應用品質機能展開及設計結構矩陣設計智慧工廠

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：2

、訪客IP：18.119.111.9

姓名

梁乃哲(Nei-Zhe Liang) 查詢紙本館藏

畢業系所

工業管理研究所

論文名稱

應用品質機能展開及設計結構矩陣設計智慧工廠
(Applying Quality Function Deployment and Design Structure Matrix to design smart factory)

相關論文

★ 應用MFM 與PPM 監控協同設計之執行流程	★ 應用DSM與DRFT於汽車電子之協同開發流程
★ 一協同設計專案團隊組成方法- 以安全監視器產品為例	★ 應用認知工程開發全球化光纖通訊系統
★ 羽絨產業策略規劃-應用品質機能展開分析法	★ 重電業協同專案管理績效之研究-以變電所統包工程為例
★ 以屬性導向新產品開發之流程塑模與分析– 以醫療器材產業為案例	★ 以品質機能展開法應用於主管管理職能之建構
★ 應用參考模型以及流程建模改善供應鏈績效-以投影機產業為例	★ 協同產品開發之流程管理 - 以汽車零件為例
★ 配電系統之高壓電纜接頭供應商評選	★ 應用品質機能展開於產品開發之流程分析-以刀鋒式伺服器為例
★ 實施精實六標準差改進製程良率－以機頂盒表面黏著技術為例	★ 太陽能模組產業之決策營運研究
★ 新產品開發階段導入替代料之流程建模及潛在風險分析	★ 應用實驗設計研發PET複合膜及改善厚膜翹曲問題

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

至系統瀏覽論文 ( 永不開放)

摘要(中)

隨著數據通訊技術的演進，以及電腦運算能力的大幅提升，引爆數位化潮流，從而衍生了第四次工業革命，又稱為「工業4.0」。虛實整合系統（Cyber-Physical System, CPS）是「工業4.0」的關鍵技術。藉由電腦、感測器（Sensors），並運用新的網路技術聯結各種設備、機器及數位系統，通過它們之間的溝通與相互作用，整合虛擬及實體世界。為實體系統添加新的智慧及能力，達到即時感知、動態控制，並提供智慧型即時訊息服務。因此，過去毫無交集的工控領域與IT領域在物聯網開始對話。而在未來的智慧工廠在各個生產環節、操作設備都具備獨立自主的能力，可自動化完成生產線操作。且設備都能相互溝通、即時監控周遭環境，隨時找到問題加以排除，也具有更靈活、彈性的生產流程。
品質機能展開(Quality function Deployment，QFD)已被廣泛運用於許多領域，諸如產品設計、製程設計以及專案開發。其可將顧客需求轉換為組織的工程技術，經由工程技術的實踐，進而成功的達到滿足使用需求;而設計結構矩陣具有易於辨識，易懂之優點，容易表示設計參數彼此之間的關係。藉此本研究將以CPS為研究環境，應用QFD設計智慧工廠，並且應用DSM (Design Structure Matrix, DSM) 設計流程，由DSM交互作用的結果，設計出符合CPS環境的智慧工廠。

摘要(英)

With the evolution of data communications technology, as well as significantly enhance the computing power of digital, which derived the fourth industrial revolution, also known as the "Industry 4.0." Cyber-Physical System (CPS) is not only key technologies for "Industry 4.0", but also currently a hot topic. With computers, sensors and the use of new Internet technology to link various equipment, machines and digital systems through communication and interaction between them to integrate of virtual and physical world. By adding new kind of system of wisdom and capability to meet the immediate perception, dynamic control, and provides intelligent message service. Therefore, disjoint industrial areas and IT fields to start a conversation in IOT. Future every production processes in intelligence factory, each operating devices have an independent capacity, automated production line to complete the operation. And each device can communicate with each other, real-time monitoring the surrounding environment, always find a problem to be eliminated, but also has a more flexible.
Quality function Deployment (QFD) has been widely used in many fields, such as product design, process design and project development. It can be converted to customer demand for tissue engineering and technology, through the practice of engineering and technology, and thus the success of reach to meet customer demand; Design Structure Matrix (DSM) has an easy to identify, easy to understand the advantages, readily shows the relationship between each of the design parameters. This research will be an industry 4.0 environment as the background, use QFD to design smart factory, and use Design Structure Matrix (DSM) to design process. Base on the results of DSM interaction to design smart factory used in industrial 4.0 environments.

