| Title |
A Design Method to Improve End-of-Use Product Value Recovery for Circular Economy |
| ID_Doc |
4414 |
| Authors |
Cong, L; Zhao, F; Sutherland, JW |
| Title |
A Design Method to Improve End-of-Use Product Value Recovery for Circular Economy |
| Year |
2019 |
| Published |
Journal Of Mechanical Design, 141, 4 |
| DOI |
10.1115/1.4041574 |
| Abstract |
Circular economy (CE) is being increasingly accepted as a promising sustainable business model, supporting waste minimization through product life cycles. The product end-of-use (EOU) stage is the key to circulate materials and components into a new life cycle, rather than direct disposal. The economic viability of recycling EOU products is significantly affected by designers' decisions and largely determined during product design. Low economic return of EOU value recovery is a major barrier to overcome. To address this issue, a design method to facilitate EOU product value recovery is proposed. First, product EOU scenarios are determined by optimization of EOU component flows. The EOU scenario depicts which modules (groups of components) will be allocated for reuse, recycling, or disposal, the order of joint detachment (the joints for modules connection), and recovery profit. Second, in the given study, bottlenecks, improvement opportunities, and design suggestions will be identified and provided following the EOU scenario analysis. Pareto analysis is used for ranking joints, according to their detachment cost and for indicating which joints are the most suitable for replacement. An analytic hierarchy process (AHP) is employed to select the best joint candidate with trade-off among criteria from the perspective of disassembly. In addition, disposal and recycling modules are checked to eliminate hazardous material and increase material compatibility. A value-based recycling indicator is developed to measure recyclability of the modules and evaluate design suggestions for material selection. Finally, based on heuristics, the most valuable and reusable modules will be selected for reconfiguration so that they can be easily accessed and disassembled. A hard disk drive is used as a case study to illustrate the method. |
| Author Keywords |
circular economy; sustainable design; end-of-use decision making; joint selection; material compatibility; product configuration |
| Index Keywords |
Index Keywords |
| Document Type |
Other |
| Open Access |
Open Access |
| Source |
Science Citation Index Expanded (SCI-EXPANDED) |
| EID |
WOS:000461036400011 |
| WoS Category |
Engineering, Mechanical |
| Research Area |
Engineering |
| PDF |
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