KR20230073538A - Safety managing system based on bim modeling technology and method for controlling the safety managing system - Google Patents

Abstract

The present invention provides a BIM-based smart safety management system and a control method thereof. The BIM-based smart safety management system comprises: a worker status detection sensor unit accompanying one or more workers at a construction site and capable of obtaining worker's work status information; a worker status information server enabling transmission and reception of the worker's work status information through communication with the worker status detection sensor unit; a BIM server containing construction BIM modeling information of a target building at the construction site; a safety management server linked with the BIM server and the worker status information server and generating safety management information for a workplace by linking the worker's work status information from the worker status information server and the BIM modeling information of a work site; and a site manager terminal receiving workplace safety management information from the safety management server and enables monitoring of a safety management status at the work site. Accordingly, a risk of accidents can be significantly reduced.

Description

BIM-based smart safety management system and its control method {SAFETY MANAGING SYSTEM BASED ON BIM MODELING TECHNOLOGY AND METHOD FOR CONTROLLING THE SAFETY MANAGING SYSTEM}

The present invention relates to a safety management system using BIM for controlling safety-related information at a construction site and a control method thereof.

As predicted in 「The Third Wave」 by futurist Alvin Toffler, IT (Information Technology) technology plays a role in determining the competitiveness of companies in the modern industrial field. The remarkable development of the overall industry, such as manufacturing, cannot be explained without IT technology, such as communication technology and automation technology.

The construction industry is no exception to this trend, and it is clear that the construction industry is changing and developing efficiently through the application of IT technologies such as ‘electronic procurement system’ and ‘construction management system’. However, unlike the manufacturing industry, the construction industry has many IT technologies such as construction CALS, CIC, U-CITY, PMIS, and RFID that have been tried so far because of the one-off production method, multi-step production process, and labor-intensive production characteristics. can't Due to the lack of active use of IT technology, the productivity of the construction industry is rather retreating compared to the past, and the gap with the manufacturing industry is gradually widening.

In general, BIM (Building Information Modeling) began in 1975 when Charles M. Eastman of Carnegie Mellon University used the term Building Description System through “The use of computers instead of drawing” thesis, and this name is It was understood as the concept of an integrated database, and in the United States, the concept of BIM was completed while using the term Building Product Models until the mid-1980s. During this period, software that can execute the BIM concept was developed and became the basis for development. And starting with the formation of buildingSMART and the development of international standards in 1994, about 20 years ago, the term BIM was established and has continued to this day.

Building Information Modeling (BIM): BIM is a technology that produces and manages all information applied to various fields throughout the life cycle of a building. It is a three-dimensional object that aims to improve collaboration, communication, and information compatibility among participants. oriented modeling. BIM is a technology that produces and manages all information applied in various fields throughout the entire life cycle of a building, from the initial concept design to the maintenance stage. can be utilized BIM is a technology that shapes objects (walls, slabs, windows, doors, roofs, stairs, etc.) in 3D and includes information on each attribute (function, structure, use, etc.) in 3D objects to provide more systematic construction information. It is a skill that can be managed. In addition, since information such as characteristics, relationships, and constraints between objects is obtained by simulation or calculation using model data, it is regarded as a rich model and enables design automation.

On the other hand, recently, Building Information Modeling (BIM) technology, which seeks to integrate information of the entire life cycle of a building through modeling, is receiving high attention. BIM is in the limelight as a way to meet the goals that the construction industry has pursued so far, such as increasing the efficiency of construction projects, promoting teamwork, reducing project costs, and shortening the construction period, all at once. The Public Procurement Service, which is at the forefront of applying BIM technology in Korea, has set the BIM application goals as business innovation, budget reduction, and design quality improvement, and has announced that it will apply BIM to all PPS orders from 2016. As a result, domestic construction companies and architectural design offices are greatly increasing their interest in BIM, and many projects are actually being built with BIM. The recently completed Dongdaemun Design Park is evaluated as a representative achievement through BIM design.

The latest BIM is that existing 2D and 3D architectural CAD tools have disadvantages such as drawing-oriented creation and inability to automatically change when design changes are made. Interconnection is possible, there are various performance analysis functions of buildings, and a lot of information about buildings can be stored. By utilizing these BIM functions, the application of BIM is spreading in Korea, centering on the architectural field. are doing

In addition, in the construction field, we are developing 5D BIM (Ssangyong E&C's construction cost management and construction company fund management through ERP system linkage) that can predict the project process while showing the required material and manpower input status, completion rate, input cost, etc. for each construction section. In the field of environmental facilities, we are developing BIM-based green design technology and evaluation tools (Virtual Builders) that reflect BIM eco-friendly design performance evaluation, eco-friendly certification and housing performance evaluation, and LEED certification.

In line with this trend, interest in improving the safety of construction projects using cutting-edge technologies such as IoT, big data, and BIM is rising. Need to develop integrated safety management technology using smart technology for customized safety management considering the characteristics of each participating entity (owner-constructor-supervisor) and object (manpower-equipment-temporary facility-structure) for domestic construction sites with high accident rates this is being revived

The present invention relates to the role and information process of BIM for controlling safety-related information at a construction site, and aims to provide a BIM-based smart safety management system and a BIM-based smart safety management system control method for controlling it. do.

