JPS6257238B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a reactor containment vessel stabilizer device for supporting a nuclear reactor pressure vessel.

Conventionally, nuclear reactor containment vessels, such as over-under type reactor containment vessels, have been constructed as shown in FIGS. 1 and 2. That is, 1 is the main body of the containment vessel, which is made of, for example, reinforced concrete, and has pressure resistance and radiation shielding ability. A liner 2 is stretched over the inner surface of the containment vessel body 1 to provide airtightness. The inside of the containment vessel main body 1 is divided into upper and lower sections by a diaphragm floor 3, with a dry well 4 formed in the upper part and a suppression chamber 5 formed in the lower part.
A pedestal 6 is erected within the containment vessel body 1, and a reactor pressure vessel 7 is installed on this pedestal 6. A reactor shielding wall 8 is provided surrounding the reactor pressure vessel 7. The upper end of this reactor shielding wall 8 is supported by the containment vessel main body 1 via stabilizers 9 installed horizontally, and the horizontal load applied to this reactor shielding wall 8 in the event of an earthquake, etc. is configured to support. By the way, these stabilizers 9 have conventionally been provided in a horizontal direction between the outer periphery of the upper end of the reactor shielding wall 8 and the inner peripheral surface of the containment vessel body 1. Therefore, the rails 11a, piping 11b, etc. for running the hoist crane that installs and removes the main steam isolation valve 10, etc. must be provided below the stabilizer 9, and the space above the containment vessel body 1 is could not be used effectively. Furthermore, a certain distance from the rail 11a to equipment such as the main steam isolation valve 10 is required for lifting and working on these equipment, and further for installing an air conditioning duct. Therefore, as described above, the rail 11a is connected to the stabilizer 9...
If the container body 1 is placed below the container body 1, the height of the containment vessel body 1 increases accordingly, which is disadvantageous in terms of seismic design. Further, the stabilizers 9 are constructed by welding steel pipes, but if the rigidity of these stabilizers 9 is insufficient, resonance may occur in the reactor shielding wall 8 in the event of an earthquake, etc., so these stabilizers 9 The rigidity of the stabilizers 9 had to be increased, and the diameter of the steel pipes constituting these stabilizers 9 had to be increased.

The present invention was made based on the above circumstances, and its purpose is to make it possible to effectively utilize internal space, reduce the height, improve earthquake resistance, and increase the rigidity of the stabilizer. The goal is to obtain a reactor containment vessel.

That is, the configuration of the present invention is such that the stabilizer that connects the upper end of the reactor shielding wall and the containment vessel body is arranged diagonally or vertically, so that the upper space inside the containment vessel body can be effectively used, and the stabilizer The rigidity is increased by connecting the spaces between them with an auxiliary stabilizer.

A first embodiment of the present invention will be described below with reference to an embodiment shown in FIGS. 3 and 4. 10 in the diagram
1 is the main body of the containment vessel, which is strongly formed of reinforced concrete and has pressure resistance and radiation shielding ability. And this containment vessel main body 101
A liner 102 made of a steel plate or the like is tightly attached to the inner surface of the housing, and this liner 102 provides airtightness. The inside of the containment vessel main body 101 is divided into upper and lower sections by a diaphragm floor 103, with a dry well 104 formed in the upper part and a suppression chamber 105 formed in the lower part. Further, a pedestal 106 is erected at the center of the containment vessel main body 101, and a reactor pressure vessel 107 is installed on this pedestal 106. Further, a cylindrical reactor shielding wall 108 is erected on the pedestal 106 to surround the reactor pressure vessel 107 . and,
The upper part of the reactor pressure vessel 107 and the reactor shielding wall 108 are connected to the reactor pressure vessel stabilizer 109...
are connected via. Further, 110 is a main steam pipe, and a main steam isolation valve 111 is provided in the middle thereof. In addition, this containment vessel main body 101
A steel flange member 112 is provided at the upper opening of the upper lid 1.
13 is detachably attached. The upper end of the reactor shielding wall 108 and the containment vessel main body 1
01, a plurality of stabilizers 116 are bridged between them. One end of these stabilizers 116 is attached to the upper end of the reactor shielding wall 108 via a mounting bracket 117, and the other end is attached to the containment vessel via a radially slidable shear key 118. It is attached to the inner surface of the main body 101. The stabilizers 116 are assembled in a truss shape as shown in FIG. 4, and are arranged at an angle with respect to the horizontal direction so that the other ends of the stabilizers 116 are located upward. . In addition, these stabilizers 116...
The other end is attached to the inner surface of the containment vessel body 101 at a location where the distance from the upper end of the reactor shielding wall 108 is the smallest, and these stabilizers 116
... is configured so that the length is the shortest. Furthermore, auxiliary stabilizers 119 are provided between the other end portions of the stabilizers 116 to connect these other end portions to each other, and are configured to increase the rigidity of the truss constituted by these stabilizers 116. Further, the containment vessel main body 10
An annular hoist traveling rail 120 is installed at the upper part of the inside.
and piping 121... etc. are arranged.

