KR20010000959A - On-line architectual design system and method thereof - Google Patents

Abstract

PURPOSE: A system and method for architectural design is provided to allow a user to offer an integrated 3-D(Three-Dimensional) image information of a building and the cost and the period of construction via the internet. CONSTITUTION: A client(100) for a user is connected to the on-line architectural design system by internet. An administration server(200) comprises modules each having various information of building construction and provides the information to the client (200). A data server connected to the server(200) contains an architectural design DB (Data Base)(216), an internal structure DB(217), a building materials DB(218), a landscape architecture DB(220) and a membership information DB(222). An administration module(202) for external structure of a building stores and controls external architectural model classified by number of layers and pyong(approximately 3.3 square meters) into the architectural design DB(216). An administration module(204) for internal structure of a building stores and controls design information related to internal structure of a building in consideration of number of layers into internal structure DB (217). A forming module(210) for external structure of a building provides the external architectural model stored in the architectural design DB(216) in consideration of number of layers and pyong. A control module controls each modules. A user log in the server(200) using the client(100) and inputs number of layers and pyong of a building to be built and selects an external architectural model and living relative fixture layout provided by the server(200). The server(200) provides 3-D design images of internal and external architectural model and the cost of building to the user.

Description

On-line architectual design system and method

The present invention relates to an online building design system and a design method, and more particularly, a user directly inputs each item necessary for building a building on the Internet, and the input item is reflected in the architectural design as a 3D stereoscopic image in real time. The present invention relates to an online architecture design system and a design method for designing a building by a user.

In recent years, the domestic housing type has increased the desire to have their own home away from the apartment housing, alternatively the preference of single-family housing is further improved.

This increase in single-family preferences is manifested in mental dissatisfaction such as wealth accumulation due to increased income, method alternatives for property growth, and human alienation from uniform housing styles, economic margins due to improved income levels, and the pursuit of improved quality of life. It can be said that a desire is expressed.

However, the general public had limitations in drawing a building for their residence in their heads and drawing a building set with such imagination with real information or concretely. In addition, it is difficult to produce a building drawing that fully embraces the owner's intention, even if the design is commissioned by an expert, but it is more difficult for the owner to construct a building that reflects his intention without the help of the architect's drawing information.

In addition, not only the building but also the interior work inside the building is complex, there are various additional factors and changes, and in order to calculate the total cost required for the interior work, it is necessary to set up vague details to check the building presented by the contractor. The details and costs had to be calculated.

Therefore, the user who wants to build a building on the Internet directly designs the building, processes the interior of the building in real time, and confirms the processed result in 3D stereoscopic image to build the building together with the correct exterior and interior form of the building. It was required to provide an accurate estimate of the cost needed for the project.

In order to solve the above problems, an object of the present invention is to select the design of the building and the internal structure of the building according to the number of floors and the number of floors to be built on the Internet to implement the integrated information in a three-dimensional stereoscopic image To provide an online architectural design system and design method to complete the design of the building.

Another object of the present invention is to select the materials used in the construction of buildings on the Internet to check the three-dimensional stereoscopic image by online construction design system and design that can accurately check the production cost, labor costs, construction period used in the actual building construction To provide a method.

1 is a schematic diagram of an online building design system according to the present invention.

2 is a block diagram of an online building design system according to the present invention.

3 is a flowchart illustrating a process of designing a building online according to the present invention.

4 is a flowchart illustrating a process of designing the exterior of a building according to the present invention.

5 is a flowchart illustrating a process of designing an internal structure and internal equipment of a building according to the present invention.

6 is a flowchart illustrating a process of determining a finishing material of a building according to the present invention.

7 is a flowchart showing the process of determining the window material of a building according to the present invention.

8 is a flowchart illustrating a process of determining ancillary equipment of a building according to the present invention.

9 is an embodiment for inputting a building to be collectively selected according to the number of floors, floors, and construction costs according to the present invention.

10a to 10e show one embodiment of a building designed according to the invention.

The online architectural design method of the present invention comprises a building exterior determining step of selecting and determining an external model of a building from a design information DB, and an internal structure determining step of selecting and determining an internal structure of a building from an internal structural information DB. Finishing material decision step of selecting exterior and interior finishing materials from material information DB, and determining window material selection by selecting from material information DB to determine exterior and interior windows. And, and further comprising the equipment material determination step of determining by selecting from the material information DB of the external and internal auxiliary equipment.