The present invention relates to a worker state detection sensor unit accompanies one or more workers in a construction site and capable of obtaining work state information of the worker, and a worker state detection sensor unit capable of transmitting and receiving worker state information through communication with the worker state detection sensor unit. An information server, a BIM server containing construction BIM modeling information of a target building at the corresponding construction site, and interworking with the BIM server and worker status information server, and worker status information from the worker status information server and BIM modeling of the work site BIM-based including a safety management server that generates safety management information of the corresponding workplace by linking information, and a site manager terminal that receives workplace safety management information from the safety management server and enables monitoring of the safety management status of the workplace. Provides a smart safety management system.

In the BIM-based smart safety management system, a worker information transmission output unit accompanying one or more workers at a construction site is further provided, and when an abnormal state is detected in the workplace safety management information, the safety management server generates an abnormal alarm signal, The abnormal alarm signal may be transmitted to a site manager's terminal of the site manager and the worker information transfer output unit.

According to another aspect of the present invention, the present invention provides a worker state detection sensor unit accompanies one or more workers in a construction site and capable of obtaining work state information of the worker, and the worker state detection sensor unit and the worker state detection sensor unit and communicates with the worker's work state information. A worker status information server enabling transmission and reception, a BIM server including construction BIM modeling information of a target building at the construction site, and a worker status information server interworking with the BIM server and the worker status information server, and the worker status information from the worker status information server A safety management server that creates safety management information of the workplace by linking information and BIM modeling information of the work site, and a site that enables monitoring of the safety management status of the work site by receiving workplace safety management information from the safety management server A provision step of providing a BIM-based smart safety management system including a manager terminal, an abnormal state monitoring step of generating an abnormal alarm signal when the safety management server detects an abnormal state in the workplace safety management information, and the abnormal state monitoring step Provides a BIM-based smart safety management system control method comprising an abnormal state alarm step of transmitting and outputting the abnormal alarm signal from the safety management server to the site manager's terminal when an abnormal alarm signal is generated in .

In the BIM-based smart safety management system control method, the construction BIM modeling information includes temporary member modeling information for temporary members disposed in the construction site, and in the abnormal state monitoring step, the arrangement state of the temporary member in the construction site and the safety management server may compare with temporary member modeling information in the construction BIM modeling information.

In the BIM-based smart safety management system control method, in the abnormal state warning step, the safety management server matches the temporary member modeling information in the construction BIM modeling information to the temporary member in the monitored construction site, and in the corresponding construction site When it is determined that there is a need for information on temporary members, information on modeling temporary members in the corresponding construction site may be transmitted to the site manager terminal.

Through the BIM-based smart safety management system control method of the present invention, it relates to the role and information process of BIM for controlling safety-related information at a construction site, providing a BIM-based smart safety management system and providing 3-dimensional visualization of the work scope It is possible to significantly reduce the risk of field workers' safety accidents through modeling of temporary members, and promote smooth usability in the field through lightening of the system.

1 to 27 are diagrams illustrating the BIM-based smart safety management system control method of the present invention.

The BIM-based smart safety management system and its control method of the present invention is a BIM-based smart safety management system and its control method that can be directly used for safety management at construction sites where risks are always present, especially small and medium-sized construction sites where safety management supervision is practically weak. Provide control methods to ensure on-site performance of safety management supervision in the field.

The safety management information used in the present invention is data for safety analysis and is operated in conjunction with BIM. In addition, BIM can be utilized as a basic framework of information for effectively inputting, distributing, and outputting interlocked information.

First, the BIM modeling characteristics used in the BIM-based smart safety management system and its control method of the present invention are the characteristics of 3D and object-oriented modeling, parametric modeling, library, and LOD (Level Of Detail). to provide

In other words, BIM is a new technique of designing a 3D model of a building on a computer, just like making a real building. However, if the computer in the 2D drawing was a structure that could not distinguish the wall and the floor because it was only marked with a line or a list, in BIM, it is modeled as a recognizable object so that the computer can analyze the object data and distinguish it. That is, the information included in the objects of each building element used in the BIM of the present invention expands the range of functions as a tool that can be utilized in engineering aspects such as quantity calculation, process management, energy analysis, structural analysis, and legal review, After all, 3D object-oriented modeling can be said to be a key factor in providing information for various analysis and decision-making.

In addition, in the case of BIM used in the present invention, it can be expressed by parametric modeling. One of the greatest strengths of BIM is that it supports parametric modeling techniques. Parametric modeling refers to a modeling method in which a condition for establishing a relationship between objects is specified, and operation is performed according to the condition. For example, if you connect the level and height of a building, the height of the wall automatically changes when the value of the level changes. With this function, when there is a change in the floor height, all the wall heights of the floor can be modified only by modifying the level. In the conventional CAD design, each drawing, such as a floor plan, elevation, and cross-section, is created independently, and these drawings exist as individual data. , In the BIM of the present invention, when any one part of a building is changed, any one view is modified and immediately reflected in all other views related to it. With this feature of bi-directional compatibility, work time and design errors due to design modifications can be reduced, and the efficiency of drawing management can be increased.