關鍵字(中)

★ 網宇實體系統
★ 智慧工廠
★ 設計結構矩陣
★ 品質機能展開

關鍵字(英)

★ Cyber-Physical System
★ smart factory
★ Design Structure Matrix
★ Quality function Deployment

論文目次

中文摘要 i
Abstract ii
Table of Contents iv
List of Figures vi
List of Tables vii
Chapter 1 Introduction 1
1.1 Background 1
1.2 Motivation & Objectives 3
1.3 Research Overview 3
Chapter 2 Literature Review 5
2.1 Industry 4.0 5
2.2 Cyber-Physical System 8
2.2.1 Cyber-Physical Systems and Internet of Things 9
2.3 Smart factory 11
Chapter 3 Methodology 16
3.1 Methodology framework 16
3.2 Overview of Methodology 17
3.2.1 Quality Function Deployment 17
3.2.2 Design Structure Matrix 21
Chapter 4 Application 28
4.1 Smart factory 28
4.2 Methodology implement 31
4.2.1 Analysis of QFD and DSM 31
Chapter 5 Conclusion and Future Research 36
5.1 Conclusion 36
5.2 Future Research 37
Reference 38

參考文獻

Akao, Yoji. "Quality function deployment." (2004).
Azuma, Ronald T. "A survey of augmented reality." Presence: Teleoperators and virtual environments 6.4 (1997): 355-385.
Baheti, Radhakisan, and Helen Gill. "Cyber-physical systems." The impact of control technology 12 (2011): 161-166.
Bauer, Martin, Lamine Jendoubi, and Oliver Siemoneit. "Smart Factory–Mobile Computing in Production Environments." Proceedings of the MobiSys 2004 Workshop on Applications of Mobile Embedded Systems (WAMES 2004). 2004.
Browning, Tyson R. "Applying the design structure matrix to system decomposition and integration problems: a review and new directions." IEEE Transactions on Engineering management 48.3 (2001): 292-306.
Browning, Tyson R. "Design structure matrix extensions and innovations: a survey and new opportunities." IEEE Transactions on Engineering Management 63.1 (2016): 27-52.
Chan, Lai-Kow, and Ming-Lu Wu. "Quality function deployment: A literature review." European Journal of Operational Research 143.3 (2002): 463-497.
Kim, Eui-Jik, and Sungkwan Youm. "Machine-to-machine platform architecture for horizontal service integration." EURASIP Journal on Wireless Communications and Networking 2013.
Govers, Cor PM. "What and how about quality function deployment (QFD)."International journal of production economics 46 (1996): 575-585.
Heng, Stefan. "Industry 4.0: Upgrading of Germany′s Industrial Capabilities on the Horizon." Available at SSRN 2656608 (2014).
Shrouf, Fadi, Joaquin Ordieres, and Giovanni Miragliotta. "Smart factories in industry 4.0: a review of the concept and of energy management approached in production based on the Internet of things paradigm." 2014 IEEE International Conference on Industrial Engineering and Engineering Management. IEEE, 2014.
Jazdi, Nasser. "Cyber physical systems in the context of Industry 4.0."Automation, Quality and Testing, Robotics, 2014 IEEE International Conference on. IEEE, 2014.
Kao, Hung-An, et al. "A Cyber Physical Interface for Automation Systems—Methodology and Examples." Machines 3.2 (2015): 93-106.
Kagermann, Henning, et al. Recommendations for implementing the strategic initiative INDUSTRIE 4.0: Securing the future of German manufacturing industry; final report of the Industrie 4.0 Working Group. Forschungsunion, 2013.
Lacey, Gerard, and Kenneth M. Dawson-Howe. "The application of robotics to a mobility aid for the elderly blind." Robotics and Autonomous Systems 23.4 (1998): 245-252.
Lee, Edward A. "Cyber physical systems: Design challenges." 2008 11th IEEE International Symposium on Object and Component-Oriented Real-Time Distributed Computing (ISORC). IEEE, 2008.
Lucke, Dominik, Carmen Constantinescu, and Engelbert Westkämper. "Smart factory-a step towards the next generation of manufacturing." Manufacturing systems and technologies for the new frontier. Springer London, 2008. 115-118.
MacDougall, William. Industrie 4.0: Smart Manufacturing for the Future. Germany Trade & Invest, 2014.
McAfee, Andrew, et al. "Big data." The management revolution. Harvard Bus Rev 90.10 (2012): 61-67.
Shi, Jianhua, et al. "A survey of cyber-physical systems." Wireless Communications and Signal Processing (WCSP), 2011 International Conference on. IEEE, 2011.
Wasserman, Gary S. "On how to prioritize design requirements during the QFD planning process." IIE transactions 25.3 (1993): 59-65.
Yassine, A. "An introduction to modeling and analyzing complex product development processes using the design structure matrix (DSM) method."Urbana 51.9 (2004): 1-17.
Zanella, Andrea, et al. "Internet of things for smart cities." IEEE Internet of Things Journal 1.1 (2014): 22-32.
Zühlke, Detlef. "SmartFactory–A Vision becomes Reality." IFAC Proceedings Volumes 42.4 (2009): 31-39.
Deloitte (2014) Industry 4.0 Challenges and solutions for the digital transformation and use of exponential technologies
Ignite – Manufacturing and Industry from: http://enterprise-iot.org/book/enterprise-iot/part-i/manufacturing/

指導教授

高信培(Hsin-Pei Kao)

審核日期

2016-7-21

推文