KR102671894B1 - Web-based Architectural Design Decision Support Method and System using the same - Google Patents

Abstract

The present invention relates to a web-based architectural design decision support method and system.
To this end, the web-based architectural design decision support method of the present invention uses a modeling server that is connected to a communication network and responds by implementing an architectural design model according to the request of a web client, and a database containing object information of various objects. Each step is performed, including an architectural design model implementation step in which the modeling server loads preprocessed data to implement an architectural design model composed of a plurality of objects; An object change request step in which the modeling server receives a request to change object information from a web client; and an object change response step in which the modeling server receives object information to be changed from a database and responds by implementing it to be reflected in the architectural design model.
As a result, users representing building owners can receive a 3D visualized architectural design model in real time through a web browser even without installing a separate BIM program, so they can intuitively understand the design plan and immediately express their opinions about the design plan. This is possible.

Description

Web-based Architectural Design Decision Support Method and System using the same}

The present invention relates to a web-based architectural design decision support method and system, wherein a modeling server loads preprocessed data to implement an architectural design model composed of multiple objects, and when a web client requests a change in object information, This relates to a web-based architectural design decision support method and system that receives object information to be changed from a database and reflects it in the architectural design model in real time.

When constructing a building, multiple entities, such as the owner, the architect in charge of design, the partner company in charge of structure, equipment, and firefighting, the construction company constructing the building, and the inspector in charge of supervision of the building, use the language of drawings. communicate with each other through the medium.

However, due to the client's budget and time constraints, most design companies focus on document-based plan drawings that only exist in form, and as a result, partners sometimes fail to review them or misunderstand the shape of the building. occurred. In particular, construction companies had to spend a huge amount of time and money to construct the actual building, so they had difficulty calculating quantities accurately and quickly, which became the cause of construction cost lawsuits and defects. In addition, the architect, who communicated most closely with the designer, was the subject with the lowest understanding of architecture, so there were limitations in communicating through flat drawings.

For this reason, the use of BIM (Building Information Modeling), which combines 3D models and construction information, is actively recommended in the architectural design field. According to BIM, all errors that occur in the architectural planning, design, construction, and maintenance stages are actively recommended. and waste factors can be reviewed in advance using a single BIM data, thereby maximizing accuracy and productivity. In particular, in 2024, BIM orders will be mandatory for public housing over a certain size, and in 2030, design using BIM will be fully mandatory for public construction projects.

However, the active introduction of BIM in the architectural design field still faces many difficulties for practical and institutional reasons. It is difficult for design companies to secure BIM experts, the standards for design results are different for each client, the initial cost is too high compared to its utility, and due to the diversity of the software, it is only partially used by large design companies or construction companies.

Meanwhile, despite the fact that building owners generally have the lowest level of basic knowledge about architecture, they are bound to be the ones who have to make major decisions. In this respect, the BIM currently being produced has the advantage of being able to provide three-dimensional, intuitive visualization information of the overall shape of the building to the owner from the design stage.

However, building owners have no choice but to consider not only design factors but also economic factors such as cost and construction period, and in order to make such decisions, accurate and realistic quantity calculations must be made from the design stage of the building. However, even if BIM is used, a separate quantity calculation program must be used to calculate quantity, and it is not easy to extract data unless you are an expert, so there are various limitations in using it for immediate decision-making by building owners.

In particular, the format and quality of data in 2D or 3D design models for BIM modeling are different, making it difficult to create consistent BIM models. Most of the functions provided by current quantity calculation programs are based on the data of BIM data. As it relies entirely on shape information, the accuracy of quantity calculation is bound to deteriorate.

Above all, BIM contains a large amount of object information, so the files are heavy, making it difficult to simulate various design plans for free decision-making by architects. Even if various design plans are implemented with individual BIM data, the inconvenience of having to use this to calculate the quantity again using a separate quantity calculation program is inevitable.

