KR101885692B1 - Heavy equipment management system based on BIM and heavy equipment management method of the same - Google Patents

Abstract

The present invention includes a heavy equipment DB module storing specifications for each heavy equipment, a heavy equipment BIM data module for extracting and cataloging heavy equipment information for construction of the building from the BIM data of the BIM model for the building to be constructed, A heavy equipment selection module for selecting a heavy equipment satisfying a target condition set among the heavy equipment stored in the heavy equipment DB module through the heavy equipment information of the BIM data module, and a heavy equipment form module for automatically adjusting the parameters for the heavy equipment, BIM-based heavy equipment management system.
According to the above, it is possible to scientifically and rationally manage the plan and management plan based on the BIM data of the objective and reliable BIM model, automatically list the necessary information for equipment selection of each project, By supporting the selection of equipment, it is possible to increase the work efficiency of the construction manager who establishes initial site management and equipment plan.

Description

[0001] The present invention relates to a BIM-based heavy equipment management system and a heavy equipment management method using the same,

The present invention relates to a BIM-based heavy equipment management system and a heavy equipment management method using the same. More particularly, the present invention relates to a BIM-based heavy equipment management system capable of reducing pre-construction risks based on BIM three- will be.

In recent years, the construction of high-rise buildings has been increasing globally in order to raise land prices, securing the maximum floor area ratio and revealing economic richness and growth. In recent years, domestic high-rise residential complexes High-rise buildings are being built continuously.

On the other hand, in order to successfully carry out the construction work at the construction site, both heavy and heavy equipment are required to carry heavy materials up and down and to the left and right and to move the worker and materials to the upper part of the building. These heavy and heavy equipment include tower crane and hoist Hoist car, etc., and the importance of systematic management and control of these heavy equipment is increasing day by day due to the high-rise of buildings.

This is because, in the case of high-rise buildings, the time required for manpower or resources to reach from the ground to the target point is much longer than in the case of general building construction. Therefore, systematic and reasonable planning of high- .

However, in the present construction site, the planning of the mooring plan, especially the management of the tower crane, is based on a simple and empirical method due to lack of objective and reliable data, and it is frequently used inefficiently.

Especially, in the case of a construction site where a comprehensive management system such as a construction site of a high-rise building is required, the operation planning and operation system of the equipment which is not systematic has a problem that the efficiency of equipment operation is greatly deteriorated at the construction site.

In addition, such conventional scientific and non-rational planning of the piling up of the piling equipment in the construction site makes the amount of the material ineffective, hindering the entire construction progress, and consequently, the construction period and the construction cost, which are important factors in successful construction of the building, There was a serious problem to increase.

In addition, since the degree of use of the equipments is different according to the frame type of the high-rise building, it is necessary to select the exact number of equipments and the model of the equipments. In the past, There was a problem that the errors were overflowed due to the lack of systematic standards and the efficiency was extremely reduced.

Korean Patent Application No. 10-2008-0056157

The present invention aims to improve the efficiency of equipment operation by scientific and rational management based on objective and reliable data, and to reduce the construction period and construction cost, and reduce errors in planning And to provide a BIM-based heavy equipment management system capable of reducing pre-construction risks and a heavy equipment management method using the same.

 According to an aspect of the present invention, there is provided a method for constructing a building from a BIM data of a building information modeling (BIM) model for a building to be constructed, the heavy equipment DB module storing specifications for each heavy equipment, A BIM data extraction module for extracting and cataloging the absent information and the heavy equipment information and the heavy equipment information and the absent information of the BIM data extraction module to identify the heavy equipment satisfying the set target condition among the heavy equipment stored in the heavy equipment DB module A BIM-based heavy equipment management system including a heavy equipment selection module for selecting a heavy equipment selection module.

According to another aspect of the present invention, there is provided a method for building a building, the method comprising the steps of: building a heavy equipment DB module storing specifications for each heavy equipment; extracting, from BIM data of the BIM model for the building, Automatically selecting and cataloging the absent information and the heavy equipment information and selecting the heavy equipment satisfying the target condition from the heavy equipment stored in the heavy equipment DB module from the absence information and the heavy equipment information through the heavy equipment selecting module And a BIM-based heavy equipment management method.

