JP2015018308A - Cable selection system and selection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cable selection system and selection method for selecting a cable line type for each cable.SOLUTION: In a cable selection system for, when laying a cable in a job site such as a plant, determining the cable to be used there, information of a device in a cable route from a start point to an end point is held for each cable number of the cable to be used, and the device and an area in which the device is arranged are held in association, and environmental conditions in the area are held, and environmental condition information available for each cable material is held, and required conditions necessary as the cable to be connected to each device for use is held for each device, and the environmental conditions at a spot where the cable passes and the cable materials under the environmental conditions and the required conditions necessary as the cable are extracted as information associated with each cable number, and output in association with each cable number.

Description

  The present invention relates to a cable selection system and a selection method for determining the line type of a cable used here when laying a cable at a site such as a plant.

  When laying a cable at a site such as a plant, it is necessary to appropriately select the line type to be used in consideration of the environment where the cable is laid and the conditions of the equipment to be applied.

  Conventionally, to select the line type of a cable, the designer extracts the related conduit and tray from the cable route, and extracts the ambient temperature and ambient radiation dose of the cable from the layout information of the conduit and tray. The cable line type is selected together with the circuit classification of the cable, the number of cores, and the requirements of the equipment that is the starting point of the cable. At this time, the information necessary for selecting the cable line type is confirmed and compared by visual observation of a plurality of materials, etc., and there is a possibility that information selection mistakes or oversights may occur.

  For this reason, automatic processing of these design work is desired. Regarding this automation technique, for example, in Patent Document 1 as a method for managing cable deterioration in a nuclear power plant, cable information, arrangement information, environmental information, cable deterioration information, and cable replacement work, which are information necessary for cable management, are disclosed. A method has been proposed in which information is stored as a database, and necessary data in the database is called up and automatically calculated in a computer to obtain and manage priorities regarding cable replacement for each tray. In addition, cable information shows the information regarding a cable wire type, a material, and an installation route.

Japanese Patent Laid-Open No. 09-274094

  However, Patent Document 1 merely proposes that necessary information is accumulated in a database in a method for managing cable degradation, and that processing by a computer proceeds from the viewpoint of degradation.

  It does not use a database or arithmetic processing to determine the line type as in the present invention. For this reason, even if useful data can be stored in the database, the calculation method for performing the selection flow of the cable circuit category information, the number of cores information, the equipment requirement information and the cable line type using this data Was unknown, and the cable type could not be selected on the system. In other words, Patent Document 1 merely stores various data in a database, and an arithmetic processing method for selecting a cable for organically combining them to obtain a desired result has not been established.

  Therefore, the present invention adds cable information, equipment arrangement information, ambient environment condition information, circuit classification information, core count information, equipment requirement information, and manages the information in the database. The cable selection system and the selection method for selecting the cable line type are provided by automatically calculating the cable line type selection flow for each cable.

As described above, in the present invention, the cable selection system includes a storage device and an arithmetic device, and determines a cable to be used here when laying a cable at a site such as a plant,
In the storage device, information on the cable route from the start point to the end point is stored for each cable number of the cable used, the cable information database, and the arrangement information held by associating the device with the area in which the device is arranged. Necessary as a database, an environmental condition information database that holds environmental conditions in the area, a cable material information database that holds environmental condition information that can be used for each cable material, and a cable that is connected to the equipment and used for each equipment With equipment information database that holds the requirements,
The computing device extracts the environmental condition of the point where the cable passes, the cable material under this environmental condition, and the necessary requirements for the cable as information related to each cable number from a plurality of databases. It is characterized by being output in association with.

  The cable selection system of the present invention includes a centralized management database unit, records cable circuit classification information, etc. as information necessary for cable line type selection in the database, and stores information necessary for selecting the cable line type in the database. The cable line type selection flow is automatically calculated on the system, and the cable line type can be automatically selected.

