JP2012234256A - Through-hole covering management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a through-hole covering management system for reducing difficulty level of hole covering work.SOLUTION: The through-hole covering management system has a piece of information on building frame including a piece of information on a building frame constituting a plant building; a piece of information on equipment and control panel layout including a piece of information on the layout of the equipment and control panels and the like associated with the information on the building frame; a piece of information on environmental conditions including environmental conditions and request names of corrective actions relevant to the equipment; a piece of information on wall/floor through-hole covering model including a piece of information on hole covering work of through holes corresponding to the request names; a piece of information on difficulty level of hole covering works based on the specification including a piece of information on the difficulty level of the hole covering work of through holes corresponding to the number of the request names; and a piece of information on difficulty level of cable, conduit tube, cable tray, piping and duct works based on the distance including a piece of information on connecting means used to connect among the equipment. The through-hole covering management system assesses the difficulty level of the hole covering work corresponding to the number of the request names depending on the equipment adjacent to the building frame and determines connection route among the equipment while taking into consideration the difficulty level of the hole covering work.

Description

  The present invention relates to a through hole finishing process management system, and more particularly, to a through hole finishing process management system devised to reduce the difficulty of hole finishing process work in a through part.

  In a nuclear power plant, the plant building is partitioned into several areas, and environmental conditions such as fire prevention classification, airtight classification, and dose rate classification are determined in detail for each area.

  In such a plant, the environmental conditions required for the two penetrating areas may be different in a penetrating portion where a cable tray, a conduit, a pipe, an air conditioning duct and the like penetrate the floor or wall. For this reason, it is necessary to perform hole closing processing in consideration of the influence on other areas.

  The hole closing process here is different for each environmental condition. Measures to be applied to the penetrating part are different for each fire prevention category, airtight category, and dose rate category. For example, when the radiation dose in one area is higher than the radiation dose in the other area, it is necessary to take measures against environmental conditions in the dose rate classification, and it is necessary to shield the radiation at the penetration portion. Therefore, it is necessary to make the shape of the penetrating portion an offset structure or the like, or to stuff lead hair or the like into the penetrating portion.

  With regard to these hole closing processes, in Patent Document 1, in order to carry out so that there is no disconnection or leakage, centrally managed cables, piping, air conditioning duct route information, frame information, environmental condition information, floor / wall through hole completion Based on the model information, the penetrating part is automatically determined, the penetrating hole closing form is registered for each frame (floor, wall, etc.), and the hole closing processing method has been determined.

  FIG. 17 shows a conventional automated system for finishing a through hole. In the conventional penetrating part selection system, the housing information 3, the environmental condition information 4, the floor / wall penetrating hole type information 5, and the cable / pipe / duct route information 16 are registered in the central management database part 1 (Step 1). .

  From these data, the penetrating part information selecting unit 11 automatically selects the penetrating part (Step 2), and for each box (floor, wall, etc.), the penetrating part hole finishing processing method registration unit 18 for each box (floor / wall) Etc.), the hole closing processing method required at the penetrating part is registered (Step 3).

  Further, the penetrating part information selected by the penetrating part information selecting unit 11 and the penetrating part hole for each box (floor, wall, etc.) selected by the penetrating part hole finishing processing method registration unit 18 for each box (floor, wall, etc.) From the closing process method, the hole closing information selection unit 12 determines a hole closing process method for each penetrating part (Step 4).

  The final result is output by the output unit 13 (Step 5).

Japanese Patent Laid-Open No. 2-74898

  In the conventional hole closing processing method in the penetrating portion, first, cables, piping, and air conditioning duct routes are determined in advance in the plant building, and a location where these structures penetrate the casing is determined. Next, the hole closing process of the penetrating part is determined from the pre-registered frame (floor, wall, etc.) penetrating hole closing form.

  However, in this method, when selecting routes for cables, piping, and air-conditioning ducts, it was not considered whether hole penetration processing was necessary for the penetration part, and work difficulty such as hole finishing processing and material costs were not considered . For this reason, the location where the hole closing process is necessary is not specified, and the work difficulty of the hole closing process is high.

  In order to solve these problems, an object of the present invention is to propose a penetrating hole closing processing management system for reducing the difficulty level of hole closing processing work.