The BIM-based heavy equipment management system and the heavy equipment management method using the same according to the present invention provide the following effects.

First, we can manage the plan and management plan scientifically and rationally based on the BIM data of the objective and reliable BIM model.

Second, systematic and rational management can ensure the efficiency of equipment operation at the construction site, and can reduce construction period and construction cost.

Thirdly, systematic and explicit system selection can reduce the errors that may occur in the planning and reduce the construction risk by the heavy equipment in advance.

Fourth, BIM-based heavy equipment selection system automatically lists the material information required for equipment selection of each project and supports optimum equipment selection, thereby improving work efficiency of construction manager who establishes initial site management and equipment plan .

Fifth, the BIM model can be used to automatically catalog the quantitative information on the basis of the quantitative information, and to efficiently search for and select the heavy equipment that meets the conditions based on the information.

1 is a block diagram illustrating a configuration of a BIM-based heavy equipment management system according to an embodiment of the present invention.
2 is a flowchart illustrating a BIM-based heavy equipment management method according to an embodiment of the present invention.
FIG. 3 is a flowchart illustrating an embodiment of a heavy equipment selection process in the BIM-based heavy equipment management method of FIG.
FIG. 4 is a diagram illustrating a process of adjusting parameters for heavy equipment and extracting and cataloging the heavy equipment information through the heavy equipment form module in the BIM-based heavy equipment management method of FIG.
FIG. 5 is a diagram illustrating a process of listing and storing heavy equipment information in the heavy equipment DB module in the BIM-based heavy equipment management method of FIG. 2;
FIG. 6 is a diagram illustrating a list of heavy equipment that meets the list of heavy equipment information and the target condition in the BIM-based heavy equipment management method of FIG. 2. FIG.

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

Referring to FIG. 1, a BIM-based heavy equipment management system according to an embodiment of the present invention supports selection of both heavy equipment based on BIM. The system includes a heavy equipment DB module 100, a BIM data extraction module 200, A heavy equipment selection module 300, and a heavy equipment shape module 400.

The heavy equipment DB module 100 stores specs for each heavy equipment. Here, the heavy equipment is a heavy equipment such as a tower crane (L type, T type), a crawler crane, a hydro crane, and a jib crane. The specifications of the heavy equipment include all the specifications relating to the performance of the load such as the load chart of the heavy equipment.

The BIM data extraction module 200 automatically extracts member information and heavy equipment information for construction of the corresponding building from BIM data of a building information modeling (BIM) model for the building to be constructed, .

Here, the heavy equipment information includes the absence information of the building, the type information of the heavy equipment with respect to the absence information, and the location information of the heavy equipment. At this time, the member information includes information on the structure type, position, quantity, length, volume, weight, and the like of the corresponding building such as RC, SRC, PC, etc. The heavy equipment information also includes information on the heavy equipment location, The information is calculated by storing information such as material, length, and volume of each member.

The heavy equipment selecting module 300 selects the heavy equipment, which is stored in the heavy equipment DB module 100, through the building member information, the list of the heavy equipment information and the field data listed in the BIM data extraction module 200 And list and select the heavy equipment satisfying the target condition.

Here, the target condition may take into account the demand position of the member and the supply position of the member, taking into consideration the size and weight of the member, the possibility of paying attention to the working radius of the heavy equipment, By expressing the efficiency of the worker considering the daily processing capacity and the leasing cost, the operator can select the most efficient TC.

When the operator adjusts the parameters of the selected heavy equipment, the heavy equipment form module 400 displays the type of the heavy equipment according to the parameter adjustment on the screen.

As shown in FIG. 4, the heavy equipment shape module 400 is a heavy equipment BIM object database (DB), which automatically catalogs the three-dimensional coordinate, length, and weight of the two- And the working radius and the working radius can be expressed in three dimensions on the screen. The weight of the member is automatically calculated by considering the type of the member (the characteristics of the RC, SRC, PC, and the like), the length and the volume, and the weight of the member is automatically calculated and stored.

