WENIGER IST HEUTZUTAGE MEHR

In order to make design for board to achieve the miniaturization, multi-purpose, recycling; and to pursue the energy conservation, saving materials, little waste, the closed circuit in the technology, it is necessary to carry on the research of green design for board. Based on analyzing requirement of the market adequately, green design for multi-purpose dovetail groove board is presented. The research primary including: Firstly, choice of material for green design of board; Secondly, design for disassembly of board; Thirdly, design for recycling & recovering of board; finally, applications of board. The research has certain theory value and the practice significance.

Download Full-text

Design for and from Recycling: A Circular Ecodesign Approach to Improve the Circular Economy

Sustainability ◽

10.3390/su12239861 ◽

2020 ◽

Vol 12 (23) ◽

pp. 9861

Author(s):

Jorge Martínez Leal ◽

Stéphane Pompidou ◽

Carole Charbuillet ◽

Nicolas Perry

Keyword(s):

Product Design ◽

End Of Life ◽

Circular Economy ◽

Raw Materials ◽

Time Lag ◽

Design Guidelines ◽

Design Phase ◽

Design For Recycling ◽

Circular Design

In the context of a circular economy, one can observe that (i) recycling chains are not adapted enough to the end-of-life products they have to process and that (ii) products are not sufficiently well designed either to integrate at best their target recycling chain. Therefore, a synergy between product designers and recycling-chains stakeholders is lacking, mainly due to their weak communication and the time-lag between the product design phase and its end-of-life treatment. Many Design for Recycling approaches coexist in the literature. However, to fully develop a circular economy, Design from Recycling also has to be taken into account. Thus Re-Cycling, a complete circular design approach, is proposed. First, a design for recycling methodology linking recyclability assessment to product design guidelines is proposed. Then, a design from recycling methodology is developed to assess the convenience of using secondary raw materials in the design phase. The recyclability of a smartphone and the convenience of using recycled materials in a new cycle are both analyzed to demonstrate our proposal. The Fairphone 2® and its treatment by the WEEE French takeback scheme are used as a case study.

Download Full-text

Design for recycling

Knowable Magazine ◽

10.1146/knowable-093020-1 ◽

2020 ◽

Author(s):

M. Mitchell Waldrop

Keyword(s):

Design For Recycling

Download Full-text

Design for Recycling Principles Applicable to Selected Clean Energy Technologies: Crystalline-Silicon Photovoltaic Modules, Electric Vehicle Batteries, and Wind Turbine Blades

Journal of Sustainable Metallurgy ◽

10.1007/s40831-020-00313-3 ◽

2020 ◽

Vol 6 (4) ◽

pp. 761-774

Author(s):

Alex Norgren ◽

Alberta Carpenter ◽

Garvin Heath

Keyword(s):

Wind Turbine ◽

Crystalline Silicon ◽

Raw Materials ◽

Turbine Blades ◽

Lithium Ion ◽

Clean Energy ◽

Raw Material ◽

Wind Turbine Blades ◽

Design For Recycling ◽

Pv Modules

Abstract The global growth of clean energy technology deployment will be followed by parallel growth in end-of-life (EOL) products, bringing both challenges and opportunities. Cumulatively, by 2050, estimates project 78 million tonnes of raw materials embodied in the mass of EOL photovoltaic (PV) modules, 12 billion tonnes of wind turbine blades, and by 2030, 11 million tonnes of lithium-ion batteries. Owing partly to concern that the projected growth of these technologies could become constrained by raw material availability, processes for recycling them at EOL continue to be developed. However, none of these technologies are typically designed with recycling in mind, and all of them present challenges to efficient recycling. This article synthesizes and extends design for recycling (DfR) principles based on a review of published industrial and academic best practices as well as consultation with experts in the field. Specific principles developed herein apply to crystalline-silicon PV modules, batteries like those used in electric vehicles, and wind turbine blades, while a set of broader principles applies to all three of these technologies and potentially others. These principles are meant to be useful for stakeholders—such as research and development managers, analysts, and policymakers—in informing and promoting decisions that facilitate DfR and, ultimately, increase recycling rates as a way to enhance the circularity of the clean energy economy. The article also discusses some commercial implications of DfR. Graphical Abstract

Download Full-text