In addition, in the case of the BIM of the present invention, a library is included, and the range of its usability is larger and wider than that of the 2D CAD. Since the characteristics of information utilization can be maximized by obtaining necessary design information such as material list, manufacturing information, and cost through the attribute information included in the library, the construction and utilization of the BIM library is a key basis for starting successful BIM utilization. Since the BIM library creates a three-dimensional shape based on a two-dimensional CAD file and contains a lot of information, it requires a high technical level and takes a lot of time. In the introduction of BIM, In order to increase the productivity of design work, building a rich and detailed library is required.

In particular, in the case of BIM of the present invention, LOD (Level Of Detail) refers to the level of detailed characteristic information. If the LOD is high, the details of the model are detailed, making the same shape as the actual construction, so it is very effective for quantity calculation, design accuracy, and constructability. However, if the LOD is set high for all models, too much time and effort are invested in the design, and the file size increases, which takes a lot of time for modeling.

In the following table, modeling levels according to LOD levels are exemplarily described.

LOD modeling level LOD 100 At the level of conceptual design, the shape, volume, and type of building are defined, and the area, height, volume, location, and orientation of the entire building are set. LOD 200 In the planning stage where the concept is materialized, the form, space plan and spatial relationship are defined, and the approximate gross floor area, building coverage ratio, floor area ratio, number of floors, floor height, main structure, skin structure, facility system, etc. are planned. LOD 300 A building system including specific facility elements is determined and all building elements are modeled. LOD 400 Model the size, shape, and quantity of all systems determined as a modeling step for actual construction. Model all elements such as details, members, structures, facilities, piping, and wiring related to construction, manufacturing, and assembly. LOD 500 The model of the LOD 500 stage is a completed model, and the modeling data is the same as that of the actual building, and includes overall maintenance, management and operation.

The BIM-based smart safety management system and its control method of the present invention summarize the main functions of BIM that can be applied to the safety management field as follows.

(1) Accurate design and visualization

The design through the BIM technique has high design accuracy because it reproduces the shape of the building and the interior space as it is in 3D. Errors such as interference that occur during design are easily derived and corrected at the design stage to improve the completeness of the design. In addition, the BIM model can easily see the state after completion in 3D, so the design contents can be naturally shared with project related parties. BIM makes it possible to reflect and evaluate the various requirements of the owner in the design, and to compare and evaluate various design alternatives. In this way, the improvement of communication can lead to clear communication and prompt decision-making, thereby minimizing design change factors that may occur in the construction stage.

(2) Continuity of information

The drawing information generated in the design stage contains information that can be utilized in the construction, operation, and maintenance stages, and as the work progresses, the data becomes more specific and abundant as each stage is performed. Since the main purpose of using BIM is to eliminate duplication of work and inefficiency between business stages by increasing information compatibility, information continuity can be said to be a major function of BIM. BIM can prevent trial and error due to lack of information and increase work efficiency by storing information in 3D modeling objects and continuing information at each stage such as project planning, design, construction, and maintenance.

(3) Cost management and quantity calculation (5D)

Quantity calculation refers to calculating the quantity of materials required for construction and the required amount of work in construction work. It can be defined as importing and calculating the quantity in connection with the corresponding details. As the model and quantity calculation details are linked, when a design change occurs, the quantity is automatically changed and additional quantity calculation work can be prevented.

(4) Construction management

It can be used in various ways in the process of establishing and reviewing construction plans due to its excellent 3D visual expression. Interference between work types can be adjusted, and process progress can be more easily grasped. For example, by utilizing BIM for temporary facility planning, etc., complex process problems in the field can be solved. In addition, by linking the work breakdown structure (WBS) of the schedule with model objects, it is possible to reduce many problems of scheduling errors by linking the schedule with a virtual construction site. In terms of quality, high design quality is directly related to high construction quality, and productivity can be greatly improved through rich 3D modeling and information. As the knowledge of experienced engineers is reflected in BIM, trial and error are minimized, and the 3D reinforcement drawing and steel assembly drawing can play a role in blocking construction errors by the constructor.

(5) Safety management

In the last 4 years (2010-2013), the total number of BIM-related applications in the construction field reached 449. By field, construction accounted for the highest portion at 44.8%, followed by design at 25.6%, safety at 16.0%, and eco-friendliness at 13.6%. While the construction sector showed a gradual upward trend, and the design/eco-friendly sector showed a decreasing trend, the number of applications for safety sector showed a high increase from 6.9% in 2010 to 20.8% in 2013. This means that BIM utilization technology is evolving from simply pursuing efficiency to reduce cost and period to disaster prevention and facility management that prioritizes safety.

