JP2019215827A - Design assistance device - Google Patents

Abstract

To appropriately assist exterior wall design.SOLUTION: A design assistance device 100 comprises: an information acquisition unit 26 configured to acquire basic requirement information representing information regarding requirements of a design target building, and a basic requirement object representing an object showing a shape of the design target building; and a generation unit 27 configured to generate an exterior wall object of the design target building using the basic requirement information and the basic requirement object acquired by the information acquisition unit 26.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a design support device.

  2. Description of the Related Art Conventionally, a tallying system using a virtual three-dimensional model of an assembly of parts constituting a building is known (for example, Patent Document 1). Further, a processing system using a virtual three-dimensional model of an aggregate of components constituting a building is known (for example, Patent Document 2).

JP 2016-115040 A JP 2017-224014 A

  In designing the outer wall of a building, it is necessary to consider both the design and the price of the outer wall, so that the designer often performs trial and error on the outer wall design. However, it takes time to design an exterior wall that satisfies the requirements of the building to be designed and calculate the price of the design content. For this reason, it is preferable that the design support of the outer wall is automatically performed.

  However, the techniques described in Patent Documents 1 and 2 do not disclose design support for an outer wall.

  The present invention has been made in view of the above circumstances, and has as its object to appropriately provide design support for an outer wall.

  In order to achieve the above object, a design support apparatus of the present invention acquires basic requirement information representing information on requirements of a building to be designed and basic requirement objects that are objects representing the shape of the building to be designed. An information acquisition unit; and a generation unit that generates an object of an outer wall in the building to be designed based on the basic requirement information and the basic requirement object acquired by the information acquisition unit. Thereby, design support of the outer wall can be appropriately performed.

  The generation unit of the present invention may generate information on the specification of the outer wall according to the basic requirement information and the object of the outer wall, and may add the information to the object of the outer wall. Since the specification of the outer wall is automatically given to the object of the outer wall, design support of the outer wall can be appropriately performed.

  The design support device according to the present invention is configured such that a specific gravity information providing unit that provides physical property information relating to a specific gravity of the outer wall object to the outer wall object, and the outer wall object to which the physical property information is provided by the specific gravity information providing unit. And a load calculator for calculating a load of the building based on the calculated load. By automatically calculating the load on the outer wall, design support for the outer wall can be appropriately performed.

  The design support device of the present invention is a heat load information providing unit that provides physical property information relating to a heat load of the object on the outer wall to the object on the outer wall, and the physical load information is provided by the heat load information providing unit. A heat load calculation unit configured to calculate a heat load of the building based on the object on the outer wall. By automatically calculating the heat load of the outer wall, design support of the outer wall can be appropriately performed.

  A price information providing unit for providing price information representing a price of the outer wall object to the outer wall object; and the building based on the outer wall object to which the price information is provided by the price information providing unit. And a price calculation unit that performs the price calculation described above. Since the price calculation of the outer wall is automatically performed, the design support of the outer wall can be appropriately performed.

  ADVANTAGE OF THE INVENTION According to this invention, the effect that the design support of an outer wall can be performed appropriately is acquired.

It is a block diagram showing an example of composition of a design support device concerning this embodiment. It is a figure showing an example of basic requirement information of this embodiment. FIG. 3 is an explanatory diagram for describing a processing flow according to the embodiment; It is explanatory drawing for demonstrating the outer wall type of this embodiment. It is explanatory drawing for demonstrating the window type of this embodiment. FIG. 4 is an explanatory diagram for describing specification information of the present embodiment. FIG. 4 is a diagram illustrating an example of a design support processing routine according to the embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Configuration of Design Support Apparatus According to Embodiment of the Present Invention>

  FIG. 1 shows an example of a configuration of a design support apparatus 100 according to an embodiment of the present invention. The design support apparatus 100 according to the present embodiment can be functionally represented by a configuration including a receiving unit 10, a computer 20, and a display unit 50, as shown in FIG. The design support device 100 of the present embodiment supports a building design performed by a building designer.

