KR101396795B1 - Bim system and modeling method - Google Patents

Abstract

A BIM system according to one aspect of the present invention may comprise a factory production server for modeling materials and components of a unit modular building; an on-site assembly server for modeling the unit modular building as scenario that an actual building is constructed by using the materials and the components of the building, which are modeled in the factory production server; and an interference check server for checking errors of the building modeled in the factory production server and the on-site assembly server.

Description

[0001] BIM SYSTEM AND MODELING METHOD [0002]

The present invention relates to a BIM system and a modeling method, and more particularly, to a BIM system and a modeling method for modeling a unit module from a factory to a field assembly and performing an interference check.

Demand for small houses has been steadily increasing due to the recent increase in small-sized households due to low fertility and changes in social structure. The government is also encouraging the development of small houses through relaxation of housing laws and regulations on construction standards. One of these policies is urban living houses.

Urban residential housing is a residential type that has been implemented since May 2009 to stabilize the residence of ordinary people and one to two people, which is less than 300 households, which is the size of national residence (housing area less than 85㎡ for first generation). Attempts have been made to build urban living houses using environmentally friendly unit modular technology.

Unit modular technology is a method that differentiates the existing method of on-site construction, and various kinds of interior materials, mechanical equipment, electric wiring, etc. are built in the structure composed of a box shaped cubic body in the factory, The building method is completed by combining each unit.

Building Information Modeling (BIM) refers to the process of modeling a facility in a multidimensional virtual space such as planning, design, engineering (structure, facility, electricity, etc.) and further maintenance and disposal. The building information is integrated Applying the available BIM design to the unit modular will maximize the synergy. However, the conventional design of the unit modular architecture is a 2D-based design system, so that it is not possible to reflect the unit modular architectural characteristics required to manage the information of each member and the unit.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a BIM system and a modeling method in which design and construction are simultaneously performed.

It is another object of the present invention to provide a BIM system and a modeling method for reducing the design and construction errors of a unit modular building.

According to an aspect of the present invention, there is provided a BIM system including a factory production server for modeling materials and components of a unit modular building, A field assembly server for modeling according to a scenario in which an actual building is installed, and an interference check server for checking an error of a building modeled by the factory production server and the field assembly server.

The factory production server includes a family construction server for modeling and building a family of the materials and components constituting the unit module, and a combination server for combining the families constructed by the family construction server into a group of the unit modules can do.

Wherein the combining server comprises a structural process of combining the beam, the column, the tec floor slab, and the junction plate of the unit module, a building process of installing a wall and a window in the unit module combined in the structure process, And a facility process for installing facility equipment in the combined unit module.

The field assembly server includes an RC foundation construction for integrating the on-site cast concrete, an assembling operation for assembling the unit modules after the completion of the RC foundation work, It is possible to model the roof truss construction to be formed and the facility assembly work for installing the facility piping and electric piping after completion of the roof truss construction and the finish work for finishing the wall after the facility assembly work is completed.

The roof truss construction can be divided into a main truss and a sub truss.

In order to shorten the construction work and to facilitate construction, the non-welded piping system can be applied to the facility assembly work.

The on-site assembly server may be run in a bottom-up manner to build from a foundation to a roof finish.

The interference check server can check that design errors and interference occur in the unit modular building modeled by the factory production server and the field assembly server, respectively.

According to another aspect of the present invention, there is provided a BIM modeling method including the steps of: (a) setting a conceptual diagram of a location where a unit modular building is installed; (b) designing a 2D drawing of the prototype based on the conceptual diagram; (c) building a material and a part into a family based on the 2D drawing at a factory production server and executing a modeling process; (d) modeling the unit module by combining the modeling of the family; (e) checking the modeling of the unit module in an interference check server; (f) assembling the unit module in a field assembly server to model the unit modular building; And (g) checking the unit modular building at the interference check server.

Wherein the factory production server comprises a family construction server for building the family of the material and parts constituting the unit module and a combination server for combining the families constructed by the family construction server into a group of the unit modules can do.

