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I am Mohammad Maliha, I graduated from the Faculty of Civil Engineering in only four years as the first graduate among my colleagues and I hold a diploma in managing institutions and civil society organizations in addition to a master's in engineering projects management. Also, I obtained PMD Pro1, PMD Pro 2 and FMD Pro certificates. I have worked as a site engineer and supervision in several engineering offices and then worked with NGOs institutions in the field of relief as a field coordinator and then as a Projects coordinator and after that as senior assistant project manager.
The Architecture, Engineering, and Construction (AEC) industry is one of the most dangerous industries due to its unique nature. Safety is a critical issue in developed and developing countries. The main objective of this paper was to identify and classify the barriers that hinder the implementation of safety in projects and ways to improve safety performance. The method used in this paper includes a heavy review of many sources related to the safety barriers in the AEC industry, including a process of identification and classification of these barriers, after which we discuss the most popular methods between them, based on the appearance of it in the sources which were reviewed. Then, the ways to improve safety performance were viewed in AEC industry. Based on that, it was found that there are the following 4 categories associated with safety barriers: (1) Behavior Barriers; (2) Management Barriers; (3) Awareness Barriers; and (4) Culture Barriers. At the same time, the most popular barriers are based on appearance in sources: lack of safety training, lack of commitment, work pressure is high when deadlines are approaching, and low level education, lack of experience, and lack of knowledge. The many ways to improve safety performance are illustrated in the end of this paper. The results of this paper show the importance of safety and that the actual safety of the projects should be focused on in order to reduce injuries, accidents, and reduce barriers of applying safety, which will enhance the sustainability and development of safe environments within in AEC industry.
Mohammed Maliha; Yazan Abu Aisheh; Bassam Tayeh; Ali Almalki. Safety Barriers Identification, Classification, and Ways to Improve Safety Performance in the Architecture, Engineering, and Construction (AEC) Industry: Review Study. Sustainability 2021, 13, 3316 .
AMA StyleMohammed Maliha, Yazan Abu Aisheh, Bassam Tayeh, Ali Almalki. Safety Barriers Identification, Classification, and Ways to Improve Safety Performance in the Architecture, Engineering, and Construction (AEC) Industry: Review Study. Sustainability. 2021; 13 (6):3316.
Chicago/Turabian StyleMohammed Maliha; Yazan Abu Aisheh; Bassam Tayeh; Ali Almalki. 2021. "Safety Barriers Identification, Classification, and Ways to Improve Safety Performance in the Architecture, Engineering, and Construction (AEC) Industry: Review Study." Sustainability 13, no. 6: 3316.
Background: The Architecture, Engineering, and Construction (AEC) industry is one of the sectors that contribute the most to the Palestinian economy. However, it now suffers from many problems, one of which is not adopting new innovations, such as Building Information Modeling (BIM). BIM recently achieved far reaching consideration in the AEC industry. Aim: This research aimed to understand the contribution of BIM to the enhancement and application of Knowledge Areas (KAs) in the AEC industry in Palestine. Methods: A quantitative survey was utilized in the pilot study. Thirty copies of the questionnaire were dispersed to respondents from the target group. The completed questionnaires were analyzed to test for statistical validity and reliability. After the pilot study, the questionnaire was validated and dispersed to the entire sample, comprising respondents from the target group who were selected by convenience sampling. Eighty copies of the questionnaire were dispersed, and 71 copies of the questionnaire were obtained from the respondents with a response rate of 88.8%. Results: To draw meaningful results, the gathered information was analyzed by utilizing quantitative data analysis techniques, including the RII, Pearson correlation analysis, and Factor analysis. Conclusion: The results illustrated the extent of enhancing the application of KAs in the AEC industry using BIM technology from the highest to lowest as follows: Cost Management (CM), Time Management (TM), Resource Management (REM), Procurement Management (PROM), Scope Management (SCM), Stakeholder Management (STM), Integration Management (IM), Quality Management (QM), Communication Management (COM), Risk Management (RM), and Safety Management (SM). As an example, BIM is effectively applied to each KA, and high efficiency is achieved when BIM is applied to TM by 4D modeling; to CM by 5D modeling; to REM by collaboration; to PROM by quantity takeoff; to SCM by element-base; to STM and IM by using integrated project delivery; to QM by using clash detection; to COM by centralized, structured data management, and information flow; to RM by constructability; and to SM by automated safety code checking.
Mohammed N. Maliha; Bassam A. Tayeh; Yazan I. Abu Aisheh. Building Information Modeling (BIM) in Enhancing the Applying of Knowledge Areas in the Architecture, Engineering and Construction (AEC) Industry. The Open Civil Engineering Journal 2020, 14, 388 -401.
AMA StyleMohammed N. Maliha, Bassam A. Tayeh, Yazan I. Abu Aisheh. Building Information Modeling (BIM) in Enhancing the Applying of Knowledge Areas in the Architecture, Engineering and Construction (AEC) Industry. The Open Civil Engineering Journal. 2020; 14 (1):388-401.
Chicago/Turabian StyleMohammed N. Maliha; Bassam A. Tayeh; Yazan I. Abu Aisheh. 2020. "Building Information Modeling (BIM) in Enhancing the Applying of Knowledge Areas in the Architecture, Engineering and Construction (AEC) Industry." The Open Civil Engineering Journal 14, no. 1: 388-401.