In the first embodiment of the present invention configured as described above, when a horizontal load is generated on the reactor pressure vessel 107 due to an earthquake or the like, this horizontal load is transferred to the reactor pressure vessel through the reactor pressure vessel stabilizer 109... The direction of this load and 90
It is transmitted to and supported by the containment vessel main body 101 via the stabilizers 116 located at positions shifted by .degree.
Therefore, swinging of the upper end of the reactor pressure vessel 107 is prevented. In addition, since these stabilizers 116 are provided at an angle with respect to the horizontal direction, the upper space inside the containment vessel main body 101 can be used effectively, and the hoist running rail 120
etc. can be arranged completely in the upper part of the containment vessel main body 101, so the height of the containment vessel main body 101 can be reduced, and the earthquake resistance of this containment vessel main body 101 can be improved. Further, since the ends of these stabilizers 116... are connected to each other by auxiliary stabilizers 119..., these stabilizers 116...
The rigidity of the truss constructed by this can be increased. In addition, in this first embodiment, the other end of the stabilizer 116 is attached to the inner surface of the containment vessel body 101 at a location closest to the upper end of the reactor shielding wall, so the length of the stabilizer 116 is short. Thus, the rigidity can be further increased.

Note that the present invention is not limited to the first embodiment described above.

For example, FIGS. 5 and 6 show the second embodiment of the present invention.
An example is shown. In this second embodiment, a plurality of stabilizers 116' are provided vertically protruding upward from the upper end surface of the reactor shielding wall 108, and the upper ends of these stabilizers 116' are connected to the containment vessel main body 101.
For example, the mounting bracket 114 is attached to the upper wall portion of the mounting bracket 114 . Reference numeral 122 is a mounting bracket for attaching these stabilizers 116' to the upper end of the reactor shielding wall 108.
It is embedded in the upper end of 8. As shown in FIG. 6, these stabilizers 116' are assembled in a continuous truss shape in the circumferential direction, and are configured to withstand loads in the circumferential direction. Therefore, the horizontal load acting on the reactor shielding wall 108 is received by the stabilizers 116' located in a direction perpendicular to the direction of the load, and is transmitted to the containment vessel body 101. has been done. This second embodiment has the same structure as the first embodiment except for the above points, and the parts in FIGS. 5 and 6 that correspond to the first embodiment are given the same reference numerals and explained. omitted. In this second embodiment, since the stabilizers 116' are provided in the vertical direction, the upper space inside the containment vessel body 101 can be used more effectively.

As described above, in the present invention, the stabilizer that connects the upper end of the reactor shielding wall and the containment vessel body is arranged diagonally or vertically with respect to the horizontal direction, so that the space above the containment vessel body can be used effectively. Earthquake resistance can be improved by lowering the height of the containment vessel body, and auxiliary stabilizers are provided between the ends of the stabilizers to increase the rigidity of the truss made up of these stabilizers, further improving earthquake resistance. The effects are great, such as being able to do the following.

[Brief explanation of the drawing]

1 and 2 show a conventional example, and FIG. 1 is a longitudinal cross-sectional view, and FIG. 2 is a view taken along the - arrow in FIG. 1.
3 and 4 show a first embodiment of the present invention, FIG. 3 is a longitudinal sectional view, and FIG.
It is an arrow view. 5 and 6 show a second embodiment of the present invention, FIG. 5 is a longitudinal sectional view, and FIG. 6 is a view taken along the - arrow in FIG. 101... Containment vessel main body, 107... Reactor pressure vessel, 108... Reactor shielding wall, 116, 11
6'... Stabilizer, 119... Auxiliary stabilizer.

Claims (1)

[Claims] 1. A containment vessel body, a cylindrical reactor shielding wall provided surrounding a reactor pressure vessel housed in the containment vessel body, and one end of which is attached to the upper end of the reactor shielding wall. a plurality of stabilizers arranged in a truss-like manner and inclined or vertical with respect to the horizontal direction so that the other end is attached to the upper inner surface of the containment vessel and the other end is located above the one end; A nuclear reactor containment vessel stabilizer device comprising an auxiliary stabilizer that connects end portions of the stabilizer to each other. 2. The reactor containment vessel stabilizer device according to claim 1, wherein the other end of the stabilizer is attached to the inner surface of the containment vessel body at a position closest to the upper end of the reactor shielding wall. .