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2018 | OriginalPaper | Buchkapitel

12. Product Life Cycle Design for Sustainable Value Creation

verfasst von : Jing Tao, Suiran Yu

Erschienen in: Value Creation through Engineering Excellence

Verlag: Springer International Publishing

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Abstract

This chapter aims to provide methods and tools for sustainable values creation in the context of high value engineering. First, a sustainable value-driven life cycle design framework is proposed for product and process engineering innovation for sustainability and provides a conceptual linkage with the value-creating activities such as design, production, supply chains, partnerships, and distribution channels. Then, approaches for the integration of ecological assessment (i.e. LCA) with computer-aided product development are proposed as a useful tool to support sustainable value-oriented product and process engineering. The proposed approaches and tools are expected to help bring experts in fields of product and process engineering, industrial management, and ecological assessments to a common vision, and therefore accelerate development of more sustainable products, processes, and business strategies.

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Vorheriges Kapitel Engineering for Sustainable Value

Nächstes Kapitel Engineering and the Skills Crisis in the UK and USA: A Comparative Analysis of Employer-Engaged Education

Adams, W. M. (2006). The future of sustainability: Re-thinking environment and development in the twenty-first century. Report of the IUCN renowned thinkers meeting.

An, Y., Lee, S., & Park, Y. (2008). Development of an integrated product-service roadmap with QFD. International Journal of Service Industry Management, 19(5), 621–638.CrossRef

Babic, B. R., Nesic, N., & Miljkovic, Z. (2008). A review of automated feature recognition with rule-based pattern recognition. Computers in Industry, 59, 321–337.CrossRef

Banks, J., Carson, J., et al. (2005). Discrete-event system simulation (4th ed.). New York: Prentice Hall.

Baumann, H., & Tillman, A. M. (2004). The hitch hiker’s guide to LCA. Stockholm: Studentlitteratur.

Bocken, N. M. P., Short, S. W., Rana, P., et al. (2013). A value mapping tool for sustainable business modelling. Corporate Governance, 13(5), 482–497.CrossRef

Bronsvoort, W. F., & Noort, A. (2004). Multiple-view feature modelling for integral product development. Computer Aided Design, 36(10), 929–946.CrossRef

Cooper, R., & Slagmulder, R. (1997). Target costing and value engineering. Oregon: Productivity Press.

Du, Y., Cao, H., Chen, X., et al. (2013). Reuse-oriented redesign method of used products based on axiomatic design theory and QFD. Journal of Cleaner Production, 39, 79–86.CrossRef

Figge, F., & Hahn, T. (2013). Value drivers of corporate eco-efficiency: Management accounting information for the efficient use of environmental resources. Management Accounting Research, 24(4), 387–400.CrossRef

Friedrich, J., & Krasowski, H. (1998). Ecology-based product data model. SAE technical paper.

Graede, T., & Allenby, B. (1995). Industrial ecology. Englewood Cliffs: Prentice Hall.

Ishii, K. (1995). Life-cycle engineering design. ASME Journal of Vibration and Acoustics, 117(B), 42–47.

Ishii, K., & Lee, B. (1996). Reverse fishbone diagram: A tool in aid of design for product retirement. Paper presented at the proceedings of ASME design technical conference, irvine, CA,USA.

Ishii, N., Fuchino, T., & Muraki, M. (1997). Life cycle oriented process synthesis at conceptual planning phase. Computers & Chemical Engineering, 21, S953–S958.CrossRef

ISO. (1994). ISO10303-1: Industrial automation systems and integration-product data representation and exchange-part 1: Overview and fundamental principles. Geneva: International Organisation for Standardisation (ISO).

ISO. (2006). ISO 14040 Environmental management—Life cycle assessment—Principles and framework. Geneva: International Organization for Standardization.

Kara, S., Mazhar, M., Kaebernick, H., et al. (2005). Determining the reuse potential of components based on life cycle data. CIRP Annals-Manufacturing Technology, 54(1), 1–4.CrossRef

Kato, S., Hata, T., & Kimura, F. (2000). Decision factors of product life cycle strategies. Paper presented at the Proceedings of 7th CIRP international seminar on life cycle engineering.

