This study introduces and validates a method for deriving and expanding building safety components using Industry Foundation Classes (IFC) based on the Work Breakdown Structure (WBS) for fire safety building maintenance. The study first identifies IFC building safety components through schema analys...
This study introduces and validates a method for deriving and expanding building safety components using Industry Foundation Classes (IFC) based on the Work Breakdown Structure (WBS) for fire safety building maintenance. The study first identifies IFC building safety components through schema analysis and semantically expands WBS objects to align with the IFC hierarchy using fire safety WBS analysis. Furthermore, by focusing on fire safety, the study derives building safety components based on four fire-related variables, encompassing prevention, inspection, and post-reporting, in line with fire safety WBS and widely used fire simulations.
To assess the applicability of the derived objects to building safety management simulations, the study establishes relationships between the objects and creates a user-defined modified IFC for verification. The geometric, attribute, and relationship information within the modified IFC is confirmed as intended using a custom IFC viewer.
The research demonstrates that this approach can enhance information consistency and efficiency within building safety management systems and highlights the utility of WBS-based IFC schema extensions in this context. Such extensions provide a clear means of deriving building safety components, facilitating effective planning, tracking, and monitoring of safety management tasks.
Moreover, the study tests the suggested extension method in practical building safety management systems by creating and verifying an IFC modified through research, confirming that the geometric, attribute, and relationship information align with expectations. These results suggest the potential for applying the proposed extension method to real-world building safety management systems.
While this study primarily focuses on fire situations, it has the potential for broader applications. Extending IFC to consider other building threats, such as construction sites, disasters, and aging, can significantly contribute to the development of a BIM-based building safety system. An inclusive safety management system accommodating various risk factors can serve as a foundation for effective preventive measures, risk assessments, response strategies, and safety enhancements. These anticipated benefits are pivotal in improving the efficiency and reliability of building safety management systems.
Given the ongoing developments in IFC standards, this study underscores the importance of adhering to standards. The architecture and construction sectors are continually evolving, and IFC standards are updated to reflect the latest technologies and regulations. Collaborative efforts and further research related to IFC standardization will be crucial in enhancing the efficiency and reliability of building safety management systems in the future, thereby ensuring safety on construction sites and in buildings.
This study introduces and validates a method for deriving and expanding building safety components using Industry Foundation Classes (IFC) based on the Work Breakdown Structure (WBS) for fire safety building maintenance. The study first identifies IFC building safety components through schema analysis and semantically expands WBS objects to align with the IFC hierarchy using fire safety WBS analysis. Furthermore, by focusing on fire safety, the study derives building safety components based on four fire-related variables, encompassing prevention, inspection, and post-reporting, in line with fire safety WBS and widely used fire simulations.
To assess the applicability of the derived objects to building safety management simulations, the study establishes relationships between the objects and creates a user-defined modified IFC for verification. The geometric, attribute, and relationship information within the modified IFC is confirmed as intended using a custom IFC viewer.
The research demonstrates that this approach can enhance information consistency and efficiency within building safety management systems and highlights the utility of WBS-based IFC schema extensions in this context. Such extensions provide a clear means of deriving building safety components, facilitating effective planning, tracking, and monitoring of safety management tasks.
Moreover, the study tests the suggested extension method in practical building safety management systems by creating and verifying an IFC modified through research, confirming that the geometric, attribute, and relationship information align with expectations. These results suggest the potential for applying the proposed extension method to real-world building safety management systems.
While this study primarily focuses on fire situations, it has the potential for broader applications. Extending IFC to consider other building threats, such as construction sites, disasters, and aging, can significantly contribute to the development of a BIM-based building safety system. An inclusive safety management system accommodating various risk factors can serve as a foundation for effective preventive measures, risk assessments, response strategies, and safety enhancements. These anticipated benefits are pivotal in improving the efficiency and reliability of building safety management systems.
Given the ongoing developments in IFC standards, this study underscores the importance of adhering to standards. The architecture and construction sectors are continually evolving, and IFC standards are updated to reflect the latest technologies and regulations. Collaborative efforts and further research related to IFC standardization will be crucial in enhancing the efficiency and reliability of building safety management systems in the future, thereby ensuring safety on construction sites and in buildings.
Keyword
#IFC Standard
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