JPH02245699A - Supporting pedestal for turbine-generator of nuclear power station - Google Patents

Abstract

PURPOSE:To enable an easy application of a supporting pedestal to a highly seismic area by forming the pedestal by providing a reinforced concrete structure at a position to be ordinarily occupied by a frame/rigid structure. CONSTITUTION:A supporting pedestal of a turbine-generator (T-G supporting pedestal) installed in a turbine building 1, is installed on a same foundation mat 2 as a foundation mat 2 of a turbine building 1, and is installed separately from a floor 8 and inner walls of the turbine building. The T-G supporting pedestal is constituted of a T-G pedestal deck 9 which supports a high pressure turbine 3, a low pressure turbine 4 and a generator 5, and a lower structure which supports the deck 9. As the lower structure of the deck 9, a reinforced concrete wall 10 for a lower part of the high pressure turbine, is provided at a high pressure turbine side as well as a pillar 6 and a beam 7. In the same manner at a generator side, a reinforced concrete wall 11 for a lower part of the generator is provided as well as the pillar 6 and the beam 7. Also, a lower part of the low pressure turbine 4 is supported by a reinforced concrete wall 12 around a condenser.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a nuclear power plant turbine/generator support frame.

[Conventional technology]

The basic structure of the turbine/generator support frame (hereinafter referred to as T-G frame) is as described on pages 513 to 515 of "Planning, Design, and Operation of Modern Thermal Power Plants" (Denkishoin). It has been shown that frame rigid-frame structures based on column and beam structures have been used in the past. It is also stated that the T-G frame is made of steel or reinforced concrete.

In addition, in Japanese Patent Application Laid-open No. 63-27794, the basic structure of the T-G mount is the same as the above-mentioned document published by Denkishoin, but this mount is extended, and the main steam stop valve, steam control valve, and turbine It is shown that the bypass valve is housed within this cradle.

In these conventional techniques, the basic structure of the T-G frame is a frame rigid structure consisting only of columns and beams.

Due to its ability to bear earthquake forces, there are limits to its application as a Re (reinforced concrete) construction in high earthquake areas.

[Problem to be solved by the invention]

The above-mentioned conventional technology has a limit of applicability to high-earthquake regions within the four-stage column reinforcement arrangement, and requires countermeasures such as the use of high-strength, large-diameter reinforcing bars.

The present invention has been made in view of the above points.

The object of the present invention is to provide a nuclear power plant turbine/generator support frame made of reinforced concrete that can be easily applied to high earthquake areas.

[Means to solve the problem]

The above object is achieved by forming the pedestal by providing a reinforced concrete wall at a predetermined position of a frame rigid frame structure.

[Effect]

With the above measures in place, the reinforced and concrete walls now bear a large amount of seismic force.

It is now able to handle greater seismic forces than before.

Application to high earthquake areas is easily possible.

〔Example〕

The present invention will be described below based on two illustrated embodiments. An embodiment of the present invention is shown in FIGS. 1-3.

As shown in the figure, the T-G mount is installed on the foundation plate 2 in the turbine building 1 and supports the turbines (3 high pressure turbines, 4 low pressure turbines) 2 generators 5 of the 9M child power plant. 6. The pillars are made of reinforced concrete and reinforced concrete. It is formed into a frame rigid structure with beams 7. In this example, the T-G mount constructed in this manner was formed by providing a reinforced concrete wall at a predetermined position of the frame rigid-frame structure. By doing this, the reinforced and concrete walls can bear large seismic forces, making it possible to cope with larger seismic forces than before, making it easier to apply reinforced concrete to high earthquake areas.
A T-G frame made of concrete can be obtained.

In other words, the T-G mount installed in the turbine building 1 is
The foundation version 2 of the turbine building 1 is the same - ii2 on the foundation version 2
It is installed separately from the turbine building floor 8 and the building inner wall. The T-G mount has a high pressure turbine 3. It is composed of a T-G mount deck 9 on which the low-pressure turbine 4 and the generator S are loaded, and a lower structure that supports the TG mount deck 9.

The lower structure of the T-G frame deck 9 has a column of 6°g? ,
Along with 7, on the high pressure turbine side, the high pressure turbine lower reinforcing steel
Similarly, for the 0 generator side where the concrete wall 10 is provided, the pillar 6. Along with the beam 7, a reinforced concrete wall 11 is provided below the two generators. on the other hand.

The lower part of the low pressure turbine 4 is supported by a reinforced concrete wall 12 surrounding the condenser. A condenser connecting pipe opening 13 is provided in the reinforced concrete wall 12 around the condenser.

By doing this, the shear strength against the seismic force that the T-G frame can bear can be the sum of the burdens of the column 6 of the T-G frame and the reinforced concrete wall 10, 11, 12, so compared to the conventional A significant improvement in earthquake force resistance can be expected compared to the T-G frame.

In other words, against the seismic force generated in the axial direction of the turbine/generator, the rigidity of the structure at the lower part of the low-pressure turbine side (condenser area 14) is sufficiently equal to the rigidity of the structures at the lower part of the high-pressure turbine side and the lower part of the generator side. However, since the seismic force is low, the earthquake force is borne by the structures on the lower part of the high-pressure turbine side and the lower part of the generator side.

Column 6 and additionally installed lower reinforcement/concrete wall of high pressure turbine 10. The reinforcing steel/concrete wall 11 at the bottom of the generator can withstand a sufficiently large seismic force.