Kato, S., & Kimura, F. (2004). The product life cycle design method using a strategic analysis. Paper presented at the proceedings of 11th international CIRP life cycle seminar on product life cycle quality management issues.

Kobayashi, H. (2006). A systematic approach to eco-innovative product design based on life cycle planning. Advanced Engineering Informatics, 20(2), 113–125.CrossRef

Kroll, E., & Hanft, T. A. (1998). Quantitative evaluation of product disassembly for recycling. Research in Engineering Design-Theory Applications and Concurrent Engineering, 10(1), 1–14.

Lam, S., & Wong, T. (2010). Recognition of machining features—A hybrid approach. International Journal of Production Research, 38(17), 4301–4316.CrossRef

Lee, S. H. (2009). Feature-based non-manifold modeling system to integrate design and analysis of injection molding products. Journal of Mechanical Science and Technology, 23, 1331–1341.CrossRef

Masui, K., Sakao, T., & Inaba, A. (2001). Quality function deployment for environment: QFD (1st)—A methodology in early stage of DfE. Paper presented at the proceedings of eco-design 2001-second international symposium on environmentally conscious design and inverse manufacturing.

Marosky, N., Dose, J., Fleischer, G., et al. (2007). Challenges of data transfer between CAD and LCA software tools. In Proceedings of 3rd international conference on life cycle management.

Mathieux., F, Roucoules., L, Lescuyer, L, et al. (2005). Opportunities and challenges for connecting environmental assessment tools and CAD software. In Proceedings of LCM 2005-innovation by Life cycle management.

Matsuyama, Y., Matsuno, T., Fukushige, S., et al. (2014). Study of life cycle design focusing on resource balance throughout product life cycles. Procedia CIRP, 15, 455–460.CrossRef

Merante, P., Van Passel, S., & Pacini, C. (2015). Using agro-environmental models to design a sustainable benchmark for the sustainable value method. Agricultural Systems, 136, 1–13.CrossRef

Nawata, S., & Aoyama, T. (2001). Life-cycle design system for machined parts-linkage of LCI data to CAD/CAM data. In Environmentally conscious design and inverse manufacturing, 2001. Proceedings EcoDesign (pp. 299–302).

Noller, R. M. (1992). Disassembly for disassembly tactioes. Assembly Automation, 33(1), 24–26.

Ometto, A, Gueler, A., & Pigosso, D. (2008). A proposal for a framework for life cycle engineering. Paper presented at the proceeding of 15th CIPR international conference on life cycle engineering.

Ostad Ahmad Ghorabi, H., & Jerlich, J. (2008). Value based life cycle analysis for occupational. In Environmental and legal compliance in organizations 1st international conference on industry safety, occupational health and safety in organizations. Isfahan, Iran.

Otto, H.E., Mueller, K.G., & Kimura, F. (2001). A Framework for structured data retrieval in LCA using feature technology. In Proceedings of second international symposium on environmentally conscious design and inverse manufacturing (pp. 250–255).

Otto, H.E., Kimura, F, Mandorli, F., et al. (2003). Integration of CAD models with LCA. In Proceedings of 3rd international symposium on environmentally conscious design and inverse manufacturing.

Rana, P, Short, S., & Evans, S. (2013). D2.5—Lessons learned report, documenting the impact from use of the tools and methods and areas for improvement.

Ray, D. L., & Guazzo, L. (1993). Environmental overkill: Whatever happened to common sense? New York: Harper Collins.

Riou, A., & Mascle, C. (2009). Assisting designer using feature modeling for lifecycle. Computer-Aided Design, 41(12), 1034–1049.CrossRef

Rose, C. M., Beiter, K. A., & Ishii, K. (1998). Characterization of product end-of-life strategies to enhance recyclability. Paper presented at the proceedings of design for manufacturing symposium, ASME, Atlanta, Gergia.

Sakao, T., Masui, K., & Kobayashi, M. (2001). Quality function deployment for environment: QFDE(2nd report)-verifying the applicability by two case studies. Paper presented at the proceedings of eco-design 2001—Second international symposium on environmentally conscious Design and inverse manufacturing.