The figure which shows the structure of the cable selection system which concerns on Example 1 of this invention. The figure which shows the example of a concrete wiring field. The figure which shows the example of the cable information table stored in database DB1. The figure which shows the example of the arrangement | positioning information table stored in database DB2. The figure which shows the example of the environment information table stored in database DB3. The figure which shows the example of the cable material information table stored in database DB4. The figure which shows the example of the cable apparatus information table stored in database DB5. The figure which shows the example of the cable wire type selection condition information table stored in database DB6. The figure which shows an example of the arrangement | positioning information selection table formed after the process of an arrangement | positioning information selection part. The figure which shows an example of the highest environmental condition information selection table formed after the process of the highest environmental condition information selection part. The figure which shows an example of the cable material information selection table formed after the process of a cable material information selection part. The figure which shows an example of the required condition information selection table of the cable formed after the process of the required condition selection part of a cable. The figure which shows an example of the cable wire type selection condition selection table formed after the process of a cable wire type selection condition selection part. The figure which shows the structure of the cable selection system which concerns on Example 2 of this invention. The figure which shows the memory content of cable information table TB1 of Example 2. FIG. The figure which shows the memory content of cable size data table TB7 of Example 2. FIG. The figure which shows the memory content of cable size selection table TB8 of Example 2. FIG. The figure which shows the memory content of cable wire type selection table TB15 of Example 2. FIG. The figure which shows the example of the wiring site in Example 3. FIG. The figure which shows an apparatus and its attribute information as CAD information. The figure which shows a conduit and its attribute information as CAD information. The figure which shows a tray and its attribute information as CAD information. The figure which shows a cable and its attribute information as CAD information.

  Embodiments of the present invention will be described with reference to the drawings.

  The cable selection system according to the present invention will be described below with reference to a specific example of a wiring site. The wiring site in FIG. 2 is divided into areas RA, RB, and RC, and each area is under a different temperature and radiation environment. Of these, the control panel Bd1 and instruments S1, S2 are installed in the area RA, the control panel Bd2 is installed in the area RB, and the motor M and the valve V are installed in the area RC. The cables are arranged between these devices across the area, and a conduit P or a tray T is used for cable storage.

  FIG. 1 is a diagram showing a configuration of a cable selection system according to the present invention. This system is realized by a computer system composed of a storage device and an arithmetic device. In FIG. 1, various databases DB in the storage device are shown in the upper part, and the processing procedure Pr in the arithmetic unit is shown in the lower part.

  Various databases DB in the storage device are centrally managed, and not only basic data but also intermediate data generated by processing in the processing procedure Pr or final data as final products are appropriately stored here. . The database DB that is centrally managed is a cable information database DB1, an arrangement information database DB2, an environmental condition information database DB3, a cable material information database DB4, a device information database DB5, and a cable line type selection condition information database DB6. These various databases DB are created, registered and recorded for each type of information.

  DB1 of the databases DB is a cable information database, and an example of basic data stored therein is a cable information table TB1 shown in FIG. What to have as the cable information stored here is determined in consideration of the following. First, in order to finally select the cable line type, it is necessary to obtain the maximum ambient environment condition in the cable route. For example, in a power plant, devices are arranged in various areas, and cable route information about which conduits and trays the cables connected to the devices pass through is necessary. In addition, since the use and line type may be different even in the same cable route, it is necessary to identify one by one by cable number, and cable number information is necessary.

  In consideration of these points, each column constituting the cable information table TB1 includes a column 100 for the cable number, 101 for the circuit classification, 102 for the number of cores, 103 for the starting device, 104 for the landing device, and column 105. The cable route is divided and stored.

  According to the stored data, referring to the wiring site in FIG. 2, for example, the cable with the cable number 1 is a three-core cable used in the control circuit, from the control panel Bd1 to the control panel Bd2. It can be understood that the wires are wired via the conduit P1, the tray T1, the tray T2, and the conduit P2. The cable with cable number 3 is a three-core cable used in the power circuit, and is wired from the control panel Bd1 to the motor M via the conduit P5, the tray T5, the tray T6, and the conduit P6. . In addition, since it can understand similarly about the other cable of table TB1, description here is omitted.