In order to solve the above problems, the present invention comprises a centralized management database unit and an information processing unit,
The centralized management database unit stores chassis information that stores information on the chassis that makes up the plant building, equipment / panel layout information that stores information related to the layout of equipment such as equipment and panels in relation to the information on the chassis, and Related environmental condition information for storing environmental conditions and request names for countermeasures, floor / wall through hole closing type information for storing information related to hole closing processing for penetrations corresponding to the required names, and request names Cable / conduit / cable that stores information on work difficulty information for each hole finish processing specification and information on connection means used for connection between devices. Work difficulty level information is provided for each tray, piping, and duct distance, and the information processing unit performs hole completion processing for the penetrating part with respect to the housing from the number of the housing, the equipment adjacent to the housing, and the required name. Depth-by-box penetration processing work difficulty level information registration unit for determining the degree of difficulty, connection means for connecting between devices, and cable for determining the connection route in consideration of the difficulty of through-hole processing for through-holes・ Pipe / duct route selection part, penetration part information selection part that defines the penetration part to be provided in the chassis of the determined route, and hole completion that obtains information related to the hole finishing process of the penetration part from the required name determined by the penetration part chassis An information selection unit and an output unit for outputting information on the through hole completion are provided.

  According to the present invention, a cable, pipe, and air conditioning duct route is determined using a through hole processing process management system for reducing the difficulty of hole finishing processing work, and the hole finishing process of the through part is minimized to complete the hole. Processing work difficulty can be reduced.

The figure which shows the structure of the penetration part hole closing process management system of this invention. The figure which shows an example of the plant building which performs a hole closing process. The figure which shows the specific housing information in the case of the plant building of FIG. The figure which shows the specific environmental condition information in the case of the plant building of FIG. The figure which shows the specific floor and wall through-hole completion type information in the case of the plant building of FIG. The figure which shows the work difficulty level information for every specific hole closing process specification in the case of the plant building of FIG. The figure which shows the specific arrangement | positioning information, such as an apparatus and a board, in the case of the plant building of FIG. The figure which shows the specific work difficulty information for every cable, electric wire pipe, cable tray, piping, and duct distance in the case of the plant building of FIG. The figure which shows the example of the new database produced | generated and registered into the penetration part hole finishing process work difficulty information registration part for every frame. The figure which shows the example of the new database produced | generated and registered into the cable, piping, and duct route selection part. The figure which shows the example of the new database produced | generated and registered into the penetration part information selection part. The figure which shows the example of the new database produced | generated and registered into the hole closing information selection part. The figure which shows an example of the hole closing list finally displayed. The flowchart which shows a series of processing content of this invention. The flowchart which shows the detail of process S8 of FIG. The flowchart which shows the detail of process S9 of FIG. The figure which shows the conventional penetration part hole finishing processing system.

  FIG. 1 shows an overall configuration of a through hole hole finishing process management system (hereinafter referred to as the present system) for reducing the difficulty level of hole closing process work related to the present invention. This system is mainly composed of a centralized management database unit 1 and an information processing unit 2.

  The central management database unit 1 mainly includes body information 3, environmental condition information 4, floor / wall through hole closing type information 5, hole closing processing specification work difficulty level information 6, equipment / panel etc. arrangement information 7, , Work difficulty information 8 for each cable / conduit / cable tray / pipe / duct distance.

  The information processing unit 2 mainly includes a per-body penetration part hole closing process work difficulty level information registration unit 9, a cable / pipe / duct route information selection unit 10, a penetration part information selection unit 11, and a hole closing information selection unit 12 The output unit 13 is configured.

  Hereinafter, detailed contents of the centralized management database unit 1 and the information processing unit 2 will be described. However, in order to facilitate understanding, the following description will be made assuming that the hole closing process for the plant building of FIG. 2 is performed.

  The plant building in this example is composed of four rooms (room 1 to room 4) partitioned by a wall (wall 1 to wall 13) and a floor (floor 1 to floor 4). In addition, a board 1 and a device 1 are disposed in the room 1, a device 2 is disposed in the room 3, and a device 3 is disposed in the room 4. Between the panel 1 and the device 1, the device 2, and the device 3, a power supply route 1, a route 2, and a route 3 using a cable, a conduit tube, a cable tray, a pipe, a duct, and the like are formed. Note that this power supply route is not fixedly determined in advance as in the conventional example, but is determined by the present invention.