In addition, building owners cannot directly implement the BIM model without visiting a design company with BIM software installed, otherwise, there is a limitation in that they have no choice but to experience the BIM model indirectly through separate outputs or printed materials.

Meanwhile, the conventional prior art that provides three-dimensional shape information of buildings based on the web is “In a web environment “BIM visualization system and method” has been proposed. However, the prior art document 1 proposes a plurality of preprocessing steps to lighten the BIM data so that the produced BIM model can be visualized in a web environment. However, in the web environment, the attribute information of the model itself is changed in real time or There is a limitation in that the visualization information of the model itself cannot be changed.

In addition, "3D modeling system distributed between a client device web browser and a server" in US Patent No. 10,868,890 (registered on December 15, 2020, hereinafter referred to as 'Prior Art Document 2') by Trimble Navigation, the company that produced SketchUp " has been proposed. Although the prior art document 2 provides a function to change the model based on shape information, it only relies entirely on shape information, and does not provide a function to immediately calculate the quantity using the object information of the objects constituting the model, or the changed shape information. The function to calculate the changed quantity according to the above is not proposed at all.

Republic of Korea Patent No. 2467152 (registered on November 10, 2022) U.S. Patent No. 10,868,890 (registered on December 15, 2020)

The web-based architectural design decision support method and system of the present invention was proposed to solve the problems of the prior art described above, and allows users such as building owners to be provided with a three-dimensional visualized architectural design model through a web browser. The design can be intuitively understood, immediate expression of opinion is possible, design changes can be simulated immediately through a web browser, and not only shape information but also property information can be changed during the simulation process, allowing immediate response to the changed design. The purpose is to provide a web-based architectural design decision support method and system that can provide quantity calculation results.

In addition, another purpose is to improve the limits of accuracy that occurs as most quantity calculation programs calculate quantities based solely on the shape information contained in BIM data.

The web-based architectural design decision support method (M) of the present invention for achieving the above-mentioned purpose includes a modeling server 20 that is connected to a communication network and responds by implementing an architectural design model according to the request of a web client; , each step is performed by a database (DB) containing object information of various objects, with object information separated into shape information and attribute information for each object constituting BIM data, and the separated shape information is in binary format. An architectural design model implementation step (S10) in which the modeling server 20 loads the pre-processed data and implements an architectural design model composed of a plurality of objects by using the converted pre-processed data; Including an object selection step (S21) of selecting an object from a web client and a command reception step (S23) of receiving a command to change object information, the modeling server 20 receives a request to change object information from a web client. Object change request step (S20); An object information calling step (S31) of calling a mapping image or shape information in addition to attribute information as object information to be changed to the database (DB), and mapping the called mapping image or shape information to a scale corresponding to the structural member to determine the selected object information. An object information change step (S32) of providing a web client to receive a three-dimensional visualized architectural design model reflecting the change command in real time through a web browser by reflecting it on the object, and converting the called object information into a unique identifier of the selected object. Including an object information storage step (S33) of matching based on (ID) and storing it to be finally reflected in the selected object, the modeling server 20 receives object information to be changed from the database (DB) and adds it to the architectural design model. An object change response step (S30) that implements and responds to be reflected; and a quantity calculation step (S40) in which the modeling server 20 calculates the quantity using shape information and attribute information as object information reflecting a command to change the selected object.

In addition, before the architectural design model implementation step (S10), the BIM data preprocessor 10 separates object information into shape information and attribute information for each object constituting the BIM data, and converts the separated shape information into binary format. It may include a data pre-processing step (SPT) of forming pre-processed data and storing the converted pre-processed data in the data storage unit 11.

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Additionally, in the object selection step (S21), when the cursor is hovered over an object or an object is selected, the target object can be highlighted in real time and output to a web client so that it can be visually recognized.

In addition, the object change request step (S20) further includes a product name list providing step (S22) of providing a changeable product name list using object information of the selected object, and the command receiving step (S23) includes a change command The product name to be changed is selected, and in the object information calling step (S31), object information according to the selected product name can be called into the database (DB).