(6) BIM adoption effect

Drawing-centered construction projects are evolving into a form of applying BIM through the introduction of 3D CAD. Design errors that may occur during design can be prevented by designing a virtual building in 3D with the same shape, structure, and size as the real thing on a computer. In addition, various information generated during the project can be utilized more efficiently. If we examine the effects of the introduction of each business entity for the projects to which BIM has been applied, it can be summarized as follows.

According to these systems and control methods, the client side is accompanied by the effect of identifying construction progress, securing design and construction quality, reducing construction cost, and efficient facility maintenance management, and the CM/supervisor side is accompanied by effects of design, construction quality management / interference review / ordering party and Utilized as persuasive data such as rental negotiations / Construction progress monitoring / Quantity calculation and construction cost analysis / BIM drawing review and efficiency of instructions are secured, construction error verification such as construction simulation and interference review due to 3D visualization from the contractor's point of view / Frame, reinforcing bar Interference review / quantity calculation using BIM / reduction of construction cost through reduction of construction errors and compliance with construction period / various information can be used for construction, and 3D design can be performed according to the BIM technique applied to some large projects, and it is efficient from the designer's point of view Design, eco-friendly design, design quality improvement, and various designs (atypical) can be provided.

Looking at the application status of BIM for safety management at home and abroad in terms of safety management, some efforts are being made to introduce BIM to the field of safety management both domestically and internationally, recognizing the importance of BIM in the field of safety management. However, there are no studies related to guidelines, work processes, and safety management BIM application policies to be applied to actual projects at the level of literature review or prior safety check using 4D simulation, which is at the level of possibility of being used in safety management. can do.

In order for the BIM of the present invention to be more systematically applied to the safety management field, first of all, it is necessary to prioritize the understanding of safety management contents based on the understanding of the BIM modeling informatization characteristics. In addition, in order to obtain the effect through the introduction of BIM in the safety management field, it should be accompanied by an integrated change in the organization, work process, and technology, not a simple change in design techniques. Therefore, in the present invention, we want to understand the overall situation of BIM and analyze the need to introduce BIM into safety management and control. Recognizing the importance of BIM in the field of safety management, some efforts are being made to introduce BIM into the field of safety management both domestically and internationally. However, there are no studies related to guidelines, work processes, and safety management BIM application policies to be applied to actual projects at the level of literature review or prior safety check using 4D simulation, which is at the level of possibility of being used in safety management. However, in order for BIM to be applied more systematically to the safety management field, it is necessary to prioritize the understanding of safety management contents based on the understanding of the BIM modeling informatization characteristics. In addition, in order to obtain the effect through the introduction of BIM in the safety management field, it should be accompanied by an integrated change in the organization, work process, and technology, not a simple change in design techniques. Therefore, in this study, it is possible to understand the overall situation of BIM and analyze the need to introduce BIM into safety management and control.

The BIM-based smart safety management system and its control bar of the present invention can analyze earthquake effects as a BIM application field in the safety field.

In other words, among the information necessary for safety evaluation against earthquakes, the general matters of a building include the number of floors, plan dimensions, height, structural type, use of the building, weight of the building, and seismic grade. Among them, the weight of the building cannot be calculated in the BIM program itself, but it is automatically calculated in the structural analysis program when the designed model is reflected in the structural analysis program. In addition, the user can directly input the seismic grade in the structural analysis program through the gross floor area and usage, which are information obtained through the BIIM design model. . Concrete strength and reinforcing bar strength of material strength and member strength can be entered into the program and can also be extracted. The seismic zone (region) of the seismic load can be displayed in the BIM software, and can be directly entered and checked at the same time as the location input in the environment setting. The ground type can be entered in the environment analysis setting, but the type is different from the ground type required for performance evaluation. As a result of the review, the load combination and torsional amplification factor could not be confirmed with the BIM program, but it can be overcome through the present invention.

The BIM-based smart safety management system and its control method of the present invention can analyze wind load. Information on the wind speed level analysis can be checked up to regional wind speed among the functions related to climate data in the BIM program. The classification of ground surface roughness can be input into a structural analysis program under the user's judgment through a 3D model or 2D model for which BIM design has been completed. While various studies are being conducted for smart city construction in Korea, attempts are being made to use BIM software. This study derives required information in the field of energy management and disaster and safety management, and can check the information derived from ArchiCAD, a BIM software. As a result of the analysis, it was found that energy-related information was generally easy to obtain, and among information for implementing disaster and safety management functions, information for evaluating structural safety against earthquakes and strong winds was relatively easy to obtain.

In addition, the BIM-based smart safety management system and its control method of the present invention can review evacuation safety laws and regulations. In order to carry out a construction project, it is necessary to review and comply with numerous relevant laws and regulations, such as quality, safety, environment, etc., from reviewing the legality of permits during design to construction, and these laws and regulations are constantly being revised and strengthened. Since it takes a lot of time to do this, accuracy is also difficult to guarantee. Accordingly, domestic and foreign public institutions developed an automatic review system for building-related laws based on 2D drawings in the 1990s, and recently, research using BIM, which is based on 3D objects, is being actively conducted, and information can be provided through the present invention.

