一個新產品的誕生在概念設計的階段，新構想的產生經常是依賴設計人員本身的經驗與創造力。但設計人員之創意變化難測，其過程亦難以掌握，甚至可能陷入以往經驗的束縛之中而無法掙脫。TRIZ是TIPS（Theory of Inventive Problem Solving）的俄文同義字，意思是解答發明問題的方法。TRIZ的創新方法是一種提升革新和快速改進設計的工具，將現有產品及創新概念轉換為系統化的思維。
本文結合TRIZ創新方法最新的48項工程參數與生態效益七要素及綠色產品生命週期八階段等原則，試圖建構一套以TRIZ的創新方法為基礎，又能符合綠色產品設計原則之系統方法，協助設計人員在解決與執行綠色產品之創新設計時所面臨的問題。此外，爲了使設計人員能在缺乏矛盾訊息時，亦能有效且迅速地找到適合的創新概念以玆運用，本文將48 X 48的矛盾矩陣，統計整理出「單一工程參數之創新法則表」供設計人員參考運用，以提升設計效率，並符合環保之需求。
上述所建構之創新研發流程，經由光學引擎機構設計案例之分析確認，可提供綠色產品之設計人員儘早評估產品對生態效益之衝擊，有效排除系統矛盾的情況，縮短研發時間，降低研發成本。

The creation of a new product comes from the conceptual design stage. A new idea usually depends on designers’ experiences and creativity. However, it is hard to predict what designers are thinking and to control the process. Sometimes designers may be limited by their past experiences. “TRIZ” is a Russian synonym of “TIPS”, which is a method of solving inventive problems. The TRIZ innovative method is a tool that rapidly improves the design. It is also a thought process that transfers the original product and innovative concept into a systematic idea.
The purpose of this thesis is to develop a methodology that helps designers to solve problems while confronting and practicing the innovative design of green products. This method is based on three topics, including TRIZ newest 48 engineering parameters, 7 eco-efficiency elements and 8 green product life cycle stages. Furthermore, this thesis provides a “Single Parameter Inventive Principle” to support designers in finding the right concept quickly and effectively. This principle, based on 48X48 Contradiction Matrix, enables designers to implement the method easily. The advantages of this principle not only increase design efficiency but also meet the need of environmental protection requirements.
The above innovative development process has been analyzed and affirmed by case studies on optical engine mechanism design. This process helps designers to evaluate the impact of their products on ecological benefits, exclude systematic contradiction effectively, shorten development time, and lower cost.

【01】S. Ferrendier, Eco-Design Guide: Environmentally Improved Product Design Case Studies of the European Electrical and Electronics Industry, Ecolife Thematic Network, 2002.
【02】陳振甫等編著，「綠色設計總論」，中華民國對外貿易發展協會設計推廣中心，1995。
【03】陳家豪、劉志成，「TRIZ綠色創新設計方法」，綠色設計電子報，第五期，2003年。
【04】郭財吉，「綠色產品設計-綠色品質機能展開」，永續產業發展雙月刊，頁54-52，2002。
【05】G. Altshuller, The Innovation Algorithm: TRIZ, Systematic Innovation and Technical Creativity, Technical Innovation Center, Inc., Worcester, 2000.
【06】S. D. Savransky, Engineering of Creativity: Introduction to TRIZ Methodology of Inventive Problem Solving, CRC Press, Boca Raton, 2000.
【07】Ideation International Inc., Tools of Classical TRIZ, Ideation International Inc., Southfield, MI, 1999.
【08】S. Kaplan, An Introduction to TRIZ: The Russian Theory Of Inventive Problem Solving, Ideation International Inc., Southfield, MI, 1996.
【09】D. W. Clarke, TRIZ: Through The Eyes of an American TRIZ Specialist, Ideation International Inc., Southfield, MI, 1997.
【10】D. Mann, B. Zlotin and A. Zusman, Matrix 2003: Updating the TRIZ Contradiction Matrix, CREAX, Press, Detroit, USA, 2003.
【11】E. Jones and D. Harrison, Investigating the Use of TRIZ in Eco-innovation, The TRIZ Journal, Sep. 2000.
【12】劉志成，「TRIZ方法改良與綠色創新設計方法之研究」，國立成功大學機械工程學系博士論文，2003。
【13】吳智暐，「結合TRIZ與QFD之綠色創新產品開發流程」，中華大學科技管理研究所碩士論文，2005。
【14】吳政豫，「TRIZ之於DFSS的應用—以我國筆記型電腦產業為例」。新竹：中華萃思學會第一屆學術暨實務研討會，2006。
【15】葉志峰、田方治，「應用TRIZ方法於改善輸電地下電纜運轉容量」。新竹：中華萃思學會第一屆學術暨實務研討會，2006。
【16】劉季昌、陳永信、沙永傑，「TRIZ創新設計原則應用於汽車Telematics平台開發之個案研究」。新竹：中華萃思學會第一屆學術暨實務研討會，2006。
【17】華曉佩，「應用TRIZ理論探討綠色產品設計研發機制之研究」，聖約翰科技大學自動化及機電整合研究所碩士論文，2006。
【18】張永忠，「綠色設計教育現況探討與方向規劃之研究」，大葉大學工業設計研究所碩士論文，1998。
【19】鄭源錦等編著，「綠色設計技術參考手冊－家電產品」，中華民國對外貿易發展協會設計推廣中心，1997。
【20】H. Wenzel, M. Hauschild, and L. Alting, “Environment Assessment of Products”, Vol. 1Methodology, Tools and Case Studies in Product Development. Chapman & Hall, London, 1997.