  Since the power feeding route (route 1, route 2, route 3) is disposed through a wall or the like, a penetrating portion (penetrating portion 1-penetrating portion 3) is formed at an appropriate location. These penetrating parts (penetrating part 1-penetrating part 3) are targeted for the hole closing process for the plant building. In addition, although the plant building of FIG. 2 is described two-dimensionally, it is good to use the thing of the three-dimensional notation actually comprised by three-dimensional CAD.

  Next, each piece of information stored and stored in the unified management database unit 1 will be described in detail below. First, the frame information 3 indicates a floor, a wall, a ceiling, an opening, or the like registered in 3D-CAD or the like. FIG. 3 shows specific frame information in the case of the plant building of FIG. Here, for example, the thickness, material, etc. are stored as information on the walls constituting the room, taking the wall 1, wall 2, and wall 3 as an example. In addition, information that the room 1 is composed of the wall 1 to the wall 6 and the floor 1 is described as the frame information of the room 1. In addition, although FIG. 3 is provided with frame information about other floors, walls, ceilings, openings, etc., only some of them are shown here. This partial description is the same for other information described below.

The environmental condition information 4 stored and stored in the central management database unit 1 indicates specifications required for fire prevention, explosion prevention, shielding, airtightness, earth pressure, oil prevention, and the like.
FIG. 4 shows specific environmental condition information in the case of the plant building of FIG. In this example, environmental conditions and required names are defined for each device or panel installed in the plant building. For example, the board 1 installed in the room 1 is defined as a fire source as an environmental condition and a fire prevention request as a request name. Similarly, device 1 is defined as a dose source as an environmental condition, and a shielding requirement is defined as a requirement name, device 2 is defined as an explosion source as an environmental condition, and an explosion-proof requirement is defined as a requirement name, and device 3 is an oil source and a requirement name as an environmental condition. Oil-proof requirements are defined as Thus, the environmental conditions are determined by the attributes of the equipment stored in the room.

  The floor / wall through hole completion type information 5 stored and stored in the central management database unit 1 indicates a specific processing method for each environmental condition. FIG. 5 shows specific floor / wall through hole completion type information in the case of the plant building of FIG. A processing method is defined for each request name in FIG.

  The specific treatment method for each required name is that where there is a fire prevention requirement, the floor and wall penetrations in the area where there is a possibility of a fire should not be spread to other areas. (Mortar, rock wall, etc.) and seal material.

  When there is an explosion-proof requirement, it means that it is necessary to install a seal fitting etc. on the floor / wall penetration of an area with potentially explosive gas so that the explosion pressure does not go to other areas. .

  Where there is a shielding requirement, it is necessary to make the penetration part an offset or U-bend structure for the penetration part of the floor / wall in areas with different radiation dose rates, or to fill the penetration part with mortar or lead hair. Say there is.

  Where there is a demand for airtightness, it is necessary to fill the floor and wall penetrations in areas with different atmospheric pressures to prevent the spread of contamination and ensure the digestive function of the target room for non-combustible gas digestion equipment. That means.

  Where there is a water tightness requirement, the walls such as the basement floor of the building are water tight walls, so it is necessary not to provide a through-hole.

  When there is a demand for earth pressure, it means that it is necessary to fill a sealing material with flexibility in a penetration part that is buried underground.

  Where there is a demand for oil proofing, it means that, as a rule, it is necessary to provide a higher position than the oil dam in the penetrating part of the compartment storing the oil.

  The work difficulty level information 6 for each hole finish processing specification stored and stored in the central management database unit 1 is information obtained by dividing the work difficulty level according to the process workability and material cost for each floor / wall through hole finish type. For example, when there is a shielding request, it is necessary to pack lead hair or mortar into the penetrating portion, which increases the work difficulty. FIG. 6 shows the work difficulty level information for each specific hole closing process specification in the case of the plant building of FIG. As an example of the idea of the difficulty level information in this case, the difficulty level is set to be higher as the number of required conditions is larger. Alternatively, the difficulty level can be defined for each individual work.

  The device / board layout information 7 stored and stored in the central management database unit 1 refers to the layout information of devices and boards registered in 3D-CAD or the like. FIG. 7 shows specific equipment / panel arrangement information in the case of the plant building of FIG. Here, the arrangement information (case information) and the device name are stored as a pair.

