JP6444808B2 - Method of installing new equipment in power plant and power plant - Google Patents

Description

  The present invention relates to a method for installing new equipment in a power plant such as a nuclear power plant or a thermal power plant, and a power plant.

  In recent years, power plants such as nuclear power plants and thermal power plants have been required to take measures to protect outdoor buildings from natural disasters such as tornadoes and tsunamis and external factors such as intentional aircraft collisions. For example, Patent Document 1 describes a technique for installing a nuclear reactor facility in a cave discovered in a rocky area or a mountain.

  In addition, when installing new equipment such as a power supply room, fuel tank, and monitoring control room for existing equipment, it is required to bury these new equipment in the ground to protect them from external factors. It has been.

Next, a method for installing new equipment in a conventional power plant will be described with reference to FIGS.
7 and 8 are explanatory diagrams for explaining a method for installing a new facility in a conventional power plant.

  As shown in FIGS. 7A and 7B, in a conventional power plant 200, a new facility 201 is installed in the ground around an existing building 1 such as a nuclear reactor or an existing power supply facility. And the installation method of the new installation 201 in the conventional power plant 200 excavates the installation vertical hole 203 in the ground 5 around the existing building 1 as shown in FIGS. 8A and 8B. When the excavation work is completed, floor and wall concrete are placed in the installation vertical hole 203.

  Then, after placing the floor and wall concrete, the new equipment 201 is carried into the installation vertical hole 203 using the heavy machine 209, and installation work is performed. After the installation work of the new equipment 201 is completed, ceiling concrete is placed on top of the new equipment 201. Then, after the ceiling concrete is placed, the installation vertical hole 203 is backfilled, whereby the new equipment 201 is installed in the ground.

Special table 2014-52533 gazette

  However, in the conventional installation method shown in FIGS. 7 and 8, the installation vertical hole 203 needs to be excavated to be larger than the size of the new installation 201 in order to bury the new installation 201 and to lay the floor and wall concrete. was there. Further, around the existing building 1, not only a space for burying new equipment 201 but also a work space 204 for temporary storage of materials for excavation work, installation of heavy machinery 209 and a work site, etc. It was. Therefore, in the conventional installation method, a vast site is required around the existing building 1 in order to secure a space for excavating the installation vertical hole 203 and a work space 204.

  In addition, an emergency vehicle stop space 7 for stopping the emergency vehicle is provided around the existing building 1. The stop space 7 is connected to an emergency vehicle road 6a through which an emergency vehicle passes from the road 6. The stop space 7 and the emergency vehicle road 6a need to be secured so that the vehicle can pass and stop even during the work of installing the new equipment 201. Therefore, in the conventional installation method, it is necessary to excavate the installation vertical hole 203 while avoiding the stop space 7 and the emergency vehicle road 6a, and the construction procedure is complicated.

Further, when the cutting range of the installation vertical hole 203 is included in the stop space 7, the road 6 or the emergency vehicle road 6a, as shown in FIGS. 8A and 8B, a gantry 207 through which the vehicle can pass and stop is provided. It was necessary to provide a detour, which caused the construction procedure to increase.

  An object of the present invention is to provide a new facility installation method and a power plant in a power plant that can reduce the construction space and simplify the construction work in consideration of the above problems.

In order to solve the above problems and achieve the object of the present invention, a method for installing new equipment in a power plant of the present invention includes the following steps (1) to (4).
(1) A step of excavating a horizontal hole for installation on a slope provided around an existing facility.
(2) A process of excavating a groove from an existing facility to a horizontal hole for installation.
(3) The process of installing the connection member which consists of piping and a cable in a groove part, and filling a groove part.
(4) A process of installing new equipment in the installation side hole.
Further, the groove portion is formed avoiding the emergency vehicle stop space provided around the existing equipment and the emergency vehicle road through which the emergency vehicle passes.

Moreover, the power plant of this invention is equipped with the existing installation by which the surroundings were provided with the slope, a new installation, and the connection member which consists of piping or a cable. The new equipment will be installed in the installation side hole formed on the slope. The connecting member connects the existing equipment and the new equipment. The connecting member is disposed in a groove portion excavated from the existing equipment to the installation side hole. Further, the groove is formed avoiding the emergency vehicle stop space provided around the existing facility and the emergency vehicle road through which the emergency vehicle passes, and is filled after the connection member is installed.

