JP6749156B2 - Architectural design and construction planning method and architectural design and construction planning system - Google Patents

Description

The present invention relates to a building design and construction planning method and a building design and construction planning system.

Conventionally, from the data of the construction method of the building, the construction method data to be used for the construction of the construction plan object is selected, and the selected construction method data is referred to A technique is known in which attribute information is given to each member, and attribute information given to each member is aggregated to generate construction plan information (see, for example, Patent Document 1).

JP 2007-239223A

However, the design work of building shape data is often performed by a plurality of functions. Therefore, when design work is performed by multiple functions and there are multiple function models corresponding to each function, the requirements of the builder are expressed in a distributed manner in the function model corresponding to each function. There is a problem that it is not possible to efficiently create a design and construction plan that meets the requirements of the building owner.

In consideration of the above facts, the present invention provides a building design and construction planning method and a building design and construction planning system that can efficiently create a design and construction plan that meets the requirements of the building owner when a plurality of functional models exist. The purpose is to provide.

In order to achieve the above-mentioned object, the building design construction planning method of the present invention reflects the shape information regarding the shape of the building, which is determined from the information regarding the requirements of the building owner, and adds the attribute information of each element of the building. And a step of generating a base model which is a three-dimensional model of a building and a three-dimensional structure for building the building by referring to each information obtained from the generated base model for a plurality of functions. Generating a plurality of functional models as models and assigning attribute information of each element of the building to the base model, which is determined from information about requirements of the building owner.

According to the building design and construction planning method of the present invention, a base model is generated which reflects the shape information regarding the shape of the building, which is determined from the information regarding the requirements of the building owner, and which is provided with the attribute information of each element of the building. By designing multiple functional models by referring to each information obtained from the generated base model for multiple functionals, a design and construction plan that meets the requirements of the builder when multiple functional models exist Can be created efficiently.

The base model of the present invention may further include the attribute information given from the function and referred to for generating a function model for another function. Thereby, even if the attribute information included in the base model is updated by the function model for another function, the design and construction plan can be efficiently advanced.

Further, the building design and construction planning system of the present invention is a receiving means for receiving shape information regarding a shape of a building and attribute information of each element of the building, which is determined from information representing requirements of a building owner, and the receiving means. A base model, which is a three-dimensional model of a building, which reflects the shape information obtained by the above, and which generates a base model including the attribute information received by the receiving means. And a plurality of client computers for a plurality of functions, transmitting means for transmitting the attribute information input by the function to the server, obtaining the base model generated by the server, and obtaining the base model from the base model. Is a three-dimensional model for constructing the building based on the display means for displaying the respective information, the receiving means for receiving the design information input by the function, and the design information received by the receiving means. And a plurality of client computers each having a model generation unit for generating a functional model.

According to the present invention, a base model is created that reflects the shape information about the shape of the building, which is determined from the information about the requirements of the building owner, and that is provided with the attribute information of each element of the building. , By creating multiple functional models by referring to each information obtained from the generated base model, when there are multiple functional models, efficiently create a design and construction plan that meets the requirements of the builder. The effect that can be obtained is obtained.

It is a figure for explaining the outline of this embodiment. It is a figure which shows the example of a classification of the requirement of a builder. It is a figure for explaining the outline of this embodiment. It is an example of a base model. It is a block diagram showing a schematic structure of a building design construction planning system concerning this embodiment. It is a block diagram showing a schematic structure of a client computer according to the present embodiment. It is a block diagram which shows schematic structure of the server which concerns on this Embodiment. It is a figure for explaining a generation process of a base model. It is an example of an operation of the architectural design construction planning system according to the present embodiment. It is a figure for demonstrating the difference between a base model and the conventional model. It is a figure for explaining an example in case a base model and a BIM model according to each occupation are linked.

<Outline of Embodiment of the Present Invention>
In BIM (Building Information Modeling) used when designing and constructing a building, a three-dimensional model representing a building is generated on a computer. When creating a design and construction plan using BIM, each of the plurality of functions creates a BIM model according to its own function, and creates a plan by linking each BIM model.

FIG. 1 shows a conceptual diagram of a design and construction plan using BIM. FIG. 1 shows, as an example of each BIM model, a building design model, a structural design model, a facility design model, a cumulative model, a construction plan model, a construction model, a steel frame model, a facility construction model, and an FM (Facility Management) model. .. Hereinafter, a case where a design and construction plan is created by each of these BIM models will be described as an example.