  For example, the room 1 as the arrangement information is composed of the walls 1 to 6 and the floor 1 as the frame information, and the board 1 is installed therein as the device name. Further, the room 1 as the arrangement information is composed of the wall 1 to the wall 6 and the floor 1 as the frame information, and the device 1 is installed therein as the device name. The room 3 as the arrangement information is composed of the wall 5, the wall 8, the wall 9, the wall 12, and the floor 3 as the body information, and the device 2 is installed therein as the device name. The room 4 as the arrangement information is composed of the wall 6, the wall 9, the wall 10, the wall 13, and the floor 4 as the frame information, and the device 3 is installed therein as the device name.

  The work difficulty information 8 for each cable / conduit / cable tray / pipe / duct distance stored and stored in the central management database unit 1 divides the work difficulty from the workability and material cost of each structure. Say information.

  FIG. 8 shows specific work difficulty level information for each cable, conduit, cable tray, piping, and duct distance in the case of the plant building of FIG. For each type of cable (cable 1, 2, 3), conduit (conduit 1, 2), cable tray (tray 1, 2), piping (piping 1), duct (duct 1, 2) The material cost per unit length, the installation cost per unit length, and the work difficulty (level A-J) are set.

  The various information stored and stored in the central management database unit 1 has been described above. These are databases stored in a storage device of a computer such as a three-dimensional CAD. Of these, the chassis information 3 and the device / panel layout information 7 are set and input unique to the plant via an input unit (not shown) when designing the plant building. On the other hand, environmental condition information 4, floor / wall through hole closing type information 5, hole closing processing specification work difficulty information 6, and cable / conduit / cable tray / pipe / duct distance work difficulty information 8 is not limited to this plant, but can be held in advance as general information.

  Further, as is apparent with reference to FIGS. 3 to 8, these various types of information accumulated and stored in the unified management database unit 1 are not linked data but data linked to each other. That is, for example, if the device name is known, it can be understood that each database is connected using this as a direct key or other information derived from the device name as a secondary key.

  In the through hole finishing processing management system of the present invention, various types of information are stored and stored in the central management database unit 1 in FIG. 1, and the subsequent processing in the information processing unit 2 is executed. The first stage is Step1. Here, these pieces of information are managed by the unified management database unit 1 and registered as computer data such as 3D-CAD.

  Next, each process in a series of subsequent processing units in the information processing unit 2 will be described.

  As the second stage, in each step 2 through-hole penetration process work difficulty level information registration unit 9, the chassis information 3, the environmental condition information 4, the floor / wall through-hole completion model information 5, and the hole completion process specification From the work difficulty level information 6, the penetrating hole finishing process work difficulty level information is registered for each chassis.

  FIG. 9 shows an example of a new database created and registered in the through-hole penetration process work difficulty level information registration unit 9 (hereinafter simply referred to as the registration unit 9). In association with the chassis name, information on adjacent device names, device-accompanying environmental conditions, request names, number of request conditions, and difficulty levels is extracted in association with the information shown in FIGS. In this case, the chassis name may be automatically generated to extract the related information, but the operator can also specify the chassis name and extract the related information.

  For example, assume that the operator designates the wall 1 as a housing. At this time, since there is wall information in the arrangement information (frame information) of FIG. 7, the device name corresponding to the arrangement information (frame information) including the wall 1 is extracted, and this is used as the adjacent device name. To the registration unit 9. Specifically, the board 1 and the equipment 1 are extracted in relation to the wall 1, and the environmental condition information 4 in FIG. 4 is searched by using the board 1 and the equipment 1 as keys to obtain information on the environmental conditions (in this case, the board 1). 1 is extracted as a device incidental environmental condition, and is extracted to the registration unit 9 in FIG.

  Further, the environmental condition information 4 in FIG. 4 is searched by using the panel 1 and the device 1 as keys, and information on the required name (in this case, fire prevention request for the panel 1 and shielding request for the device 1) is extracted and obtained. To the registration unit 9 in FIG. Further, since the number of request names in the information stored in the registration unit 9 in FIG. 9 is 2, the number of request conditions is set to 2, and level 2 is generated in the difficulty level column with reference to FIG. .