On the other hand, regarding the seismic load that occurs in the direction perpendicular to the turbine/generator axis direction, the lower part of the low-pressure turbine side (condenser area 14) structure will also bear some of the seismic force, but the column 6 and the additionally installed lower reinforcing steel for the high-pressure turbine.
The concrete wall 102 and the reinforced concrete wall 11 at the bottom of the generator can sufficiently withstand earthquake forces larger than the conventional structure. In addition, regarding the high-pressure turbine side lower structure 9 and the complete electric machine side lower structure, the columns 6 and the additionally installed high-pressure turbine lower reinforced concrete wall 10. The reinforced concrete wall 11 at the bottom of the generator can withstand sufficiently large earthquake forces.

These additional reinforced concrete walls 10.11゜1
2 is the column 6 of the T-G frame due to the joint effect of the reinforcing bars. Since it is integrated with the beam 7 and is part of the T-G frame structure, it will surely bear the seismic force as a strong wall during an earthquake, so it can cope with larger seismic forces than conventional structures. . In the figure, 15 is a condenser, 16 is a main steam lead, a pipe opening, and 17 is a high-pressure turbine bleed pipe opening.

As described above, according to this embodiment, the following effects can be achieved.

(1) To protect against the turbine/generator axial seismic force, install reinforcing steel/concrete walls (high-pressure turbine lower reinforcing bars/concrete wall 2 generator lower reinforcing bars/concrete 1-wall) at the lower part of the high-pressure turbine side and the lower part of the generator side. By installing
The rigidity of the T-G frame can be increased and the amount of walls can be mutually adjusted.

1: This allows the balance of rigidity of the T-G frame to be the same on the high-pressure turbine side and the generator side.

The seismic force generated on the reinforced concrete walls around the condenser can be minimized.

As a result, the following effects can be achieved.

(a) By increasing the rigidity of the T-G frame.

This reduces the seismic displacement of the T-G frame and is advantageous in terms of equipment design.

(b) The shear strength of the T-G mount is greatly improved because it can be calculated by the shear force (relative to earthquake force) can withstand.

(c) When assuming the same seismic force as before.

The number of reinforcing bars arranged within the column cross section of the T-G frame can be significantly reduced, and workability can be improved.

(2) In response to seismic force in the direction perpendicular to the turbine/generator axis, the rigidity of the high-pressure turbine side and the generator side can be made the same by adding the amount of walls as shown in (1) above. At that time, T
- It is possible to minimize the displacement of the G frame, which is advantageous in terms of two-device design.

As a result, the following effects can be achieved.

(b) The earthquake load caused by torsion is averaged over the entire T-G frame, and the reinforcing bars M (number) arranged in the cross section of each column, beam, and wall are averaged. , construction efficiency is improved.

(b) The shearing force (relative to earthquake force) is (column + wall)
Since the shear strength of the T-G mount can be calculated as follows, the shear strength of the T-G mount is greatly improved, and it can withstand a larger seismic force than the conventional TG mount.

(c) When assuming the same seismic force as before.

The number of reinforcing bars arranged within the column cross section of the T-G frame can be significantly reduced, and workability can be improved.

〔Effect of the invention〕

As described above, the present invention makes it possible to obtain a nuclear power plant turbine/generator support frame made of reinforced concrete that can be easily applied to high-earthquake areas. It is possible to obtain a nuclear power plant turbine/generator support frame made of steel and concrete.

[Brief explanation of drawings]

FIG. 1 is a perspective view of an embodiment of the nuclear power plant turbine/generator support frame of the present invention, FIG. 2 is a longitudinal cross-sectional side view of the support frame and building of the same embodiment, and FIG. Z-Z
It is a sectional view along a line. DESCRIPTION OF SYMBOLS 1... Turbine building, 2... Base plate, 3... High pressure turbine, 4... Low pressure turbine, 5... Generator, 6
... Column, 7... Beam, 10... Reinforced steel/concrete wall at the bottom of the high-pressure turbine, 11... Reinforced/concrete wall at the bottom of the generator, 12... Reinforced/concrete wall around the condenser, 16. ... Main steam lead pipe opening, 17 ... 4° between high pressure turbine oil trachea pipes Figure 3 ... High pressure terpino 4 ... Low pressure turbine 5 ... Generator 10 ... Lower part of high pressure terpino reinforced concrete wall 11・
・・Reinforcing bars at the bottom of the generator・Concrete 1・Wall 12・・Reinforcing bars around the condenser・Concrete wall 16・・Main steam lead pipe opening 17・High pressure turbine bleed pipe opening

Claims (1)

[Claims] 1. The pedestal that is installed on the foundation slab in the turbine building and supports the turbines and generators of the nuclear power plant is formed into a frame rigid structure made of reinforced concrete columns and beams. A nuclear power plant turbine/generator support pedestal, characterized in that the pedestal is provided with a reinforced concrete wall at a predetermined position of the frame rigid-frame structure. 2. The nuclear power plant turbine/generator support according to claim 1, wherein the reinforced/concrete wall is provided at a lower support portion of the high-pressure turbine side and the generator side of the turbine. trestle. 3. Claim 1, wherein the reinforced concrete wall is provided at a lower part of the turbine on the low-pressure turbine side in a direction perpendicular to the axial direction of the generator.
Nuclear power plant turbine/generator support frame described in Section 1. 4. Claim 1 or 2, wherein the reinforced concrete wall installed at the lower part of the high-pressure turbine and generator of the turbine is formed with an opening.
Nuclear power plant turbine/generator support frame described in Section 1. 5. The nuclear power plant turbine/generator support pedestal according to claim 1, wherein the pedestal is separated from a turbine building adjacent to the pedestal. 6. Claim 1, wherein the high-pressure turbine-side lower support structure and the generator-side lower support structure of the turbine have the same rigidity depending on the amount of the reinforcing steel/concrete wall installed. Nuclear power plant turbine
Generator support pedestal.