Each BIM model shown in FIG. 1 is created by each function. For example, a building design model, which is an example of a BIM model, is created by the function of a person responsible for building design.

In addition, the BIM model includes three-dimensional shape information of the target building and attribute information of each element of the building. For example, an object name “door” is given to an object “door” which is an element included in a building, and information such as “dimension” and “material” is given as attribute information.

Here, when creating a design and construction plan using BIM, it is necessary to create a plan that meets the requirements of the building owner. FIG. 2 shows an example of classification of requirements of the building owner. As shown in FIG. 2, there are many diversified requirements of the building owner, from requirements relating to space to requirements relating to waterproofing.

The requirements of the builder are communicated to each function in written or verbal form. For example, when the requirements of the builder are indicated orally, each function interviews the builder, understands the requirements of the builder, and converts the requirements into shape information or attribute information of the BIM model. And reflect it in the BIM model that corresponds to your function.

For example, as shown in FIG. 1, the case where A, B, and C are shown as requirements of the building owner will be described as an example. Each function performs design work based on the requirements A to C, and creates a BIM model according to the function.

Here, a case where the requirement A is, for example, “I want to provide a room for the purpose of a on the b floor and have an area of approximately c [m ² ]” will be described.

Based on the requirement A, the function of architectural design performs a design work so as to provide a room for the purpose of a, which is c[m ² ] on the b floor, and generates an architectural design model. The shape information that meets the requirements of the building owner is reflected in the building design model by the design work of the building design function.

In addition, the function of architectural design gives attribute information such as a purpose “a”, a floor number “b floor”, and an area “c[m ² ]” to the room as an object. Here, the shape information reflected on the architectural design model based on the requirement A and the added attribute information are A1.

Next, the function of structural design performs design work on the structure based on the requirement A and A1 obtained by the architectural design model, and generates the structural design model. For example, when the use “a” in the requirement A is “library”, the function of structural design performs design work so that the load condition in the “library” is satisfied, and generates a structural design model. Further, the function of structural design gives attribute information such as “load condition XX” to the room as an object. Here, the shape information reflected on the structural design model based on the requirement A and the added attribute information are A2.

Next, the facility designing function performs a designing work on the facility based on the requirement A and A1 obtained by the architectural design model, and generates the facility design model. For example, the facility design function is based on the room area “c[m ² ]” of A1 obtained by the requirement A or the architectural design model and the height of the room obtained by the architectural design model, Calculate the volume of the room. Then, the designing function of the facility design performs the design work of the air conditioning facility so that the condition of the air conditioning facility according to the calculated room volume is satisfied, and generates the facility design model. Here, the attribute information given to the equipment design model based on the requirement A is A3.

In this way, the requirement A of the builder is expressed in different formats (A1 to A3) in the BIM model of each function.

Next, when the requirement B is, for example, “equipment of equipment of f[ton] can be placed in room of e.”, the function of structural design is that equipment of f[ton] can be placed based on requirement B. Design work is performed to satisfy the load condition, and a structural design model is generated. Further, the function of structural design gives attribute information such as “load condition XX” to the room as an object. Here, the shape information and the added attribute information reflected in the structural design model based on the requirement B are set as B2.

Next, when the requirement C is, for example, "the cleanliness of the room of g is h.", the function of equipment design is that the cleanliness of the room of g satisfies h based on the requirements C. Design work will be performed to generate an equipment design model. Further, the facility designing function gives attribute information such as "cleanliness XX" to the room as an object. Here, the shape information reflected on the equipment design model based on the requirement C and the added attribute information are C3.

It should be noted that in the process of generating the BIM model of each function, information referred to for generating the BIM model of another function is generated. For example, the shape of the window is not included in the requirements A to C and is not a requirement of the building owner, but it is generated in the process of generating the architectural design model, and is generated when the structural design model and the equipment design model are created. Referenced. Further, the range of the precast concrete structure, etc. is not a requirement of the building owner, but is generated in the process of generating the structural design model and is referred to when the other BIM model is generated. In this way, the information referred to in the generation of the BIM model in the post process is also generated in the BIM model of each function.

Therefore, as shown in FIG. 1 above, the attribute information referred to in order to generate the BIM model of another function is X1 to X3.

In this way, each function converts the information regarding the requirements of the builder into information according to its own BIM model, and creates a BIM model. In addition, each function creates its own BIM model based on the information generated by other functions.

