a large square, and interference with in-core housings (not shown) etc. disposed between CRD housings 104 is reduced.

Further, FIG. 9 shows a second embodiment of the present invention.
In this second embodiment, CRD housings 104 are arranged in a grid pattern in the arrangement direction of two hanger rods 110 provided for each CRD housing 104.
These hanger rods 11 as diagonal directions of 4...
0..., and the support member 111...
have their hypotenuses in contact with each other. In this second embodiment, all the support members 111 are attached in the same direction, so the work is easy and erroneous attachment can be prevented.

Further, FIG. 10 shows a third embodiment of the present invention. This third embodiment is for a case where the flange 107 of the CRD 104 is not formed with a large diameter part and a small diameter part, and the fitting hole 1 of the support member 111...
The lower ends of the CRDs 105 are inserted into the fitting holes 112, and the upper surfaces of the peripheral edges of the fitting holes 112 are brought into contact with the bolts 108 to support the CRDs 105.

Note that the present invention is not limited to the above embodiments.

For example, the shape of the support member is not necessarily limited to that of the above embodiment.

Further, the number of hanger rods per CRD housing is not limited to two, and may be three or more.

〔Effect of the invention〕

As described above, the present invention includes a plurality of hanger rods arranged around each CRD housing and having their upper ends attached to the support beam, and each of the above-mentioned hanger rods.
The hanger rods are fitted from below to the lower ends of the CRDs housed in the CRD housing, and are removably attached to the lower ends of the plurality of hanger rods arranged around each CRD housing, and are attached to the side surfaces of the adjacent hanger rods. and a support member provided in contact with the support members. Therefore, by removing this support member from the hanger rod, only one CRD can be attached or detached, regardless of the adjacent CRD, and the CRD can be attached or detached very easily and quickly.

Furthermore, since the adjacent support members are in contact with each other, it is possible to prevent the lower end of the CRD housing from swinging in the horizontal direction, and the structure is simple, which has great effects.

[Brief explanation of drawings]

Figures 1 to 5 show a conventional example, where Figure 1 is a longitudinal sectional view, Figure 2 is a perspective view of the lower part of the CRD housing and its support structure, Figure 3 is an exploded perspective view of the support fitting, and Figure 4. 5 is a partial side view, and FIG. 5 is a partial plan view. 6 to 8 show a first embodiment of the present invention, in which FIG. 6 is a longitudinal sectional view of the whole, FIG. 7 is a partial plan view, and FIG. 8 is a partial side view. In addition, FIG. 9 is a plan view of a part of the second embodiment, and FIG.
The figure is a side view of a part of the third embodiment. DESCRIPTION OF SYMBOLS 101... Reactor pressure vessel, 104... CRD housing, 105... CRD, 109... Support beam, 110... Hanger rod, 111... Support member, 112... Fitting hole, 113... Mounting hole, 114
...Natsuto.

Claims (1)

[Claims] 1 A plurality of hanger rods are arranged around each control rod drive mechanism housing and the upper end is attached to the support beam, and a hanger rod is attached to the lower end of the control rod drive mechanism housed in each control rod drive mechanism housing from below. support members that are removably attached to the lower ends of the plurality of hanger rods that are fitted together and arranged around each control rod drive mechanism housing, and that adjacent ones are provided with their side surfaces in contact with each other; A support device for a control rod drive mechanism housing.