Wherein the combining server comprises a structural process of combining the beam, the column, the tec floor slab, and the junction plate of the unit module, a building process of installing a wall and a window in the unit module combined in the structure process, And a facility process for installing facility equipment in the combined unit module.

The method of modeling in a field assembly server comprises the steps of: constructing an RC foundation that integrates the locally cast concrete; combining the generations of the unit modules after the RC foundation is completed; Performing a roof truss construction for laying a roof truss on the upper part of the unit modular building; performing facility assembly work on the unit module after the roof truss is stacked; And a step of finishing the process.

The roof truss construction can be divided into a main truss and a sub truss.

In order to shorten the construction work and to facilitate construction, the non-welded piping system can be applied to the facility assembly work.

The on-site assembly server may be run in a bottom-up manner to build from a foundation to a roof finish.

According to the BIM system of the present invention, the factory production server and the field assembly server can be operated at the same time, so that the design and construction can be separated and the air delay can be prevented from increasing.

In addition, the interference check server interferes with the modeling completed by the factory production server and the field assembly server, so that the design and construction errors can be minimized.

1 is a block diagram illustrating a BIM system in accordance with an embodiment of the present invention.
FIG. 2 illustrates an example of a family construction server according to an embodiment of the present invention; FIG.
3 is an exemplary view illustrating a design process according to an embodiment of the present invention;
Fig. 4 is an exemplary view showing a combination server that combines the unit modules shown in Fig. 3; Fig.
5 is an exemplary view showing a field assembly server according to an embodiment of the present invention;
Fig. 6 is an exemplary view showing the construction of a household by combining the unit modules shown in Fig. 5. Fig.
7 is an exemplary view showing a facility assembly work according to an embodiment of the present invention.
FIG. 8 is an exemplary view showing an interference check server according to an embodiment of the present invention; FIG.
9 is a flowchart illustrating a BIM modeling method according to another embodiment of the present invention.
10 is a conceptual diagram illustrating a BIM modeling method according to another embodiment of the present invention.

Hereinafter, a BIM system and a modeling method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating a BIM system according to an embodiment of the present invention. FIG. 2 is an exemplary view illustrating a family construction server according to an exemplary embodiment of the present invention. FIG. Fig. 4 is an exemplary view showing a combination server combining the design process shown in Fig. 3; Fig.

1 to 4, a BIM system according to an exemplary embodiment of the present invention includes a factory production server 100 for modeling materials and components of a unit modular building 10, A field assembly server 200 for modeling a building according to a scenario in which an actual building is constructed using materials and components of a building modeled in the building 200 and an error of a building modeled by the factory production server 100 and the field assembly server 200 And an interference check server 300 for checking the interference.

The factory production server 100 includes a family construction server 110 for constructing a family 111 of materials and components constituting the unit module 20 and a building management server 110 for building the family 111 in the family construction server 110. [ And a combination server 120 that combines the unit modules 20 into a group of the unit modules 20.

The family construction server 110 can execute the modeling process of the material and the parts to be constructed in the family 111 by modeling the family 111 constituting the material and parts. The family building server 110 converts the basic objects of the member into data and libraries for each type so that the modeling is effectively applied.

In the modeling process of the family 111, the family 111 of the unit module 20 can be created in the first step as shown in FIG. At this time, the dimensions of the member can be modeled by completing the basic unit module 20 according to the design standard, and then modeling the family 111 constituting the unit module 20 of different types by scale using the parameter values. The unit modular building 10 is a dry system, and its physical regionality is clear, which can be advantageous for informing the member. The next step is to model the modular joint part of the connector, bolt, and so on. Because the unit modular building 10 is made up of a combination of units, the shape of the structure may vary depending on the type of the joining material.