  In short, the contents stored in the cable information database DB1 define the arrival and departure points and routes and the circuits (control circuit, power circuit, instrumentation circuit) used for each cable.

  Arrangement information is stored in the database DB2. Here, it is necessary to consider the following when determining the arrangement information. For example, in a power plant, a building is partitioned into several areas, and the ambient temperature and the ambient radiation dose are different for each area. For this reason, arrangement information about where the conduits, trays, and devices are arranged is necessary.

  An example of basic data stored in the database DB2 is an arrangement information table TB2 shown in FIG. In this table, individual devices and electric circuits (wiring routes) are stored in the column 106, and locations (areas) where the devices are arranged are stored in the column 107. For example, installation locations such as devices that are arranged in the area RA for the control panel Bd1 and in the area RB for the control panel Bd2 are stored for each device. Since other devices of the table TB2 can be understood in the same manner, the description here is omitted.

  Environmental condition information is stored in the database DB3. Here, in order to determine the environmental condition information, the following points should be noted. First, cable deterioration is largely due to the effects of ambient temperature and ambient radiation. For this reason, the cable must be made of a material that can withstand the ambient environmental conditions of the area where the cable is installed. Therefore, the values of ambient temperature information and ambient radiation information of the area where the cable is laid are required.

An example of basic data stored in the database DB3 is the environmental condition information table TB3 shown in FIG. In this table, the area is stored in the column 108, and the temperature and radiation dose at that location are stored in the columns 109 and 110, respectively. According to this, the area RA has a temperature of 40 ° C. and the radiation dose is 3 × 10 ⁴ Gy, the area RB has a temperature of 50 ° C. and the radiation dose is 1 × 10 ⁵ Gy, the area RC has a temperature of 30 ° C., and the radiation dose is 2 × 10 ⁶ Gy. In terms of temperature, the area RB is severe in a high temperature environment, but it can be seen that the area RC is the most severe in terms of radiation dose.

  The database material DB4 stores cable material information. The following points should be noted when determining environmental condition information. First, cable deterioration is largely due to the effects of ambient temperature and ambient radiation. For this reason, the cable must be made of a material that can withstand the ambient environmental conditions of the area where the cable is installed. Therefore, ambient temperature information and ambient radiation information values for each cable are required.

  An example of basic data stored in the database DB4 is a cable material information table TB4 shown in FIG. In this table, the cable material is stored in the column 111, and the allowable temperature and the allowable radiation dose of the cable material are stored in the columns 112 and 113, respectively. According to this memory case, it is better to use a glass braid when the temperature is high, use ethylene propylene rubber when the radiation dose is high, and use vinyl when both are not so high.

  Device information is stored in the database DB5. The following points should be noted when defining device information. First, the cable is divided into a power circuit, a control circuit, an instrumentation circuit, a thermocouple circuit, and the like according to the circuit division, and the structure of the cable differs depending on the circuit division. Therefore, circuit classification information of the device is necessary. Also, the structure of the cable differs depending on the number of cores even if the material is the same. Therefore, core number information is required. Furthermore, even if the circuit classification is a control circuit, a shielded cable may be applied depending on the equipment requirements. In this case, an instrumentation cable is selected instead of a control cable. Also, the type of cable varies depending on the measurement accuracy and measurement range of the device. Therefore, device requirement information is required.

  An example of basic data stored in the database DB5 is a device information table TB5 shown in FIG. In this table, the device is stored in the column 114, and the cable request condition for this device is stored in the column 115. In this example, there is no cable limitation for the control panel Bd, the motor M, and the valve V, but a cable for high-temperature piping is specified for the instrument S1, and a shielded cable is specified for the instrument S2.

