Abstract
In recent years, sustainable product design process gained notable attentions and evolved having Triple Bottom Line (TBL) accounting perspective. TBL requires integrating environmental, social as well as economic factors at the design phase. Making a product sustainable is important from the customers’ point of view, because today customers show tendency not to prefer non-sustainable products. Besides, customers today are more and more interested in accessing to product usage or functions instead of its ownership. So, in this study, an Axiomatic Design Framework is proposed for the Sustainable Product-Service Systems, for the first time in the literature, so that a complete conceptual design is made based on the environmental, economic and social dimensions for the products that concerns the customer expectations for the circular economy. Besides, a washing machine design is discussed based on the proposed sustainable product service-system framework.
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References
Ahmad, S., Wong, K.Y., Tseng, M.L., Wong, W.P.: Sustainable product design and development: a review of tools, applications and research prospects. Resour. Conserv. Recycl. 132, 49–61 (2018)
Babic, B.: Axiomatic design of flexible manufacturing systems. Int. J. Prod. Res. 37(5), 1159–1173 (1999)
Bahadir, M.C., Satoglu, S.I.: A novel robot arm selection methodology based on axiomatic design principles. Int. J. Adv. Manuf. Technol. 71(9–12), 2043–2057 (2014)
Bal, A., Satoglu, S.I.: A goal programming model for sustainable reverse logistics operations planning and an application. J. Clean. Prod. 201, 1081–1091 (2018)
Baysan, S., Kabadurmus, O., Cevikcan, E., Satoglu, S.I., Durmusoglu, M.B.: A simulation-based methodology for the analysis of the effect of lean tools on energy efficiency: an application in power distribution industry. J. Clean. Prod. 211, 895–908 (2019)
Bovea, M.A.D., Pérez-Belis, V.: A taxonomy of ecodesign tools for integrating environmental requirements into the product design process. J. Clean. Prod. 20(1), 61–71 (2012)
Bressanelli, G., Perona, M., Saccani, N.: Assessing the impacts of circular economy: a framework and an application to the washing machine industry. Int. J. Manag. Decis. Mak. 1–27 (2019)
Campadello, L., Deubzer, O., Langle, A., Amadei, A., Arienti, G., Sala, M.: Upgrading regulations and standards to enable recycling of CRM from WEEE. Solutions for Critical Raw materials—a European Expert Network (SCRREEN). Report no: D8.2 (2019)
Cebi, S., Kahraman, C.: Determining design characteristics of automobile seats based on fuzzy axiomatic design. Int. J. Comput. Intell. Syst. 3(1), 43–55 (2010)
Cebi, S., Kahraman, C.: Extension of axiomatic design principles under fuzzy environment. Expert Syst. Appl. 37(3), 2682–2689 (2010)
Cebi, S., Kahraman, C.: A new weighted fuzzy information axiom method in production research. J. Enterp. Inf. Manag. 32(1), 170–190 (2019)
Chen, C., Zhu, J., Yu, J.Y., Noori, H.: A new methodology for evaluating sustainable product design performance with two-stage network data envelopment analysis. Eur. J. Oper. Res. 221(2), 348–359 (2012)
Delaram, J., Valilai, O.F.: An architectural view to computer integrated manufacturing systems based on axiomatic design theory. Comput. Ind. 100, 96–114 (2018)
Du, Y., Cao, H., Chen, X., Wang, B.: Reuse-oriented redesign method of used products based on axiomatic design theory and QFD. J. Clean. Prod. 39, 79–86 (2013)
Durmusoglu, M.B., Satoglu, S.I.: Axiomatic design of hybrid manufacturing systems in erratic demand conditions. Int. J. Prod. Res. 49(17), 5231–5261 (2011)
Ertay, T., Satoğlu, S.I.: System parameter selection with information axiom for the new product introduction to the hybrid manufacturing systems under dual-resource constraint. Int. J. Prod. Res. 50(7), 1825–1839 (2012)