However, as shown in FIG. 1, the information regarding the requirements of the builder is expressed in a distributed manner in a plurality of BIM models, and the information regarding the requirements of the builder is in a different format according to the BIM model of each function. Expressed. For example, in the above-mentioned example, the information regarding the requirements of the building owner is distributed to each BIM model in the format of A1 to A3, B2, C3.

Further, in the process of generating the BIM model, information used for generating a BIM model of another function which is a post process is generated. For example, in the above-mentioned example, the information X1 to X3 used for generating the BIM model of another function is generated.

Therefore, the information regarding the requirements of the builder is dispersed, and the information regarding the requirements of the builder and the information referred to in the generation of the BIM model in the subsequent process are mixed, and thus the conventional construction It was not possible to efficiently create a design and construction plan that met the main requirements.

Therefore, in the present embodiment, in order to reflect the shape information regarding the shape of the building and the attribute information of each element of the building, which is determined from the information regarding the requirements of the building owner, and to generate the BIM model for other functions. Generate a base model that contains the referenced information. The shape information and attribute information determined from the information about the requirements of the builder and the information referred to for generating the BIM model for other functions are distinguished and reflected in the base model.

The base model according to the present embodiment is constructed as a BIM model based on the requirements and required performances of the building owner, and not only serves as the basis of the contract but also the core of the BIM model for each function.

FIG. 3 shows an explanatory diagram for explaining the base model according to the embodiment of the present invention. As shown in FIG. 3, in the present embodiment, information regarding requirements of the building owner (for example, A1 to A3, B2 and C3 described above) is reflected, and is referred to for generating a BIM model for each function. A base model including information (for example, X1, X2, X3 described above) is generated. In FIG. 3 described above, the conventional information flow is indicated by a dotted arrow, and the information flow in the present embodiment is indicated by a solid arrow.

In the above FIG. 3, each function creates its own BIM model in accordance with the “input”, and “output” is obtained from the created BIM model. Further, "what I want to do" represents what I want to achieve in the BIM model according to each function.

As shown in FIG. 3 above, conventionally, it was necessary to refer to a plurality of BIM models generated in the previous process to generate a BIM model according to one's own function, but in the present embodiment, each function is , Refers to the information obtained from the base model and creates its own BIM model. Accordingly, each function can efficiently create a BIM model that reflects the requirements of the building owner without referring to the plurality of BIM models generated in the previous process.

FIG. 4 shows an example of the base model. In the base model of Fig. 4, the site, zero cube, main line, floor height, area of each room, ceiling height (zone), span, basic column division, outer wall and building perimeter line are information regarding the requirements of the builder. Is reflected as. In addition, as other attributes relating to the performance of the building, a dedicated classification, a waterproof range, a load condition, a cleanliness degree, etc. are given as information regarding the requirements of the building owner.

In addition, the special classification, the waterproof range, the load condition, the cleanliness, etc., which represent the attributes relating to the performance of the building, are set according to the characteristics of the building owner or the project. In addition, attributes relating to the performance of the building are basically input to the zone.

Hereinafter, embodiments of the present invention will be described in detail. First, the configuration of a building design and construction planning system 10 to which the present invention is applied will be described with reference to FIG.

<System configuration of architectural design and construction planning system>
As shown in FIG. 5, the building design and construction planning system 10 includes a plurality of client computers 12 and a server 14. The plurality of client computers 12 correspond to a plurality of functions, and each function uses its own client computer 12 to generate a BIM model.

The plurality of client computers 12 and the server 14 are connected via a network 16 such as the Internet or a LAN.

Client computer
FIG. 6 is a block diagram showing an example of the configuration of the client computer 12. The client computer 12 includes a CPU (Central Processing Unit), a ROM (Read Only Memory) that stores programs for implementing each processing routine, a RAM (Random Access Memory) that temporarily stores data, and a storage unit. It is configured to include a memory and a network interface. Functionally, the client computer 12 can be represented by a configuration including an operation unit 120, a computer 122, and a display unit 130, as shown in FIG. The operation unit 120 is an example of a reception unit.

Each function creates a BIM model according to its own function, reflects the shape information about the shape of the building that is determined from the information that represents the requirements of the building owner in the base model, and is determined from the information that represents the requirements of the building owner. The work of assigning attribute information of each element of the building to the base model and the work of generating a BIM model according to one's own function by referring to each information obtained from the base model.

First, a description will be given of the work in which each function creates a BIM model according to its function, reflects the shape information regarding the shape of the building in the base model, and adds the attribute information of each element of the building to the base model. ..