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Additionally, when the selected object is a building member and includes a plurality of product names, the object information change step (S32) can automatically collectively change other product names associated with the product name to be changed as a change command.

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In addition, the attribute information includes specifications, basic units, and calculation formulas for each product name, and in the quantity calculation step (S40), the product name is calculated using the specifications, basic units, and calculation formula for each product name as shape information and attribute information of the selected object. Different quantities can be calculated.

Meanwhile, the web-based architectural design decision support system (S) of the present invention separates object information into shape information and attribute information for each object constituting BIM data, converts the separated shape information into binary format, and converts it into preprocessed data. A BIM data pre-processing unit 10 that forms and stores the pre-processed data in a data storage unit; A modeling server 20 that loads preprocessed data from the data storage unit to implement an architectural design model, is connected to a communication network, receives a request for object change from a web client, and responds by changing the object information of the object implemented in the architectural design model. ; and a database (DB) that stores object information of various objects and provides it to the modeling server 20.

According to the web-based architectural design decision support method and system of the present invention, the modeling server immediately responds by implementing an architectural design model reflecting the command according to the request of a web client connected through a communication network, so that the user can use a separate BIM program. Even without installation, you can receive a 3D visualized architectural design model in real time through a web browser.

Therefore, the user, represented by the building owner, can intuitively understand the design plan and can immediately express his or her opinion regarding the design plan.

In particular, when a change in object information is requested from a web client, the modeling server can receive object information to be changed from the database and immediately reflect it in the architectural design model, allowing immediate simulation of the design change plan through a web browser.

At this time, the BIM data preprocessor separates the object information into shape information and attribute information and converts the separated shape information into a binary format represented by the GLB file format, thereby providing a lightweight file that is easily implemented on the web.

Furthermore, during the simulation process, the attribute information matching the shape information for each object can be changed using a unique identifier, so there is an advantage in being able to receive immediate quantity calculation results for the changed design plan.

In addition, the quantity by product name can be calculated using the shape information of the selected object as well as the product name calculation formula, basic unit, and unit cost, which are attribute information as object information stored in the database, so there is an advantage in being able to quickly and accurately calculate the quantity. .

1 is a conceptual diagram illustrating a web-based architectural design decision support system according to an embodiment of the present invention.
Figure 2 is a block diagram illustrating in time series a web-based architectural design decision support method according to an embodiment of the present invention.
3 to 5 are user interfaces on which architectural design models are output according to various embodiments of the present invention.
6A to 6C are user interfaces showing an object change request step according to an embodiment of the present invention.
7A to 7C are user interfaces showing an object change request step according to another embodiment of the present invention.
Figure 8 is a user interface in which the command receiving step, object information calling step, and object information changing step are reflected in real time according to an embodiment of the present invention.
Figure 9 is a user interface showing a step of changing object information according to another embodiment of the present invention.
Figure 10 is a user interface showing the object information storage step according to an embodiment of the present invention.
11A and 11B are user interfaces showing an object selection step according to various embodiments of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail based on the matters shown in the drawings. However, if it is judged that a detailed description of the related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be provided. Omit it.

1 is a conceptual diagram overall illustrating a web-based architectural design decision support system (S) according to an embodiment of the present invention, wherein the decision support system (S) includes a modeling server 20 and a web connected to a communication network. It includes a client 30, a data pre-processing unit 10 for pre-processing the collected BIM data, and a database (DB) for providing object information of various objects to the modeling server 20.

First, the modeling server 20 is implemented to include a memory 21 and a processor 22, and the memory 21 is a modeling application for implementing the architectural design decision support method (M) of the present invention. It is stored, and the modeling application is executed and operated sequentially by the processor 22, and the modeling server 20 may include a web application server for providing various dynamic contents.