  In the field of architectural design, BIM (Building Information Modeling) is being utilized. When performing architectural design, the architect designer proceeds with the design work by creating a BIM model representing a three-dimensional model of the building to be designed.

  When an architect designs an outer wall of a building, a plurality of outer wall designs may be created on a trial basis. When a plurality of exterior wall designs are created on a trial basis, it takes time to calculate the prices of the exterior walls. In addition, when a building designer designs an exterior wall, it is necessary to perform various calculations such as load calculation and heat load calculation, but after calculating the prices of a plurality of exterior walls, the load calculation and heat load calculation of those exterior walls are required. Takes time.

  Therefore, in the present embodiment, when a building designer designs an outer wall, physical property information (for example, specific gravity of each building member constituting the outer wall, a heat load factor, and the like) and an outer wall object of the BIM model are provided. Link various information such as price information. In the present embodiment, the load calculation, the heat load calculation, and the price calculation of the outer wall are automatically performed based on various information given to the object of the outer wall.

  Various calculation processes can be easily performed by using various information given to the object on the outer wall. Thereby, design support of the outer wall can be efficiently and appropriately performed.

  Hereinafter, the present embodiment will be specifically described.

  The receiving unit 10 receives information input by a user. The receiving unit 10 is realized by, for example, a keyboard, a mouse, or an input / output device that receives an input from an external device. For example, the user inputs a design support instruction signal to the computer 20 via the reception unit 10.

  The computer 20 includes a CPU (Central Processing Unit), a ROM (Read Only Memory) storing a program for realizing each processing routine, a RAM (Random Access Memory) for temporarily storing data, and a memory as storage means. , A network interface and the like. As shown in FIG. 1, the computer 20 functionally includes a basic requirement information storage unit 22, an object storage unit 24, an information acquisition unit 26, a generation unit 27, a physical property information storage unit 28, Information storage unit 30, specific gravity information giving unit 32, heat load information giving unit 34, price information giving unit 36, outer wall model setting unit 38, load calculating unit 40, heat load calculating unit 42, price calculating A unit 44 and a result output unit 46 are provided.

  The basic requirement information storage unit 22 stores basic requirement information indicating information on requirements of a building to be designed. The basic requirement information includes information on the outer wall according to the request of the builder. FIG. 2 shows an example of the basic requirement information. As shown in FIG. 2, the basic requirement information is expressed, for example, in a table format. In the present embodiment, an example will be described in which a basic requirement table, which is an example of basic requirement information, stores information on an outer wall according to a request from a builder.

  As shown in FIG. 2, the basic requirement table includes a building area "AAA", an outer wall type "BBB", a floor height "CCC", a support span "DDD", a wind pressure "EEE", and a window type "FFF". , And the presence or absence of a balcony “GGG” are stored as information on the outer wall. The basic requirement table is created by, for example, a building designer who has heard the request of the builder, and is stored in the basic requirement information storage unit 22.

  For example, in the outer wall type of the basic requirement table, information on the type of outer wall such as a double skin and a curtain wall is stored. In the window type of the basic requirement table, information on types of windows such as a sweep window, a FIX window, and a garbage is stored.

  The object storage unit 24 stores a basic requirement object that is an object representing the shape of the building to be designed. The basic requirement object according to the present embodiment is an object representing the shape of the entire building, and is created in advance according to the request of the builder. For example, the architect designer creates a basic requirement object according to the request of the architect, and stores the basic requirement object in the object storage unit 24.

  When receiving the design support instruction signal, the information acquisition unit 26 acquires a basic requirement table stored in the basic requirement information storage unit 22 and a basic requirement object stored in the object storage unit 24.

  The generating unit 27 is based on each information of the basic requirement table acquired by the information acquiring unit 26 and the basic requirement object, and is an object of an outer wall of the building to be designed (hereinafter, simply referred to as “outer wall object”). Generate

  FIG. 3 is an explanatory diagram for explaining generation of an outer wall object. As shown by X1 in FIG. 3, an outer wall object G is generated in a virtual three-dimensional space on the computer. For example, the outer wall object G is represented by a vector V in a virtual three-dimensional space.