  The database DB 6 stores cable line type selection condition information. The following points should be noted regarding the determination of cable line type selection information. First, there are various types of cables installed in the power plant, and materials such as insulators and sheaths differ depending on the cable type. The environmental conditions that can be used differ depending on the material. Also, the cable structure varies depending on the circuit classification and the requirements of the equipment. For this reason, the cable type information applicable by the environmental conditions in a power plant, a circuit division, etc. is required.

  An example of basic data stored in the database DB6 is a cable line type selection information table TB6 shown in FIG. In this table, as the cable line type selection, for example, when “circuit classification is control circuit” and “cable requirement is shielded cable”, the circuit classification is set as an instrumentation circuit, or “cable material is vinyl. "If the cable requirement is for high-temperature piping," the cable material is stored in glass braiding.

  In the processing procedure Pr configured by the arithmetic device of FIG. 1, the storage type of various databases DB in the storage device is linked to finally determine the cable line type. The processing procedure Pr includes a conduit, tray, and device arrangement information selection unit Pr1 for selecting information related to the cable number, and a maximum ambient environment condition information selection unit Pr2 for obtaining the maximum ambient environment condition from the environmental condition information for a certain cable number. Cable material information selection section Pr3, cable circuit classification, number of cores, equipment requirement condition information selection section Pr4, the highest ambient environment condition information of a certain cable number, circuit classification information, and equipment requirement condition information Cable line type information selection unit Pr5 that obtains cable line type information by automatically calculating the selection flow, cable route information related to the cable for each cable number, maximum ambient temperature information, maximum ambient radiation dose information, circuit classification information The cable list output unit Pr6 outputs the number of cores information and cable line type information as a cable list. It is.

  The processing procedure for linking the information in the database will be described below. The premise is that the cable number is specified by an external operator, or the cable number is specified by a processing start command. . The first process for this is executed by the conduit, tray, and device arrangement information selection unit Pr1 (hereinafter simply referred to as the arrangement information selection unit).

  When the cable number is designated, the arrangement information selection unit Pr1 refers to the cable information table TB1 as the table TB including the cable number information, and extracts the corresponding data. That is, for example, when cable number 1 is designated, the cable number 1 is extracted from the column 100 of the cable information table TB1, and the control circuit is set as the circuit classification of the column 101 stored in association with the cable number 1. Information, 3 as the number of cores in column 102, control panel Bd1 as the starting device in column 103, control panel Bd2 as the landing device in column 104, Bd1 → P1 → T1 → T2 → P2 → Bd2 as the cable route in column 105 To extract.

  Further, from the extracted information, the device included in the cable route in the column 105 is referred to, and using this as an index, the column 106 of the arrangement information table TB2 is referenced to extract all the information on the area where the device is arranged. . In the case of cable number 1, the area R1 is extracted with respect to the control panel Bd1, the conduit P1, and the tray T1, and the area R2 is extracted with respect to the tray T2, the conduit P2, and the control panel Bd2. In addition, these data are stored in cooperation. The above-described series of processing is executed for all designated cable numbers.

  An example of the arrangement information selection table TB10 formed after execution of a series of processes in the arrangement information selection unit Pr1 is shown in FIG. According to this figure, it can be seen that the data in the column 107 of the arrangement information table TB2 is added to the data in the columns 100 to 105 of the cable information table TB1 to form a new data group. For example, it can be understood that the cable No. 1 is used in the areas RA and RB, the cable No. 3 is used in the areas RA and RC, and the cable No. 5 is used in the areas RB and RA.

  According to the process of the arrangement information selection unit Pr1, the following relationship can be organized. First, in the cable information of the cable information table TB1, the cable route of a certain cable number indicates which conduit or tray the cable passes through when connecting from the source device to the destination device. You can find the conduit number and tray number related to the cable number. In the arrangement information of the arrangement information table TB2, the conduit number and tray number and the area number in which the conduit, tray, and connected device are arranged are described. For this reason, the cable route and the arrangement area number of the cable route can be known by linking the cable information and the arrangement information.