The design system for the design method of the present invention includes a client that can be connected to the Internet, an operation server that is connected to the client and the Internet and provides various information related to the construction of the building, and a data server storing the construction related information. The server,

Design information related to the internal structure of the building including the room, kitchen, and bathroom according to the building appearance management module that stores and manages the external model of the building classified as floor, floor, shape, and structure in the design information DB. The internal structure management module that stores and manages the data in the internal structure information DB, and when the user inputs the number of floors and floors of the building to be built, the external model of the building is provided according to the number of floors and the floors inputted from the design information DB. The building appearance selection module to be selected, the internal structure forming module for designing the internal structure of the building by receiving the internal structure according to the number of floors from the internal structure information DB, the user and the control module for controlling the various modules Is done.

Preferably, the operation server is a building material management module that stores and manages information on building materials, including internal equipment materials, exterior materials, interior materials, finishing materials and window materials used in the building in the material information DB, and the user of the building It further includes an interior forming module for receiving a building material including an interior facility, an exterior material, an interior material, a window material and a finishing material from a material information DB to form an interior related to the building, an interior related to the exterior and the interior.

In addition, the operation server preferably comprises an adjustment management module for creating a site of the building as an image or a three-dimensional image to store in the landscape information DB, and a landscape forming module for selecting the landscape information stored in the material information DB to complete the building landscape It includes more.

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

1 is a schematic diagram of an online building design system according to the present invention, and FIG. 2 is a block diagram of an online building design system according to the present invention.

According to the present invention, it is connected to the operation server 200 through the communication interface 224 connected to the Internet 300 from the client 100 having a general purpose or dedicated browser.

The operation server 200 is a building appearance management module 202, an internal structure management module 204, a building material management module 206, landscape management module 209 for providing and managing various information on the operation server manager side, Consists of the member management module 208, the building exterior forming module 210 for use by the user for receiving the building, the internal structure forming module 212, the interior forming module 214 and the landscape forming module 215 It is linked with various databases (216, 217, 218, 220, 222; DB).

Database is

Design information DB (216) that stores information on the design of various buildings according to the number of floors, the number of floors, the form and the structure, and the internal structure of the location and size of the room, living room, kitchen, etc. Internal structure information DB (217) for storing information, material information DB (218) for storing information about various building materials used for building exterior materials, interior materials, and building construction, trees, lawns, etc. Landscaping information DB 220 for storing information related to the user and creating and storing the actual site as an image or a 3D image; And a member information DB 222 that stores information about the member.

The building appearance management module 202 of the operation server 200 separates the roof according to the model suitable for the first floor, the model applied on the second floor or more, and the type applied according to the number of floors of the building. Or store the building model in the design information DB (216).

The internal structure management module 204 provides a design on the internal structure of the location and size of the kitchen, bathroom, etc., together with the number, location, and size of the rooms located in the building according to the building number and floor. To store and manage.

The building material management module 206 stores and manages information on various building materials used in the interior facilities, exterior materials, interior materials, finishing materials, window materials, etc., which are disposed in the bathroom and kitchen of the building in the material information DB 218. . At this time, the building materials stored in the material information DB 218 appears to the user so as to compare and determine the provider, the unit price and the like when the user selects an item.

The member management module 208 stores and manages information about a member who is a user in the member information DB 222.

The landscaping management module 209 stores and manages the contents of the land of the building as an image or a three-dimensional image in the information DB 220. At this time, the landscaping information includes the user creating the site of the building where the building is built in an image or three-dimensional.

The building appearance forming module 210 receives the information on the exterior model of the building, the exterior forming material and the roof provided from the design information DB 216 when the user inputs the number of floors and the floor of the building to be constructed to obtain the optimal building appearance. Manage the selection of the overall building appearance to complete. In this case, a 3D image may be obtained in a batch of corresponding buildings by selecting the number of floors, the number of floors, the number of rooms, and the estimated construction cost, depending on the user. can do.

The internal structure forming module 212 selects the number, size, etc. of the interior of the building from the design information inside the building divided into a room, a kitchen, a bathroom, etc. provided by the user from the internal structure information DB 217 according to the number of floors. Manage the decision.

The interior forming module 214 manages the user to select a suitable one from the information on the exterior materials, interior materials, window materials and finishing materials provided from the material information DB 218.

The landscaping forming module 215 manages to select a suitable one from the information on the external landscaping of the building stored in the landscaping information DB 220.

3 is a flowchart illustrating a process of designing a building online according to the present invention.

