JP4643599B2 - Steel plate concrete condenser-integrated turbine building and its construction method - Google Patents

Description

  The present invention relates to a turbine building of a power plant, and relates to a steel plate concrete condenser-integrated turbine building that integrates a casing structure of a steel plate concrete condenser and a turbine building, and a construction method thereof.

  In the turbine building of a conventional power plant, the building and the turbine generator base are structurally separated. For this purpose, a building structure is constructed by building pillars and beams of the turbine building around the turbine generator base.

  This conventional turbine building will be described with reference to FIGS.

  4 is a longitudinal sectional view of a conventional turbine building, and FIG. 5 is a sectional view as seen from the direction VV in FIG. The condenser 9 is installed on a condenser base 10 constructed on the turbine building mat 1. A turbine generator base 11 is constructed around the condenser base 10. As shown in section IV, the condenser 9 is structurally separated from the turbine building 7 and constructed independently. A low-pressure turbine 6, a generator and a high-pressure turbine (not shown) are installed on the upper part of the turbine generator base 11.

  Since the turbine generator base 11 is installed in the central part of the turbine building 7, the structure of the turbine building 7 is a building structure in which the central part is a space. In order to establish the structure of the turbine building 7, a turbine building column 12 is erected in the vicinity of the turbine generator base 11. As described above, the turbine building pillar 12 and the turbine generator base 11 of the turbine building 7 are structurally separated and are constructed close to each other, so that the construction method is complicated.

  As described above, in the turbine building 7 of the conventional power plant, the turbine building 7 and the turbine generator base 11 are structurally separated, and the turbine building column 12 of the turbine building around the turbine generator base 11. And beams are built to form the building. Such a separation structure between the turbine building column 12 and the turbine generator base 11 is a restriction on the size reduction of the turbine building 7.

  In addition, the turbine building 7 of the boiling water nuclear power plant has a shielding wall in consideration of radiation exposure reduction in the surroundings of equipment and piping that contain radiation, since radioactive steam is introduced to the turbine. Is required. For this reason, the amount of concrete is increased as compared with a turbine building of a thermal power plant and a turbine building of a pressurized water nuclear power plant in which no radiant steam is introduced into the turbine building.

  In recent years, in order to reduce the construction cost of a boiling water nuclear power plant, a construction method in which equipment and piping are made into large blocks to shorten the construction period, and a construction method in which a building frame is constructed with steel plate concrete have been implemented. Furthermore, in order to reduce costs and shorten the construction period, it is necessary to reduce the amount of concrete in the turbine building itself.

In consideration of such circumstances, a condenser and a technology related to a construction method for shortening the construction period are known (for example, see Patent Document 1). In this technology, since there are many construction procedures regarding the construction of the condenser and the turbine generator base, the time required for the construction is reduced. In this technology, concrete is placed between a steel plate of a condenser main body and a support wall made of steel plate concrete, and a deck portion is constructed on the upper portion of the support wall. Thus, by constructing a condenser in which the condenser and the turbine generator base are integrated, and simplifying the construction procedure, the time required for the construction is shortened.
JP 2002-295981 A

  As described above, in the conventional turbine building, the construction period is shortened by constructing a condenser integrated with a support wall made of steel plate concrete in connection with the condenser constituting this part.

  However, the turbine building of the boiling water nuclear power plant requires a shielding wall that considers radiation exposure reduction compared to the turbine building of the thermal power plant and the turbine building of the pressurized water nuclear power plant. There were issues where there were many.

  In addition, the turbine building of the boiling water nuclear power plant is structurally separated from the turbine generator base and the turbine building pillars and beams are constructed around the turbine generator base. It has been established. There is a problem that the separation structure between the turbine building and the turbine generator base is a restriction on the reduction of the building.

  The present invention has been made to solve the above-described problems, and has an object to provide a steel plate concrete condenser-integrated turbine building and a construction method thereof capable of reducing the size of the turbine building and reducing the amount of concrete. To do.

To achieve the above object, in a steel plate concrete condenser integrated turbine building of the present invention, a turbine building mat underlying turbine building, provided on the turbine building mat, inner and outer walls of a steel plate A steel plate concrete condenser main body in which concrete is placed between the inner wall and the outer wall, and an upper portion of the steel plate concrete condenser main body connected to the side wall of the turbine building. Provided in the longitudinal direction of the steel plate concrete condenser main body on the upper deck to be installed, the vibration isolator provided between the upper deck and the steel plate concrete condenser main body, and the turbine building mat And a supporting base for supporting a portion that cannot be supported by the steel plate concrete condenser main body .