The heavy equipment form module 400 displays the parameters of the heavy equipment on the screen so that the operator can automatically adjust the parameters of the heavy equipment through the screen. The heavy equipment form module 400 automatically adjusts the main parameters after selecting the heavy equipment and displays objects on the screen. At this time, the parameter includes shape information of the heavy equipment including the Jib length of the heavy equipment, mast dimensions, and the like.

Here, the heavy equipment form module 400 may be configured such that the operator adjusts the detailed parameters and the heavy equipment form is changed, so that not only the parameters of one member are adjusted, but also the association members can be simultaneously and automatically adjusted have. That is, the heavy equipment form module 400 is constrained between the members associated with each other in the heavy equipment, so that the parameters of the members related to each other at the time of parameter adjustment are automatically adjusted correspondingly.

Meanwhile, the heavy equipment form module 400 may display the other processes for selecting the heavy equipment that can improve the efficiency of the other work as well as the automatic adjustment of the parameters after selecting the heavy equipment as described above Of course.

Meanwhile, the BIM-based heavy equipment management system can be developed based on the Autodesk Revit common program, and can support the selection of the heavy equipment based on the information extracted from the two DB data and the BIM data.

According to the above, the BIM-based heavy equipment management system is capable of automatically cataloging the weight information by utilizing the BIM data. Accordingly, since the worker does not have to directly input the absence information and the weight of the heavy equipment, The efficiency can be improved. In addition, the BIM-based heavy equipment management system can search and select the heavy equipment that satisfies the target condition based on this, and through the systematic and explicit system, Can be reduced.

Hereinafter, a BIM-based heavy equipment management method according to an embodiment of the present invention will be described with reference to FIG. 2, which uses the above-described BIM-based heavy equipment management system and its detailed description has been described above. do.

First, the BIM-based heavy equipment management system stores the specifications for each heavy equipment and constructs the heavy equipment DB module 100 (S10).

The BIM-based heavy equipment management system automatically extracts the absence information and the heavy equipment information of the corresponding building from the BIM data of the BIM model 10 for the building to be constructed through the BIM data extraction module 200, (S20).

When the list of the heavy equipment information is completed, the BIM-based heavy equipment management system selects a heavy equipment satisfying the target condition from the heavy equipment stored in the heavy equipment DB module 100 from the heavy equipment information through the heavy equipment selection module 300 (S30).

At this time, the selection of the heavy equipment can be made on the screen by the heavy equipment form module 400, and if the operator adjusts the parameters of the heavy equipment selected through the heavy equipment form module 400 after selection, The shape of the heavy equipment can be displayed on the screen. At this time, the heavy equipment form module 400 is constrained between mutually related members in the heavy equipment, and the parameters of the members related to each other at the time of the parameter adjustment are also automatically adjusted correspondingly.

FIG. 3 is a flowchart illustrating an exemplary embodiment of a heavy equipment selection process when the project is operated in the BIM-based heavy equipment management method of FIG. 2. When the BIM data of the setting project is created through the heavy equipment feature module 400, Gt; At this time, the data thus extracted is stored in a project data extraction DB (see FIG. 5). The project data extraction DB includes project characteristics (S, RC, SRC, PC, etc.), weight, position, length, demand, Position, and includes positions of both heavy equipment such as a tower crane as shown in Fig.

After the data for selection of both heavy equipment is constructed and cataloged according to the above, the heavy equipment selection module 300 selects and selects the optimal amount of heavy equipment through the extracted project data and the heavy equipment information of the heavy equipment DB module 100 It is proposed to suggest the optimum position of heavy equipment.

