近年來的建築產業對於綠建築越來越重視，綠建築評鑑內容要求越來越高，但是根據很多文獻顯示，雖然目前各國家綠建築評分內容越來越嚴苛越來越專精，但是除了新版的美國綠建築評估系統有提到條文與條文當中有其相應的「關聯性」，其他綠建築評估系統確無注意到此建議，常常在沒有考量關聯性條件下會重複設計造成效率低下，本研究透過系統性的處理關聯性條文，增加條文整合性，減少在評估綠建築時的錯誤增加效率。
本次研究透過建築物理的思考方式，把綠建築條文要求進行分類，並以室內熱環境為例，從中找取室內熱環境相關的物理因子，藉由物理因子與物理因子間的傳遞關係思考相關條文的整合，透過一體化的設計，可以一次分析多個相關條文減少並且作業上的失誤增加工作效率。

In recent years, construction industry has seen more and more attention in the field of green building design. Green building rating system therefore becomes more specific and demanding. According to literature review, many countries are trying to develop more comprehensive and rigorous green building rating systems, but there is still a lack of an integrated design system that capable of considering several related credits of green building in one model. Therefore, there is a need for studies of integrated green building design to increase credits integration and reduce errors while evaluating green buildings by system.

To tackles aforementioned problem, this study proposes an integrated green building assessment, taking indoor environmental quality design as an example. The research objective is applying Physical Factors to classify the related credits into groups, and then reorganize them to become an integrated model. Physical factors of indoor thermal environmental design are used to classify the credits in LEED rating system and integrates requirements from several credits into one model Therefore, the errors and incongruities of design can be reduced and productivity can be improved.

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