  Note that each object for generating the outer wall object is prepared in advance. FIG. 4 shows a list of outer wall type objects for generating an outer wall object. FIG. 5 shows a list of window type objects for generating an outer wall object.

  For example, the generation unit 27 generates one of the objects in FIGS. 4A to 4H according to the outer wall type read from the basic requirement table. Further, the generation unit 27 generates one of the objects in FIGS. 5A to 5H according to the window type read from the basic requirement table. “Ew” in FIGS. 4A to 4H represents identification information for identifying the outer wall type. “Wt” in FIGS. 5A to 5H represents identification information for identifying the window type. Note that there is a type for the glass constituting the window.

  Further, when generating these objects, the generation unit 27 generates information on the specification of the outer wall (hereinafter, simply referred to as “specification information”) according to each information of the basic requirement table and the outer wall object, and Assigned to the outer wall object.

  The specification information of the outer wall object includes, for example, specifications (for example, a material and a base member of the outer wall) relating to a building material forming the outer wall, dimensions (for example, wall thickness) of the outer wall, and the like. When there are a plurality of candidates for the specification information of the outer wall object, the candidates may be displayed on the display unit 50, and the building owner or the building designer may make a selection.

  For example, as illustrated in FIG. 6, when generating the outer wall object having the outer wall type of “double skin”, the generating unit 27 uses the outer wall specification information based on the “floor height” information in the basic requirement table. As S, a height dimension L of the outer wall object is generated. When the basic requirement table includes the dimensional information d of “Marion”, the generating unit 27 determines the dimensional information d of the mullion M among the outer wall objects, as shown in FIG.

  The physical property information storage unit 28 stores physical property information indicating information on physical properties of each of a plurality of types of building members (or materials). In the present embodiment, the specific gravity and the heat transmission coefficient of each building member are stored as physical property information.

  The price information storage unit 30 stores price information representing information on prices for each of a plurality of types of building members (or materials).

  The specific gravity information providing unit 32 reads from the physical property information storage unit 28 the physical property information related to the specific gravity corresponding to the specification information of the outer wall object generated by the generating unit 27. Then, the specific gravity information giving unit 32 gives the read physical property information on the specific gravity to the outer wall object.

  The heat load information providing unit 34 reads, from the physical property information storage unit 28, physical property information related to the heat load corresponding to the specification information of the outer wall object generated by the generation unit 27. Then, the heat load information giving unit 34 gives the read physical property information on the heat load to the outer wall object. Examples of the physical property information on the heat load include a heat transmission coefficient of each member.

  The price information providing unit 36 reads out the price information corresponding to the specification information of the outer wall object generated by the generation unit 27 from the price information storage unit 30. Then, the price information giving unit 36 gives the read price information to the outer wall object.

  For example, as indicated by X2 in FIG. 3, the specific gravity information providing unit 32 provides the physical property information H1 regarding specific gravity to the external wall object G according to the specification information of the external wall object G. Further, the heat load information giving unit 34 gives the physical property information N1 on the heat load to the outer wall object G according to the specification information of the outer wall object G. Further, the price information giving unit 36 gives the price information K1 to the outer wall object G according to the specification information of the outer wall object G.

  Further, as indicated by X3 in FIG. 3, the specific gravity information giving unit 32 gives the physical property information H2 related to the specific gravity to the window object W according to the specification information of the window object W included in the outer wall object G. Further, the heat load information giving unit 34 gives the property information N2 on the heat load to the window object W according to the specification information of the window object W. Then, the price information providing unit 36 provides the price information K2 to the window object W according to the specification information of the window object W. In addition, since the glass included in the object W of the window also has a type (a heat ray reflection glass, a heat ray absorption glass, a Low-e glass, a single-pane glass, a laminated glass, a paired glass, and the like), information corresponding to the type of the glass is provided. Granted.