The memory 21 may be composed of a main memory implemented as a non-volatile or volatile memory that stores and reads instructions constituting a modeling application, and an auxiliary memory device that stores various data and provides them to the main memory. Additionally, the processor 22 is a concept encompassing a controller, microcontroller, microprocessor, and microcomputer, and may be implemented by hardware, firmware, software, or a combination thereof.

The web client 30 is implemented in the form of a terminal such as a personal computer, laptop, tablet, or mobile phone. The main users who access the modeling application of the present invention through the web client 30 are building owners who do not have a high level of knowledge about architecture, and the users are connected to the modeling server 20 through a communication module and a communication network regardless of their location and use a web browser. Through the architectural design model output through the system, you can easily understand the design plan and freely express your opinion about the design plan.

Meanwhile, the database (DB) may be implemented in the form of an auxiliary storage device in the modeling server 20, but may also be implemented in the form of a separate server. The database (DB) stores object information of various objects and provides it to the modeling server 20, so that the modeling server 20 implements an architectural design model or calculates the quantity.

In addition, the BIM data pre-processing unit 10 lightweights BIM data so that the architectural design model can be quickly implemented on the web and the changed design plan is immediately revealed. The BIM data preprocessing unit 10 separates object information into shape information and attribute information for each object for the collected BIM data, converts the separated shape information into a binary format such as a GLB file format, and converts the converted preprocessed data into shape information and attribute information. It is stored in the data storage unit 11.

The object information refers to information possessed by each object having a unique identifier (ID). In the present invention, object information is defined by dividing it into shape information and attribute information. In other words, information about the shape that is visually implemented by the architectural design model is shape information, and all information that is not visualized other than shape information is attribute information. Attribute information includes member types such as structural members or building members, location information such as floors, arcs, and real names, and detailed types of member types, such as beams, columns, walls, slabs, foundations, stairs, and architecture in the case of structural members. In the case of members, floors, ceilings, walls, etc. may be included. In addition, as shown in Figures 11a and 11b, the object's hollow species, structural part, product name, standard, basic unit, quantity, calculation formula, unit cost, etc. may include.

The BIM data pre-processing unit 10 may be implemented in the form of a separate server, or may be implemented in the form of a module in the modeling server 20. Additionally, the data storage unit 11 may be stored in various non-volatile memory types.

Meanwhile, Figure 2 is a block diagram showing the web-based architectural design decision support method (M) in time series according to an embodiment of the present invention, which includes an architectural design model implementation step (S10) and an object change request step (S20). ), it may include an object change response step (S30) and a quantity calculation step (S40), and each step is connected to a communication network by the modeling server 20 that implements and responds to the architectural design model according to the request of the web client. It is carried out.

First, the architectural design model implementation step (S10) is a step in which the modeling server 20 loads preprocessed data and implements an architectural design model composed of a plurality of objects. Figure 3 shows a user interface output by the web browser of the web client 30 according to an embodiment of the present invention, and it can be seen that the overall shape of the architectural design model is implemented in a perspective projection method.

At this time, the user can freely change the viewpoint through the 3D orbit function, and as shown in Figure 4, only the desired floor or object in the architectural design model can be selectively output to check the outdoor shape information as well as the indoor shape information. there is.

Meanwhile, objects defined in the present invention include individual structural members and architectural members with instances. Structural members include columns, beams, walls, slabs, roofs, or foundations, and architectural members include openings (windows, doors, etc.). doors), insulation materials, finishing materials, base materials, etc. In other words, each object can be classified as a structural member or an architectural member depending on the member type.

Therefore, the user enters a command to select a member type in the user interface of the web browser to select the objects that make up the architectural design model, such as openings (windows, doors), insulation, finishing materials, base materials, etc., as shown in FIG. 4. The output can include the same building members, or, as shown in FIG. 5, only structural objects such as columns, beams, walls, slabs, roofs, or foundations can be output for the objects that make up the architectural design model.

