Rozvoj zručností pre prevenciu bezpečnostných rizík výstavby prostredníctvom nástrojov na báze BIM
Zuzana Struková, Mária Kozlovská
Technical University of Košice, Faculty of Civil Engineering, Institute of Construction Technology and Management, zuzana.strukova@tuke.sk, maria.kozlovska@tuke.sk
Abstract
Although there is a clear improvement on the safety performance in construction sector, it is still a high risk occupational area and suffers from very high accident rates. One of the most effective ways to improve health and safety conditions in construction sites rests in sound education of people incorporated in construction planning, managing or executing. In our region, the creative approaches are essential to encourage new methods to teach health and safety in a stimulating way. The potential of digital technologies widely used in designing buildings for creation of design/construction visualization tools focused on design for construction safety implementation is discussed in the paper. There is also presented the educational program centred on development of construction safety awareness through unconventional teaching techniques. It is addressed particularly to designers or future designers and is focused on implementation of Prevention through Design concept and so is aimed at designers’ safety education especially through the supporting tool developed on building information modelling (BIM) platform.
Keywords: construction, safety awareness, safety education, prevention through design, occupational safety
Abstrakt
Aj napriek neustále sa zlepšujúcej úrovni bezpečnosti práce na staveniskách, stavebníctvo stále patrí k vysoko rizikovým odvetviam z pohľadu pracovných podmienok a má jednu z najhorších bilancií z hľadiska pracovnej úrazovosti. Jedna z najefektívnejších metód zlepšovania stavu bezpečnosti a ochrany zdravia pri práci na staveniskách spočíva v dôkladnom vzdelávaní osôb, ktoré sa podieľajú na príprave, riadení a realizácii stavebných projektov. U nás je nevyhnutné presadzovať tvorivé prístupy, podporujúce nové stimulujúce metódy výučby v oblasti bezpečnosti práce. Príspevok poukazuje na potenciál digitálnych technológií, dnes využívaných pri navrhovaní stavieb, pre ich využitie pri tvorbe tzv. vizualizačných nástrojov prispievajúcim k implementácii konceptu prevencie prostredníctvom návrhu v stavebnej praxi. Zároveň je v príspevku prezentovaný vzdelávací program vytvorený s cieľom zvyšovania povedomia v oblasti bezpečnosti práce pri výstavbe prostredníctvom nekonvenčných výučbových metód. Zameriava sa najmä na projektantov a budúcich projektantov. Vzdelávanie prebieha najmä za podpory nástroja vybudovaného na platforme BIM, umožňujúceho prevenciu bezpečnostných rizík výstavby vo virtuálnom prostredí modelovania stavby, čo má významne prispieť k implementácii konceptu prevencie prostredníctvom návrhu v stavebnej praxi.
Kľúčové slová: výstavba, povedomie o bezpečnosti, vzdelávanie v oblasti bezpečnosti, prevencia prostredníctvom návrhu, bezpečnosť pri práci
According to the International Labour Organization, the construction industry almost in the world over accounts for a disproportionate number of occupational related injuries and still remains one of the most physically demanding and risky occupational areas. Although there is some improvement on the health and safety performance in construction sites in recent years. In European Union, the construction sector is one of the largest industrial employers, encompassing more than 2,4 million enterprises and approximately 14 million employees (Goulding and Arif, 2013). Unfortunately, it also has almost the most problematic occupational safety and health records. For an example, from the year 1992 till 2010, there have been recorded more than three hundreds fatal injuries occurred at construction sites in Slovak Republic (Labour Office database on labour statistics, 2013).
The construction as a project based industry exists in a dynamic and changing environment. The poor health and safety records in construction are influenced by many factors. As well, it is definitely concerned the low level and absence or malfunction of safety management and control systems in small construction companies and tradesman and low knowledge and a lack of construction safety risk awareness of persons involved in construction projects.