  The same processing is executed and generated every time the operator designates the wall 2, the wall 3, the wall 4, and the wall 5 in order after the wall 1 as a casing. In the case of the wall 2, the wall 3, and the wall 4, the information accumulated in the registration unit 9 in FIG. 9 is the same result as that in the case of the wall 1, but the result is different in the case of the wall 5.

  It is assumed that the operator designates the wall 5 as a housing. At this time, since there is wall information in the arrangement information (frame information) of FIG. 7, the device name corresponding to the arrangement information (frame information) including the wall 5 is extracted, and this is used as the adjacent device name. To the registration unit 9. Specifically, the board 1, the equipment 1 and the equipment 2 are extracted in relation to the wall 5, and the environmental condition information 4 in FIG. Information (in this case, a fire source for the board 1, a dose source for the device 1, and an explosion source for the device 2) is extracted and extracted as an equipment-related environmental condition in the registration unit 9 of FIG.

Further, the board 1, the equipment 1, and the equipment 2 are used as keys to search the environmental condition information 4 in FIG. 4, and request name information (in this case, the fire prevention request for the board 1, the shielding request for the equipment 1, and the explosion prevention request for the equipment 2). ) And extracted as a request name to the registration unit 9 in FIG. Further, in the case of the wall 5, since the number of request names is 3 in the information accumulated in the registration unit 9 of FIG. 9, the number of request conditions is set to 3, and the difficulty level is referred to with reference to FIG. Generate level 3 in the column.
These processes are automatically executed in accordance with the designation of the chassis or the designation of the operator.

  As a third stage, the cable / pipe / duct route selection unit 10 of Step 3 performs the penetration part hole finishing process work difficulty information for each chassis registered by the penetration part hole finishing process work difficulty information registration part 9 for each chassis (figure 3). 9), equipment / panel layout information 7 (Fig. 7), and cable / conduit / cable tray / pipe / duct distance information 8 (Fig. 8)・ Automatically select piping and duct routes.

  FIG. 10 shows an example of a new database created and registered in the cable / pipe / duct route selection unit 10. Here, by selecting the board 1 as the starting point of the wiring and specifying each of the devices 1, 2, and 3 as the landing points, the electric circuit used and the route are selected. Among these, regarding the selection of the electric circuit to be used, information such as the electric capacity of the device is retained in association with the device name in FIG. 4, and the type of cable, piping, duct, etc. is determined appropriately referring to this information. Can do.

  In addition, a minimum rule is set for wiring route selection. For example, routes do not cross each other, routes are shared as much as possible, routes with high difficulty are avoided, and the like.

  In this case, for example, the route between the board 1 and the equipment 2 refers to the equipment and board layout information of FIG. 7 and the board 1 penetrates the wall 5 because the board 1 exists in the room 1 and the equipment 2 exists in the room 3. Is the shortest, but the difficulty of FIG. 9 is high, so this is avoided and the detour route (route 1) via the room 2 is selected. In this case, since there is no equipment or the like installed in the room 2, the difficulty level of the wall 8 is a low value although not shown in the table of FIG. As described above, in the route selection of the present invention, the possibility of a route with a low difficulty level is also examined and a route is determined.

  Since the route between the board 1 and the device 1 exists in the same room with reference to the device and board arrangement information of FIG. 7, the route in the room is selected. In addition, since the route is shared as much as possible, a part of the route 3 is shared.

  The route between the board 1 and the equipment 3 is the shortest through the wall 6 because the board 1 is in the room 1 and the equipment 3 is in the room 4 with reference to the equipment and board arrangement information of FIG. In this case, the difficulty level of the wall 6 is level 3, but since there is no detour like the wall 5, the route 3 is selected.

  As a fourth step, the penetration part information selection unit 11 of Step 4 automatically selects penetration part information at locations that interfere with the housing from the cable / pipe / duct route information selected by the cable / pipe / duct route selection unit 10. To do.

  FIG. 11 shows an example of a new database generated and registered in the penetrating part information selecting part 11. In this database, the chassis name and the penetrating part name are recorded in association with the route name. According to the route 1 defined in FIG. 10, since the room 2 is bypassed when going from the room 1 to the room 3, the penetration part 1 is formed in the wall 4 and the penetration part 2 is formed in the wall 8. According to the route 2, since it is the movement in the room 1, there is no housing and there is no penetration part. According to the route 3, the through portion 3 is formed in the wall 6 because the route goes directly from the room 1 to the room 4. Although FIG. 2 is represented in two dimensions, it goes without saying that the penetrating part information including the information on the height direction position is actually stored as three dimensions.