As shown in the figure, the method for building new buildings online and the system using the same are largely divided into the necessary matters for building new buildings online in real time, and are divided into five stages. Determine the external model of the building (step S302), the second step determines the internal structure of the room, living room, bathroom, etc. of the interior of the building according to the number of floors (step S304), and the third step is to determine the exterior and interior of the building. The finishing materials used are determined (step S306), the fourth is the selection of windows and doors used on the outside and inside of the building (step S308), and the last is the auxiliary equipment installed inside and outside the building. Is selected (step S310). In this case, the material selected in each step is represented as a three-dimensional image at the selected position, and is displayed in a state coupled to the building. In addition, estimates, labor costs, and construction periods for the selected materials are presented alone or in aggregate, in real time.

Hereinafter, the options will be described in detail with reference to the step-by-step embodiments according to the process shown in FIG. 3.

4 is a flowchart illustrating a process of determining the appearance of a building according to the present invention.

The user who wants to build a new building is automatically designed and provided from the design information DB 216, the internal structure information DB 217, and the material information DB 218 for the building suitable for the number of floors, the number of floors, the number of rooms and the construction cost. It is selected whether or not to use it or whether the user decides on designing the number of floors, the number of floors, etc. step by step (step S402).

When the buildings are designed in a batch, items corresponding to the number of floors, the number of floors, the number of rooms, and the construction cost of the building to be built are input as shown in FIG. 9 (step S404). According to the inputted items, the model of the building that matches the corresponding items in the design information DB 216 and the material information DB 218 is presented (step S406), and the user determines the model suitable for himself from the presented model. (Step S408). At this time, the model of the selected building is presented in a three-dimensional shape, the user can change the interior equipment, finishing materials, window materials, auxiliary equipment, and the like.

If the user wants to decide the stage of the building to be constructed, input the number of floors to be constructed in 25 pyeong, 30 pyeong, 33 pyeong, 38 pyeong, 40 pyeong or more, and design the stored exterior of the building according to each area. If the external model of the building according to the square number is presented from the information DB 216 (step S410), the most suitable model is selected to determine the external model of the entire building (step S412). At this time, the external model of the selected building is presented in a three-dimensional shape, the building cost for each base area is calculated and presented together with the selection.

When the user builds a building of two or more floors, the user selects an exterior model according to the number of floors and inputs the number of floors of the building. According to the number of floors input, an external model to be used on two or more floors is presented from the design information DB 216 for each type (step S414), and an external shape is determined by selecting the presented model (step S416). In the case of two or more floors, the floor can be selected to have the same size as the floor of the first floor of the building, or various floors different from the floor of the first floor of the building can be selected (for example, the first floor is 30 pyeong, the second floor 25 It is possible to design a building with 20 pyeong on the 3rd floor). Thus, the rough appearance of the building is formed by selecting an exterior model of the building by floor and floor.

When the number of floors and the number of floors are determined, various materials (for example, reinforced concrete, brick, wood, steel, etc.) are presented from the material information DB 218 as materials for constituting the foundation and walls of the building (step S418). ), The user selects a desired material from the presented materials (step S420).

The roof shapes of the various buildings are presented from the design information DB 216 (step S422), and a suitable roof shape is determined from the presented shapes (step S424). That is, various types of roofs such as eave roof, double eave roof, European eave roof, slab, semi slab, etc. are presented with the price.

When the shape of the roof is determined, various kinds of shingles, tiles, etc. are presented from the material information DB 218 according to the shape of the roof (step S426), and the user selects a desired material from the presented materials (step S428).

In this process, when the overall external model of the building as shown in FIG. 10A is determined, the construction cost required for the construction of each building is comprehensively estimated.

5 is a flowchart illustrating a process of designing an internal structure and internal equipment of a building according to the present invention.

After determining the external model of the building, the user selects a suitable model from the presented model when various models of the location and size of the room and the living room inside the building are presented from the internal structure information DB 217 (step S502). Step S504). In this case, when the building has two or more floors, the number and size of rooms for each floor and the location and size of the living room are determined. In this case, the user is provided with a changeable matter in consideration of the optimal matters when the number of rooms increases or decreases or the use is changed.

Then, from the material information DB 218, various structural forms relating to the structure of the kitchen, the structure of the sink, the design of the kitchen, etc. in the interior of the building are presented (step S506), and the appropriate structural form is determined from the presented structural forms (step S508). ).

