近年來環保永續觀念在世界各處蓬勃地傳播,促進綠能產業的成長與茁壯;人們效仿植物嘗試將太陽光直接轉換為可用的電力資源,藉由半導體技術的應用,太陽能電池的發展快速。如此一來,具汙染之火力燃煤發電廠以及具風險之核能電廠的使用都可以降低。自2010年起,太陽能發電板的價格快速的下降;成熟的技術與低廉的價格,使得太陽板的安裝量逐年攀升。國內太陽能發電版的生產廠商,因不敵中國大陸廠商的競爭,在政府綠能政策的引導之下,轉型成為能源維運公司,負責評估各個客戶的太陽能發電板安裝需求,以及安裝後長年的維運事宜。由於太陽能板安裝在室外且太陽能板的清潔狀況會直接影響發電效率,太陽能板表面必須時常清洗。現行方法為發電效率降低至標準後派遣人力清洗,此法不僅耗時費工,且因太陽能板常安裝於高處,工安風險也存在其中。本計畫針對日益興盛的太陽能維運產業,將研發太陽能板表面適用的表面鍍膜劑。此鍍膜劑不同於市售鍍膜劑,必須具有抗汙易潔的效果、較高的環境耐久度、簡易的施工方法、合理的成本、以及環境友善的特性。將此鍍膜配方應用於太陽能板表面,可顯著地降低其清潔頻率、人力成本、以及工安風險,並提升發電效益。 ;In recent years, environmental awareness flourishes around the world, which promotes the development of the green energy industry. Scientists imitate plants to convert solar energy into electric energy through semiconductor technology, which makes the solar energy generation system evolves fast. The application of solar energy systems reduces the usage of high pollution thermal power plant and risky nuclear power plant. Since 2010, the price of solar panel has been dropped continuously. Well-developed techniques and cheap prices lead to the rapid growth of power generation by solar panels. However, domestic manufacturers of solar panels cannot compete with foreign manufacturers in price. Therefore, they follow the green energy policy of our government to transform themselves into maintenance companies of power systems, which are in charge of solar system installation and regular maintenance.Solar panels are usually installed outside the buildings and their surface conditions affect the power generation efficiency directly. As the result, solar panels have to be cleaned frequently. The cleaning process is not only time-consuming but also has safety risk. This project focuses on the industry of solar system maintenance and develops surface coating agents for solar panels. These coatings should have properties of anti-soiling, easy to clean, endurable, easy to use, affordable and environmental friendly characteristics. By applying this coating on the surface of solar panel, the clean frequency, cost, and safety risk will be significantly reduced. Simultaneously, the optimal power generation efficiency will be maintained.
