JP2009002803A - Construction method for building nuclear power plant - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a construction method for building a nuclear power generation plant which streamlines measurements in the work for installing a relevant item in a normal position during each work, and also performs an efficient engineering work free from any retracements such as the avoidance of the interference with a temporary construction in advance. <P>SOLUTION: In the construction work on the nuclear power generation plant, equipment and piping are displayed in an actual space on the basis of three-dimensional computer-aided design data to install them on the basis of the positions displayed in the actual space. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to installation of equipment air and piping in construction work of a nuclear power plant, and by applying a virtual construction method, a construction method of a nuclear power plant that can be set without requiring measurement of an installation position, etc. About.

  A nuclear power plant is a large building including a reactor building, a turbine building, and the like made of reinforced concrete, and this construction work is roughly divided into the following three stages of construction steps.

  The first construction step is a concrete frame work performed as a building work and a buried work performed simultaneously with this. This burial work includes a work for setting foundation bolts for equipment embedded in concrete, a work for setting buried pipes, a work for setting buried conduits, and the like.

  The second construction step is a prior carry-in work of equipment or the like performed in parallel with the building frame construction. This pre-loading work includes construction performed before construction of the top part is performed on each floor of the building. That is, after the ceiling is completed, equipment / pipe that cannot be carried into the area, or equipment / pipe that is more effective in terms of work are carried in first.

  The third construction step is a step to carry in equipment / piping etc. that is performed after the construction work is completed. Here, installation work of equipment / piping that has been pre-loaded on each floor and equipment / piping to be carried in afterwards, Electrical instrumentation work will be carried out and full-scale construction will begin.

  A conventional example of such a construction method will be described with reference to FIGS.

  FIG. 8 shows an embedment work for equipment foundation bolts among the burial work that is the first work step. At the time of concrete frame construction, after the reinforcement bar 21 is constructed, setting work of the equipment foundation bolts 22 is performed on the maker side. Since this setting work needs to be installed in a normal position, the construction base standard ink 23 is used and the setting location is set to the equipment base bolt mount 24 in the normal position using a measuring instrument such as transit. It is fixed.

  FIG. 9 and FIG. 10 show a prior carry-in operation for equipment and the like, which is the second step. As shown in these drawings, when building, concrete is first placed on the floor 25, and when the construction of the wall 26 is completed, the equipment 27 and the piping 28 are carried into the area in advance. This is because after the ceiling construction in the area, it is carried out on equipment that is difficult to carry in and piping that is more efficient when carried in advance. After the preceding carry-in is completed, installation work for the scaffold 29 necessary for ceiling work in the area is performed. At that time, it is necessary to temporarily place equipment, piping, etc. at a position where interference with the scaffold does not occur.

  FIG. 11 shows the full-scale construction after completion of the housing construction, which is the third step. In this step, although the order of construction varies depending on each area (room), the work is generally performed in the following flow. First, the pipe 28 that has been carried in first is lifted in the air, and the installation of the equipment 27 that has been carried in first, the construction of the pipe 28, the construction of the gantry 30, the electrical equipment 31, and the instrumentation work are carried out in this order. In most of the constructions, the installation position needs to be set at a position determined in advance according to the design drawing, and the installation position needs to be measured each time.

  As described above, in each construction step, installation is performed after the installation position is measured by most work, and much labor is required for positioning.

As a conventional technique, for example, in tunnel construction, a technique for virtualizing 3D computer-aided design (3D-CAD) data for stereoscopic images and supporting construction (see Patent Document 1) is known.
Japanese Patent No. 3653196

  In the conventional construction method described above, it is necessary to measure the temporary placement position to avoid the interference with the scaffolding for the pre-delivered product, and the measurement for setting the position according to the drawing dimensions when installing the buried product. In addition, it is necessary to perform measurement work to set the position as shown in the drawing dimensions even at the full-scale construction stage.

  The present invention has been made in view of such circumstances, and aims to rationalize the measurement in the setting operation of the product to the normal position at each work, and to perform a return such as avoiding prior interference with the temporary product. The purpose is to provide a construction method for nuclear power plants that can perform efficient construction.