  As a fifth step, the hole closing information selection unit 12 of Step 5 automatically selects a hole closing method for the through part selected by the through part information selection unit 11.

  FIG. 12 shows an example of a new database generated and registered in the hole closing information selection unit 12. Since the wall which forms a penetration part is known, what is necessary is just to extract the required name set to the wall. For example, referring to FIG. 11, the wall of the penetrating portion 1 is the wall 4, and further referring to FIG. 9 using the wall 4 as a key, a fire prevention / shielding request can be extracted as a request name. Similarly, it can be extracted and arranged that there is an explosion-proof request for the penetration portion 2 and fire prevention, shielding, and oil-proof requests for the penetration portion 3.

  As a sixth stage, the output unit 13 of Step 6 displays the selection result of the hole closing method selected by the hole closing information selection unit 12 on a personal computer as a list or a through-part arrangement drawing for construction, and prints it with a printing machine or the like. .

  FIG. 13 shows an example of the finally displayed hole closing list. In the hole closing list, No is assigned to each penetrating part, and the incidental information such as how many mm the wall pressure is for each penetrating part No. and how many mm of fireproof board, sealing material, lead hair, etc. need to be packed is shown. For example, for the penetrating part 1, a 40 mm fire-resistant board is used as a specification for fire prevention requirements, and a 50 mm seal and 110 mm lead hair are used as specifications for shielding requirements for a wall with a wall pressure of 250 mm. Is displayed. These specifications are information set and stored in advance as incidental information for each request name in FIG.

  FIG. 14 is a flowchart showing a series of processing contents of the present invention. FIG. 14 shows a relationship among the central management database unit 1 and the information processing unit 2 shown in FIG. 1 and the operator. For example, a computer such as a three-dimensional CAD can describe the internal functions as a centralized management database unit 1 and an information processing unit 2, but an operator performs an appropriate input operation from the outside to this computer. The processing result is obtained as a hole closing list.

  In FIG. 14, since the computer does not hold data in the unified management database unit 1 in the initial state, the operator first inputs the basic chassis shape via the input means in process S1. This is information on the configuration of the plant building, and is stored as the chassis information 3 in FIG. 3 in the process S2. Further, the operator continues to input the basic equipment shape via the input means in the process S3. This is information on the equipment installed in the plant building, and is stored as the equipment and panel layout information 7 in FIG. The information so far is unique to this plant building.

  Subsequently, the computer obtains the information shown in FIGS. 4, 5, 6, and 8 in steps S5 to S7. Such information may be provided in advance in the computer, or may be input at this timing. Since these pieces of information are not specific to the plant building, information prepared as standard can be used.

  By the work up to the process S7, necessary data is prepared in the unified management database unit 1, and therefore, the process of the information processing unit 2 starts in the process S8 and after in FIG. The work start of the process S8 may be automatically advanced, or may be advanced by an operator's instruction and input.

  The details of the process S8 are shown in the flowchart of FIG. 15, and here, the process of the through-hole penetration part finishing process work difficulty level information registration unit 9 in step 2 of FIG. 1 is performed. That is, while updating the count number i for the chassis in the processes S81 and S84, a new device adjacent to the chassis is confirmed (Process S82), the environmental conditions for each device are confirmed (Process S83), and the difficulty level of the chassis is determined. Levels are set (processing S85).

  The work start of the process S9 may be automatically advanced, or may be advanced by an operator's instruction and input. Details of the processing S9 are shown in the flowchart of FIG. 16, and here, the processing of the cable / pipe / duct route selection unit 10 in step 3 of FIG. 1 is performed. That is, for example, information on the starting point (panel) and the landing point (device) is obtained by an operator's instruction and input (processing S91), the used electric circuit and route are searched (processing S92), and various work difficulty levels are taken into consideration. However, the route is determined (processing S94).

  In the process S10, when there is an interference part with the chassis on the route, the penetrating part information of FIG. 11 is registered in the process S11, the hole closing information is registered (process S12), and the result is output.