In addition, the BIM-based smart safety management system and its control method of the present invention comprehensively review and analyze construction safety-related laws, define types that can automate laws and regulations, and manage various safety management contents that can occur in the construction stage. In accordance with the need to devise a plan that can be linked with BIM, the safety management checklist and safety regulation system are selected with a focus on enforcement rules and guidelines, and the information necessary for safety control is separately analyzed by comprehensively analyzing the conditions and instructions of the legal text. need to extract

The BIM-based smart safety management system and its control method of the present invention establish and provide a safety management control BIM information system. BIM modeling and construction It means BIM modeling capable of real-time searching for various real situations (real-time sensor information, worker information, equipment information, and other safety-related information) occurring during the construction process, and through this construction structure, the BIM-based smart of the present invention The safety management system and its control method can provide safety management contents collection visual integration database and safety management 4D simulation.

That is, the BIM of the present invention expresses information centered on a 3D object. Such BIM modeling includes existing construction site safety accident cases and statistical data, construction accident classification and accident type causal relationship information DB that occurred at existing construction sites, safety management database for disasters during construction, and object-based safety-related attribute information for safety management control BIM. It can include a system, etc., which can be databased as a BIM object or in the form of information linked to the object. This information can serve as a visual integrated database through the BIM library safety management attribute information or linkage of various safety-related information by work type, object, space, and worker. In addition, the present invention provides 4D simulation for safety management . Currently, 4D simulation is used in the industry in connection with 4D CAD in an effort to improve the efficiency of work between each process, such as interference check in the construction stage. 4D simulation is a communication tool that broadens the understanding of the process among participants, and is used in various ways as process analysis and conference data. However, it is merely a visual expression, and is not used for efficient work such as shortening work time. 4D simulation used for construction stages and process meetings can also be applied to the field of safety management. An understanding of not only the process, but also the performance of other work teams can greatly contribute to improving safety. Through 4D simulation, it can be used in various fields of safety management by not only mutual understanding of safety matters in advance, but also checking interference between work types, between work spaces, and between workers. However, rather than just being used as a visualization tool, a methodology for improving safety management, which is the original purpose, should be developed. To this end, regulations on 4D simulation-based safety management operation methods and processes, and roles and responsibilities of participants should be defined first. The BIM 4D simulation function can be used to establish and change safety management plans in advance according to the process plan. In addition, the safety management status real-time monitoring interface of the present invention can serve as an interface for expressing various sensors installed in the field, CCTV information, real-time worker location and ecological information equipment location. Depending on the design information, each floor can be activated through cross-section, elevation, or perspective view, and various information related to the worker can be acquired by clicking on the worker associated with the BIM. In addition, through the role of a comprehensive database, it is possible to identify risk factors by object, risk factors by space, and risk factors by work type in real time, and it is possible to install a function that can notify workers adjacent to risk factors of a danger sign. In addition, the present invention It can provide analysis of safety management Digital Twin status , and it can play a role in contributing to control of dangerous situations, environments, and actions, as well as comparative analysis of real-time CCTV screens and BIM-based digital virtual spaces.

The BIM-based smart safety management system and its control method of the present invention can provide 4D simulation-based safety simulation, and as a way to utilize process 4D simulation for safety meetings, understanding of the process, types and cases of safety accidents that may occur in the process plays a role in pre-checking the Accidents and disasters can be reduced by allowing workers to understand their own work as well as the work of other subcontractors, and by recognizing safety accidents with high frequency during the process in advance, wrong and unsafe actions and situations can be prevented in advance. can

In addition, temporary facilities such as temporary scaffolding, temporary fence, horse scaffolding, and moon scaffolding through the temporary construction and temporary facility operation plan of the BIM-based smart safety management system and its control method of the present invention fall accidents, jamming, and constriction due to high-altitude work It has a close relationship with safety accidents. It is possible to grasp the installation and operation conditions of temporary facilities in advance, to grasp related safety and accident-related information in advance, to build safety management contents related to temporary facilities in the BIM library in advance, and to utilize them in the field operation stage to prevent accidents related to temporary facilities. can be prevented in advance.

In addition, the BIM-based smart safety management system and its control method of the present invention enable the provision of appropriate information to the site constructor, site supervisor or safety manager through information loading using the information of the safety management plan. Each professional construction company attaches a safety management plan when preparing a construction plan, and uses the expected major risk points, accident prevention measures, and other related photos as BIM safety management contents, and the details are used for safety management control. Accessibility to safety-related information can be improved by embedding it in BIM.

In addition, the BIM-based smart safety management system and its control method of the present invention is capable of extracting safety-related statistics and numerical data, and by linking the statistical and numerical data related to construction safety with object and spatial information of BIM, it is expressed as a graph. Safety-related information can be communicated effectively.