FIG. 6 is a diagram showing items appearing on the screen of the BIM-based heavy equipment management system through the above-described BIM-based heavy equipment management method. As shown in FIG. 6, A list of equipment and a table of the selected equipment are displayed.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100 ... Heavy Duty DB Module 200 ... BIM Data Extraction Module
300 ... Heavy Equipment Selection Module 400 ... Heavy Equipment Shape Module

Claims (18)

A heavy equipment DB module storing specifications for each of the heavy equipment including a load chart;
A BIM data extraction module for automatically extracting and cataloging member information and both heavy equipment information for construction of the corresponding building from BIM data of a building information modeling (BIM) model for the building to be constructed;
A heavy equipment selection module that selects, through the two pieces of heavy equipment information and the member information of the BIM data extraction module, an amount of heavy equipment satisfying a target condition set among the two heavy equipment stored in the heavy equipment DB module; And
And a 3D shape DB of the both heavy equipment, and when the operator adjusts the parameters of the selected heavy equipment, the heavy equipment module displays the shape of the heavy equipment according to the parameter adjustment on the screen together with the corresponding building In addition,
The BOM data extracted from the BIM data by the BIM data extraction module for selecting the BOM data includes type information of the BOM data and location information of the BOM data,
The member information extracted from the BIM data in the BIM data extraction module for selecting the heavy equipment includes the structure type, position, quantity, length, volume, and weight information of the corresponding building,
Wherein the parameter is formed of shape information of the both heavy equipment including a jib length or a mast dimension of the both heavy equipment,
The heavy equipment form module is configured such that the members associated with each other in the heavy equipment are constrained so that the parameters of the members associated with each other during the parameter adjustment are automatically adjusted correspondingly,
The heavy equipment form module comprises: a BIM-based heavy equipment management system for automatically cataloging three-dimensional phase coordinates, length and weight of a two-piece member and representing the working volume and the working radius for the selected two- system. delete delete The method according to claim 1,
In the heavy equipment selection module,
And a weighting factor in consideration of a supply position of the member, a size and a weight of the member, a working radius, and the like,
A BIM-based heavy equipment management system that includes the worker's ability to handle work and leasing costs. delete delete delete delete The method according to claim 1,
The heavy equipment form module includes:
Wherein the weight of the member is automatically calculated in consideration of the type, length and volume of the member, and stored. Building a heavy equipment DB module that stores specifications for each of the heavy equipment including a load chart;
Automatically extracting and cataloging the absent information and the heavy equipment information of the building from the BIM data of the BIM model for the building to be constructed through the BIM data extraction module; And
And selecting a quantity of heavy equipment satisfying a target condition among the quantity of heavy equipment stored in the heavy equipment DB module from the absence information and the quantity information of the heavy equipment through a heavy equipment selecting module,
The BOM data extracted from the BIM data by the BIM data extraction module for selecting the BOM data includes type information of the BOM data and location information of the BOM data,
The member information extracted from the BIM data in the BIM data extraction module for selecting the heavy equipment includes the structure type, position, quantity, length, volume, and weight information of the corresponding building,
Wherein the parameter is formed of shape information of the both heavy equipment including a jib length or a mast dimension of the both heavy equipment,
When the operator adjusts the parameters of the selected heavy equipment by the operator through the heavy equipment form module having the both heavy equipment 3D shape DB, the shape of the heavy equipment according to the parameter adjustment is displayed on the screen together with the corresponding building,
The heavy equipment form module is configured such that the members associated with each other in the heavy equipment are constrained so that the parameters of the members associated with each other during the parameter adjustment are automatically adjusted correspondingly,
Wherein the three-dimensional coordinate, length, and weight of the two-piece member are automatically cataloged by the heavy equipment module, and the working volume and the working radius of the selected two-piece heavy equipment are represented in three dimensions on the screen. Way. delete delete The method of claim 10,
In the heavy equipment selection module,
A demand position of the double-sided member, a supply position of the member, a positivity considering the size and weight of the member, a working radius, etc., and an efficiency considering the work capacity and the leasing cost of the worker BIM-based heavy equipment management method. delete delete delete delete The method of claim 10,
The heavy equipment form module includes:
Wherein the weight of the member is automatically calculated in consideration of the type, length, and volume of the member, and stored.

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