Next, the object change request step (S20) is a step in which the modeling server 20 receives a request to change object information from a web client. The user can designate a specific area in the architectural design model displayed on the web browser of the web client 30 or select an object by clicking on it.

When a user selects an object, attribute information matching the selected shape information can be retrieved from the database (DB) based on the unique identifier (ID), matched, and output on the user interface. As shown in FIG. 10A, object information about an object may be output in text format, and depending on the embodiment, the shape information of the selected object in real time is highlighted on the architectural design model so that the selected object is visually recognized and displayed on the web client. It can be output to the user interface of (30).

At this time, the user may request changes to the output object information. Although not shown, not only attribute information can be modified as object information, but shape information can also be modified.

The object change response step (S30) that follows is a step in which the modeling server 20 receives object information to be changed from the database (DB) and responds by implementing it to be reflected in the architectural design model.

That is, when a change is made to increase the thickness of a wall as an object selected by the user, attribute information according to the thickness of the wall stored in the database is called, so that the attribute information for the object is changed, and the attribute information for the object is changed. Shape information can also be implemented to be reflected in the architectural design model. Accordingly, the database (DB) includes object information on objects of the currently implemented building design model as well as object information on a wide range of other changeable objects.

Accordingly, according to the web-based architectural design decision support method (M) of the present invention, the modeling server 20 immediately implements the architectural design model in which the change order is reflected at the request of the web client 30 connected through a communication network. Users can receive a 3D visualized architectural design model in real time through a web browser even without installing a separate BIM program. Therefore, the user, represented by the building owner, can intuitively understand the design plan and can immediately express his or her opinion regarding the design plan.

Meanwhile, before the architectural design model implementation step (S10), a data pre-processing step (SPT) is further included to form pre-processed data and store it in the data storage unit 11 to lighten heavy BIM data and enable immediate implementation on the web. can do.

The BIM data pre-processing unit 10 separates object information into shape information and attribute information for each object for the objects constituting each BIM data for the collected BIM data, and the separated shape information is represented by the GLB file format. Convert to binary format to reduce overall capacity.

Meanwhile, in the above-described object change response step (S30), the modeling server 20 calls the attribute information matching the shape information selected based on the unique identifier (ID) from the database (DB) and matches the attribute information. .

In the present invention, after the BIM data preprocessing unit 10 preprocesses the BIM data and stores it in the data storage unit 11, the modeling server 20 stores the preprocessed data, shape information converted to binary format, and a database ( Since a lightweight architectural design model can be implemented using property information called from DB, an architectural design model that immediately reflects change orders can be output on the web.

Meanwhile, below, based on the details shown in FIG. 2, the object change request step (S20) and the object change response step (S30) will be described in more detail. The object change request step (S20) and the object change response step (S30) can be carried out immediately to the extent that the user cannot recognize the time difference, assuming that the state of the communication network is smooth.

First, the object change request step (S20) may include an object selection step (S21), a product name list providing step (S22), and a command receiving step (S23).

The object selection step (S21) is a step in which an object is selected from the web client 30, and an object to be changed can be selected by designating a specific area or clicking on the architectural design model output to the web browser.

At this time, object information about the object can be output in text format, and when the cursor is hovered over the object or an object is selected, the shape information of the target object is highlighted in real time on the architectural design model so that the selected object is visually recognized. It may be processed and output to the user interface of the web client 30.

Figures 6a and 6b are user interfaces showing the object selection step (S21) according to one embodiment. The process of selecting either an exterior material or an interior material as the type of finishing material to change (Figure 6a), selecting a wall among the detailed types of objects to be changed (Figure 6b), and then selecting one of the various finishing materials that make up the wall. (Figure 6c). Meanwhile, as shown in FIG. 6A, the object selection step (S21) can be performed with the change type of the object set in advance as 'finishing material change mode'.