The operation unit 120 receives design information input by a user who is a function. The operation unit 120 is, for example, a keyboard or a mouse. Specifically, each function understands the information indicating the requirements of the builder, and generates design information so as to satisfy the information indicating the requirements of the builder. Then, for the function, the operation unit 120 inputs the design information generated based on the information indicating the requirements of the building owner.

The computer 122 functionally includes a model generation unit 124, a model storage unit 126, and a transmission/reception unit 128, as shown in FIG. The transmission/reception unit 128 is an example of a transmission unit.

The model generation unit 124 generates a BIM model based on the design information received by the operation unit 120. The BIM model is an example of a functional model that is a three-dimensional model for building a building.

In the design information, the information indicating the requirements of the building owner is reflected as the shape information regarding the shape of the building and the attribute information of each element of the building. The function operates the model generation unit 124 in accordance with the operation by the operation unit 120, reflects the shape information regarding the shape of the building in the BIM model, adds the attribute information of each element of the building to the BIM model, and BIM Create a model.

The model storage unit 126 stores the BIM model generated by the model generation unit 124 according to the operation of the function.

The transmission/reception unit 128 transmits/receives information to/from the server 14. Specifically, the transmission/reception unit 128 transmits, through the network 16, the shape information regarding the shape of the building and the attribute information of each element of the building, which are input by the function according to the operation input by the operation unit 120. Transmitted to the server 14.

For example, each function operates the operation unit 120 in the process of creating the BIM model, and transmits the shape information regarding the shape of the building determined from the information indicating the requirements of the building owner to the server 14 by the transmission/reception unit 128, It is reflected in the base model generated in the server 14. In the process of creating the BIM model, the function operates the operation unit 120 to transmit attribute information of each element of the building, which is determined from information indicating requirements of the building owner, to the server 14 by the transmission/reception unit 128, It is given to the base model generated in the server 14. The base model is a three-dimensional model of a building that reflects the shape information about the shape of the building, which is determined from the information about the requirements of the building owner, and has the attribute information of each element of the building.

Similarly, each function operates the operation unit 120 to transmit attribute information as an example of information referred to in order to generate a BIM model for another function to the server 14 by the transmission/reception unit 128. Assign to the generated base model.

Next, a description will be given of work in which each function refers to each information obtained from the base model and generates a BIM model according to its own function.

Each function operates the operation unit 120, and the transmission/reception unit 128 receives the information of the base model stored in the base model storage unit 146 of the server 14 described later.

The display unit 150 acquires the base model received by the transmission/reception unit 128 and displays information obtained from the base model for the job. The display unit 150 is realized by, for example, a display or the like.

Then, each function refers to each information obtained from the base model displayed on the display unit 150, operates the operation unit 120, and creates a BIM model according to its own function. The base model is given attribute information that reflects the shape information determined from the information about the requirements of the building owner. Therefore, each function can create a BIM model that meets the requirements of the builder.

In addition, the base model is provided with attribute information that is referred to in order to generate a BIM model for another function. Therefore, each function can create a BIM model by referring to the attribute information required to generate its own BIM model.

[server]
The server 14 is configured by a server including a CPU, a ROM that stores programs for implementing each processing routine, a RAM that temporarily stores data, a memory as a storage unit, a network interface, and the like. The server 14 can be functionally represented by a configuration including a computer 140, an operation unit 148, and a display unit 150, as shown in FIG. 7.

As shown in FIG. 7, the computer 140 functionally includes a transmission/reception unit 142, a base model generation unit 144, and a base model storage unit 146.

The transmission/reception unit 142 transmits/receives information to/from the client computer 12. Specifically, the transmitting/receiving unit 142 receives, via the network 16, the shape information regarding the shape of the building and the attribute information of each element of the building transmitted from the client computer 12 by the operation of each function, and It is output to the model generation unit 144.

Further, the transmitting/receiving unit 142 receives the attribute information, which is transmitted from the client computer 12 by the operation of each function and referred to for generating the BIM model for another function, and outputs the attribute information to the base model generating unit 144.

The base model generation unit 144 is determined from the information about the requirements of the builder based on the shape information about the shape of the building and the attribute information about each element of the building obtained by the transmitting/receiving unit 142 according to the operation of each function. , A base model, which is a three-dimensional model of a building, which reflects the shape information on the shape of the building and is provided with the attribute information of each element of the building.

Specifically, the base model generation unit 144, in accordance with the operation of each function received via the transmission/reception unit 142, the shape information regarding the shape of the building transmitted from the client computer 12 of each function and each of the buildings. A base model is generated based on the attribute information of the element.