  When the assignment of various types of information in X2 and X3 in FIG. 3 is completed, an outer wall object G ′ as a composite graphic as shown in X4 in FIG. 3 is generated. The outer wall object G 'is provided with physical property information relating to specific gravity, physical property information relating to heat load, and price information according to its material and the like. For this reason, various calculation processes described later can be automatically executed based on these pieces of information.

  Further, the outer wall object G ′ as a composite figure shown by X4 in FIG. 3 can be changed in various dimensions (for example, the width Ww and height Hw of the entire outer wall object and the width Wg and height Hg of the window object). Have been. Even if various dimensions of the outer wall object G 'are changed, various information given to the outer wall object G' is not changed. For this reason, even when various dimensions of the outer wall object G 'are changed, various calculation processes described later can be automatically executed.

  The outer wall model setting unit 38 sets an outer wall model based on the outer wall object to which various kinds of information have been added by the specific gravity information giving unit 32, the heat load information giving unit 34, and the price information giving unit 36. For example, the outer wall model setting unit 38 sets the outer wall models GM1 and GM2 as indicated by X5 in FIG. 3 according to the basic requirement object Ob representing the building to be designed.

  Since the outer wall models GM1 and GM2 are provided with the property information on the specific gravity, the property information on the heat load, and the price information, various calculations described later can be easily executed.

  The load calculation unit 40 calculates the load of the building based on the outer wall model including the outer wall object to which the physical property information on the specific gravity has been added by the specific gravity information providing unit 32.

  Specifically, the load calculation unit 40 calculates the specific gravity (for example, the specific gravity of a PCa panel, a GRC panel, an ECP panel, an ALC panel, etc.) given to each member of the outer wall object, and the volume of each member of the outer wall object. To calculate the own weight of the wall represented by the outer wall object. Note that the load calculation unit 40 may further calculate the structure of the building to be designed based on the load calculation result of the building.

  The heat load calculation unit 42 calculates the heat load of the building based on the outer wall model including the outer wall object to which the physical property information on the heat load is provided by the heat load information providing unit 34.

  Specifically, the heat load calculation unit 42 multiplies the heat transmission rate given to each member of the outer wall object by the volume of each member of the outer wall object to obtain the average heat transmission coefficient of the wall represented by the outer wall object. Is calculated. Then, the heat load calculation unit 42 performs, for example, outer wall heat loss calculation at the time of air conditioning load calculation. In addition, the calculation result by the heat load calculation unit 42 can be used for calculation of CASBEE (building environment comprehensive performance evaluation system).

  The price calculation unit 44 calculates the price of the exterior wall of the building based on the exterior wall model including the exterior wall object to which the price information has been assigned by the price information assignment unit 36. Specifically, the price calculation unit 44 calculates the price of the wall represented by the outer wall object based on the unit price given to each member of the outer wall object and the volume (or quantity) of each member.

  The price calculation unit 44 may calculate the price of the outer wall based on the specification information given to the outer wall object. For example, the price calculation unit 44 may calculate the price of the outer wall using the calculation formula of the following expression (1).

(1)

The function f _Ew (EM) representing the price of the outer wall shown in the above equation (1) is determined according to a predetermined argument EM. Further, f _Ew (EM) in the above equation (1) is expressed as the sum of functions f _WE (Ew, Wt, bal, fe) representing the price of the outer wall object corresponding to each wall of the building.

  Ew represents the type of the outer wall type, Wt represents the type of the window type, bal represents the presence or absence of a balcony, and fe represents the presence or absence of a fire spread line. The price of each outer wall object is determined based on this information. The above equation (1) is expressed as a function of “con” indicating the amount of concrete, “glass” indicating the amount of glass, “steel” indicating the amount of iron, and “aw” indicating the amount of aluminum. You.

  For this reason, if the specification information of each material constituting the outer wall is known for each outer wall object, "con" indicating the amount of concrete, "glass" indicating the amount of glass, and "steel" indicating the amount of iron are used. , And “aw” representing the amount of aluminum are found, so that the price of the outer wall object can be calculated.