In addition, the BIM-based smart safety management system and its control method of the present invention can provide a safety management checklist, present guidelines for performing construction safety management tasks, link worker location and biometric data to control system data, and physically fatigue , mental fatigue, stress, etc. affect a person's attention, arousal, response to hazards, and thinking ability, and as a result, the degree of perceiving risk or the degree of risk identification of the hazard It is possible to extract and analyze the physical response of construction site workers according to their activity energy, fatigue, etc. and signal characteristics closely related to it. By measuring and defining standard activity sets for each detailed work unit, it is possible to collect operation signal data in standard state and operation signal in abnormal state. The collected data can provide an algorithm that can automatically monitor workers' anomalies through a machine learning process that extracts/classifies signal characteristics.

That is, in order to measure the physical activity of workers, it is possible to collect information from accelerometers (3-Axis Acceleration), which is a measurable motion signal from mobile devices, and analyze patterns according to differences in movement according to workers' movements to capture differences in patterns. Based on the designed model, the work performed in the actual field is performed in a laboratory environment (simulated field) by extracting and classifying the signal characteristics that can be detected, and conducting an experiment to measure the physical activity state of workers based on the designed model. Collects signals related to changes in energy, amount of energy, and stress. In order to identify signs of safety accidents based on workers' motion signals, as shown in the figure below, risk awareness and risk perception are analyzed, and motion signal-based activity state measurement models are verified/corrected to determine the level of risk to individual workers in advance. can In BIM for control, each worker's location can be monitored in real time, and the individual's risk level can be displayed using the worker's biometric data.

In addition, the BIM-based smart safety management system and its control method of the present invention link equipment location and action radius data with control system data, and link sensing data and CCTV with control system data, enabling monitoring to cope with safety accidents.

The BIM-based smart safety management system and its control method of the present invention provide a BIM information linkage method for smart safety management control, and the BIM for smart safety management control is first expressed with BIM model utilization risk site information. In other words, by expressing areas with high frequency of safety accidents in BIM, risk factors and countermeasures for each member can be linked to a database. As such, it is possible to access safety-related matters more easily by utilizing BIM according to the characteristics of the facility and the applied method.

Then, temporary member modeling is executed. At this stage, it is common to not express temporary members in design BIM and construction BIM, but most safety accidents are related to temporary members (temporary fences, retaining walls, various scaffolding, etc.). Therefore, BIM for efficient safety management control must be able to express temporary members.

The present invention utilizes the 3D visualization function of the work scope, and structures in the construction industry are completed through cooperation in various specialized fields. It is possible to perform safe work with a sufficient understanding of the work by the operator by discharging the function.

In addition, the BIM-based smart safety management system and its control method of the present invention executes a pre-check for safety check items using the 4D Simulation function. By examining process simulations such as schedule and execution, and realizing the progress of the structure over time in advance, it is possible to identify the process status and delayed processes. You can improve your understanding of safety issues and check safety-related matters in advance.

In addition, the BIM-based smart safety management system and its control method of the present invention executes an interference review using the BIM Clash Detection function, and since all drawings are generated consistently in the 3D virtual building model, Design errors can be found, physical interference between multiple systems as well as free space interference can be systematically reviewed, and other errors can be easily reviewed visually. It is possible to perform tasks such as interference review by work type and work space, which are useful for

In addition, the BIM-based smart safety management system and its control method of the present invention can significantly reduce the risk of safety accidents by linking Game Engine technology-introduced worker and equipment avatar information to enable pre-work checks in a virtual environment for workers. can

The BIM-based smart safety management system of the present invention has a smart safety management control BIM construction and operation process. First, risk factors and risk evaluation content securing technology, second safety management control BIM technology, and third smart safety control technology 3-step technology are separated by Based on the project and design information, the relevant accident case database is analyzed and the WBS-based safety management DB is extracted.

That is, the present invention sets the basic direction for constructing a BIM model including safety management contents by arranging object-based data and linking it to a library. BIM modeling is performed based on design drawings, and safety-related information that is difficult to include as objects can be implemented as spatial objects or 4D process simulations.

In the implementation of these systems, BIM models generally occupy a considerable amount of data, although there is a large variation depending on LoD for expressing detailed information depending on the scale. Therefore, a lightweight process is required, and the lightweight BIM serves as an interface for real-time linkage of the location of workers on site, sensor information, and CCTV information. It can be called a role BIM model, and in order to implement it, BIM lightweight algorithm development for safety management control is performed.