European Commission: Directive 2012/19/EU of the European Parliament and of the Council of 4 July 2012 on waste electrical and electronic equipment (WEEE). OJEU L 197/38 of 24.07.2012 (2012)
Faulkner, W., Badurdeen, F.: Sustainable value stream mapping (Sus-VSM): methodology to visualize and assess manufacturing sustainability performance. J. Clean. Prod. 85, 8–18 (2014)
Favi, C., Marconi, M., Germani, M., Mandolini, M.: A design for disassembly tool oriented to mechatronic product de-manufacturing and recycling. Adv. Eng. Inform. 39, 62–79 (2019)
Hebrok, M.: Design for longevity: taking both the material and social aspects of product-life into account. J. Des. Res. 12(3), 204–220 (2014)
Huang, C.C., Liang, W.Y., Yi, S.R.: Cloud-based design for disassembly to create environmentally friendly products. J. Intell. Manuf. 28(5), 1203–1218 (2017)
Jawahir, I.S., Dillon, O.W., Rouch, K.E., Joshi, K.J., Venkatachalam, A., Jaafar, I.H.: Total life-cycle considerations in product design for sustainability: a framework for comprehensive evaluation. In: Proceedings of the 10th International Research/Expert Conference, pp. 1–10, Barcelona, Spain (2006, September)
Jeurissen, R.: John Elkington, Cannibals with forks: the triple bottom line of 21st century business. J. Bus. Ethics 23(2), 229–231 (2000)
Kapukaya, E.N., Bal, A., Satoglu, S.I.: A bi-objective model for sustainable logistics and operations planning of WEEE recovery. An Int. J. Optim. Control.: Theor. Appl. (IJOCTA) 9(2), 89–99 (2019)
Kim, S.J., Suh, N.P., Kim, S.G.: Design of software systems based on axiomatic design. Robot. Comput.-Integr. Manuf. 8(4), 243–255 (1991)
Kulak, O., Cebi, S., Kahraman, C.: Applications of axiomatic design principles: a literature review. Expert Syst. Appl. 37(9), 6705–6717 (2010)
Kulak, O., Durmusoglu, M. B., Tufekci, S.: A complete cellular manufacturing system design methodology based on axiomatic design principles. Comput. Ind. Eng. 48(4), 765–787 (2005)
Ljungberg, L.Y.: Materials selection and design for development of sustainable products. Mater. Des. 28(2), 466–479 (2007)
Rasmi, S.A.B., Kazan, C., Türkay, M.: A multi-criteria decision analysis to include environmental, social, and cultural issues in the sustainable aggregate production plans. Comput. Ind. Eng. 132, 348–360 (2019)
RĂĽdenauer, I., Gensch, C.-O., Quack, D.: Eco-efficiency analysis of washing machines
Stiassnie, E., Shpitalni, M.: Incorporating lifecycle considerations in axiomatic design. CIRP Ann. 56(1), 1–4 (2007)
Storbeck, O.: Adidas vows to use only recycled plastics by 2024. The Financial Times Limited 2019. https://www.ft.com/content/73ca70d8-84e1-11e8-96dd-fa565ec55929 (2018). Accessed 30 July 2019
Suh, N.P., Cochran, D.S., Lima, P.C.: Manufacturing system design. CIRP Ann. 47(2), 627–639 (1998)
Suh, N.P.: Axiomatic Design: Advances and Applications. Oxford University Press (2001)
Tasaki, T., Hashimoto, S., Moriguchi, Y.: A quantitative method to evaluate the level of material use in lease/reuse systems of electrical and electronic equipment. J. Clean. Prod. 14(17), 1519–1528 (2006)
Tukker, A.: Eight types of product–service system: eight ways to sustainability? Experiences from SusProNet. Bus. Strategy Environ. 13(4), 246–260 (2004)
Tukker, A.: Product services for a resource-efficient and circular economy—a review. J. Clean. Prod. 97, 76–91 (2015)
Ulrich, K.T., Pearson, S.: Assessing the importance of design through product archaeology. Manag. Sci. 44(3), 352–369 (1998)
Zhang, H.C., Li, H.: An energy factor based systematic approach to energy-saving product design. CIRP Ann. 59(1), 183–186 (2010)
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Bal, A., Satoglu, S.I. (2020). An Axiomatic Design Framework of Sustainable Product-Service Systems for Circular Economies. In: Kahraman, C., Cebi, S. (eds) Customer Oriented Product Design. Studies in Systems, Decision and Control, vol 279. Springer, Cham. https://doi.org/10.1007/978-3-030-42188-5_8
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