JP2021056846A - Design system - Google Patents

Abstract

To provide a design system which allows for efficiently designing members constituting a building.SOLUTION: A design system is provided, comprising an acquisition unit (control device, step S101) for acquiring information on a general drawing of a building, and a design unit (control device, step S104) for designing exterior parts (corner panels) of the building based on drawing information described in the general drawing acquired by the acquisition unit.SELECTED DRAWING: Figure 2

Description

The present invention relates to a technique for a building design system.

As a technique related to a building design system, for example, the technique described in Patent Document 1 is known.

Patent Document 1 includes a storage unit for storing information on a large number of structural members, and a modeling unit for arranging structural members selected based on input information of a designer at a predetermined position in a work space. The design system is disclosed. In addition, the modeling unit determines the possibility of joining between one structural member and another structural member, and when it is determined that the joining is possible, the joining portion is displayed in different colors on a three-dimensional image. To do. As described above, in the technique described in Patent Document 1, the designer can arrange the structural members while confirming the fit (bondability) of the structural members.

However, in the technique described in Patent Document 1, it is necessary for the designer himself to first select a member constituting the building (in the example described in Patent Document 1, a structural member), and the designer is specialized in the selection. Since judgment is required, there was room for improvement in terms of poor work efficiency.

Japanese Unexamined Patent Publication No. 2012-83002

The present invention has been made in view of the above circumstances, and the problem to be solved is to provide a design system capable of efficiently designing members constituting a building.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, it includes an acquisition unit that acquires information on a general map of the building, and a design unit that designs the outer skin parts of the building based on the drawing information described in the general map acquired by the acquisition unit. It is a thing.

Further, the acquisition unit may acquire basic information about the building, and the design unit may design the exodermis component based on the drawing information and the basic information.
With such a configuration, the members constituting the building can be designed more appropriately.

Further, the design unit replaces a part of the reference shape of the exodermis part with a partial shape of the exodermis part determined based on the drawing information and / or the basic information, thereby causing the exodermis part. May be designed.
With such a configuration, the members constituting the building can be efficiently designed.

Further, the general map may include an elevation view and a plan view.
With such a configuration, the members constituting the building can be efficiently designed.

The exodermis component is an outer wall panel of the building.
With such a configuration, the outer wall panel can be efficiently designed.

The exodermis component is a corner panel.
With such a configuration, the corner panel can be efficiently designed.

As an effect of the present invention, it is possible to efficiently design the members constituting the building.

The block diagram which showed the structure of the design system which concerns on one Embodiment of this invention. A flowchart showing a design method by a design system. The figure which showed an example of the elevation view of a building. The figure which showed an example of the plan view of a building. The figure which showed an example of the information about a building classified. A flowchart showing how to determine the configuration of the corner panel. The figure which showed an example of the conclusion-related information. The perspective view which showed an example of the standard-sized corner panel. Similarly, a cross-sectional perspective view. The figure which showed the appearance of replacing the upper part and the lower part of a standard-sized face material. A perspective view showing an example of the upper shape of a corner panel according to a building. The perspective view which showed the example which showed the dimension together with the frame and the like. The figure which showed an example of production information.

First, the outline of the design system 100 according to the present embodiment will be described with reference to FIG.

The design system 100 is for designing a building, and in particular, for designing an exodermis component that partitions the interior space and the exterior space of the building. The exodermis part is a member that does not bear the structural strength of the building. The exodermis part is a member capable of dividing the area from the outer shell of the building. As an example, the design system 100 according to the present embodiment designs an outer wall panel (particularly, a corner panel used for a corner portion).

The design system 100 according to the present embodiment mainly includes an input device 10, a display device 20, and a control device 30.

The input device 10 is for inputting various information to the control device 30. The input device 10 is composed of a terminal that can be operated by an operator (designer). For example, as the input device 10, a keyboard, a touch panel, a scanner, or the like can be used.

The display device 20 is for displaying various information (characters, drawings, etc.) received from the control device 30. For example, as the display device 20, a liquid crystal monitor, a touch panel, or the like can be used.

The control device 30 performs various calculations, storage, and the like based on various information. The control device 30 is composed of a storage unit such as a RAM, a ROM, an HDD, a CPU, and the like. For example, a personal computer or the like can be used as the control device 30. The control device 30 is connected to the input device 10 and can acquire information input via the input device 10. The control device 30 is connected to the display device 20 and can display various information on the display device 20.