The highest environmental condition information selection unit Pr2 refers to the environmental condition information table TB3 using the area information in the column 116 of the arrangement information selection table TB10 created by the arrangement information selection unit Pr1 as an index, and information on the temperature and radiation dose corresponding to the area To extract. For example, in FIG. 9, the areas where the cable with the cable number 1 is laid are RA and RB. Therefore, referring to the environmental condition information table TB3 in FIG. 5, the temperature of the area RA is 40 ° C. and the radiation dose is 3 × 10 ^4. Gy is extracted, and a temperature of 50 ° C. and a radiation dose of 1 × 10 ⁵ Gy are extracted for the area RB. These pieces of extracted information are linked to the arrangement information selection table TB10 created by the arrangement information selection unit Pr1.

When the environmental condition information table TB3 is referenced for all the specified cable numbers, the maximum environmental condition information selection table T11 of FIG. 10 is formed. However, since the cable of the cable number 1 is laid through the areas RA and RB, the temperature of the area RB of 50 ° C. is extracted as the higher temperature, and the radiation dose of the area RB as the higher radiation dose. 1 × 10 ⁵ Gy is extracted and reflected in the maximum ambient environment condition information selection table T11.

  According to the processing of the highest environmental condition information selection unit Pr2, the following relationships can be organized. First, the arrangement information selection unit Pr1 knows the cable route in a certain cable number and the arrangement area number of the cable route, and in the ambient environment condition information, the value of the area number, the ambient temperature information in the area, and the ambient radiation dose information Is marked. For this reason, by associating the selection result of the arrangement information selection unit Pr1 with the ambient environment condition information, the cable route at a certain cable number, each ambient temperature in the cable route, and each ambient radiation dose can be known. When selecting a cable route material, it is necessary to select a wire type that can withstand the maximum ambient temperature information and maximum ambient radiation dose information in the cable route. Therefore, the maximum ambient temperature information and the maximum ambient radiation dose information are obtained from each temperature and each radiation dose in the cable route of a certain cable number.

  The cable material information selection unit Pr3 refers to the cable material information table TB4 using the maximum temperature information and maximum radiation dose information in the columns 117 and 118 of the environmental condition information selection table TB11 created by the maximum environmental condition information selection unit Pr2 as indexes. , Extract information on cable material corresponding to maximum temperature information and maximum radiation dose information.

For example, in FIG. 10, the material satisfying the specifications of the maximum temperature information 50 ° C. and the maximum radiation dose information radiation dose 1 × 10 ⁵ Gy, which is the environment where the cable of cable number 1 is laid, is extracted from the cable material information table TB4 of FIG. This can then be vinyl. Similarly, a material that satisfies the specifications of the maximum temperature information 50 ° C. and the maximum radiation dose information radiation dose 2 × 10 ⁶ Gy, which is the environment in which the cable of cable number 3 in FIG. 10 is laid, is the cable material information table TB4 in FIG. When extracted from, ethylene propylene rubber can be used. FIG. 11 shows a cable material information selection table TB12 that is formed when all the processes in the cable material information selection unit Pr3 are completed. An item in the column 119 is newly added.

  The cable material information selection unit Pr3 can select a material that can withstand even the harshest environment from the environment of the highest temperature and radiation dose in the passing environment.

  In the cable circuit classification, the number of cores, and the required condition information selection unit Pr4 (hereinafter simply referred to as the required condition information selection unit) Pr4, the device information in the column 105 of the cable material information selection table TB12 created by the cable material information selection unit Pr3 is indexed. As described above, with reference to the device information cable TB5, the required condition of the cable used in the device is extracted. For example, in FIG. 7, when the equipment is the control panel Bd, the motor M, and the valve V, the cable requirements are not set, but a cable for high-temperature piping should be used for the instrument S1, and the instrument S2 Is directed to use shielded cables.

  FIG. 12 shows a request condition information selection table TB13 that is formed when all the processes in the request condition information selection unit Pr4 are completed. A column 120 item (requirement condition for cable) is newly added. According to this, there is no information on the cable requirements of the cable numbers 1, 2, 3, and 4 that are not connected to the instruments S1, S2, but the cable numbers 5, 6 that are connected to the instruments S1, S2. Cable requirements are set for the cable. As a result, it is found that there are conditions to be observed other than the temperature and radiation conditions described above.