The combination server 120 can set the design process so that the families 111 modeled in the modeling process of the family 111 are combined to form one module as shown in FIG. The families 111 of the respective members can be input into the shared family 111 and constructed as one family 111. [ The installed module may form one unit module 20 together with the material and the parts. At this time, the members of the joints may be mounted on the unit module 20 and formed into a single group and organized. In particular, each unit module 20 may have various alternatives depending on the size of the material and the type of the parts.

4, the combination server 120 includes a structural process 121 for combining the beam, the column, the tec floor slab, and the bonding plate of the unit module 20, and the structural process 121, A building process 122 for installing a wall and a window on the unit module 20 combined in the building process 122 and a facility process 123 for installing facility equipment in the unit module 20 combined by the building process 122, Can be combined.

The structural process 121 can construct a family 111 of the group by combining a family 111 of joins connecting beams and columns and combining the columns and beams, deck-type floor slabs, and joining plates.

In the building process 122, walls and windows are modeled according to the criteria of an eye scale, and the unit modular building 10 uses a method in which walls are pre-manufactured in the factory and windows are installed on the spot, Parameter settings such as values can be important. Therefore, it is necessary to input the parameter of the gap value in the modeling of the wall so that the accuracy can be secured at the time of construction.

The installation process 123 is intended to install a facility piping, an electric wiring, and the like on the unit module 20 in advance, and to assemble the module using an electrical connection box and a piping connector in the field. However, The facility may use a method in which the unit module 20 is installed in the field and then the installation process 123 is separately installed in the existing method.

The field assembly server 200 includes an RC foundation construction 210 that integrates the spotted concrete and an assembling operation 220 that combines the generations of the unit modules 20 after the RC foundation construction 210 is completed. A roof truss construction 230 formed on the upper part of the combined unit module 20 after the assembly work 220 is completed and a facility piping and an electric piping installed after the roof truss construction 230 is completed The facility assembly work 240 and the finishing work 250 finishing the wall after the facility assembly work 240 is completed can be modeled.

The interference check server 300 can check an error of a building modeled by the factory production server 100 and the field assembly server.

FIG. 5 is a view illustrating an on-site assembly server according to an embodiment of the present invention. FIG. 6 is an exemplary view showing the construction of a household by combining unit modules shown in FIG. 5. FIG. FIG. 8 is an exemplary view showing a facility assembly work according to an embodiment.

5 to 7, the field assembly server according to the embodiment of the present invention carries out the modeling into a scenario in which the completed units are transferred to the site in the factory production server 100 and a building is constructed at an actual construction site .

The field assembly server can visualize a process of assembling in a virtual space as a basic operation for realizing virtual simulation which is an important advantage of the BIM system.

The field assembly server 200 includes an RC foundation construction 210 that integrates the spotted concrete and an assembling operation 220 that combines the generations of the unit modules 20 after the RC foundation construction 210 is completed. A roof truss construction 230 formed on the upper part of the combined unit module 20 after the assembly work 220 is completed and a facility piping and an electric piping installed after the roof truss construction 230 is completed The on-site process of the facility assembly work 240 and the finishing work 250 finishing the wall after the facility assembly work 240 is completed can be modeled.

Also, the field assembly server 200 may proceed in a bottom-up manner as shown in FIG. 5, from the foundation to the roof finish.

The RC foundation work 210 can be modeled by dividing a column, a main entrance / exit stair, and a mat foundation into a basic structure of a field-inserted reinforced concrete as a first stage of the field process modeling. The reinforced concrete in situ is composed of one piece, the physical area between the members is not clear differently from the precast concrete and the steel frame, so that the overlapping part of the concrete member is regarded as part of one member and part of another member can do. Therefore, it may be necessary to use separate software to solve and model these problems.

The assembly work 220 may combine the generations of the unit modules 20 manufactured by the factory production server 100 after the RC foundation work 210 is completed. The generation of the unit module 20 of the assembly work 220 can be variously formed, such as a balcony, a staircase, a door, and the like.

