隨著全球暖化情況日益嚴重，節能減碳的議題愈來愈受到重視，本研究探討太陽能透光模組特性，利用切割度不同太陽能透光模組進行加工與分析，透過光學性質試驗、熱學性質試驗、標準電力試驗、密閉環境試驗與空調節能試驗分析太陽能透光模組經過加工後其效能提升多少。最後於模擬軟體效益評估部分，設計簡單建築體模型，將其放置於不同氣候型態地區，經由軟體模擬各式太陽能節能玻璃應用於簡單建築體模型，探討其發電量效益、不同氣候型態地區與節能效益之關聯性，並針對臺灣地區進行經濟效益評估。
本研究結果顯示，太陽能透光模組經由特殊封裝加工製成太陽能節能玻璃後，各項性能表現皆明顯提升，包括模組發電量、隔熱性能等相關性能。太陽能節能玻璃在總熱傳導係數與遮蔽係數降低情形下相較於其他玻璃建材更能有效阻隔太陽輻射熱能與傳導熱，能使建築物維持於較佳的舒適環境，並且太陽能節能玻璃能供給建築物額外電力，研究結果顯示能大幅降低建築物電力需求，充分展現太陽能節能玻璃良好的發電性能與隔熱性能。太陽能節能玻璃更可以取代傳統一般玻璃建材，進而能開源節流與節能減碳，達到環境永續之效益。

For all mankind, how to live friendly with current global warming situation being lasted for decades by the application of energy saving and reduction of carbon emission as well as the clean output of renewable energy, such as sunlight, is a major challenge. The main focus of this study is to assemble and create a new type of translucent building glass, 2 out of 3 layers embedded a thin film photovoltaic module inside; the third glass sealed with a highly reflective coating film on the internal surface.On the other hand, this PV module composite glass also undertakes several tests analysis, including optical, thermal, power generation and air conditioning simulation, to seek for the best synergy results fit for global climates demands.

This study shows the highly reflective coating PV module glass with much better performance in terms of power generation and heat insulation.The test results show that the highly reflective coating PV module glass applied on a building can control the indoor temperature with minimum power consumption due to its lowest SC and U values compared to normal or low-e glasses.

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