  The result output unit 46 outputs a calculation result calculated by the load calculation unit 40, a calculation result calculated by the heat load calculation unit 42, and a calculation result calculated by the price calculation unit 44 as a result.

  The display unit 50 displays various calculation results output from the result output unit 46. The display unit 50 is realized by, for example, a display.

<Operation of Design Support Apparatus 100>

  Next, the operation of the design support apparatus 100 will be described. When the receiving unit 10 of the design support device 100 receives the input of the basic requirement table, the information acquisition unit 26 stores the basic requirement table in the basic requirement information storage unit 22. When the receiving unit 10 of the design support device 100 receives the input of the basic requirement object, the information acquisition unit 26 stores the basic requirement object in the object storage unit 24. Then, when receiving the design support processing start instruction signal, the design support apparatus 100 executes the design support processing routine shown in FIG.

<Design support processing routine>

  In step S100, the information acquisition unit 26 acquires a basic requirement table stored in the basic requirement information storage unit 22.

  In step S102, the information acquisition unit 26 acquires the basic requirement object stored in the object storage unit 24.

  In step S104, the generation unit 27 generates an outer wall object based on each information of the basic requirement table acquired in step S100 and the basic requirement object acquired in step S102.

  In step S106, the generation unit 27 generates specification information of the outer wall according to each information of the basic requirement table acquired in step S100 and the outer wall object generated in step S104, and attaches the specification information to the outer wall object. I do.

  In step S108, the specific gravity information providing unit 32 reads from the physical property information storage unit 28 the physical property information related to the specific gravity corresponding to the specification information provided to the outer wall object in step S106. Then, in step S108, the specific gravity information giving unit 32 gives the read physical property information on the specific gravity to the outer wall object.

  In step S110, the thermal load information providing unit 34 reads from the physical property information storage unit 28 the physical property information on the thermal load corresponding to the specification information provided to the outer wall object in step S106. Then, in step S110, the heat load information giving unit 34 gives the read physical property information on the heat load to the outer wall object.

  In step S112, the price information providing unit 36 reads out the price information corresponding to the specification information provided to the outer wall object in step S106 from the price information storage unit 30. Then, in step S112, the price information providing unit 36 provides the read price information to the outer wall object.

  In step S114, the outer wall model setting unit 38 sets an outer wall model based on the outer wall object to which various information has been added in step S106, step S108, step S110, and step S112.

  In step S116, the load calculation unit 40 calculates the load of the building based on the physical property information of each outer wall object in the outer wall model set in step S114.

  In step S118, the heat load calculation unit 42 calculates the heat load of the building based on the physical property information of each outer wall object in the outer wall model set in step S114.

  In step S120, the price calculation unit 44 calculates the price of the outer wall of the building based on the price information of each outer wall object in the outer wall model set in step S114.

  In step S122, the result output unit 46 calculates the load calculation result obtained in step S116, the heat load calculation result obtained in step S118, and the price calculation obtained in step S120. The result is output as a result, and the design support processing routine ends.

  The display unit 50 displays various calculation results output from the result output unit 46. The architect who is a user of the design support apparatus 100 proceeds with the design work with reference to various calculation results.

  As described in detail above, the design support apparatus 100 according to the present embodiment performs design based on a basic requirement table indicating information on requirements of a building to be designed and a basic requirement object indicating a shape of the building to be designed. Generate an outer wall object of the target building. Thereby, design support of the outer wall can be appropriately performed.

  More specifically, the BIM model of the building to be designed is managed by dividing the BIM model into a basic requirement table and a basic requirement object, and only the information in the basic requirement table is changed. Is automatically generated. This makes it possible to automatically generate the outer wall object according to the request of the builder.

  In addition, the design support apparatus 100 of the present embodiment provides physical property information relating to specific gravity, physical property information relating to heat load, and price information to the outer wall object. Thereby, the load calculation result, the heat load calculation result, and the price calculation result of the BIM model of the building to be designed including the outer wall object can be automatically obtained.