The base model storage unit 146 stores the base model generated by the base model generation unit 144.

The operation unit 148 receives, for example, operation information input by the user of the server 14. The computer 140 executes each process according to the operation information received by the operation unit 148.

The display unit 150 displays the information output from the computer 140 to, for example, the user of the server 14 or the like. For example, the display unit 150 can display the base model according to the operation information received by the operation unit 148.

In this way, a base model that reflects the shape information about the shape of the building and the attribute information of each element of the building, which is determined from the information about the requirements of the building owner, is generated. Further, each information obtained from the generated base model is referred to for a plurality of occupations, a plurality of BIM models corresponding to the respective occupations are generated, and each building is determined based on the information about the requirements of the building owner. Element attribute information is added to the base model.

FIG. 8 shows a diagram for explaining the process of generating the base model. As shown in FIG. 8, when an order is received for a design and construction plan of a building in ph (phase) 0 and 1, each function in charge of the plan starts to create a BIM model.

In ph0 and 1, the function of architectural design starts to create a structural design model as a BIM model, the function of structural design starts to create a structural design model as a BIM model, and the function of equipment design functions as a BIM model to an equipment design model. Start creating.

Here, the building design function, the structural design function, and the facility design function create a BIM model in which the requirements are reflected based on the information about the requirements of the building owner.

For example, the function of architectural design reflects the shape information determined from the information about the requirements of the building owner in the architectural design model. Then, the function of architectural design reflects the shape information A _in reflected on the architectural design model on the base model.

In addition, each function adds attribute information A _in of each element of the building, which is determined from information regarding requirements of the building owner, to the base model _in the process of creating a BIM model according to its own function. In addition, each function adds attribute information B _in, which is referred to in order to generate a BIM model for another function, to the base model _in the process of creating a BIM model according to its own design function.

Each function creates a BIM model according to its own function by referring to the information (A _out , B _out ) obtained from the base model.

In ph2, of the design work for the architectural design function, the structural design function, and the equipment design function, the part relating to the requirements of the building owner is completed, and the plan is finalized. When the plan is finalized, the part of the base model related to the requirements of the building owner is finalized.

Then, in ph2 to ph6, each function gives the base model the attribute information B _in which is referred to in order to generate a BIM model for another function in the process of creating a BIM model corresponding to its own function. Each function creates a BIM model according to its own function by referring to the information (A _out , B _out ) obtained from the base model.

When the requirements of the builder are changed and the design is changed, the base model is also changed. When the base model is changed, each function is notified of the change of the base model.

The partial model shown in FIG. 8 is a partial model forming a part of the BIM model according to each function, and includes, for example, a volume model, a detail verification model, a reinforcing bar fitting model, a design model, a PC/ There are a C study model, a construction method comparison model, a simulation model, a digital mockup model, an excavated mountain retention study model, and the like.

<Operation of architectural design and construction planning system>
Next, as an operation of the building design and construction planning system 10 according to the present embodiment, an operation of the building design and construction planning system 10 when executing the generation processing of the base model will be described with reference to FIG. 9. In FIG. 9, a building design model, a structural design model, an equipment design model, a cumulative model, and a construction plan model will be described as examples of BIM models according to each function.

In addition, in the following description, among the information reflected from the BIM model of each function to the base model, the shape information regarding the shape of the building and the attribute of each element of the building, which is determined from the information indicating the requirements of the building owner Let A _in be the information, and B _in be the attribute information that is referred to in order to generate the BIM model for other functions generated in the subsequent process.

In addition, among the information that each function refers to from the base model when generating its own BIM model, the shape information regarding the shape of the building and the attribute information of each element of the building that is determined from the information that represents the requirements of the building owner _Is A _out, and attribute information that is referred to in order to generate a BIM model for another function in a later step is B _out .

First, in step S1, the architectural design function operates the operation unit 120 of the client computer 12 of his/her own to input design information. The design information includes shape information about the shape of the building and attribute information of each element of the building, which is determined from information about the requirements of the building owner, and attribute information referred to for generating a BIM model for other functions. It is included.

The function of architectural design generates design information based on the information about the requirements of the building owner and inputs it through the operation unit 120. Then, the model generation unit 124 of the client computer 12 generates an architectural design model based on the design information received by the operation unit 120. The model generation unit 124 stores, in the model storage unit 126, the architectural design model generated according to the operation of the occupation of the architectural design.