Hereinafter, the operation of the design system 100 (a method of designing a corner panel using the design system 100) will be described. The design system 100 can automatically design the outer skin parts (corner panels) from the information (outer shell shape, etc.) regarding the outer shell of the building. Hereinafter, a specific description will be given.

In step S101 of FIG. 2, the control device 30 acquires information regarding the planning and design performed in advance. In this embodiment, as information on planning and design, information on general maps (elevation view, plan view (plan view) and specifications) of the building to be designed shall be used. 3 and 4 show an example of an elevation view and a plan view of the building, respectively. The plan view shown in FIG. 4 corresponds to the third floor portion of the building shown in FIG. In addition, FIGS. 3 and 4 are a part of the elevation view and the plan view of the building, and the control device 30 also acquires the elevation view seen from other directions, the plan view of another floor, and the like. ..

Since the design system 100 according to the present embodiment designs the exodermis parts from the outer shape of the building and the like, structural members such as columns and beams of the building (exhibiting the structural strength of the building) for the design. Information about the member) is not always necessary. That is, in step S101, it is sufficient to acquire the information obtained from the general map, and it is not always necessary to include the detailed information obtained from the so-called plan, which describes various structures in more detail.

In step S102, the control device 30 acquires basic information (building information) regarding the building. Building information mainly includes information on building construction methods and products, and information on fireproof specifications. Building information can be obtained from specifications, etc. in the general map of the building to be designed.

Note that FIG. 5 shows an example of classifying information (attribute classification) regarding a building (particularly, a corner panel to be designed). Information as shown in FIG. 5 is stored in the control device 30 by the steps S101 and S102, and other methods.

For example, as shown in FIG. 5, the control device 30 uses the building information acquired in step S102 to obtain information on the building construction method and product classification (product name, etc.), "construction method / product", and fireproof specifications of the building. Acquire "fireproof specifications", etc., which are information about.

Further, the control device 30 has a "horizontal cross section" which is information about the shape of the horizontal cross section of the corner panel to be designed, a "part" which is information about a part of the corner panel, and a corner panel from the general map acquired in step S101. "Arranged floors" which is information about the number of floors arranged, "Height" which is information about the height of the corner panel, "Surface material specifications" which is information about the face material specifications of the corner panel, Shapes of the upper and lower parts of the corner panel "Upper / lower shape" which is information about the shape, "intermediate shape" which is information about the shape of the middle part of the face material of the corner panel, etc. are acquired.

Further, in the control device 30, "fastening-related", which is information on standard (in principle) fastening materials and joint holes of various members, is stored in advance.

In step S103 of FIG. 2, the control device 30 creates three-dimensional data of the outer shell (appearance) of the building from the information acquired in steps S101 and S102. Specifically, the control device 30 plots the position information regarding the outer shell of the building acquired in step S101 on the three-dimensional coordinates, and creates the three-dimensional data of the building. By creating the 3D data of the building in this way, the 3D image of the building can be displayed (viewed) using appropriate software, and the outer shape of the building can be easily grasped. Can be done.

In step S104, the control device 30 designs the corner panel. The control device 30 determines a specific configuration (shape, etc.) of the corner panel based on the general map acquired in step S101, the building information acquired in step S102, and the like. Hereinafter, a specific description will be given.

In step S201 of FIG. 6, the control device 30 determines the "fireproof specification" based on the information (building information) such as the specifications acquired in step S102. Specifically, the control device 30 has a plurality of specifications (“fireproof specifications”, “fireproof specifications”, in which the specifications of the building to be designed are assumed in advance based on the “fireproof specifications” obtained in step S102. Judge which of the "b semi-fireproof specifications", "a semi-fireproof specifications", "fireproof specifications", etc.) corresponds to, and determine the "semi-fireproof specifications".

In step S202, the control device 30 determines the "horizontal cross section" of the corner panel based on the general map (particularly, the plan view) acquired in step S101. Specifically, the control device 30 has a horizontal cross-sectional shape of the corner panel to be designed (for example, the corner panel of the part A in FIGS. 3 and 4) by referring to the plan view acquired in step S101. , Multiple shapes assumed in advance (L-shape with two sides equal (equal sides), L-shape with one side longer than the length of the other side by a predetermined value (unequal sides) Etc.), determine which shape corresponds to, and determine the "horizontal cross section".