To achieve the above object, the method for constructing a steel plate concrete condenser integrated turbine building of the present invention, a turbine building mat construction step of constructing a turbine building mat underlying turbine building, the turbine building A steel plate concrete condenser main body construction step for constructing a steel plate concrete condenser main body provided on the mat , the inner wall and the outer wall are made of steel plates, and concrete is placed between the inner wall and the outer wall ; An upper deck construction step for constructing an upper deck on which a turbine is installed, provided on the upper part of the steel plate concrete condenser main body and connected to a side wall of the turbine building, and the upper deck and the steel concrete condenser A vibration isolator installation step for installing a vibration isolator between the main body and the turbine building mat; Provided in the longitudinal direction of the over preparative made condenser body, which is characterized in that it has a, a supporting foundation base construction step of constructing the supporting foundation base for supporting a portion that can not be supported by the steel plate concrete condenser body It is.

  According to the steel plate concrete condenser-integrated turbine building of the present invention and the construction method thereof, a condenser body constructed of steel plate concrete is incorporated as a part of the structure of the turbine building, By removing the pillars and beams constituting the turbine building, the size of the turbine building can be reduced and the amount of concrete can be reduced.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a steel plate concrete condenser-integrated turbine building and a construction method thereof according to the present invention will be described with reference to the drawings. Here, the same or similar parts are denoted by common reference numerals, and redundant description is omitted.

  FIG. 1 is a longitudinal sectional view showing a configuration of a steel plate concrete condenser-integrated turbine building according to a first embodiment of the present invention, and FIG. 2 is a sectional view seen from the II-II direction of FIG. It is.

  As shown in this figure, the steel plate concrete condenser-integrated turbine building has a steel plate concrete condenser main body 4 constructed at the top of the turbine building mat 1. The steel plate concrete condenser main body 4 includes a condenser main body steel plate 2 and a condenser outer steel plate 3 installed on the upper part of the turbine building mat 1. The condenser main body steel plate 2 forms the inner wall of the condenser main body, and the condenser outer steel plate 3 forms the outer wall of the condenser main body. Concrete is placed between the condenser main body steel plate 2 and the condenser outer side steel plate 3 to construct a steel plate concrete condenser main body 4.

  At least a part of the constructed steel plate concrete condenser body 4 constructs a turbine building body 13 as a part of the building structure. That is, the condenser main body steel plate 2 and the condenser outer side steel plate 3 and the concrete 16 placed therebetween constitute a part of the steel plate concrete condenser main body 4. In addition, the condenser main body steel plate 2, the condenser outer steel plate 3, and the concrete 16 also function as a part of the turbine building main body 13.

  A low-pressure turbine 6, a generator and a high-pressure turbine (not shown) are installed above the condenser main body steel plate 2 and the condenser outer steel plate 3. Further, a floor 14 is constructed between the upper part of the steel plate concrete condenser main body 4 and the turbine building main body 13. A traveling crane rail 18 is laid on the upper part of the turbine building body 13. A traveling crane 17 is installed on the traveling crane rail 18 and travels vertically and horizontally in the turbine building body 13.

  In the present embodiment configured as described above, the steel plate concrete condenser main body 4 constitutes the condenser main body, and at least a part of the steel plate concrete condenser main body 4 is a part of the building structure. Is incorporated in the turbine building body 13. For example, the turbine building column 12 illustrated in FIG. 5 is deleted, and instead the condenser main body steel plate 2, the condenser outer steel plate 3, and the concrete 16 support the weight of the turbine building 7. . Further, a part of the turbine generator base 11 is also deleted, and the condenser main body steel plate 2 and the condenser outer steel plate 3 are used instead as load supporting members. However, since the turbine generator or the like is long, another turbine generator base 15 is installed at a location that cannot be supported by the condenser main body steel plate 2 and the condenser outer steel plate 3 or the like.