Sakao, T. (2007). A QFD-centered design methodology for environmentally conscious product design. International Journal of Production Research, 45, 4143–4162.CrossRef

SAVE International (Society of American Value Engineers). 2007. Value Methodology Standard, US.

Shah, J. J., & Mäntylä, M. (1995). Parametric and feature-based CAD/CAM. New York: Wiley.

Suh, N. P. (2001). Axiomatic design—Advances and applications. New York: Oxford University Press.

Syaimak, A.S., & Axinte, D. A. (2011). An approach of using primitive feature analysis in manufacturability analysis systems for micro-milling/drilling. International Journal of Computer Integrated Manufacturing 2011, 22(8), 727–744.

Takata, S., & Kimura, T. (2003). Life cycle simulation system for life cycle process planning. CIRP Annals—Manufacturing Technology, 52(1), 37–40.CrossRef

Tao, J., Chen, Z., Yu, S., et al. (2017). Integration of life cycle assessment with computer-aided product development by a feature-based approach. Journal of Cleaner Production, 143, 1144–1164.CrossRef

Tchertchian N, Millet D., & El Korchi A (2010). A method helping to define ecoinnovative systems (product architecture + reverse supply chain structure + use cycles scenario). Paper presented at the Proceedings of seventeenth CIRP International Conference on Life Cycle Engineering.

Umeda, Y. (2001). Toward a life cycle design guideline for inverse manufacturing. In Proceedings Second International Symposium on Environmentally Conscious Design and Inverse Manufacturing (pp. 143–148).

Umeda, Y., Kondoh, S., & Sugino, T. (2006). Analysis of reusability using ‘marginal reuse rate’. CIRP Annals-Manufacturing Technology, 55(1), 41–44.CrossRef

Verma, A., & Rajotia, S. (2010). A review of machining feature recognition methodologies. International Journal of Computer Integrated Manufacturing I, 23(4), 353–368.CrossRef

Xie, Y., Liu, J., Liu, H., et al. (2013). Features and interoperability of computer aided engineering systems. Semantic Modeling and Interoperability in Product and Process Engineering. London: Springer.

Xing, K., Abhary, K., & Luong, L. (2003). IREDA: An integrated methodology for product recyclability and end-of-life design. Journal of Sustainable Product Design, 3(3–4), 149–172.CrossRef

Yang, M., Vladimirova, D., Rana, P., et al. (2014). Sustainable value analysis tool for value creation. Asian J. Management Science and Applications, 1(4), 2014.

Yu, S., Yang, Q., Tao, J., et al. (2011). Product modular design incorporating life cycle issues—Group Genetic Algorithm (GGA) based method. Journal of Cleaner Production, 19(9–10), 1016–1032.CrossRef

Zhang, Y., Wang, H. P., & Zhang, C. (1999). Green QFDII: A life cycle approach for environmentally conscious manufacturing by integrating LCA and LCC into QFD matrices. International Journal of Production Research, 37, 1075–1091.CrossRef

Zhang, L., Zhan, Y., Liu, Z. F., et al. (2011). Development and analysis of design for environment oriented design parameters. Journal of Cleaner Production, 19(15), 1723–1733.CrossRef

Ziout, A., Azab, A., & Atwan, M. (2014). A holistic approach for decision on selection of end-of-life products recovery options. Journal of Cleaner Production, 65, 497–516.CrossRef

Zwolinski, P., Lopez-Ontiveros, M. A., & Brissaud, D. (2006). Integrated design of remanufacturable products based on product profiles. Journal of Cleaner Production, 14(15–16), 1333–1345.CrossRef

Titel: Product Life Cycle Design for Sustainable Value Creation
verfasst von: Jing Tao
Suiran Yu
Verlag: Springer International Publishing
Buch: Value Creation through Engineering Excellence
Print ISBN: 978-3-319-56335-0

Electronic ISBN: 978-3-319-56336-7

Copyright-Jahr: 2018
DOI: https://doi.org/10.1007/978-3-319-56336-7_12

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