And, for example, the function of architectural design is the design information based on the information about the requirements of the building owner. , Floor height, span, basic pillar division, outer wall and building outer peripheral line, etc. are transmitted to the server 14 by the transmitting/receiving unit 128 as shape information regarding the shape of the building and attribute information A _in of each element of the building, It is reflected in the base model generated in the server 14.

Similarly, the function of the architectural designer operates the operation unit 120, and, for example, sets the performance attribute required for each room zone as attribute information B _in which is referred to in order to generate a BIM model for another function. It is transmitted to the server 14 by the transmission/reception unit 128 and is added to the base model generated in the server 14.

Next, in step S2, the function of structural design operates the operation unit 120 of the client computer 12 of itself to display the base model stored in the base model storage unit 146 of the server 14 via the network 16 on the display unit 150. To be displayed. Then, the function of structural design creates a structural design model by referring to information (A _out , B _out ) obtained from the base model displayed by the display unit 150.

For example, the function of structural design refers to the layout of the room, the finishing type, etc. as A _out among the information obtained from the base model. Further, for example, the function of structural design refers to the attribute information such as floor falling among the information obtained from the base model as B _out .

In step S3, the function of structural design operates the operation unit 120 of the client computer 12 of itself to input design information. Then, the function of structural design transmits A _in and B _in to the server 14 by the transmission/reception unit 128, adds A _in and B _in to the base model, and updates the base model.

For example, the function of structural design is the attribute information “load capacity 〇 〇 [ton/m ² ]” generated from “Able to put equipment of 〇 〇 [ton].” _It is transmitted to the server 14 by the transmission/reception unit 128 as in, and is added to the base model generated in the server 14. Further, professional structures design, the range of the precast concrete structure as B _in, and transmitted to the server 14 by transmitting and receiving unit 128 is applied to the base model generated in the server 14.

In step S4, the facility designing function operates the operation unit 120 of the client computer 12 of the facility itself to display the base model stored in the base model storage unit 146 of the server 14 on the display unit 150 via the network 16. .. Then, the facility design function creates a facility design model by referring to the information (A _out , B _out ) obtained from the base model displayed by the display unit 150.

For example, the facility designing function refers to the room layout, volume, etc. as A _out among the information obtained from the base model. Further, for example, the function of facility design refers to attribute information such as an important functional room as B _out among the information obtained from the base model.

In step S5, the facility designing function operates the operation unit 120 of the client computer 12 of his/her own to input design information. Then, the facility designing function transmits A _in and B _in to the server 14 by the transmitting/receiving unit 128, adds A _in and B _in to the base model, and updates the base model.

For example, the equipment designing function is based on the "Contractor agreement in the room condition table", which is information about the requirements of the building owner, based on the power capacity of each room, illuminance, temperature and humidity conditions, air conditioning zoning, water supply and drainage. The necessity of supplying hot water or the like is determined as A _in , transmitted to the server 14 by the transmission/reception unit 128, and added to the base model generated in the server 14.

In addition, the function of equipment design is difficult to express on the drawing, and as information that needs to be shared, the load of heavy equipment, the condition of each room and infrastructure coordinate information by consultation of various government offices, dangerous goods information, etc. are set as _Bin. It is transmitted to the server 14 by the transmission/reception unit 128 and is added to the base model generated in the server 14. Live Load Weight equipment of B _in is used when predominantly structural design professional to produce structural design model, each chamber conditions and infrastructure coordinate information by government agencies consultation, and dangerous goods information and the like are all professional Used in.

When the process of step S5 ends, at time C, all the requirements of the building owner are reflected in the base model as shape information regarding the shape of the building and attribute information of each element of the building. This establishes the part of the base model that is relevant to the requirements of the building owner.

Then, in step S6, the estimation function operates the operation unit 120 of the client computer 12 of itself to display the base model stored in the base model storage unit 146 of the server 14 on the display unit 150 via the network 16. Let Then, the estimation function creates an integrated model by referring to the information (A _out , B _out ) obtained from the base model displayed by the display unit 150.

For example, the estimation function refers to the layout of the room, the finishing type, the area, the volume, etc. as A _out among the information obtained from the base model.

In step S7, the function of the construction plan operates the operation unit 120 of the client computer 12 of his/her own to display the base model stored in the base model storage unit 146 of the server 14 on the display unit 150 via the network 16. .. Then, the function of the construction plan creates the construction plan model by referring to the information (A _out , B _out ) obtained from the base model displayed by the display unit 150.