  According to the present embodiment, the steel plate concrete condenser-integrated turbine building of the present invention has the steel plate concrete condenser main body 4 constituting the condenser main body and the steel plate concrete condenser main body 4. Is incorporated in the turbine building body 13 as part of the building structure. The steel plate concrete condenser main body 4 and the turbine building 7 can establish a structurally integrated building structure. Thus, it becomes possible to delete the pillars and beams constituting the turbine building around the conventional turbine generator base, reducing the size of the turbine building and reducing the amount of concrete. Furthermore, the construction process can be shortened by simplifying the building structure.

  In addition, since the conventional condenser body was only a steel plate, the effect of shielding the radiation from the condenser was small, but by adopting a steel plate concrete condenser, the radiation from the condenser was shielded. As a result, the shielding wall installed in the turbine building can be made thinner and lighter.

  FIG. 3 is an explanatory view showing a steel plate concrete condenser-integrated turbine building according to a second embodiment of the present invention, and is a longitudinal sectional view showing a portion III of FIG. 1 in an enlarged manner.

  As shown in the figure, the steel plate concrete condenser main body 4 has an upper deck 5 provided on the upper part. The steel plate concrete condenser main body 4 includes a condenser main body steel plate 2 and a condenser outer steel plate 3 installed on the upper part of the turbine building mat 1. Concrete is placed between the condenser main body steel plate 2 and the condenser outer side steel plate 3 to construct a steel plate concrete condenser main body 4.

  A vibration isolator 8 is installed between the steel plate concrete condenser main body 4 and the upper deck portion 5. Further, a floor 14 is constructed between the upper part of the steel plate concrete condenser main body 4 and the turbine building main body 13. On the upper deck portion 5, a low-pressure turbine 6, a generator, and a high-pressure turbine (not shown) are installed.

  In the present embodiment configured as described above, the upper deck portion 5 and the steel plate concrete condenser main body 4 can be constructed by being structurally separated. Further, when structurally separating the upper deck portion 5 and the steel plate concrete condenser main body 4, a vibration isolator 8 is installed between them to maintain the alignment of the turbine generator rotor.

  Further, the steel plate concrete condenser main body 4 constitutes the condenser main body and is incorporated as a structural housing of the turbine building main body 13. As shown in FIG. 5, the turbine building pillar constructed around the conventional turbine generator base 11 can be deleted. Thus, by integrating the steel plate concrete condenser main body 4 and the turbine building main body 13, the building size can be reduced.

  According to the present embodiment, by incorporating at least a part of the steel plate concrete condenser main body 4 as a structural housing of the turbine building main body 13, the conventional turbine building pillar is eliminated, and the turbine building is reduced in size. The structure can be simplified. In addition, the amount of concrete can be reduced. Furthermore, it is possible to shorten the construction period related to the construction of the turbine building.

  Moreover, since the conventional condenser main body was only a steel plate, the effect which shields the radiation from a condenser was small. According to this embodiment, by adopting a steel plate concrete condenser, the performance of shielding the radiation from the condenser is greatly improved, and the shielding wall installed in the turbine building can be made thin. It has become possible to reduce the weight.

  Here, the construction method of the steel plate concrete condenser integrated turbine building will be described with reference to FIG.

  First, in the turbine building mat construction step, for example, the turbine building mat 1 is constructed adjacent to the reactor building. In the steel plate concrete condenser main body construction step, a steel plate concrete condenser main body 4 is constructed on the turbine building mat 1. The steel plate concrete condenser main body 4 includes a condenser main body steel plate 2 and a condenser outer steel plate 3 installed on the upper part of the turbine building mat 1. The condenser main body steel plate 2 forms the inner wall of the condenser main body, and the condenser outer steel plate 3 forms the outer wall of the condenser main body. Concrete is placed between the condenser main body steel plate 2 and the condenser outer side steel plate 3 to construct a steel plate concrete condenser main body 4.

  Next, in the turbine building main body construction step, at least a part of the steel plate concrete condenser main body 4 is incorporated as a part of the building structure to construct the turbine building main body 13. That is, the condenser main body steel plate 2 and the condenser outer side steel plate 3 and the concrete 16 placed therebetween constitute a part of the steel plate concrete condenser main body 4. In addition, the condenser main body steel plate 2, the condenser outer steel plate 3, and the concrete 16 also function as a part of the turbine building main body 13. An upper deck portion 5 is constructed on the upper portion of the steel plate concrete condenser main body 4. A low-pressure turbine 6, a generator, and a high-pressure turbine (not shown) are installed above the condenser main body steel plate 2 and the condenser outer steel plate 3.