If the foundation of the unit module 20 is assembled in the field, there is a problem that the assembling time is delayed if the foundation and smoothness are not ensured. A loading space is required depending on the number of the unit modules 20, Since the construction is performed in a limited space in the urban area, it may be necessary to secure space for the unit module 20. Therefore, it is necessary to collaborate with the construction company from the design stage, but air delay and construction error can be increased in the current construction method where design and construction are separated. In order to solve these problems, the process design can be carried out on the premise that the BIM design and the construction are ordered at the same time.

The roof truss construction 230 may install a roof truss on the combined unit modular building 10 after the assembly work 220 for assembling the unit module 20 is completed. The roof truss construction 230 may be constructed of two types of main trusses and sub trusses by being assembled on site after being pre-assembled at a factory.

The facility assembly work 240 may include facility piping and electrical piping after the unit modular building 10 is assembled on-site. The facility assembly work 240 is a type of connecting a variety of electric wires, sanitary pipes, mechanical pipes, etc. mounted on the unit module 20 by using connection boxes and connectors in the field, It is possible to shorten the length and ease the workability.

The finishing work 250 may be modeled from the RC foundation work 210 to the facility assembly work 240 and then modeled as finishing on the wall. The finishing work 250 is divided into an RC part and an interior / exterior finishing part. The finishing part is a part of the BIM modeling collaboration system, so that the element characteristic of the building material used as a part belonging to the building part can be informed and applied to the calculation of the quantity The kind and size of the material can be written in the element properties. The interior finishing can be done in the order of ceiling and floor after construction.

FIG. 8 illustrates an example of an interference check server according to an embodiment of the present invention. Referring to FIG.

As shown in FIG. 8, the interference check server 300 according to an exemplary embodiment of the present invention can check an error of a model modeled by the factory production server 100 and the field assembly server 200.

The interference check server 300 includes a factory production server 100 in which a variety of interior materials, mechanical equipment, electric wiring, and the like are installed in a structure formed of a box-shaped shaped cube, , It is possible to perform an interference check for each type of unit model.

Unless interference is checked in the unit module 20 modeled by the factory production server 100, grouping of units for efficiency of modeling in the future may cause difficulties in modeling modification if design errors and inter-species interference occur.

8, when the modeling for assembling the unit module 20 modeled by the factory production server 100 by the field assembly server 200 is performed, the interference check server 300 can check the design error and the inter- Indirect situation can be confirmed.

For example, if the depth of the stairway window is projected to the exterior wall finish line rather than the interior finish, this can be solved by adjusting the exterior wall thickness for the insulation space and modular steel fireproofing. For example, if interference occurs on the outer wall of a roof staircase, it is possible to solve the problem by adjusting the eaves in the architectural design.

In this way, interference check is performed in order to check the design error, the interference between the process and the work type in the interference check server 300, and error occurrence and time can be shortened.

In the following description of the BIM system according to another embodiment of the present invention, the same reference numerals as those of the BIM modeling method according to the above-described embodiment are used, and detailed description thereof will be omitted.

FIG. 9 is a flowchart illustrating a BIM modeling method according to another embodiment of the present invention, and FIG. 10 is a conceptual diagram illustrating a BIM modeling method according to another embodiment of the present invention.

At S100, a conceptual diagram of the location where the unit modular building 10 is constructed can be set.

S200 can design 2D drawings of the prototype based on the concept diagram set in S100. The 2D drawings of the prototype can be pre-set by the design process, such as sizing and planar space configuration.

S300 may execute a modeling process of building the family 111 of materials and components based on the 2D drawing at the factory production server 100. [ The factory production server 100 includes a family construction server 110 for constructing a family 111 of materials and components constituting the unit module 20 and a family 111 constructed by the family construction server 110. [ And a combination server 120 for combining the plurality of unit modules 20 into a group of the unit modules 20.

S400 can model the unit module 20 by assembling the materials and parts modeled in S300.

The interference check server 300 can check the modeling of the unit module 20 modeled at S400 in S500.