In step S203, the control device 30 determines the "part", "arrangement floor", and "height" of the corner panel based on the general map (particularly the elevation view) acquired in step S101. Specifically, in the control device 30, by referring to the elevation view acquired in step S101, the portion of the corner panel to be designed (for example, the corner panel of the part A in FIGS. 3 and 4) can be changed. It is determined which part corresponds to a plurality of parts (outer wall, waist wall, Iraka, etc.) assumed in advance, and the "part" is determined.

Further, the control device 30 determines the number of floors of the corner panel to be designed (for example, the third floor in the case of the corner panels shown in FIGS. 3 and 4) by referring to the elevation view acquired in step S101. Then, determine the "number of floors to be placed".

Further, the control device 30 determines the height (for example, 2400 mm, 2700 mm, etc.) of the corner panel to be designed by referring to the elevation view acquired in step S101, and determines the “height”.

In step S204, the control device 30 determines the "upper / lower shape" of the corner panel based on the general map (particularly, the plan view) acquired in step S101. Specifically, the control device 30 is designed by taking into consideration the general map (plan view, etc.) acquired in step S101 and the building information (products, etc.) acquired in step S102. In detail, the shapes of the upper part and the lower part of the various members such as the face materials constituting the corner panel) are determined.

The pattern of the shape of the upper part and the lower part of the corner panel is predetermined according to the product and the like. For example, for a certain product, 41 patterns are predetermined as shapes that may be applied to the upper part of the corner panel. When determining the shape of the upper part of the corner panel, one shape is selected and applied from the shapes of the 41 patterns. Further, for the product, 16 patterns are defined in advance as shapes that may be applied to the lower part of the corner panel. When determining the shape of the lower part of the corner panel, one shape is selected and applied from the shapes of the 16 patterns.

When selecting the shape of the upper and lower parts of the corner panel, the members connected to the corner panel are taken into consideration. For example, considering information such as "the rammer (rammer panel) is connected to the corner panel" and "the waist wall panel of the balcony is connected to the corner panel", the connection was made. The top and bottom shapes are selected. Further, if necessary, the upper and lower shapes are selected in consideration of other information (for example, the above-mentioned "horizontal cross section", "site", "height", etc.).

When considering a member to be connected to the corner panel as described above, an identification symbol (combination of numbers, alphabets, etc.) indicating an attribute such as the shape of the connecting portion is used. The control device can grasp the characteristics of the connecting portion based on the identification symbol and select the shape of the upper part and the lower part. In addition, the upper and lower shapes of the corner panel can also be managed by using appropriate identification symbols.

In step S205, the control device 30 determines the fastening material, the connection, and the like used for the corner panel according to the information of "fastening-related" defined in principle. Specifically, the control device 30 takes into consideration the "conclusion-related" information applied to the product based on the building information (product name, etc.) acquired in step S102, and is used for the corner panel according to the information. Determine the fastening material, etc.

Note that FIG. 7 shows an example of “conclusion-related” information. As shown in FIG. 7, as "fastening-related" information, applications, specifications (part number of fastening material, etc.), parts used (names of members fixed to each other), pitch, and the like are defined for each product.

In step S206, the control device 30 fuses the items determined in steps S201 to S205 to determine the shape of the corner panel. Hereinafter, the processing will be specifically described.

8 and 9 show an example of a corner panel (hereinafter referred to as a corner panel 1). The corner panel 1 is formed in a long shape that is long in the vertical direction. As shown in a cross section in FIG. 9, the corner panel 1 is formed by combining a plurality of members so as to form a layer. The illustrated corner panel 1 is formed by combining the frame 2, the glass wool board 3, the caucal plate 4, the base iron plate 5, and the face material 6 in this order from the inside to the outside.

Note that FIGS. 8 and 9 show a standard-sized (standard) corner panel 1 before the shape is determined by the design system 100. The standard length (standard size) is a shape before the shape is determined according to the building, and is a shape that serves as a reference for design.

The control device 30 is a standard-sized corner panel 1 (more specifically, a corner panel) based on the items determined in steps S201 to S205 (“upper / lower shape”, “height”, etc. of the corner panel). The shapes of the upper part and the lower part of the face material 6 and the like constituting 1) are replaced.