  In order to achieve the above object, in the invention according to claim 1, in the construction of the nuclear power plant, equipment and piping are displayed in the real space based on the three-dimensional computer-aided design data, and are displayed in the real space. A construction method for a nuclear power plant is provided, in which equipment and piping are installed based on the position.

  In the invention according to claim 2, in the construction work of the nuclear power plant, the completed state of the equipment and piping is displayed in the real space based on the three-dimensional computer-aided design data, and based on the position displayed in the real space A construction method for a nuclear power plant characterized by installing equipment and piping is provided.

  In the invention according to claim 3, in the construction work of the nuclear power plant, the completed state is displayed in the real space in relation to the building frame, so that the interference between the support member of the deck plate installed on the ceiling and the piping, etc. Construction method for a nuclear power plant, which allows the state to be confirmed in advance, confirms the displacement of hardware embedded in walls, etc., provides feedback to the design such as support design, and implements on-site construction. I will provide a.

  In the invention according to claim 4, by providing a time axis to the three-dimensional computer-aided design data, the construction status in the area is displayed in the real space, and the actual construction status is checked against the progress of the on-site construction. A construction method for a nuclear power plant characterized by checking the situation is provided.

  According to the present invention, installation at an installation position is possible without using a measuring device or the like. In addition, by installing the temporary installation location in advance at a position where there is no interference with the main installation, it is possible to carry out construction without returning. Further, by comparing the position of the steel frame and hardware already constructed on the construction side with the completed state, it is possible to confirm the interference in advance and to implement feedback to the design side at an early stage. In addition, field design can be started at an early stage while performing on-site construction, enabling timely construction. In addition, it is possible to check the progress of construction by displaying and checking the actual construction status and the status linked to the planned process, and it is possible to adjust the construction at the location by displaying the completed status. be able to.

  Hereinafter, embodiments of a construction method for a nuclear power plant according to the present invention will be described with reference to the drawings.

[First Embodiment (FIGS. 1 to 3)]
FIG. 1 is a display image diagram showing a real space in the virtual construction method, and FIG. 2 is an image diagram showing a state before pipe construction. FIG. 3 is an image diagram showing a state after the pipe construction.

  As shown in FIG. 1, in the present embodiment, 3D-CAD data in a completed state is first displayed in the real space. Specifically, a plurality of display pipes installed in the room, that is, display pipe (A) 1, display pipe (B) 2, display pipe (C) 3, display pipe (D) 4, display pump 5, and display The motor 6, the display frame 7, and the display instrumentation rack 8 are displayed at their normal positions.

  2 and 3 show examples of piping construction. As shown in FIGS. 2 and 3, the pipe (A) 9 that has been previously carried in and temporarily placed in the room is lifted and can be set to the normal position by matching the position of the display pipe (A). Become. FIG. 3 shows a state where the pipe (A) 9 is installed at the regular position, and the display pipe (A) 1 is displayed at the same position as the pipe 9.

[Second Embodiment (FIG. 4)]
FIG. 4 shows a second embodiment according to the virtual construction method of the present invention. In the real space, as shown in the first embodiment, the completion state of 3D-CAD is displayed. In the case of construction work on site, temporary equipment for construction is required, and it is necessary to arrange it near the work place. However, if there is interference with this equipment, the temporary equipment will be moved each time. In the temporary distribution board 10 that supplies construction power as temporary equipment, the completed state is displayed in the real space, so that it can be arranged in advance at a position without interference with the equipment. It is possible to prevent in advance the occurrence of the return work.

[Third Embodiment (FIG. 5)]
FIG. 5 shows a third embodiment according to the virtual construction method of the present invention. In the present embodiment, as shown in FIG. 5, the deck plate 11 is provided on the ceiling by construction in an area where equipment, piping, and the like that are carried in advance are provided. Concrete 12 is placed on the deck plate, and a steel frame 13 is applied to the lower end of the deck plate 11 to support the load.

  By displaying 3D-CAD in the real space in the area in such a state, the interference state between the steel frame 13 and the display pipe (E) 14 can be confirmed even before the construction starts, and the steel frame It becomes possible to carry out notching work of 13 interference sites in advance.