  According to the installation method of a new facility and the power plant in the power plant of the present invention, it is possible to reduce the construction space and simplify the construction work.

It is a figure which shows schematic structure of the power plant concerning the embodiment of this invention, FIG. 1A is a top view, FIG. 1B is the SS sectional view taken on the line shown to FIG. 1A. It is a flowchart explaining the installation method of the new installation in the power plant concerning the embodiment of this invention. It is explanatory drawing which shows the installation method of the new installation in the power plant concerning the embodiment of this invention. It is explanatory drawing which shows the installation method of the new installation in the power plant concerning the embodiment of this invention. It is explanatory drawing which shows the installation method of the new installation in the power plant concerning the embodiment of this invention. It is explanatory drawing which shows the installation method of the new installation in the power plant concerning the embodiment of this invention. It is a figure which shows schematic structure of the conventional power plant, FIG. 7A is a top view, FIG. 7B is the SS sectional view taken on the line shown to FIG. 7A. It is explanatory drawing which shows the installation method of the new installation in the conventional power plant.

  Hereinafter, a method for installing a new facility and an embodiment of a power plant in a power plant according to the present invention will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected to the common member in each figure.

1. Configuration Example of Power Plant First, the configuration of a power plant according to an embodiment of the present invention (hereinafter referred to as “this example”) will be described with reference to FIG.
1A and 1B are diagrams showing a schematic configuration of a power plant of this example.

  The power plant 100 of this example shown in FIGS. 1A and 1B is, for example, an electronic power plant or a thermal power plant. The power plant 100 includes an existing building 1 and peripheral facilities 2 and 3 arranged around the existing building 1. Examples of the existing building 1 include a reactor building and an existing power supply room in a nuclear power plant, and a cooling tower and a turbine room in a thermal power plant. Examples of the peripheral facilities 2 and 3 include a storage tank for storing cooling water and a power supply room in a nuclear power plant, and a storage tank and a power supply chamber in a thermal power plant. The existing building 1 and the peripheral facilities 2 and 3 constitute an example of the existing facility of this example.

  Around the existing building 1, a road 6 and a stop space 7 for stopping an emergency vehicle are provided. The road 6 and the stop space 7 are connected by an emergency vehicle road 6a. When the vehicle passes through the emergency vehicle road 6 a, the vehicle can access the stop space 7 from the road 6.

  Generally, the existing building 1 is constructed by cutting a mountain, a hill 9 or the like. Therefore, a hill 9 higher than the ground 5 on which the existing building 1 is installed and a slope 8 indicating an example of a slope are provided around the existing building 1. The slope 8 is an artificial slope formed by cutting or embankment.

  An installation lateral hole 11 is excavated on the slope 8 and the hill 9. A new facility 10 is installed in the installation lateral hole 11. This new facility 10 is a facility newly installed than the existing building 1 and the peripheral facilities 2 and 3. Examples of the new facility 10 include various other facilities such as a standby power supply room, a fuel tank, and a control room.

  Moreover, the opening in the horizontal hole 11 for installation is provided so that the door part 12 can be opened and closed. The door 12 seals the opening of the installation lateral hole 11 in a watertight or airtight manner. The door 12 isolates the internal space of the installation lateral hole 11 in which the new facility 10 is installed from the outside of the installation lateral hole 11.

  The new facility 10 and the existing building 1 are connected by a pipe and a cable (hereinafter referred to as “connecting member”) 13. The connecting member 13 is installed in a groove portion 16 described later, and is embedded in the ground 5 and the ground 9.

2. Next, with reference to FIGS. 1-6, the example of the installation method of the new installation 10 in the power plant 100 mentioned above is demonstrated.
FIG. 2 is a flowchart showing a method for installing new equipment in a power plant. 3 to 6 are explanatory diagrams showing a method for installing new equipment in a power plant.

