Dezembro 2021 vol. 9 num. 5 - 14th International Conference of the European Academy of Design, Safe Harbours for Design Research
Full Paper - Open Access.
The current status of environmental sustainability implementation during the design process in New Product Development
The current status of environmental sustainability implementation during the design process in New Product Development
Delaney, Emelia ; Liu, Wei ;
Full Paper:
Environmental sustainability during New Product Development has been identified within in literature as being a key issue. The design process has been highlighted as having a great impact on the overall sustainability of a product and has been a rising theme for academic and industrial interest. Although there is an extensive range of literature identifying key methodologies, tools and factors of environmental sustainability to be implemented during the product design process, it is unclear of what is currently being implemented by product designers within industry. This study explores the themes of environmental sustainability and the design process through a literature review and semi-structured interviews to understand the current status of environmental sustainability during the product design process. From this study an initial conceptual framework has been developed to illustrate this. Future research directions have also been outlined.
Full Paper:
Environmental sustainability during New Product Development has been identified within in literature as being a key issue. The design process has been highlighted as having a great impact on the overall sustainability of a product and has been a rising theme for academic and industrial interest. Although there is an extensive range of literature identifying key methodologies, tools and factors of environmental sustainability to be implemented during the product design process, it is unclear of what is currently being implemented by product designers within industry. This study explores the themes of environmental sustainability and the design process through a literature review and semi-structured interviews to understand the current status of environmental sustainability during the product design process. From this study an initial conceptual framework has been developed to illustrate this. Future research directions have also been outlined.
Palavras-chave: Product Design, Environmental Sustainability, Sustainability, Design Process, New Product Development,
Palavras-chave: Product Design, Environmental Sustainability, Sustainability, Design Process, New Product Development,
DOI: 10.5151/ead2021-162
Referências bibliográficas
- [1] "Ahmad, S., Wong, K. Y., Tseng, M. L., & Wong, W. P. (2018). Sustainable product design and development: A review of tools, applications and research prospects. Resources, Conservation and Recycling, 132, 49-6
- [2] Alayón, C., Säfsten, K., & Johansson, G. (2017). Conceptual sustainable production principles in practice: do they reflect what companies do? Journal of cleaner production, 141, 693-701.
- [3] Bakker, C., Wever, R., Teoh, C., & De Clercq, S. (2010). Designing cradle-to-cradle products: a reality check. International Journal of Sustainable Engineering, 3(1), 2-8.
- [4] Bjørn, A., & Strandesen, M. (2011). The Cradle to Cradle concept-is it always sustainable? Paper presented at the The Life Cycle Management (LCM) conference: Towards Life Cycle Sustainability Management.
- [5] Brones, F., de Carvalho, M. M., & de Senzi Zancul, E. (2014). Ecodesign in project management: a missing link for the integration of sustainability in product development? Journal of cleaner production, 80, 106-118.
- [6] Brundtland, G. H., Khalid, M., Agnelli, S., Al-Athel, S., & Chidzero, B. (1987). Our common future. New York, 8.
- [7] Buchert, T., Halstenberg, F. A., Bonvoisin, J., Lindow, K., & Stark, R. (2017). Target-driven selection and scheduling of methods for sustainable product development. Journal of cleaner production, 161, 403-421.
- [8] Ceschin, F., & Gaziulusoy, I. (2016). Evolution of design for sustainability: From product design to design for system innovations and transitions. Design studies, 47, 118-163.
- [9] Chan, H. K., Wang, X., & Raffoni, A. (2014). An integrated approach for green design: Life-cycle, fuzzy AHP and environmental management accounting. The British Accounting Review, 46(4), 344-360.
- [10] Chen, C. (2001). Design for the environment: A quality-based model for green product development. Management Science, 47(2), 250-263.
- [11] Chiu, M.-C., & Chu, C.-H. (2012). Review of sustainable product design from life cycle perspectives. International Journal of Precision Engineering and Manufacturing, 13(7), 1259-1272.
- [12] Clark, G., Kosoris, J., Hong, L. N., & Crul, M. (2009). Design for sustainability: current trends in sustainable product design and development. Sustainability, 1(3), 409-424.
- [13] De Ron, A. J. (1998). Sustainable production: the ultimate result of a continuous improvement. International Journal of Production Economics, 56, 99-110.
- [14] Deutz, P., McGuire, M., & Neighbour, G. (2013). Eco-design practice in the context of a structured design process: an interdisciplinary empirical study of UK manufacturers. Journal of cleaner production, 39, 117-128.
- [15] Eddy, D. C., Krishnamurty, S., Grosse, I. R., Wileden, J. C., & Lewis, K. E. (2015). A predictive modelling-based material selection method for sustainable product design. Journal of Engineering Design, 26(10-12), 365-390.
- [16] Gardner, J., & Roseland, M. (1989). Thinking Globally and Acting Locally Part I: Thinking Globally: The Role of Social Equity in Sustainable Development. Alternatives, 26-34.
- [17] Glavič, P., & Lukman, R. (2007). Review of sustainability terms and their definitions. Journal of cleaner production, 15(18), 1875-1885.