  The following can be arranged by the requirement condition information selection unit Pr4. In the cable information, the device to be connected is described in the cable route of a certain cable number, and the device number to which the certain cable number is connected is known. In the device information, a device number and its circuit classification are described. For this reason, the circuit classification of a certain cable number can be known by linking the cable information and the device information. Since the device number is known, the number of cores can be determined from the number of terminals of the device. Furthermore, since the device number is known, the requirements for the device are known.

  The cable line type information selection unit Pr5 refers to the cable line type selection condition table TB14 of FIG. 8 with the item (cable request condition) in the column 120 newly added to the request condition information selection table TB13 as an index. As a result of this reference, the line type condition including the condition for high-temperature piping specified for the cable of cable number 5 is “when the cable material is vinyl and the cable requirement is for high-temperature piping, the cable material is glass braided. Get. Since the cable of cable number 5 corresponds to this condition, in the table TB13 of FIG. 12, the information on the corresponding part is corrected from vinyl to a glass braid to obtain a table TB14.

  Also, as the line type condition including the condition with the shielded cable indicated for the cable of cable number 6, "When the circuit classification is a control circuit and the cable requirement is a shielded cable, the circuit classification is an instrumentation circuit." Get. Of the cables with cable numbers 6 and 7 that have received instructions for shielded cables, the cable with cable number 6 meets this condition. Therefore, in the table TB13 of FIG. 12, the information on the corresponding part is transferred from the control circuit to the instrumentation circuit. The table TB14 is obtained by correcting. Note that the cable of cable number 7 is applied to the instrumentation circuit from the beginning, so there is no need for correction.

  According to the processing of the cable line type information selection unit Pr5, the following relationship can be arranged. First, the maximum environmental condition information selection unit Pr2 knows the maximum ambient temperature information and the maximum ambient radiation dose information in the cable route of a certain cable number. The cable circuit category selection unit Pr3 knows the circuit classification information, core of the cable number. Number, equipment requirements information is known. Therefore, a cable line type selection flow is constructed from the maximum temperature in the cable route, maximum radiation dose, cable circuit classification, equipment requirements, and the maximum temperature in the cable route for a cable number in the cable line type selection flow. The optimum cable line type is obtained from the cable line type information table TB5 by automatically calculating from the information, the maximum radiation dose information and circuit classification information, the number of cores, and the device request information.

  The cable list output unit Pr6 outputs the finally collected cable line type selection condition selection table TB5 as a cable list.

  As described above in detail, in the present invention, the cable number is the starting point, the cable route information related to the cable number is selected, the conduit and tray arrangement information related to the cable route information, and the equipment arrangement Select the information, select the temperature information and radiation dose information related to the placement information of the conduit and tray and the equipment placement information, find the maximum environmental condition from the temperature information and radiation information, and relate to the cable number Select cable circuit classification information from cable route information, circuit classification information, number of cores information, and equipment requirement information, and select maximum environmental condition information, cable circuit classification information, number of cores information, equipment requirement information, and cable line type selection. The cable type is automatically selected by calculating the information together.

  The present invention is not limited to the above-described embodiments, and it is possible to obtain the following functions and effects by further expanding the information recorded in the centralized management database and by adding arithmetic expressions in the information processing unit. it can.

  The realization of cable size selection by adding elements will be described with reference to FIG. In the system configuration of FIG. 14 showing the cable selection system according to the second embodiment of the present invention, a cable size information database DB7 is additionally installed in the central management database DB. Further, load current information is given and held in the cable information table TB1 in the cable information database DB1.