Many different approaches to safety should be implemented to achieve the goal of fewer injuries. Work-related injuries are often associated with insufficient knowledge and unsafe behaviours of construction workers as well as all other participants of construction projects. One of the most effective ways to improve health and safety conditions in construction sites rests in responsible development of construction safety risks awareness and sound education and training of people incorporated in construction projects planning, managing and executing. Training and education programs play a significant role in enhancement of safety in construction and are important to increase safety awareness (Ghani et al., 2010) and change behaviour of persons involved in construction projects.
Almost all injuries in the sites are predictable and preventable. According to Toole and Gambatese (Toole and Gambatese, 2008), the ideal situation for the safety of the construction workers is to make this an important parameter for the planners and designers of the conceptual and preliminary design phase.
The fundamental principles of safe buildability are among others described in the following manner (Baxendale and Jones, 2000):
Addressing construction worker safety and health in the design of a project, also referred to as Prevention through Design (PtD) and designing for construction safety and health, has been slowly recognized and applied in the USA over the past ten years (History of PtD, 2013). Several research studies have identified the design aspect of projects as being a significant contributing factor to construction site injuries.
Prevention through design in construction implies:
The European Union have appreciated the beneficial impacts of PtD in construction and is leading the way through European Union (EU) directive - Council Directive 92/57/EEC of 24 June 1992 - concerning minimum demands for health and safety at temporary construction sites. In the directive, the role of the building planner, be it the client as well as the architects and designers, is emphasized as having the responsibility for taking account of the general principles of prevention concerning safety and health during the stage of designing and preparing the project. The Slovak Republic adopted the mentioned directive; now it is represented by the Regulation of the Slovak Republic Government no. 396/2006 Coll. on minimum safety and health requirements of construction sites.
Indeed, not all of the prevention principles are relevant to what a designer can do, but it would appear correct that a designer should as far as reasonably practicable:
Unfortunately, the idea of workers safety consideration in designing phase of construction projects often remains only at the level of legislation article and its implementation in construction practice is rare. Most designers use to make rarely decisions pertaining to construction worker safety. They declare their responsibility only for the final product and no for means and methods affecting the workers safety.
The cardinal barriers to PtD implementation in construction practice, identified by the worldwide propagators of the concept, involve in particular (Gambatese, 2012):
Development of design engineer experience and training from occupational safety point of view and creation and application of design/construction visualization tools are thought to be the most distinguished enablers to PtD implementation.
As digital technologies become widely used in designing buildings, questions about their impacts on construction safety arise. Architects and contractors use many computer tools for tasks related to 3D visualization, constructability reviews and digital fabrication which have potential to be used for purposes of occupational safety improvement by design. Several researchers have developed a variety of new tools for use in construction design and execution phase to help contractors achieve safety in their projects (Zhou et al., 2012). Digital technologies are noticeably applied in these tools for construction site risk prevention and safe project delivery. The digital technologies involve in particular:
A key objective of Building Information Modelling (BIM) is to make construction processes more predictable and efficient via increased visual communication and removal of uncertainties at start of the construction process, thereby improving safety and predictability of construction. BIM is seen as a tool to achieve the goals of Virtual Design and Construction. Early involvement of key project stakeholders by BIM ensures that problems are resolved early in the project life-cycle when costs of any changes are minimal. BIM has the potential during early design phases and during construction to reveal situations that involve risk management attention and provides the possibility for designers to conceive hazard recognition during design and provide this information to constructors. The visualization offers a totally new tool for risk assessment, planning, introduction and safety management. The BIM models created in the design process can be developed to serve site and safety planning by adding the planned temporary site and safety arrangements to the model created in the architectural design or structural engineering stages.
There are case examples of BIM that show applications for planning, scheduling, improved conflict control, and hazard recognition in buildings. The most known are the BIM based safety management and communication system, developed by VTT Technical Reseacrh Centre of Finland (Sulankivi et al., 2010) and the automated rule-based safety checking system on BIM platform, developed by researchers from USA and Republic of Korea (Zhang et al., 2013). The first mentioned research aimed to develop and test solutions for the planning and management of construction site safety using dynamic 4D site models and so revealed possibilities for improving construction safety using commercially available BIM tools as Tekla Strucutres, ArchiCAD and Revit. In the Fig. 1 is presented an example of custom components created for site layout planning, as it was developed during the system testing by some real case studies.