  Further, according to the present embodiment, by adding various types of information to the outer wall object, it is possible to obtain a load calculation result, a heat load calculation result, and a price calculation result according to the outer wall design in an initial stage of design. Therefore, it is possible to reduce an operation in which various calculations are repeated according to a change in the outer wall design.

  Further, according to the present embodiment, the price of the outer wall can be calculated in the initial stage of the design, so that the outer wall can be appropriately designed in consideration of the budget of the builder.

  Further, according to the present embodiment, the period for determining the outer wall design by the architect can be shortened. Therefore, it is possible to sufficiently secure the time for the structural calculation by the structural designer and the time for the thermal load calculation by the facility designer.

  In addition, when the construction of the building to be designed is performed, by linking a process table relating to the construction to the outer wall object generated by the design support apparatus 100 of the present embodiment, each building member of the outer wall is linked. It can also be used for order planning.

  The present invention is not limited to the above-described embodiment, and various modifications and applications can be made without departing from the gist of the present invention.

  For example, the outer wall object to which various types of information have been added may be used at a work place when a building is constructed. In this case, it is possible to utilize the load quantity and the external dimensions given to the outer wall object and to use it for a lifting plan and the like.

  Also, when determining the specification information of the outer wall object, if there are a plurality of candidates for the specification information, the selection result by the builder or the architect may be obtained and the selection result may be stored in the database. Good. In this case, the output of the next specification information may be determined by using the selection result stored in the database (for example, the specification information recommendation).

  Further, in the above embodiment, the case where the outer wall object is generated based on the basic requirement table and the basic requirement object as an example of the basic requirement information has been described as an example, but the present invention is not limited to this. For example, an outer wall object may be generated using information stored in another BIM model representing a building to be designed. Specifically, since the type of window and the number of windows of the outer wall object may vary depending on the area of the building to be designed, the information is obtained from the BIM model in which the information is stored, and the outer wall is obtained. The type of window and the number of windows of the object may be determined.

  In the above description, the mode in which the program is stored (installed) in a storage unit (not shown) in advance has been described. However, the program is recorded on any of recording media such as a CD-ROM, a DVD-ROM, and a micro SD card. It is also possible to provide in the form which has been done.

10 Receiving unit 20 Computer 22 Basic requirement information storage unit 24 Object storage unit 26 Information acquisition unit 27 Generation unit 28 Physical property information storage unit 30 Price information storage unit 32 Specific gravity information addition unit 34 Heat load information addition unit 36 Price information addition unit 38 Outer wall Model setting unit 40 Load calculation unit 42 Heat load calculation unit 44 Price calculation unit 46 Result output unit 50 Display unit 100 Design support device

Claims (5)

An information acquisition unit that acquires basic requirement information representing information on requirements of a building to be designed, and a basic requirement object that is an object representing the shape of the building to be designed,
Based on the basic requirement information and the basic requirement object acquired by the information acquisition unit, a generation unit that generates an object of an outer wall of the building to be designed,
Design support equipment including. The generation unit generates information related to the specification of the outer wall according to the basic requirement information and the object of the outer wall, and provides the information to the object of the outer wall.
The design support device according to claim 1. A specific gravity information providing unit that provides physical property information related to the specific gravity of the outer wall object to the outer wall object,
A load calculation unit configured to calculate a load of the building based on the object of the outer wall to which the physical property information is added by the specific gravity information addition unit;
Further comprising
The design support device according to claim 2. A heat load information providing unit that provides physical property information related to a heat load of the outer wall object to the outer wall object;
A heat load calculation unit configured to calculate a heat load of the building based on the object of the outer wall to which the physical property information regarding the heat load is provided by the heat load information providing unit;
Further comprising
The design support device according to claim 2. A price information assigning unit that assigns price information representing the price of the outer wall object to the outer wall object,
A price calculation unit configured to calculate a price of the building based on the object of the outer wall to which the price information is provided by the price information provision unit;
Further comprising
The design support device according to claim 2.