In S600, the unit module 20 modeled and manufactured by the factory production server 100 is set in the field assembly server 200 under the same conditions as the actual site, and the unit module 20 is connected to an RC An assembling operation 220 for assembling the generations of the unit modules 20 after the completion of the RC foundation works 210 and the unit modules 220 assembled after the assembling operation 220 is completed, A roof truss construction 230 formed at an upper portion of the roof truss construction 230 and a facility truss construction 240 for installing a facility piping and an electric piping after the roof truss construction 230 is completed, And can be modeled as a field process of the finishing work 250 finishing the rear wall.

In step S700, the interference checking server 300 may check the unit modular building 10 assembled by the field assembly server 200. [

Although the BIM system and the modeling method according to an embodiment of the present invention have been described above, the spirit of the present invention is not limited to the embodiments disclosed herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

10: Unit modular building 20: Unit module
100: factory production server 110: family building server
120: combination server 200: field assembly server
300: interference check server

Claims (15)

A factory production server for modeling materials and components of the unit modular building,
A field assembling server for modeling the actual building using the material and the parts of the building modeled by the factory production server according to a scenario in which the actual building is constructed,
And an interference check server for checking an error of a building modeled by the factory production server and the field assembly server,
The factory production server includes a family construction server for modeling and building a family of the materials and components constituting the unit module,
And a combination server for combining the families constructed by the family construction server into a group of the unit modules,
The on-site assembly server includes an RC foundation construction that integrally constructs on-site concrete,
An assembly work for assembling the generations of the unit modules after completion of the RC foundation work,
A roof truss work which is formed on the upper part of the combined unit module after the assembling work is completed and is divided into a main truss and a sub truss,
After the completion of the roof truss construction, facility piping and electric piping are installed. In order to shorten the construction pipeline and facilitate construction,
And a finishing work for finishing the wall after completion of the facility assembly work is modeled.
delete The method according to claim 1,
Wherein the combination server comprises a structural process of combining the beam, the column, the technical floor slab and the junction plate of the unit module,
A building process for installing a wall and a window in the unit module combined in the structure process;
And a facility process for installing facility equipment in the unit module combined by the building process.
delete delete delete The method according to claim 1,
Wherein the on-site assembly server is implemented in a bottom-up manner to build from a foundation to a roof finish.
The method according to claim 1,
Wherein the interference check server checks that a design error and interference occur in the unit modular building modeled by the factory production server and the field assembly server, respectively.
(a) establishing a conceptual view of the location where the unit modular building is to be installed;
(b) designing a 2D drawing of the prototype based on the conceptual diagram;
(c) building a material and a part into a family based on the 2D drawing at a factory production server and executing a modeling process;
(d) modeling the unit module by combining the modeling of the family;
(e) checking the modeling of the unit module in an interference check server;
(f) assembling the unit module in a field assembly server to model the unit modular building; And
(g) checking the unit modular building at the interference check server,
Wherein the factory production server comprises a family construction server for building the family of the materials and parts constituting the unit module,
And a combination server for combining the families constructed by the family construction server into a group of the unit modules,
The method for modeling in the field assembly server comprises the steps of: constructing an RC foundation for integrally constructing the spotted concrete;
Combining the generations of the unit modules after the RC foundation is completed;
Performing a roof truss construction by stacking a roof truss on top of the unit modular building after the generations of the unit modules are combined and dividing into a main truss and a sub truss;
A step of performing facility assembly work to apply a no-weld piping system to the unit module after the roof truss is stacked, in order to facilitate construction workability and ease of construction,
And finishing the wall after the facility assembly work is completed.
delete 10. The method of claim 9,
Wherein the combination server comprises a structural process of combining the beam, the column, the technical floor slab and the junction plate of the unit module,
A building process for installing a wall and a window in the unit module combined in the structure process;
And a facility process for installing facility equipment in the unit module combined by the building process.
delete delete delete 10. The method of claim 9,
Wherein the on-site assembly server is implemented in a bottom-up manner to build from a foundation to a roof finish.

Images