  FIG. 15 shows the storage contents of the cable information table TB1 in the cable information database DB1. Here, the magnitude of the maximum load current is further stored in the column 121 in the stored contents of FIG. According to this, the load current of the cables 1 and 2 used in the control circuit is 30 amperes, the load current of the cable 3 used in the motor M of the power circuit is 100 amperes, and the cable used in the valve V of the control circuit. The load current of 4 loads is set to 15 amperes, and the load currents of the cables 5, 6 and 7 used in the instrumentation circuit are set to 5 amperes.

  FIG. 16 shows the storage contents of the cable size information database DB7 further added to the database DB in FIG. In the cable size data table TB7 of FIG. 16, the column 122 stores the cable size, and the column 123 stores the allowable current for the cable size. Size 1 has an allowable current of 10 amperes and size 2 has an allowable current of 20 amperes, and the allowable current increases by 10 amperes each time the size number increases by one.

  Using the above data added to the database DB7, the processing unit Pr performs the following additional functions. First, the request condition information selection unit Pr4 performs a search and information acquisition using the cable request condition as an index with respect to the cable line type selection condition table TB6, and acquires the information in the request condition information selection unit Pr4.

  Further, at the same time as this instruction, the request condition information selection unit Pr4 gives the load current for each cable number as an index to the newly added cable size information database DB7 to obtain the cable size information at this current. Is sent to the cable size selection unit Pr7.

  As a result, specifically, cable size 3 is selectively extracted as a cable that can pass the load current (30 amperes) of cable numbers 1 and 2, and the cable that can pass the load current (100 amperes) of cable number 3 The cable size 10 is selected and extracted, and the cable size 2 is selected and extracted as a cable capable of flowing the load current (15 amperes) of the cable number 4, and the load currents (5 amperes) of the cable numbers 5, 6, and 7 are passed. The cable size 1 is selectively extracted as a cable that can be used. Here, the minimum size is selected.

  In the newly added cable size selection unit Pr7, as a result of collecting information for all cable numbers, the cable size selection table TB8 of FIG. 17 is generated. The cable size selection table TB8 includes the cable number in the column 100, the load current in the column 120, and the cable size in the column 123.

In the cable line type selection unit Pr5, the table TB13 created by the requirement condition information selection unit Pr4
The cable line type selection table TB15 of FIG. 18 is obtained in consideration of the information of the table TB8 created by the cable size selection unit Pr7. The cable size in the column 124 is newly added.

  By adopting the structure as in the second embodiment, it is possible to automatically calculate the line type and size of the cable by consistent work, so that work efficiency is improved.

  In the first embodiment and the second embodiment, it is premised that data necessary for a database is organized and stored from the viewpoint of the components of each database. However, in the process of actually designing the system, since the on-site design of the plant or the like has already been performed using CAD or the like, it is preferable to construct each database using CAD information. The use of CAD information will be described below.

  The description here will be made with reference to an example of the wiring site shown in FIG. Here, the devices 301, 302, and 303 are connected via conduits 401, 402, and 403 and trays 501 and 502. And in CAD, these elements are grasped | ascertained and stored with each ID number and attribute information as an object.

FIG. 20 shows an example of CAD information arranged for grasping and expressing 301 as a device, and other devices are arranged in the same manner. The device 301 is assigned with an ID number of 301, and as attribute information, an arrangement area (area 601), temperature (50 ° C.), radiation dose (2.0 × 10 ⁵ Gy), circuit classification (power circuit), core The number (2) and the requirements for the device (with a shield requirement) are given.

FIG. 21 is an example of CAD information organized to grasp and represent 401 as a conduit, and other conduits are also organized in the same manner. The conduit 401 is given 401 as an ID number, and is also given an arrangement area (area 601), temperature (50 ° C.), and radiation dose (2.0 × 10 ⁵ Gy) as attribute information.

FIG. 22 shows an example of CAD information arranged for grasping and indicating 501 as a tray, and other trays are arranged in the same manner. The tray 501 is assigned ID number 501 and, as attribute information, is given an arrangement area (area 602), temperature (40 ° C.), and radiation dose (1.0 × 10 ⁵ Gy).