Figure 1: Example of BIM Safety custom components for site planning (Sulankivi et al., 2010)
As a result of the testing, a BIM based 4D safety railing demonstration has been created (Fig. 2).
Figure 2: The 4D safety railing visualization as part of precast element erection visualization (Sulankivi et al., 2010)
Tasks corresponding erection of precast elements and related safety railings were created into a task list in the task manager - tool. Then the tasks were scheduled and linked with the corresponding parts in the model. After creating suitable visualization rules, it became possible to visualize project status on any selected review-date on the planned time scale.
In our country, only students of construction technology and management field of study attend the course intent on construction health and safety knowledge. There is the absence of safety education and training of future architects or designers. The creation of suitable supporting tools focused on effective development of skills for early detection of construction safety risks in the design stage and consistent revision of the design solutions or protection equipment planning is inevitable. In our faculty, this need is going to be satisfied by development of the multimedia educational program centred on implementation of PtD concept through increasing the designers’ construction safety awareness. The materials of the mentioned educational program will be convenient for construction safety skills and competences development through lifelong education of practicing designers, as PtD education efforts should cover not only university education but also continuing education. The main objective of the program consists in integration of construction safety risks issues into education centred on buildings design. The educational program is developed as the multimedia-based interactive source for e-learning.
In our virtual laboratory, equipped by high-efficiency computers including right software available for various approaches to construction projects design, operative planning and management, are created good conditions for application of digital design technologies to enhance designers’ skills for PtD implementation. For example, Tekla Structures, Autodesk Nawisworks, Revit, 4D Google SketchUp, Solibri Model Checker, etc. (enabling 3D coordination, 4D planning, photorealistic visualization, dynamic simulation and accurate analysis) suit to creation of tools for automated detection and elimination of construction safety risks in designing stage. Such tools can present the base for designers training through unconventional teaching techniques in order to increase their awareness for implementation of PtD concept.
In order to realize the mission of designers safety awareness increase, the program involves several partial objectives, among those belong:
The mentioned objectives of the educational program are going to be reached by multimedia file of educational sources involved in the program. These sources support the performance of the developed program idea. The multimedia-based files of educational sources include:
The most meaningful benefit of the program for our faculty consists in creation of educational material (sources) and methods centred on designers training and education from occupational safety risks elimination point of view. Digitalization and accessing of these teaching aids is going to support the presentation as well as the distance form of learners’ education.
Conventional safety practices have held designers responsible for safety of the end-users, and considered constructors responsible for the safety of construction workers. With Prevention through Design concept, designers and constructors can work together to enhance construction workers’ safety early in the design phase. But, no or minimal construction site safety in designer education and training and lack of knowledge of how to design for safety belong to the most meaningful barriers to implementation of PtD concept. In the paper is discussed the educational program centred on development of construction safety awareness through unconventional teaching techniques. It is addressed particularly to designers or future designers and is focused on implementation of well known concept of PtD. The skills development through the program is based especially on the supporting tool, developed on building information modelling platform, aimed at effective education for detection of construction safety risks through virtual building modelling and for relevant building design revise or protective equipments planning.
The authors are grateful to the Slovak Grant Agency for Science (Grant No. 1/0840/11 Multi-dimensional approaches supporting integrated design and management of construction projects) for financial support of this work.
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Vzorová citace
STRUKOVÁ, Zuzana; KOZLOVSKÁ, Mária. Skills development for construction safety risks prevention through BIM based tools. Časopis výzkumu a aplikací v profesionální bezpečnosti [online], 2013, roč. 6, č. 3-4. Dostupný z WWW: <http://www.bozpinfo.cz/josra/josra-03-04-2013/bim.html>. ISSN 1803-3687.