Additionally, FIGS. 7A and 7B are user interfaces showing an object selection step (S21) according to another embodiment. This shows the process of selecting the type of finishing material to be changed as an interior material (Figure 7a), selecting the floor among the detailed types of objects to be changed (Figure 7b), and then selecting at least one of the various rooms that make up the floor (Figure 7a). Figure 7c).

Next, in the step of providing the product name list (S22), the modeling server 20 may provide a changeable product name list using object information of the selected object. In one embodiment, as shown in FIG. 8, when 'long brick' is selected as the exterior material to be deleted, it is a user interface showing a state in which old bricks 1 to 4 of various textures are provided as a list of product names that can be changed.

The command receiving step (S23) is a step of receiving a command to change object information, and various methods for the user to input the change command through the user interface of a web browser can be implemented. For example, although not shown, if you want to change shape information, you can select an object and drag it with one side activated, or you can edit the text about the numerical value itself.

Meanwhile, Figure 8 also shows the process of selecting a product name to be changed from a list of changeable product names. As shown in Figure 8, even if the product name is not finally selected or saved, the process of temporarily selecting the product name by hovering the cursor on the icon of the product name to be changed is defined as being included in the command reception step (S23). .

Next, the object change response step (S30) may include an object information calling step (S31), an object information changing step (S32), and an object information storing step (S33).

The object information calling step (S31) is a step of calling object information to be changed into the database (DB). As shown in FIG. 8, when a product name is selected, object information according to the selected product name is called into the database (DB). Meanwhile, when the selected object is a building member, the object information calling step (S31) may be called to further include a mapping image or shape information as object information.

As shown in FIG. 8, the object information change step (S32) can be immediately output to a web client with the selected product name reflected in the architectural design model. However, even before executing 'Save to statement' shown in FIG. 10 and finally saving the changed object information, the modeling server 20 stores the shape information to be changed according to the product name selected from the database (DB) in the architectural design model. It can be implemented in advance on the computer.

At this time, the modeling server 20 implements the shape information to be immediately reflected in the architectural design model, but before executing 'Change', the attribute information called from the database (DB) and provided as text is reflected in the architectural design model. It may not be reflected. As a result, it is possible to perform quick calculations by allowing the user to immediately recognize the changing shape information while omitting the attribute information.

Meanwhile, when the selected object is a building member, the object information is called to further include a mapping image or shape information, so the object information change step (S32) maps the called mapping image or shape information to a scale corresponding to the structural member. It can be processed and output.

Additionally, in the object information changing step (S32), when the selected object is a building member, one product name may correspond to each object, but a plurality of product names may be included in one object. At this time, the modeling server 20 can automatically batch change other product names associated with the product name to be changed as a change command.

In one embodiment, as shown in FIG. 9, when the selected object is a building member, 'Gang Maru', which includes a plurality of product names, and the object to be changed is 'Vinyl-based tile', the user can only select 'Gang Maru' among the product names. Even if you change 'floor laying' to 'vinyl tile attaching', the other linked product name 'bangtong mortar application' can be automatically changed to 'mortar application' all at once. On the other hand, product names that do not need to be changed, such as 'inter-floor noise flooring', 'lightweight foam concrete', 'cement', and 'Remital', are automatically maintained without change.

In particular, as one product name is changed, not only the names of other linked product names are automatically changed, but attribute information such as thickness and standard may also be changed.

As shown in the user interface of Figure 9, it is a list of product names constituting the 'Gangmaru' object, including 'inter-floor noise flooring', 'lightweight foam concrete', 'bangtong mortar application', 'cement', 'Remital', and ' ‘River floor laying’ can be provided as a set, and in this case, the preset can be changed and defined by the user.

Next, the object information storage step (S33) is a step of storing the changed object information so that it is finally reflected in the selected object. As shown in FIG. 10, by executing 'Save to Statement' displayed on the user interface of a web browser, the changed object information, including attribute information, can be saved to be finally reflected in the architectural design model.