For example, the function of the construction plan refers to the building layout information as A _out of the information obtained from the base model, and uses it as the basis for calculating the area such as the temporary business range other than the construction and the usage history of the parking lot.

In step S8, the function of the construction plan operates the operation unit 120 of the client computer 12 of his/her own to input design information. The professional construction plans, for example, to be able to time enter the information of the sequence as B _in, utilizing construction process, the efficient arrangement of heavy equipment in building construction model is a BIM model for other professional To do. Further, the function of the construction plan is, for example, a range as a means for taking in an optimum construction method (for example, precast concrete conversion, floor reinforcement range, temporary opening range, etc.) is determined as B _in , and the transmission/reception unit 128 transmits to the server 14. Send, give B _in to the base model and update the base model.

When the process of step S8 is completed, the information (A _out , B _out ) obtained from the base model in the process of creating the BIM model of another function, that is, the building construction model, the steel frame model, the equipment construction model, and the FM model. Referenced. Further, the attribute information B _in generated by each BIM model and referred to for generating the BIM model for other functions is added to the base model, and the base model is updated.

Then, when the generation of the FM model is completed after the building is completed, the generation/update process of the base model in the architectural design and construction planning system is also completed.

As described above in detail, in the present embodiment, the base model that reflects the shape information regarding the shape of the building, which is determined from the information regarding the requirements of the building owner, and that is provided with the attribute information of each element of the building is used. When a plurality of BIM models corresponding to the function exist by generating a plurality of BIM models corresponding to the function by referring to each information obtained from the generated base model for the plurality of functions, It is possible to efficiently create a design and construction plan that meets the requirements of the building owner.

In addition, in the present embodiment, by including attribute information, which is given from a function and referred to for generating a BIM model for another function, in the base model, it is included in the base model by the BIM model for another function. Even if the attribute information stored is updated, the design and construction plan can be efficiently advanced.

In addition, the information about the requirements of the builder and the information referred to in other BIM models in the post-process are stored in the base model, so that the design that meets the requirements of the builder can be performed without referring to a plurality of BIM models. A construction plan can be efficiently created.

Further, according to the present embodiment, the requirements of the building owner, which are conventionally expressed as a document, can be expressed as a BIM model. As a result, the requirements of the building owner can be grasped as a BIM model.

In addition, since information about the requirements of the builder is reflected in the base model, when a design change is made, it is necessary to clarify whether the design change is based on the requirements of the builder. You can For example, when the base model before the design change and the base model after the design change are overlaid and compared, it becomes clear whether the part of the requirements of the builder has been changed. This makes it possible to smoothly change the contract.

In addition, in the present embodiment, by generating a base model in which information about requirements of the builder is reflected, the BIM model of the builder is based on the base model and the BIM model corresponding to the profession. It is possible to confirm whether or not the requirements of are met.

FIG. 10 shows a diagram for explaining the difference between the conventional model and the base model.

As shown in FIG. 10, conventionally, the consistency of the BIM models has been confirmed by integrating or superimposing the BIM models according to each function. For example, conventionally, an interference check or the like has been performed between the architectural design model and the equipment design model to determine whether or not the piping equipment is accommodated in the ceiling.

On the other hand, since the requirements of the builder are reflected in the base model in the present embodiment, as shown in FIG. 10, it is necessary to check whether the BIM model corresponding to each function and the base model are consistent. This makes it possible to confirm whether the BIM model meets the requirements of the building owner. Therefore, the base model functions as a norm to be observed, and even if there are a plurality of BIM models according to job functions, it is possible to efficiently create a design and construction plan that meets the requirements of the building owner.

Although the present invention has been described above using the embodiment, the technical scope of the present invention is not limited to the scope described in the above embodiment. Various modifications and improvements can be added to the above-described embodiment without departing from the scope of the invention, and the modified and modified embodiments are also included in the technical scope of the present invention.

Further, the above-described embodiments do not limit the present invention, and not all combinations of the features described in the embodiments are essential to the means for solving the invention. The embodiments described above include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. Even if some constituent elements are deleted from all the constituent elements shown in the embodiments, a configuration in which some of the constituent elements are deleted can be extracted as an invention as long as the effect can be obtained.

For example, in the above-described embodiment, the case where the information about the requirements of the building owner and the information referred to when the other BIM model in the subsequent process is generated is reflected in the base model is described as an example. However, the present invention is not limited to this. However, for example, only the information regarding the requirements of the building owner may be reflected in the base model.