That is, BIM model shape data requires a lot of computing resources, such as rendering, visualization, cross-section extraction, and calculation of numerous objects. As a result, the shape data size has a physical free memory limit, and it is expected that it will take a considerable amount of time to download the data, especially when visualizing large-capacity BIM data on a network with a small bandwidth. BIM technology goes beyond the existing 2D-based drawing process and includes data that occurs throughout the life cycle of facilities through 3D modeling. In IFC, as an example, there are often issues with large-capacity processing including considerable data based on object-based shape information and attribute information, which increases rendering speed and takes up a lot of graphics card capacity, so screen visualization Inefficient in terms of The problem of lightweighting of large-capacity data must be essentially solved in terms of program process and quality. In addition, the BIM-based smart safety management system and its control method of the present invention include a lightweight algorithm development structure for smooth control of safety management information. 3D facility information software related to BIM and IFC (Industry Foundation Classes) models currently in use is used as a local computing environment operated on individual PCs. That is, the conventional BIM-based collaboration system uploads a model created in a specific terminal to a server and allows other terminals accessing the server to confirm it. When you want to deliver comments to a collaborator in relation to the model, the model is converted into a PDF type. There is the hassle of having to write and deliver comments on a PDF document after writing a document such as a document such as a PDF document, etc., and there is a problem of not being able to efficiently utilize a 3D model. Due to the difficulty of exchange, it is difficult to efficiently manage the entire project and the efficiency is reduced. In order to spread and expand the use of BIM software, many small and medium-sized construction companies can utilize the existing local computing environment at an appropriate level of initial investment cost. The need to develop technology that can utilize BIM software at low cost is emerging, but the present invention utilizes an advanced Internet environment and cloud computing technology to implement a light and fast BIM model implementation method for implementing a specific purpose among general-purpose functions of existing BIM software run In other words, in BIM lightweight implementation, numerous objects constituting the BIM model are composed of shape and attribute information, and attribute information is composed of text and numbers, so the data capacity is not so large compared to the shape, and the shape is a number of solid and mesh data, and a number of coordinates included in the mesh data are real data, and one coordinate value occupies at least 24 (8-byte double-precision real number x, y, z) bytes, and the shape is only solid information itself. However, it contains a lot of mesh data for visualization. Mesh data is again composed of a lot of triangles, vertices and edge information. For this reason, if a memory problem occurs when calculating a large-capacity BIM model, it is usually a case where physical memory is insufficient while processing shape information. If expressed, the physical memory must have at least 1.96GB to be able to be calculated on the memory, and it can be largely divided into a mesh simplification method (compression, division, etc.), an external memory reference method, and a hard disk storage method. It can be implemented as a mesh simplification methodology. In other words, in a large-capacity 3D mesh, an OcTree is created from a 3D point cloud by dividing the number of points included in each partition equally, using a DB or storing point cloud data in a hard disk file instead of in the main memory. way of direct reference. Generalize the shape according to the unit by utilizing the 3D block cell technique composed of identifiable building objects with geometry information, infrastructure elements with facade textures, and non-building areas with polygons. It is also possible to simplify 3D building data by simplifying all orthogonal building structures according to one process and moving them in parallel until the building shapes are merged according to the LOD. In addition, the present invention executes a method of equally dividing the number of points of a large-capacity 3D mesh to perform both remote rendering and local rendering using the characteristics of a mobile system so that the number of points included in each partition is equal in the large-capacity 3D mesh. An identifiable building object with geometry information is created by creating an OcTree from a 3D point cloud, storing it in a hard disk file without using a DB or storing point cloud data in main memory, and directly referencing them. , infrastructure elements with façade textures, and generalized shapes according to units by utilizing the 3D block cell technique composed of non-building areas made of polygons, simplifying all orthogonal building structures according to one process, and building shapes according to LOD. It is also possible to use a method of simplifying 3D building data by moving them in parallel until they are merged. In addition, depending on the case, a cache calculation method can be executed. The cache method is calculated on the assumption that only the number of vertices of a hexahedron, that is, six data, is managed by focusing on shape data among BIM data. The cache uses a Spatial Index File that supports spatial indexing to quickly retrieve objects to be used for rendering and computation. Spatial Index File operates based on Octree and constitutes a Spatial Node. Spatial Node manages the area where objects are included in the space, divides and manages the lower 8 spaces, and constructs a spatial lattice tree. Spatial Node of each spatial grid manages Spatial Object Handle indicating object information. Cache Object maintains a handle that can access BIM object data. Cache Handle is a handle to the cache object managed by the cache, and through this handle, the stored BIM shape data file is accessed. If shape calculation is needed, data can be loaded into physical memory through this handle and unloaded when the calculation is finished. The handle of the BIM shape data stored in the cache determines when to load the corresponding shape file into memory according to the cache memory loading policy.

In addition, in some cases, a hard disk storage method may be executed, and a DB is used to create an OcTree from a 3D point cloud, or point cloud data is stored in a hard disk file without being stored in the main memory and directly referenced to memory. It can be analyzed by comparing the reference method and the file reference method.

In addition, a method of extracting large-capacity 3D object shape information as Xml data may be executed. In order to utilize large-capacity BIM data on a network with insufficient physical memory or low bandwidth, only data necessary for BIM shape rendering and calculation is extracted, and in advance This is a method that automatically adjusts the object's head and height according to the defined logic. A methodology of processing BIM modeling information as metadata (text data), extracting information, and building a separate 3D shape model can be utilized. That is, it can be said to be a method of generalizing the shape according to units by utilizing a 3D block cell technique consisting of an identifiable building object with geometry information, an infrastructure element with facade texture, and a non-building area made of polygons. To this end, it is possible to define a minimum LoD for implementing cloud BIM functions and extract a model at a level suitable for this.