[Fourth Embodiment (FIG. 6)]
FIG. 6 shows a fourth embodiment according to the virtual construction method of the present invention. In the present embodiment, instrumentation piping and exposed electric pipes are examples of performing construction design while proceeding with on-site construction. In the present embodiment, an instrumentation pipe will be described as an example. By displaying the completed state in 3D-CAD in the real space, it becomes possible to design the route of the instrumentation pipe 15 that avoids interference with other equipment as in the case of the temporary equipment described above. Conventionally, route design and the like have been performed from the point of time when most of the facilities are completed. However, according to the present embodiment, the design can be performed from the initial stage of the work.

[Fifth Embodiment (FIG. 7)]
FIG. 7 shows a fifth embodiment according to the virtual construction method of the present invention. In this embodiment, the time axis of the construction planning process is given to the 3D-CAD, and the parts that have been completed so far are displayed in the real space, so that the pipe (A) 9, the pipe (C) 16, the pipe ( D) The installation of 17, the pump 18, the motor 19, and the gantry 20 is completed, and it can be confirmed that the display pipe (B) 2 is not constructed. In this embodiment, it is possible to grasp the progress of the construction, and display the completed state in the real space, so that the construction adjustment at the work place can be performed efficiently.

  As described above, in the virtual construction method according to the present invention, in the invention according to claim 1, it is possible to compete for the installation position without using a measuring instrument or the like by displaying the completed state in the real space. Therefore, it is possible to reduce the number of man-hours required for installation.

  Further, in the inventions according to claims 2 to 4, since the completion state is displayed, it is possible to avoid interference in advance and the reflection to the design can be carried out at an early stage. Work efficiency can be improved.

  Finally, in the invention described in claim 5, since the construction completion site up to the day can be displayed in the real space, it is possible to confirm the progress of the construction on the spot and to display the completed state. Since work adjustments can be made at the location, efficient construction management becomes possible.

The display image figure to the real space in the virtual construction method by embodiment of this invention. The image figure before the piping construction by embodiment of this invention. The image figure after the piping construction by embodiment of this invention. The temporary installation installation image figure by embodiment of this invention. The interference state display image figure with the building structure by embodiment of this invention. The instrumentation piping construction route design possible image figure by embodiment of this invention. The construction progress confirmation image figure by embodiment of this invention. The conventional equipment foundation bolt setting image figure. A prior image of conventional equipment and piping. Fig. 3 is a conventional image of a scaffold installation state in a first-in area. The image of a completed state in a conventional room.

Explanation of symbols

  1. Display pipe (A), 2 Display pipe (B), 3 Display pipe (C), 4 Display pipe (D), 5 Display pump, 6 Display mode, 7 Display stand, 8 Display Instrumentation rack, 9 ... Piping (A), 10 ... Temporary distribution board, 11 ... Deck plate, 12 ... Concrete, 13 ... Steel frame, 14 ... Display piping (E), 15 ... Instrumentation piping, 16 ... Piping (C ), 17 ... Piping (D), 18 ... Pump, 19 ... Motor, 20 ... Base, 21 ... Reinforcement, 22 ... Equipment foundation bolt, 23 ... Standard ink, 24 ... Equipment foundation bolt stand, 25 ... Floor, 26 ... Wall, 27 ... equipment, 28 ... piping, 29 ... scaffolding, 30 ... mount, 31 ... electrical equipment.

Claims (4)

In the construction of a nuclear power plant, equipment and piping are displayed as images in real space based on 3D computer-aided design data, and equipment and piping are installed based on the positions displayed in this real space. Construction method of nuclear power plant characterized by In the construction of a nuclear power plant, the completed state of equipment and piping is displayed as an image in real space based on 3D computer-aided design data, and equipment and piping are installed based on the position displayed in this real space. A construction method for a nuclear power plant characterized by In the construction of a nuclear power plant, in relation to the building frame, the completed state is displayed in real space, so that the state of interference between the deck plate support member installed on the ceiling and the piping, etc. must be confirmed in advance. A construction method for a nuclear power plant that is possible to confirm the displacement of hardware embedded in walls, etc., provide feedback to design such as support design, and carry out on-site construction. By providing a time axis to the 3D computer-aided design data, the construction status in the area is displayed in the real space, and the progress status of on-site construction is confirmed by comparing it with the actual construction status. Construction method for nuclear power plants.

Images