At this time, in the object information storage step (S33), even if the shape information is not changed, the shape information and the called attribute information can be matched and stored based on the unique identifier (ID) for the selected object. In addition, in the object information change step (S32) in advance, by executing 'Change' as shown in FIG. 8, the shape information and the called attribute information are matched based on the unique identifier (ID) and output on the user interface. You can.

Meanwhile, the quantity calculation step (S40) is a step in which the modeling server 20 calculates the quantity using shape information and attribute information as object information of the selected object.

In the quantity calculation step (S40), when the user selects an object from the web client 30 by designating a specific area in the architectural design model output to the web browser or clicking on the object to be changed, the object is selected as shown in FIG. 11a. As shown, the modeling server 20 may output non-visualized attribute information to the user interface. The attribute information may include hollow species, structural part, product name, standard, basic unit, quantity, calculation formula, unit cost, etc.

Specifically, in the quantity calculation step (S40), the modeling server 20 calculates the quantity by product name as the quantity using the shape information of the selected object and the standard, basic unit, and calculation formula for each product name as the attribute information. do. At this time, as the attribute information, different data such as specifications for each product name, basic unit, and calculation formula may be retrieved from the database (DB) depending on the object.

For example, as shown in FIG. 11B, when the member type of the object is a structural member, the quantity is a common category and includes ready-mixed concrete, formwork, and rebar for the object, and may additionally include other categories. At this time, the basic units and calculation formulas are called so that the quantity of ready-mixed concrete is calculated by volume, the formwork is calculated by the number according to the formwork standard, and the rebar is calculated by the length according to the standard. Furthermore, the unit cost can be additionally called to calculate the exact cost in terms of quantity.

In addition, building members are classified into interior and exterior, and are further classified into floors, walls, ceilings, and stairs, respectively. Building members have completely different product names, basic units, and calculation formulas for each object. For more precise quantity calculation, the quantity can be calculated by reflecting the basic supply unit of the product. For example, in the case of tiles, they are supplied in boxes rather than in the number of individual tiles, so the quantity can be calculated using the supply unit for each product. In order to calculate the accurate cost, the cost per supply unit is additionally calculated as the unit cost. You can calculate the quantity by calling .

Meanwhile, unit cost is defined as including the material cost for each item constituting the object and the labor cost or expenses required for construction.

Additionally, the modeling server 20 can select the level of quality difficulty through a user interface provided by a web browser. In one embodiment, when the object selected through the user interface is 'stone finish', the quality of the finish varies depending on the tolerance, and this may result in different labor costs due to manpower. Therefore, in the quantity calculation step (S40), the modeling server 20 may calculate the quantity by additionally reflecting the quality difficulty of the object selected by the user.

Meanwhile, the web-based architectural design decision support system (S) of the present invention includes a BIM data preprocessor 10 that preprocesses BIM data to make it lightweight, as shown in FIG. 1, and a modeling application is executed to produce preprocessed data. A modeling server 20 that loads and implements an architectural design model, a web client 30 that is connected to the modeling server 20 and a communication network to output an architectural design model, and stores object information of various objects to the modeling server ( 20) and is formed including a database (DB) provided.

Since the web-based architectural design decision support method (M) described above is implemented by the web-based architectural design decision support system (S) of the present invention, duplicate descriptions will be omitted below.

The BIM data preprocessing unit 10 separates object information into shape information and attribute information for each object constituting BIM data, converts the separated shape information into binary format to form preprocessed data, and stores the preprocessed data as data. Save it in part (11).

In addition, the modeling server 20 loads pre-processed data pre-stored in the data storage unit 11 to the processor 22 through the memory 21 to implement an architectural design model, and is connected to a communication network to provide a web client ( 30), it receives a request to change the object and responds by changing the object information of the object implemented in the architectural design model.