For example, FIG. 10 shows a state in which a face material 6a corresponding to a building is determined from a standard size face material 6 (standard size material). As shown in FIG. 10, the control device 30 determines the upper and lower parts of the standard-sized face material 6 based on the “upper / lower shape” of the corner panel 1 (face material 6) determined in step S204. Cut to the size and shape of. Further, the "upper / lower shape" determined in step S204 is arranged on the cut face material 6. That is, the control device 30 replaces the shapes of the upper and lower ends of the face material 6 with the determined shapes. Thereby, the face material 6a can be determined according to the building. Further, in the face material 6a, holes for fastening and the like are set according to the information of "fastening-related" and the pitch and dimensions defined by the "upper / lower shape".

Similarly, the control device 30 replaces the shapes of the upper and lower ends of the other members (frame 2, glass wool board 3, caical plate 4, and base iron plate 5) constituting the corner panel 1 with "upper / lower shapes". .. By combining the members thus obtained, the shape of the corner panel 1a corresponding to the building as shown in FIG. 11 is determined. The corner panels 1, the frame 2, the glass wool board 3, the caucal plate 4, the base iron plate 5, and the face material 6 whose shapes are determined according to the building are designated by the corner panels 1a, the frame 2a, the glass wool board 3a, and the caical, respectively. It is shown by changing to a plate 4a, a base iron plate 5a, and a face material 6a.

In step S207 shown in FIG. 6, the control device 30 creates three-dimensional data of the corner panel 1a from the shape of the corner panel 1a determined in step S206. Specifically, the control device 30 plots the position information regarding the shape of the corner panel 1a acquired in step S206 on the three-dimensional coordinates, and creates the three-dimensional data of the corner panel 1a. By creating the 3D data of the corner panel 1a in this way, it is possible to display (view) the 3D image of the corner panel 1a using appropriate software, and the members (corner panel) according to the building. The shape of 1a) can be easily grasped.

In this way, the process (determining the configuration of the corner panel) in step S104 of FIG. 2 is completed.

In step S105 of FIG. 2, the control device 30 applies the data related to the dimensions to the data related to the shape of the corner panel 1a determined in step S104 (specifically, the three-dimensional data of the corner panel 1a created in step S207). Associate and save. Information on the dimensions of the corner panel 1a can be grasped from the shape of the corner panel 1a determined in step S206.

Further, in the present embodiment, in step S105, not only the individual dimensions of the members (face members 6a and the like) constituting the corner panel 1a but also the dimensions indicating the relative positional relationship of the members are stored. FIG. 12 shows an example in which the individual dimensions (solid line) of the frame 2a, the glass wool board 3a, and the caucal plate 4a constituting the corner panel 1a and the dimensions (two-dot chain line) indicating the relative positional relationship of each member are displayed. Is shown. By preserving the positional relationship between the constituent members in this way, it is possible to assemble while referring to the dimensions when assembling each constituent member in a factory.

In step S106 of FIG. 2, the control device 30 associates the two-dimensional data with the data (three-dimensional data) relating to the shape of the corner panel 1a determined in step S104 and stores the data. Specifically, the control device 30 selects a location that is preferable to be grasped by two-dimensional data, such as a location that requires detailed cross-sectional dimensions, etc., and two-dimensional data (cross-sectional view, etc.) for the relevant portion of the three-dimensional data. , Two-dimensional drawing data) is linked. This makes it easier to check the detailed dimensions and improves convenience. It is possible to set (specify) in advance which part of the two-dimensional data is to be linked and saved, and the control device 30 automatically selects it in consideration of the arrangement of members and the like. It is also possible.

In step S107, the control device 30 associates the data (three-dimensional data) related to the shape of the corner panel 1a determined in step S104 with the information (manufacturing procedure, procedure, unit price, etc.) related to the production of the corner panel 1a. save.

As information (manufacturing information) regarding the manufacture of the corner panel, for example, as shown in FIG. 13, specifications regarding fixing of screws on the surface of the face material 6a (face material surface screw fixing specifications) and heat insulating material filled in the corner panel 1a. Dimensions and arrangement method (filled heat insulating material specifications), temporary fixing procedure for back surface fixing surface material (temporary fixing procedure for back surface fixing surface material), application procedure for adhesive applied to each part (adhesive application procedure), sealer There are application procedure (sealer application procedure), airtight material installation procedure to ensure airtightness (airtight material installation procedure), aluminum vapor deposition tape, etc. application method (aluminum film deposition tape / sheet application procedure).

