Research on Carbon Reduction Path for Whole-Process Design of Prefabricated Envelope System Based on SEM

Prefabricated buildings, characterized by factory production, on-site assembly, and efficient and refined management, enhance construction efficiency, reduce building time, and promote material reuse and recycling. The energy consumption (and carbon emissions) during the building operational stage are significantly influenced by the performance of the building envelope component system. To minimize carbon emissions throughout the building's lifecycle, it is essential to focus on a comprehensive optimization design for carbon reduction in prefabricated envelope systems. This paper draws on grounded theory to construct a system of factors influencing carbon emissions throughout the lifecycle of prefabricated building envelopes. Using a questionnaire survey and leveraging Structural Equation Modeling (SEM), this study identifies key pathways and factors, influencing carbon emissions throughout the lifecycle of building envelope components. It provides insights into carbon emission mechanisms in these components and establishes a comprehensive design pathway for carbon control throughout the lifecycle of building envelope systems. Subsequently, the survey results were analyzed using Structural Equation Modeling (SEM) to identify key factors influencing carbon emissions throughout the lifecycle and their interrelationships. These findings were integrated into the various stages of the whole-process design, yielding actionable recommendations for carbon control in the design process. Additionally, the case study method was employed to illustrate how carbon control design and optimization techniques can be applied at each stage of a specific project, providing a practical demonstration of the research outcomes. The study offers optimized methods for carbon control across the entire process, utilizing optimization strategies to reduce carbon emissions at each stage of the building's lifecycle.