After determining the kitchen, information about the position, structure and size of the bathroom in the building is presented from the internal structure information DB 217, and information about the shape, material, and design of the bathtub is presented from the material information DB 218. (Step S510), from the presented information, the position of a suitable bathroom and the material added to the bathroom are selected (step S512).

The selected rooms, kitchens, bathtubs, etc. are represented in three dimensions as shown in FIG. 10B or 10E, and are combined three-dimensionally with the internal shape of the building determined by the process of FIG. 4. The costs for kitchens, bathrooms and other materials accommodated in kitchens, bathrooms, etc. are automatically calculated and presented.

6 is a flowchart illustrating a process of determining a finishing material of a building according to the present invention.

The user selects the building's finishing materials after determining the building's exterior model, internal structure and equipment. The finishing materials of the building are largely divided into exterior walls, interior walls, floor decorations and stairs.

In the case of the exterior wall finishing material, various materials such as stucco, natural stone, drybit, vinyl siding, etc., which determine the final image of the exterior wall, are presented from the material information DB 218 by type (step S602), and among the materials presented, the material desired by the user. Is selected (step S604).

In the case of the interior wall finishing material, various materials such as wallpaper, water-based paint, veneer, etc., which determine the image of the interior of the building, are presented by material type from the material information DB 218 (step S606), and the user selects a desired material from the materials presented (step S606). S608).

In the case of the floor decoration agent, various materials such as wood, floorboard, and synthetic resin for determining the floor in the building are presented from the material information DB 218 by type (step S610), and the user selects a desired material from the presented materials ( Step S612).

In the case of a staircase, a location of a part requiring a staircase such as a building or an attic of two or more floors is selected. (Step S616).

The finishing material of each part selected through the process of determining the finishing material is implemented by inserting a three-dimensional image into each of the buildings selected in the above-mentioned steps, and the materials, labor and construction costs required according to the selected material are calculated and presented together.

7 is a flowchart showing the process of determining the window material of a building according to the present invention.

After determining the shape and finish of the exterior and interior of the building, the windows and materials of the exterior and interior of the building are selected.

First, models of front doors and visits of various materials and colors are presented from the material information DB 218 (step S702), and a suitable front door is selected according to the presented information (step S704). At this time, in the case of installing the method system on the front door, the method system may be separately selected.

In addition, a model of the fresh door used for each visit is presented from the material information DB 218 (step S706), and is installed in each door according to the user's choice (step S708).

In addition, a model of the window, which is one of the window materials, is presented from the material information DB 218 (step S710), and is installed in each window according to the user's choice (step S712).

Each selected window material is inserted into a building selected in the above-described steps as a three-dimensional image, and the materials, labor and construction costs required according to the selected material are calculated and presented together.

8 is a flowchart illustrating a process of determining ancillary equipment of a building according to the present invention.

Once the appearance, internal structure, finishing materials and window materials of the building are selected, the final equipment necessary for the building is determined. Auxiliary equipment includes lighting equipment, electrical equipment, mechanical equipment, method system, etc. and may or may not be installed according to the user.

First, in the case of a lighting fixture, after selecting a location of a place where lighting is installed, such as a room, a living room, and a kitchen, and the required number of lights, a lighting fixture for each type is presented from the material information DB 218 (step S802). The material desired by the user is determined (step S804). In addition, it is possible to add accessories that are added to the luminaire according to the user's selection.

In addition, after selecting the location of various electrical equipment such as an outlet and a switch, if a lighting device by type is presented from the material information DB 218 (step S806), a material desired by the user is determined from the presented lighting devices (step S808).

Various kinds of method systems such as security grate, security system, etc. are presented from the material information DB 218 (step S810), and the user determines a suitable method system (step S812).

In addition, a cooling / heating system such as a gas boiler, an electric boiler, an oil boiler or city gas is presented from the material information DB 218 (step S814), and determined according to the user's selection (step S816).

In addition, the purification environment system used in the building is presented from the material information DB 218 (step S818), and the purification environment system is determined according to the user's selection (step S820).

Further, landscaping of buildings such as trees, artificial turf, ponds, and watermills is presented from the landscape information DB 220 (step S822), and the landscape is determined according to the user's selection (step S824). In this case, the landscaping may be used by synthesizing the land status photographs provided by the user together with the shape of the building to create an image or a 3D image of the environment in which the actual building is constructed.

Other materials related to options such as a garage and a balcony are presented from the material information DB 218 and selected according to the user's selection.