  FIG. 23 is an example of CAD information arranged to grasp and represent 501 as a cable, and other cables are arranged in the same manner. The cable 701 is assigned 701 as an ID number, and is given a cable route as attribute information.

  Since each element is grasped as data as described above inside the CAD, it is obvious that the database can be easily constructed by reflecting this data in the databases DB1 to DB7.

  The present invention can be realized by linking these data. For example, when the cable route of the cable number 701 is as shown in FIG. 23, when the cable number 701 is selected, the device number 301, the conduit number 401, the tray number 501 and the conduit tube related from the cable route information of the cable are selected. The objects of the number 402 and the device number 302 are highlighted and selected.

  At this time, the temperature information and the radiation dose information of the arrangement area are called for each selected object, and the maximum temperature information and the maximum radiation dose information are selected by the maximum environmental condition information selection unit.

  In addition, the device circuit classification information, the number of cores information, and the device requirement information are called up, and the cable circuit classification, the number of cores, the device requirement condition information selection unit, the device circuit classification information related to the cable route information, the number of cores Information, equipment requirement information is selected.

  The optimum cable line type is selected by the cable line type information selection unit from the maximum temperature information and maximum radiation dose information, cable circuit classification information, number of cores information, and device requirement information for the cable number 701.

  Finally, information related to each cable number is listed and output as a cable list.

DB: Database TB: Data table Pr: Processing unit R: Area Bd: Control panel P: Conduit T: Tray M: Electric motor V: Valve

Claims (8)

A cable selection system comprising a storage device and a computing device, and determining a cable to be used here when laying a cable at a site such as a plant,
In the storage device, information on the device in the cable route from the start point to the end point is stored in association with the cable information database held for each cable number of the cable to be used, and the area where the device is arranged. An arrangement information database, an environmental condition information database that holds environmental conditions in the area, a cable material information database that holds the environmental condition information that can be used for each cable material, and a device that is connected to the device for use Equipment information database that holds the necessary requirements for cables
The arithmetic device, as information related to each cable number from the plurality of databases, to extract the environmental conditions of the point where the cable passes, the cable material in this environmental condition, and the requirements necessary for the cable, A cable selection system, wherein the cable numbers are output in association with each other. The cable selection system according to claim 1,
The storage device includes a cable line type selection condition information database holding cable line type selection conditions to be considered when selecting a cable line type, and the arithmetic unit output corresponding to the cable line type selection condition A cable selection system characterized by making corrections. A cable selection system according to claim 1 or claim 2,
The storage device has information on the cable size related to the load current of the cable with the cable number,
The arithmetic unit includes a cable size information in an arithmetic unit output. The cable selection system according to any one of claims 1 to 3,
The cable selection system is linked to a CAD system, and various databases of the storage device are constructed by using devices held in the CAD system and attribute information thereof. The cable selection system according to claim 4,
From the information necessary for selecting the cable line type and the information necessary for selecting the cable size, an object is constructed in CAD, and the object has attributes, thereby managing the information necessary for the cable line type and size. A cable selection system characterized by A cable selection method for determining a cable to be used here when laying a cable at a site such as a plant,
Holds information about the device in the cable route from the start point to the end point for each cable number of the cable to be used, holds the device in association with the area where this device is placed, holds the environmental conditions in the area, Holds the environmental condition information that can be used for each cable material, holds the necessary requirements for cables used by connecting to the equipment for each equipment,
From the plurality of information, as the information related to each cable number, the environmental condition of the point where the cable passes, the cable material in this environmental condition, and the necessary conditions necessary for the cable are extracted, and for each cable number A cable selection system characterized in that the final output is related to The cable selection method according to claim 6,
A cable selection method characterized by having a cable line type selection condition to be considered when selecting a cable line type, and correcting the final output corresponding to the cable line type selection condition. The cable selection method according to claim 6 or claim 7,
Has information on the cable size in relation to the load current of the cable of the cable number,
A cable selection method, wherein the final output includes cable size information.

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