In particular, in the BIM lightweight technology for smart safety management control of the present invention, BIM model shape data requires a lot of computing resources such as rendering, visualization, section extraction, and calculation for numerous objects. In the case of cross-section extraction, the size of the shape data is limited by physical free memory as a method of real-type geometric intersection calculation with a large number of objects loaded on the memory, especially when large-capacity BIM data is visualized on a network with a small bandwidth It is expected that it will take a considerable amount of time to download. Therefore, it is necessary to develop a lightweight algorithm for smooth control of safety management information. 3D facility information software related to BIM and IFC (Industry Foundation Classes) models currently in use is developed and used as a local computing environment operated on individual PCs. Due to the nature of 3D facility information software, a high price and a high-end PC environment are required, so the initial cost is a big burden. Therefore, in this study, we implement lightweight technology for safety management control BIM optimized for safety management control and network environment. include the method

In other words, the original BIM modeling is considering a method of extracting and communicating only the shape model by utilizing modeling including safety management contents and metadata extraction methodology, and LOD 50 level from the LOD 300 model consisting of the building envelope without openings. The weight reduction was carried out by extracting the model. By minimizing the BIM data capacity, it is possible to maximize the advantage of being able to build modeling suitable for control.

However, it may cause some inconvenience in having to check the BIM safety management contents in the BIM model. It can be divided into safety management BIM and safety control BIM. The methodology for this can be used, and the latter serves as an interface for field situations (detection of real-time location of workers and access to dangerous areas, real-time location of equipment and proximity to dangerous areas, linkage of on-site sensor information, linkage of CCTV information).

In particular, the present invention carried out the process of developing a lightweight algorithm for BIM for safety management control, building a lightweight algorithm system for BIM for safety management control (prototype), and testing the BIM model lightweight level, as shown in the drawing. They are named Rapid BIM (fast and lightweight BIM), and the process to implement this is Revit file open >> Run Ad-on Program >> Export to external xml file (whole layer) >> Open xml (Notepad) >> Lightweight Viewer uBuilder Execute .exe >> Lead file (all) >> space xml select >> It can be executed through the process of navigating the layer and area to be controlled.

In particular, reviewing the safety control BIM lightweight level, it was confirmed that the capacity of the existing BIM model was 19,550,208 bytes, and the lightweight model was reduced by 27.8 times to 702,300 bytes. This lightweight model developed an algorithm only for the shape of the structure, and the weight reduction ratio may be reduced in order to reduce the weight of temporary members essential for safety management or safety-related members to a level that can be distinguished.

Claims (5)

A worker state detection sensor unit accompanying one or more workers in the construction site and capable of acquiring work state information of the worker;
A worker state information server enabling transmission and reception of worker state information through communication with the worker state detection sensor unit;
A BIM server containing construction BIM modeling information of the target building at the construction site;
A safety management server that interworks with the BIM server and the worker status information server and creates safety management information for the workplace by interlocking the worker status information from the worker status information server and the BIM modeling information of the work site;
A BIM-based smart safety management system including a site manager terminal capable of monitoring the safety management status of a work site by receiving workplace safety management information from the safety management server. According to claim 1,
A worker information transmission output unit accompanying one or more workers at the construction site is further provided,
When an abnormal state is detected in the workplace safety management information, the safety management server generates an abnormal alarm signal,
BIM-based smart safety management system, characterized in that for transmitting the abnormal alarm signal to the field manager terminal of the field manager and the worker information transmission output unit. A worker state detection sensor unit accompanies one or more workers in a construction site and capable of acquiring work state information of the worker, and a worker state information server enabling transmission and reception of worker state information through communication with the worker state detection sensor unit; A BIM server containing the construction BIM modeling information of the target building at the construction site, interworking with the BIM server and worker status information server, and interlocking worker status information from the worker status information server and BIM modeling information of the work site A BIM-based smart safety management system including a safety management server that generates safety management information of the corresponding workplace, and a site manager terminal that receives workplace safety management information from the safety management server and enables monitoring of the safety management status of the workplace. A providing step of providing a;
An abnormal state monitoring step of generating an abnormal alarm signal when the safety management server detects an abnormal state in the workplace safety management information;
BIM-based smart safety management system control characterized in that it comprises an abnormal state alarm step of transmitting and outputting the abnormal alarm signal from the safety management server to the site manager terminal of the site manager when an abnormal alarm signal is generated in the abnormal state monitoring step. method. According to claim 3,
The construction BIM modeling information includes temporary member modeling information for temporary members disposed in the construction site,
BIM-based smart safety management system control method, characterized in that in the abnormal state monitoring step, monitoring the arrangement state of the temporary member in the construction site and comparing the safety management server with the temporary member modeling information in the construction BIM modeling information. According to claim 4,
In the abnormal state alarm step,
The safety management server
When the temporary member in the monitored construction site matches the temporary member modeling information in the construction BIM modeling information and it is determined that there is a need for information on the temporary member in the construction site, the temporary member modeling information in the corresponding construction site is transmitted to the site manager terminal. BIM-based smart safety management system control method, characterized in that for transmitting.

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