The control device 30 selects, for example, manufacturing information according to the upper and lower shapes of the corner panel 1a determined in step S205, and associates the manufacturing information with the three-dimensional data of the corner panel 1a.

In this way, by associating the data related to the structure (shape, etc.) of the corner panel 1a with information not only about the structure but also about manufacturing, the convenience when assembling the corner panel 1a can be improved. In particular, grasp the mounting method of a member (tape, etc.) that does not have a thickness (relatively thin) that cannot be expressed in the drawing, the manufacturing method that cannot be expressed in the drawing, etc. from the information linked to the data of the corner panel 1a. Therefore, convenience can be improved. In addition, this makes it possible to ensure stable quality, improve production work efficiency, prevent erroneous production, and the like.

Further, as information on manufacturing, it is also possible to link the manufacturing unit price (cost) of each component or the entire corner panel 1a or the manufacturing unit price of each member.

In addition, various information (manufacturing procedure, manufacturing unit price, etc.) associated with the data of the corner panel 1a in step S107 is input (stored) in advance to the control device 30 via the input device 10 or the like. However, it is also possible for the control device 30 to estimate the manufacturing procedure (machining method, etc.) by taking into consideration the shape of the corner panel 1a, or to calculate the manufacturing unit price from the estimated machining method or the like. The control device 30 can select necessary information from various kinds of information and associate it with the data of the corner panel 1a.

As described above, the corner panel 1a can be designed by using the design system 100. In particular, the design system 100 of the present embodiment takes into consideration the members and the like connected to the corner panel 1a from the information on the appearance of the building (general map and three-dimensional data) even if there is no detailed information on the building. The shape of 1a can be determined. This makes it possible to design building parts even in the early stages of design (without detailed information).

Further, the designed corner panel 1a can be displayed on the display device 20 or the like as three-dimensional drawing data by using appropriate software, and the image can be confirmed. At this time, various information (dimensions, two-dimensional data, manufacturing procedure, etc.) associated with the corner panel 1a can also be confirmed. For example, the associated information can be displayed by clicking the corresponding part of the three-dimensional drawing data. As a result, various types of information can be aggregated into one data (three-dimensional data), and the convenience of drawing data can be improved.

In particular, in the present embodiment, it is assumed that three-dimensional data linked with various information is provided to an outsourced manufacturer of each component member or an assembly factory. Since information can be aggregated and exchanged in three-dimensional data in this way, convenience at the time of ordering and assembling constituent members can be improved. Further, in the present embodiment, not only the information on the shape of the constituent member but also the information on the production is collected, so that the convenience can be further improved. It is also possible to order the components by level (by floor) from the outsourced manufacturer.

As described above, the design system 100 according to the present embodiment is
An acquisition unit (control device 30, step S101) for acquiring information on a general map of a building, and
A design unit (control device 30, step S104) for designing an outer skin part (corner panel 1a) of the building based on the drawing information described in the general map acquired by the acquisition unit.
Is provided.
With such a configuration, the members constituting the building can be efficiently designed. That is, since the exodermis parts can be designed based on the information acquired by the acquisition unit, the designer does not have to select the members themselves, and the design can be performed efficiently.

In addition, the acquisition unit
Obtain basic information about the building (step S102),
The design department
The exodermis component is designed based on the drawing information and the basic information (step S104).
With such a configuration, the members constituting the building can be designed more appropriately. That is, by considering the basic information in addition to the drawing information, a more appropriate design becomes possible.

In addition, the design unit (control device 30)
By substituting a part of the reference shape (standard length) of the exodermis part with the partial shape (upper / lower shape) of the exodermis part determined based on the drawing information and / or the basic information. The outer skin component is designed (step S206).
With such a configuration, the members constituting the building can be efficiently designed. That is, by replacing only a part of the reference shape, it is possible to suppress an increase in the design burden, and by extension, the design can be performed efficiently. Further, the total number of models can be reduced by considering the upper part and the lower part as models instead of treating the entire outer skin part as one model (combination of upper part and lower part). For example, assuming that there are 41 types of upper shapes and 16 types of lower shapes, and the combination of upper and lower parts is regarded as one model, the total number of models is 41 × 16 = 656 types. On the other hand, if the upper part and the lower part are regarded as models, the total number of models is 41 + 16 = 57 types, and it can be seen that the number of models can be significantly reduced.