The web-based architectural design decision support method (M) and system (S) according to the present invention described above do not allow a person skilled in the art to change the technical idea or essential features of the present invention. Without doing so, you will be able to understand that it can be implemented in other specific forms.

Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later rather than the detailed description above, and the meaning and scope of the claims. All changes or modified forms derived from the scope and equivalent concept should be construed as being included in the scope of the present invention.

S:Architectural design decision support system
10: BIM data preprocessing unit 20: Modeling server
30:Web client DB:Database
M:How to support architectural design decisions
S10: Architectural design model implementation stage S20: Object change request stage
S30: Object change response step S40: Quantity calculation step

Claims (11)

A web-based architectural design doctor in which each step is performed by a modeling server 20 that is connected to a communication network and responds by implementing an architectural design model according to the request of a web client, and a database (DB) containing object information of various objects. In the decision support method (M),
Object information is separated into shape information and attribute information for each object constituting BIM data, and preprocessed data in which the separated shape information is converted to binary format is used, where the modeling server 20 loads the preprocessed data and generates a plurality of Architectural design model implementation step (S10) of implementing an architectural design model composed of objects;
Including an object selection step (S21) of selecting an object from a web client and a command reception step (S23) of receiving a command to change object information, the modeling server 20 receives a request to change object information from a web client. Object change request step (S20);
An object information calling step (S31) of calling a mapping image or shape information in addition to attribute information as object information to be changed to the database (DB), and mapping the called mapping image or shape information to a scale corresponding to the structural member to determine the selected object information. An object information change step (S32) of providing a web client to receive a three-dimensional visualized architectural design model reflecting the change command in real time through a web browser by reflecting it on the object, and converting the called object information into a unique identifier of the selected object. Including an object information storage step (S33) of matching based on (ID) and storing it to be finally reflected in the selected object, the modeling server 20 receives object information to be changed from the database (DB) and adds it to the architectural design model. An object change response step (S30) that implements and responds to be reflected; and
A quantity calculation step (S40) in which the modeling server 20 calculates the quantity using shape information and attribute information as object information reflecting a change command of the selected object;
A web-based architectural design decision support method comprising:
According to paragraph 1,
Before the architectural design model implementation step (S10),
The BIM data preprocessing unit 10 separates object information into shape information and attribute information for each object constituting BIM data, converts the separated shape information into binary format to form preprocessed data, and stores the converted preprocessed data as data. Data preprocessing step (SPT) for storing in unit 11;
A web-based architectural design decision support method comprising:
delete According to paragraph 1,
The object selection step (S21) is a web-based architectural design decision support method characterized in that when the cursor is hovered over an object or an object is selected, the target object is highlighted in real time and output to a web client so that it can be visually recognized.
According to paragraph 1,
The object change request step (S20) is,
It further includes a product name list providing step (S22) of providing a changeable product name list using object information of the selected object,
In the command reception step (S23), a product name to be changed is selected as a change command,
The object information calling step (S31) is a web-based architectural design decision support method characterized by calling object information according to the selected product name to a database (DB).
delete delete According to clause 5,
If the selected object is a building member and contains multiple product names,
In the object information change step (S32),
A web-based architectural design decision support method characterized by automatically collectively changing other product names associated with the product name to be changed as a change command.
delete According to paragraph 1,
The attribute information includes specifications for each product name, basic unit, and calculation formula,
The quantity calculation step (S40) is a web-based architectural design decision support method characterized in that the quantity by product name is calculated using specifications, basic units, and calculation formulas for each product name as shape information and attribute information of the selected object.
A BIM data pre-processing unit ( 10);
A modeling server 20 that loads preprocessed data from the data storage unit to implement an architectural design model, is connected to a communication network, receives a request for object change from a web client, and responds by changing the object information of the object implemented in the architectural design model. ; and
A database (DB) that stores object information of various objects and provides it to the modeling server 20;
A web-based architectural design decision support system characterized in that it performs the architectural design decision support method (M) of claim 1, including.