  In the present embodiment configured as described above, the steel plate concrete condenser main body 4 constitutes the condenser main body, and at least a part of the steel plate concrete condenser main body 4 is a part of the building structure. Is incorporated in the turbine building body 13. For example, the turbine building column 12 illustrated in FIG. 5 is deleted, and instead the condenser main body steel plate 2, the condenser outer steel plate 3, and the concrete 16 support the load of the turbine building 7. . Further, a part of the turbine generator base 11 is also deleted, and the condenser main body steel plate 2 and the condenser outer steel plate 3 are used instead as load supporting members. However, since the turbine generator and the like are long, another turbine generator base 15 is installed at a location that cannot be supported by the condenser main body steel plate 2 and the condenser outer steel plate 3 or the like.

  According to the present embodiment, by incorporating at least a part of the steel plate concrete condenser main body 4 as a structural housing of the turbine building main body 13, the conventional turbine building pillar is eliminated, and the turbine building is reduced in size. The structure can be simplified. In addition, the amount of concrete can be reduced, and the construction period for constructing the turbine building can be shortened.

  Furthermore, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention by combining the embodiments of the present invention. it can.

The longitudinal cross-sectional view which shows the structure of the steel plate concrete condenser integrated turbine building of the 1st Embodiment of this invention. Sectional drawing seen from the II-II direction of FIG. It is explanatory drawing which shows the steel plate concrete condenser integrated turbine building of the 2nd Embodiment of this invention, and is a longitudinal cross-sectional view which expands and shows the III section of FIG. The longitudinal cross-sectional view of the conventional turbine building. Sectional drawing seen from the VV direction of FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Turbine building mat, 2 ... Condenser main body steel plate, 3 ... Condenser outer side steel plate, 4 ... Steel plate concrete condenser main body, 5 ... Upper deck part, 6 ... Low pressure turbine, 7 ... Turbine building, 8 ... Vibration isolator, 9 ... Condenser, 10 ... Condenser foundation, 11, 15 ... Turbine generator base, 12 ... Turbine building pillar, 13 ... Turbine building body, 14 ... Floor, 16 ... Concrete, 17 ... Travel Crane, 18 ... Rail for traveling crane.

Claims (4)

A turbine building mat that forms the basis of the turbine building;
Provided on the turbine building mat, the inner and outer walls are made of steel, and the steel plate concrete condenser body which concrete is pouring between the inner and outer walls,
An upper deck on which the turbine is installed, provided connected to the side wall of the turbine building on the upper part of the steel plate concrete condenser main body,
A vibration isolator provided between the upper deck and the steel plate concrete condenser body;
The turbine building mat is provided in the longitudinal direction of the steel plate concrete condenser main body, and a support base for supporting a place that cannot be supported by the steel plate concrete condenser main body,
A steel plate concrete condenser-integrated turbine building. The support base is a turbine generator base that is provided in the turbine building mat in the longitudinal direction of the steel plate concrete condenser main body and supports a turbine generator that cannot be supported by the steel plate concrete condenser main body. steel concrete condenser integrated turbine building according to claim 1, wherein there. The steel plate concrete condenser-integrated turbine building according to claim 1 or 2, wherein a crane is installed on an upper portion of the turbine building. A turbine building mat construction step for constructing a turbine building mat that forms the basis of the turbine building;
Construction of a steel plate concrete condenser main body that is provided on the turbine building mat, and in which a steel plate concrete condenser main body is constructed in which inner and outer walls are made of steel plates, and concrete is placed between the inner wall and the outer wall. Steps,
An upper deck construction step for constructing an upper deck on which the turbine is installed, provided to be connected to a side wall of the turbine building on the upper part of the steel plate concrete condenser main body,
A vibration isolator installation step of installing a vibration isolator between the upper deck and the steel plate concrete condenser body;
A support foundation construction step for constructing a support foundation that is provided in the longitudinal direction of the steel sheet concrete condenser body on the turbine building mat and supports a place that cannot be supported by the steel sheet concrete condenser body;
A method of constructing a steel plate concrete condenser-integrated turbine building, comprising:

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