- [18] Go, T. F., Wahab, D. A., & Hishamuddin, H. (2015). Multiple generation life-cycles for product sustainability: the way forward. Journal of cleaner production, 95, 16-29.
- [19] Graedel, T. E., Comrie, P. R., & Sekutowski, J. C. (1995). Green product design. AT&T Technical Journal, 74(6), 17-25.
- [20] Graedel, T. E., & Guth, L. A. (1990). The impact of environmental issues on materials and processes. AT&T Technical Journal, 69(6), 129-140.
- [21] Haines-Gadd, M., Chapman, J., Lloyd, P., Mason, J., & Aliakseyeu, D. (2018). Emotional durability design nine—A tool for product longevity. Sustainability, 10(6), 1948.
- [22] Hapuwatte, B. M., & Jawahir, I. S. (2019). A total life cycle approach for developing predictive design methodologies to optimize product performance. Procedia Manufacturing, 33, 11-18.
- [23] Hata, T., Kato, S., & Kimura, F. (2001). Design of product modularity for life cycle management. Paper presented at the Proceedings second international symposium on environmentally conscious design and inverse manufacturing.
- [24] He, B., Luo, T., & Huang, S. (2019). Product sustainability assessment for product life cycle. Journal of cleaner production, 206, 238-250.
- [25] Kuo, T. C., & Wang, C.-J. (2019). Integrating robust design criteria and axiomatic design principles to support sustainable product development. International Journal of Precision Engineering and Manufacturing-Green Technology, 6(3), 549-557.
- [26] Metta, H., & Badurdeen, F. (2012). Integrating sustainable product and supply chain design: modeling issues and challenges. IEEE transactions on engineering management, 60(2), 438-446.
- [27] Overby, C. M. (1991). Sustainability through Design for the Entire Life Cycle. Paper presented at the Proceedings of the 1991 International Symposium on Technology and Society-ISTAS91.
- [28] Pieroni, M. P., McAloone, T. C., & Pigosso, D. C. (2019). Business model innovation for circular economy and sustainability: A review of approaches. Journal of cleaner production, 215, 198-216.
- [29] Rosemarin, A. (1989). Global change, sustainable development and the dangers of information overkill. Ambio. Stockholm, 18(6), 307.
- [30] Singh, S., Goodyer, J., & Popplewell, K. (2007). Integrated environmental process planning for the design and manufacture of automotive components. International Journal of Production Research, 45(18-19), 4189-4205.
- [31] Sonego, M., Echeveste, M. E. S., & Debarba, H. G. (2018). The role of modularity in sustainable design: A systematic review. Journal of cleaner production, 176, 196-209.
- [32] Stuart, J. A., Ammons, J. C., & Turbini, L. J. (1999). A product and process selection model with multidisciplinary environmental considerations. Operations Research, 47(2), 221-234.
- [33] Tang, T., & Bhamra, T. (2008). Changing energy consumption behaviour through sustainable product design. Paper presented at the DS 48: Proceedings DESIGN 2008, the 10th International Design Conference, Dubrovnik, Croatia.
- [34] Venkata Rao, R. (2009). An improved compromise ranking method for evaluation of environmentally conscious manufacturing programs. International Journal of Production Research, 47(16), 4399-4412.
- [35] Vimal, K., Vinodh, S., Brajesh, P., & Muralidharan, R. (2016). Rapid prototyping process selection using multi criteria decision making considering environmental criteria and its decision support system. Rapid Prototyping Journal.
- [36] Waage, S. A. (2007). Re-considering product design: a practical “road-map” for integration of sustainability issues. Journal of cleaner production, 15(7), 638-649.
- [37] Wang, M., Zhang, Z., Li, K., Zhang, Z., Sheng, Y., & Liu, S. (2020). Research on key technologies of fault diagnosis and early warning for high-end equipment based on intelligent manufacturing and Internet of Things. The International Journal of Advanced Manufacturing Technology, 107(3), 1039-1048.
- [38] Wright, I. C. (1998). Design methods in engineering and product design: McGraw-Hill.
- [39] Yan, J., & Feng, C. (2014). Sustainable design-oriented product modularity combined with 6R concept: a case study of rotor laboratory bench. Clean Technologies and Environmental Policy, 16(1), 95-109.
- [40] Yang, Q., & Song, B. (2006). Eco-design for product lifecycle sustainability. Paper presented at the 2006 4th IEEE International Conference on Industrial Informatics.
- [41] Zhang, X., Zhang, L., Fung, K. Y., Bakshi, B. R., & Ng, K. M. (2020). Sustainable product design: A life-cycle approach. Chemical Engineering Science, 217, 115508.
- [42] "
Como citar:
Delaney, Emelia; Liu, Wei; "The current status of environmental sustainability implementation during the design process in New Product Development ", p. 251-263 . In: 14th International Conference of the European Academy of Design, Safe Harbours for Design Research.
São Paulo: Blucher,
2021.
ISSN 2318-6968,
DOI 10.5151/ead2021-162
últimos 30 dias | último ano | desde a publicação
downloads
visualizações
indexações