Further, although cases have been described with the above embodiment as examples where the present invention is realized by the building design and construction planning system 10 including the client computer 12 and the server 14, the present invention is not limited to this, and other embodiments are possible. The present invention may be realized by the form.

Further, in the above-described embodiment, as the BIM model corresponding to each function, an architectural design model, an equipment design model, a cumulative model, a construction plan model, a construction construction model, a steel frame model, an equipment construction model, and an FM model are described as examples. However, the present invention is not limited to this, and can also be applied to a BIM model according to another function.

Further, the processing flow of the building design and construction planning system shown in the above embodiment (see FIG. 9) is also an example, and unnecessary processing steps may be deleted or newly added without departing from the scope of the present invention. It is possible to add different processing steps or change the order of the processing steps.

Further, in the above-described embodiment, each function reflects the information about the requirements of the builder and the information referred to in the other BIM model in the post-process in the base model, and each function reflects the information obtained from the base model. The case where the BIM model of itself is updated with reference is described as an example, but the present invention is not limited thereto.

For example, as shown in FIG. 11, the information about the requirements of the building owner and the information referred to in other BIM models in the post-process are predetermined, and the base model and the BIM model corresponding to each function are linked. You may be allowed to.

In this case, as shown in FIG. 11, when the hatched portion of the BIM model according to the function is updated, the information regarding the requirements of the building owner and the information referred to in other BIM models in the post process are automatically updated. It can be reflected in the base model. Similarly, when the base model is updated, the BIM model corresponding to each function can be updated.

When the BIM model corresponding to each function is automatically updated when the base model is updated, the BIM model corresponding to each function is based on the updated information, for example, structural calculation, equipment The design work may be performed semi-automatically by performing calculation and quantity calculation. For example, the equipment design model calculates the air conditioning capacity based on the volume of each room among the information obtained from the base model, assists in determining the air conditioning system according to the calculation results, and semi-automatically designs piping equipment. You may go to Further, for example, the integration model may semi-automatically perform the estimation calculation based on the area of each room in the information obtained from the base model.

Further, in the above-described embodiment, each function has been described by taking as an example the case of referring to the information obtained from the base model and confirming whether or not the own BIM model satisfies the requirements of the builder. It is not limited to this. For example, the information contained in the base model and the information contained in the BIM model of each function are associated in advance, and it is possible to automatically confirm whether or not the BIM model of each function and the base model match. You may do it.

10 Building Design and Execution Planning System 12 Client Computer 14 Server 16 Network 120, 148 Operation Unit 122, 140 Computer 124 Model Generation Unit 126 Model Storage Unit 128, 142 Transmission/Reception Unit 130, 150 Display Unit 144 Base Model Generation Unit 146 Base Model Storage Unit

Claims (3)

A building design and construction planning method executed by a server and a plurality of client computers for each of a plurality of functions,
Each of the plurality of client computers is determined from information representing requirements of the building owner, transmits at least one of shape information regarding the shape of the building and attribute information of each element of the building to the server,
The server receives at least one of the shape information and the attribute information to generate the base model is a three-dimensional model of the shape information and at least one of building that reflects the attribute information,
Each of the plurality of client computers reflects each piece of information obtained from the base model generated by the server in a function model which is a three-dimensional model of function for building the building, thereby performing the function. Generate a model,
The server updates the base model each time it receives at least one of the shape information and the attribute information,
Each of the plurality of client computers updates the functional model by reflecting each information of the updated base model in the functional model every time the base model is updated by the server.
Architectural design and construction planning method. The server further adds information to the base model, the information being different from the information indicating the requirements of the builder and used when generating or updating the functional model, thereby the base model Generate or update
The building design and construction planning method according to claim 1. A building design and construction planning system comprising a server and a plurality of client computers for each of a plurality of functions,
Each of the plurality of client computers is determined from information representing requirements of the building owner, transmits at least one of shape information regarding the shape of the building and attribute information of each element of the building to the server,
The server receives at least one of the shape information and the attribute information to generate the base model is a three-dimensional model of the shape information and at least one of building that reflects the attribute information,
Each of the plurality of client computers reflects each piece of information obtained from the base model generated by the server in a function model which is a three-dimensional model of function for building the building, thereby performing the function. Generate a model,
The server updates the base model each time it receives at least one of the shape information and the attribute information,
Each of the plurality of client computers updates the functional model by reflecting each information of the updated base model in the functional model every time the base model is updated by the server.
Building design and construction planning system.