  As shown in FIGS. 3A and 3B, a planned installation location 10 a where the new facility 10 is installed is set out of the slope 8 provided around the existing building 1. The planned installation location 10 a is set in consideration of not only the position of the stop space 7, the emergency vehicle road 6 a and the road 6, but also the position of the underground facility 2 a that connects the existing building 1 and the peripheral facility 2. In addition, in order to shorten the length of the connection member 13, the vicinity of the existing building 1 is preferable for the planned installation location 10a.

  Then, as shown in FIG. 2, FIG. 4A and FIG. 4B, the installation lateral hole 11 is excavated at the planned installation location 10a on the slope 8 and the hill 9 (step S11). As shown in FIGS. 4A and 4B, the opening in the installation lateral hole 11 is formed in the slope 8.

  Further, around the existing building 1, a work space 14 serving as a heavy machine installation or a temporary storage place for materials is provided. Since the installation lateral holes 11 are provided on the slope 8 and the hill 9, a work space 14 having a sufficient area can be secured around the existing building 1. The work space 14 is not limited to the periphery of the existing building 1, and may be provided around the slope 8 or the hill 9. As a result, even when it is difficult to secure a sufficient space around the existing building 1, workability can be improved by providing the work space 14 on the slope 8 or the hill 9.

  Next, as shown in FIGS. 5A and 5B, the groove 16 is excavated (step S12). The groove portion 16 extends from the existing building 1 to the installation lateral hole 11 by excavating the ground 5. The groove part 16 is provided avoiding the stop space 7, the emergency vehicle road 6a, and the underground facility 2a. Therefore, it is not necessary to provide a gantry in the stop space 7 or the emergency vehicle road 6a, and it is not necessary to provide a detour for accessing the stop space 7.

  In addition, a gantry 17 is installed at a location across the road 6 in the groove 16. Since the gantry 17 of this example is installed only in the part which crosses the road 6 in the groove part 16, it can be made smaller than the gantry 207 in the conventional installation method shown to FIG. 8A and FIG. 8B. As a result, the installation scale of the gantry 17 can be reduced, construction work can be simplified, and temporary costs can be reduced.

  Next, the connection member 13 is installed in the groove part 16 (step S13). In addition, the connection member 13 is comprised by the piping and cable which can be bent. Therefore, the groove part 16 in which the connection member 13 is installed is not limited to a linear groove, and may be a groove having bent parts at a plurality of locations. As a result, it is possible to avoid the road 6 so that the groove 16 does not cross the road 6. Moreover, the location which excavates the groove part 16 can be set easily.

  Next, as shown in FIGS. 6A and 6B, the groove 16 is backfilled and the connecting member 13 is buried in the ground (step S14). In addition, in order to connect to the new installation 10, the edge part 13a by the side of the installation horizontal hole 11 in the connection member 13 is extended toward the ground. Further, by burying the connection member 13 in the ground, the connection member 13 can be protected from external factors such as natural disasters and intentional aircraft collisions.

  When the backfilling of the groove 16 is completed, the gantry 17 is removed. As described above, in this example, the gantry 17 may be installed only during the period in which the groove 16 is excavated and the connection member 13 is installed. Therefore, the period for installing the gantry 17 can be shortened as compared with the gantry 107 in the conventional installation method shown in FIGS. 8A and 8B.

  Moreover, although the example which excavates the groove part 16 at once was demonstrated in this example, it is not limited to this. For example, the groove 16 may be excavated in multiple times from the existing building 1 to the installation side hole 11 and the connecting member 13 may be installed in multiple times. Thereby, the period when the gantry 17 is installed can be shortened more.

  Next, as shown in FIGS. 1A and 1B, concrete is placed on the ceiling, wall, and floor of the installation lateral hole 11. Then, the new equipment 10 is carried into the installation lateral hole 11 and installed (step S15). Here, the backfilling operation of the groove 16 has been completed. Therefore, the surrounding space other than the installation horizontal hole 11 can be used as the work space 14, and the space around the existing building 1 can be used effectively.