Although described in detail with respect to preferred embodiments of the online building design system of the present invention as described above, those of ordinary skill in the art to which the present invention belongs, the spirit of the present invention as defined in the appended claims And the present invention may be modified in various ways without departing from the scope. Therefore, changes in the future embodiments of the present invention will not be able to escape the technology of the present invention.

As described above, the system and method for designing a building on the Internet of the present invention selects and synthesizes the design of the building and the internal structure of the building according to the number and floor of the building to be constructed on the Internet, respectively, By realizing the 3D stereoscopic image, the user can design the entire building.

In addition, by directly selecting the materials used in the construction of the building to make a three-dimensional image, you can easily grasp the location, color, etc. applied to the actual building, as well as accurately check the production cost, labor cost, construction cost, and construction period used in the building. Can be.

In addition, since the building is designed online, it is possible to freely modify the external shape and internal structure according to the user's desire.

Claims (13)

A client connectable to the Internet, an operation server connected to the Internet and providing various information related to the building construction, and a data server storing the construction related information. Building appearance management module for storing and managing the external model of the building classified according to the number of floors and floors in the design information DB; An internal structure management module for storing and managing design information related to an internal structure of a building including a room, a kitchen, and a bathroom in an internal structure information DB according to the number of floors of the building; A building appearance forming module configured to select an external appearance of the building by receiving an exterior model of the building according to the input floor space and the number of floors from the design information DB when the user inputs the number of floors and the floor of the building to be built; An internal structure forming module configured to design an internal structure of the building by the user receiving the internal structure according to the number of floors from the internal structure information DB of the internal structure of the building; And Online building design system, characterized in that consisting of a control module for controlling the various modules. The method of claim 1, wherein the operation server, A building material management module for storing and managing information on building materials including internal equipment materials, exterior materials, interior materials, finishing materials and window materials used in the building in a material information DB; An interior forming module configured to form an interior related to the interior equipment, the exterior and the interior of the building by receiving the building material including the interior equipment, exterior material, interior material, window material, and finishing material of the building from the material information DB; On-line architectural design system, characterized in that it further comprises. The method of claim 1 or 2, wherein the operation server, An adjustment management module for creating a site of the building as an image or a 3D image and storing it in the landscaping information DB; And On-line architectural design system further comprises a landscape forming module for completing the landscape of the building by selecting the landscape information stored in the material information DB. The method of claim 1, wherein the external model of the building includes an external model having an appearance suitable for a one-story structure and an external model having an appearance suitable for a two-story or more structure and a model classified for a roof according to the number of floors. Featured online architectural design system. The on-line architectural design system according to claim 1, wherein the external model and the internal structure of the building are displayed in a three-dimensional image. In a client that can be connected to the Internet, an operation server that is connected to the Internet and provides various information related to the construction of the building and a data server storing the construction related information, A building appearance determining step of selecting an exterior model of the building provided from a design information DB by inputting the number of floors and the number of floors of the building for the user to build; And an internal structure determination step of determining an internal structure of each floor of the building by selecting an internal structure of the building including a room, a kitchen and a bathroom of the building from an internal structure information DB. The method of claim 6, A finishing material determining step of selecting an exterior material of the building and an interior material of the building from the material information DB to determine exterior and interior decoration of the building; A window material determining step of selecting and determining a window material used for the exterior and the interior of the building from the window material provided from the material information DB; And On-line architectural design method further comprises the step of determining the auxiliary equipment of the outside and the interior of the building selected from the auxiliary equipment provided from the material information DB. The on-line architectural design method according to claim 6 or 7, further comprising a landscape decision step of selecting and determining the landscape of the building from a landscape information DB. The method of claim 8, wherein the landscaping is a user constructing the building site of the building as an image or a three-dimensional image. 8. The on-line architectural design according to claim 7, wherein the window material comprises a front door, a window or a fresh door, and the auxiliary equipment includes a lighting system, an electrical system, a method system, an air conditioning system, and a purification environment system. Way. According to claim 6, The exterior model of the building is composed of an external model having an external appearance suitable for the one-story structure according to the number of floors, and an external model having an external appearance suitable for the two-story or more structure and models for the roof classified by type. Online architectural design methods. 8. The online architectural design method according to claim 6 or 7, wherein a cost for constructing the building or material selected in each step is calculated. The method of claim 6, wherein the external shape of the building and the internal structure of the building are determined by the user inputting the balance, the number of floors, the shape of the roof, the number of rooms and the preventive construction cost collectively from the design information DB and the internal structure information DB. And in combination with the user, the on-line architectural design method.