本研究以TRIZ方法為基礎，提出一套系統化的創新設計流程，協助產品設計者開發創新能源或節省能源的技術或應用。
　　首先，對於TRIZ 40種發明法則(Inventive Principles)，蒐集目前市面上己提出之創新節能構想為案例，分析每一案例可能應用到的原理，並將其與發明法則做配對，提出創新節能技術表，讓設計者在使用發明法則時能有個具體化的案例參考，增加設計靈感。接著，以創新節能技術表為設計之核心，提供三種創新設計流程。
　　第一種創新設計流程為利用單一工程特性法則，單一工程特性法則能針對產品節能的方向做改善，給予較適合之發明法則，提供產品設計者思考方向。
　　第二種創新設計流程為利用生能及耗能配對表，將不同產品所需消耗的功率與不同能源系統所能產生的功率做比較，找出可能搭配應用之創新能源的產品。
　　第三種創新設計流程為利用演化法則及理想最終結果。演化法則及理想最終結果能提供設計者，未來創新能源或節能產品可能的發展方向。

　　This study proposed innovative design methods to help designers develop innovative energy saving products or technology.
　　The Contradiction Matrix of TRIZ is a powerful tool, especially the 40 Inventive Principles can assist designers create innovative ideas. However, the explanation of Inventive Principles may too obscure for designers to understand. Therefore, in this article, we search for innovative energy saving products or technologies as cases, analyzing the principles it might use, matching the cases with Innovative Principles, and make an innovative energy saving technologies table, so that the users of Innovative Principles will have a specific ideas of what to do. Then, based on the innovative energy saving technology table, three design methods are proposed.
　　The first design method uses the Rule of Single Parameter to help designers focus on products’ improving aspects (mainly on energy saving technology), and provides an adaptive Inventive Principles.
　　The second design method uses the matching table of energy generated and energy consumption. The tables of energy generated and energy consumption compare different power that the products need and energy sources can generate, and see if there are any applicable innovative products.
　　The third design method uses the Rules of Evolution and the Ideal Final Result to help designers predict the developing direction of novel energy saving products in the future.

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