In addition, the general map is
It includes elevations and floor plans.
With such a configuration, the members constituting the building can be efficiently designed. That is, since the design can be performed using the elevation and the plan view that can be obtained at the initial stage of the design of the entire building, the design can be performed efficiently.

In addition, the exodermis parts
It is an outer wall panel of the building.
With such a configuration, the outer wall panel can be efficiently designed. In particular, among the exodermis parts, the outer wall panel often has a laminated structure, and the structure becomes more complicated. Therefore, by applying the design system 100 to the parts having such a complicated structure, the design efficiency can be further improved. Can be planned.

In addition, the exodermis parts
It is a corner panel 1a.
With this configuration, the corner panel 1a can be efficiently designed. In particular, among the outer wall panels, the corner panel 1a has a more complicated structure. Therefore, by applying the design system 100 to a component having such a complicated structure, the design efficiency can be further improved.

As described above, the design system 100 according to the present embodiment is
The first acquisition unit (control device 30, step S101, step S102) for acquiring building information about the building, and
Based on the information acquired by the first acquisition unit, the design unit (control device 30, step S104) that designs the parts of the building, and
A second acquisition unit (control device 30, step S107) for acquiring manufacturing information regarding the manufacturing of the parts, and
A linking section (control device 30, step S107) that links the manufacturing information to the information of the component designed by the design section, and
Is provided.
With such a configuration, convenience can be improved. That is, by associating the manufacturing information with the information of the designed parts (particularly the information regarding the shape and the like), various kinds of information can be aggregated and the convenience can be improved.

In addition, the design department
The part is designed by replacing a part of the reference shape of the part with the partial shape of the part determined based on the building information (step S206).
The tying part is
The manufacturing information corresponding to the partial shape is linked (step S107).
With this configuration, appropriate production information can be linked. That is, it is possible to link appropriate information according to the designed parts.

In addition, the said parts
It is the outer skin part of the building.
With such a configuration, the convenience of information on the exodermis parts can be improved. In particular, unlike the skeleton parts, the exodermis parts have a more complicated structure. Therefore, by applying the design system 100 to the parts having such a complicated structure, the convenience is further improved.

In addition, the exodermis parts
It is an outer wall panel of the building.
With such a configuration, the convenience of information on the outer wall panel can be improved. In particular, among the exodermis parts, the outer wall panel often has a laminated structure, and the structure becomes more complicated. Therefore, by applying the design system 100 to the parts having such a complicated structure, the convenience is further improved. ..

In addition, the exodermis parts
It is a corner panel 1a.
With such a configuration, the convenience of information on the corner panel 1a can be improved. In particular, among the outer wall panels, the corner panel 1a has a more complicated structure. Therefore, by applying the design system 100 to a component having such a complicated structure, the convenience is further improved.

The control device 30 according to this embodiment is an embodiment of an acquisition unit and a design unit.
The control device 30 according to the present embodiment is an embodiment of the first acquisition unit, the second acquisition unit, the design unit, and the tying unit.

Although the embodiments have been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the design system 100 has created three-dimensional data of the building and the designed parts (corner panel 1a) (step S103, step S207), but it is not always necessary to create the three-dimensional data. For example, it is possible to manage a building, a corner panel 1a, or the like with two-dimensional data.

Further, in the present embodiment, the design system 100 has been described as designing a corner panel as an outer skin part, but the present invention is not limited to this, and various outer skin parts of a building can be designed. .. For example, it can be applied to the design of members constituting eaves, roofs, eaves and the like.

Further, the building to be designed by the design system 100 is not limited, and various buildings such as a detached house, an apartment house, and a commercial facility can be targeted.

1 Design system 10 Input device 20 Display device 30 Control device

Claims (6)

The acquisition department that acquires information on general maps of buildings,
Based on the drawing information described in the general map acquired by the acquisition unit, the design unit that designs the outer skin parts of the building, and the design unit.
Design system equipped with. The acquisition unit
Get basic information about the building,
The design department
The exodermis part is designed based on the drawing information and the basic information.
The design system according to claim 1. The design department
The exodermis part is designed by replacing a part of the reference shape of the exodermis part with a partial shape of the exodermis part determined based on the drawing information and / or the basic information.
The design system according to claim 2. The general map is
Including elevations and floor plans,
The design system according to any one of claims 1 to 3. The exodermis parts
The outer wall panel of the building,
The design system according to any one of claims 1 to 4. The exodermis parts
It is a corner panel,
The design system according to claim 5.

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