  Furthermore, since a heavy machine for carrying in and installing the new equipment 10 does not pass on the gantry 17, the gantry 17 having a small load resistance can be used. Therefore, the scale of the gantry 17 can be prevented from becoming unnecessarily large, and temporary costs can be reduced.

  In addition, you may perform the installation process of the new installation 10 in step S15 simultaneously with the process of installing the connection member 13 in the groove part 16 of step S13 mentioned above, and the process of burying the connection member 13 of step S14 in the ground. Or the installation process of the new equipment 10 in step S15 may be performed prior to the process of installing the connection member 13 in the groove portion 16 of step S13 described above and the process of filling the connection member 13 in step S14 into the ground. .

  Next, when the installation process of the new facility 10 in step S15 is completed, the door 12 is installed in the opening of the installation lateral hole 11 (step S16). Thereby, the installation work of the new equipment 10 is completed.

  As described above, the door 12 seals the opening of the installation lateral hole 11 in a watertight and airtight manner. Therefore, the internal space of the installation lateral hole 11 is isolated from the outside of the installation lateral hole 11 by the door 12. Thereby, the new equipment 10 can be covered with the hill 9 and the door part 12, and the new equipment 10 can be protected from external factors, such as natural disasters, such as a tornado and a tsunami, and an intentional aircraft collision.

  According to the installation method of the new facility 10 of this example, only the groove 16 excavates the ground 5 around the existing building 1. The groove 16 is backfilled when the connecting member 13 is installed. Therefore, compared with the conventional installation method shown in FIG. 8A and FIG. 8B, the space and period which excavate the ground 5 around the existing building 1 can be reduced. As a result, even when the space around the existing building 1 is narrow, the work space 14 can be secured and the new facility 10 can be easily installed. In addition, it is possible to reduce the size of temporary facilities such as the groove 16 and the gantry 17 and reduce work costs.

  In addition, by arranging the existing equipment 1 such as the existing building 1 and the peripheral equipment 2, 3 and the new equipment 10 apart from each other, even if a disaster or accident occurs from either the existing equipment or the new equipment 10, the remaining On the other hand, damage can be prevented from spreading.

  In addition, in the power plant 100 of this example, although the example which excavated the horizontal hole 11 for installation in the slope 8 which is an artificially formed slope and installed the new installation 10 was demonstrated, it is not limited to this Absent. For example, the new facility 10 may be installed by excavating the installation lateral hole 11 in a naturally formed slope provided around the existing facility.

  The present invention is not limited to the embodiment described above and shown in the drawings, and various modifications can be made without departing from the scope of the invention described in the claims.

  DESCRIPTION OF SYMBOLS 1 ... Existing building (existing equipment) 2, 3 ... Peripheral equipment, 2a ... Underground equipment, 5 ... Ground, 6 ... Road, 6a ... Emergency vehicle road, 7 ... Stop space, 8 ... Slope (slope), 9 DESCRIPTION OF SYMBOLS 10 ... New equipment, 10a ... Installation planned location, 11 ... Horizontal hole for installation, 12 ... Door part, 13 ... Connection member, 13a ... End part, 14 ... Working space, 16 ... Groove part, 17 ... Gantry, 100 ... Power plant

Claims (3)

Excavating a horizontal hole for installation on a slope provided around the existing equipment;
A step of excavating a groove from the existing facility to the installation side hole;
Installing a connecting member consisting of a pipe and a cable in the groove and filling the groove;
Installing a new facility in the lateral hole for installation;
Only including,
The groove part is a method for installing a new facility in a power plant that is formed around an emergency vehicle stop space provided around the existing facility and an emergency vehicle road through which the emergency vehicle passes . The method for installing new equipment in the power plant according to claim 1, wherein a door that can be opened and closed is installed in the opening of the horizontal hole for installation. Existing facilities with surrounding slopes,
New equipment installed in the installation side hole formed on the slope,
A connecting member comprising a pipe or a cable for connecting the existing equipment and the new equipment ,
The connecting member is disposed in a groove excavated from the existing facility to the installation side hole,
The groove portion is formed avoiding an emergency vehicle stop space provided around the existing facility and an emergency vehicle road through which the emergency vehicle passes, and is buried after the connection member is installed.

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