  As described above, in the system of the present invention, instead of the cable / pipe / duct route information 16 in the central management database unit 1, work difficulty information 6 for each hole closing process specification, arrangement information 7 such as equipment / panel etc., cable -Added work difficulty level information 8 for each conduit, cable tray, piping, and duct distance, so that this information can be used when selecting routes and penetrations for cables, piping, and ducts.

  Thereby, in this invention, the hole closing process which considered the difficulty is enabled.

1: Centralized management database unit 2: Information processing unit 3: Chassis information 4: Environmental condition information 5: Floor / wall through hole completion type information 6: Hole completion processing specification work difficulty information 7: Equipment / panel etc. arrangement information 8 : Cable / conduit / cable tray / pipe / duct distance information 9: Difficulty information registration section 10: Cable / pipe / duct route information selection section 11: Through section information selection Unit 12: Hole closing information selection unit 13: Output unit 16: Cable / pipe / duct route information 18: Through hole (floor, wall, etc.) through-hole closing processing method registration unit

Claims (8)

It has a central management database section and an information processing section,
The unified management database unit is
Chassis information that stores information on the chassis constituting the plant building, equipment / panel layout information that stores information related to the layout of equipment such as equipment / panels in relation to the information on the chassis, and an environment that is related to the equipment Environmental condition information for storing conditions and request names that are countermeasures, floor / wall through hole closing type information for storing information related to hole closing processing of through parts corresponding to the request names, and the number of the required names Cables, conduits, and cable trays that store information related to the work difficulty for each hole finishing process specification and information related to the connection means used for connection between the devices.・ Equipped with work difficulty information for each piping / duct distance.
The information processing unit
From the number of the chassis, the equipment adjacent to the chassis, and the number of required names, the difficulty of the hole finishing process of the penetration part for the chassis is determined. A connection means for connecting the cable, a pipe / duct route selection section for determining the connection route in consideration of the difficulty level of the hole penetration processing of the penetration section, and a penetration provided in the casing of the determined route Penetrating part information selecting part for determining the part, hole finishing information selecting part for obtaining information on penetrating part hole finishing processing from the request name determined by the penetrating part casing, and an output part for outputting information on penetrating part hole finishing Through hole processing management system. In the through hole processing process management system according to claim 1,
From the body information, the environmental condition information, the floor / wall through hole completion type information, and the work difficulty information for each hole finish processing specification, the through part for each body through hole penetration process work difficulty information registration unit Penetration hole finish processing management system that registers required hole finish processing method and difficulty level information. In the through hole processing process management system according to claim 1,
The above-mentioned cable / pipe / duct route is determined from the processing method / difficulty level information of the through-holes for each through-hole of the above-mentioned body, equipment / panel arrangement information, and work difficulty information for each cable / conduit / cable tray / pipe / duct / distance. A through hole processing system that registers cable, piping, and duct route information in the selected section. In the through hole processing process management system according to claim 1,
The penetrating part information selection unit is a penetrating part hole finishing processing management system in which penetrating part information is registered at a location where the casing information and the cable / pipe / duct route information interfere. In the through hole processing process management system according to claim 1,
The hole closing information selection unit is a penetrating hole closing processing management system for registering hole closing information in the database from the penetration part hole finishing processing work difficulty information for each case and the penetrating part information. In the through hole processing process management system according to claim 1,
Penetration hole finish processing management system that outputs hole finish information such as hole finish list and construction penetration layout to PC or paper. In the through hole processing process management system according to claim 1,
A through hole finishing processing management system that inputs the chassis information and the equipment / panel layout information as information unique to the plant building. Chassis information that stores information on the chassis constituting the plant building, equipment / panel layout information that stores information related to the layout of equipment such as equipment / panels in relation to the information on the chassis, and an environment that is related to the equipment Environmental condition information for storing conditions and request names that are countermeasures, floor / wall through hole closing type information for storing information related to hole closing processing of through parts corresponding to the request names, and the number of the required names Cables, conduits, and cable trays that store information related to the work difficulty for each hole finishing process specification and information related to the connection means used for connection between the devices.・ Equipped with work difficulty information for each piping / duct distance.
A penetrating hole hole finishing process management method that determines the difficulty level of hole closing process according to the number of request names determined by the equipment adjacent to the chassis, and determines the connection route between the devices in consideration of the difficulty level of the hole closing process. .

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