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

Leal, Jorge Martínez; Pompidou, Stéphane; Charbuillet, Carole; Perry, Nicolás

doi:10.3390/su12239861

Cited by 32 publications

(17 citation statements)

References 21 publications

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“…As an important part of green design, planning for recycling can not only reduce plastic emissions but also increase the recycling of plastic waste. The main contents of the design for recycling are as follows [ 55 , 56 , 57 , 58 , 59 , 60 ].…”

Section: Design For Recycling Of Plastic Packagingmentioning

confidence: 99%

The Key to Solving Plastic Packaging Wastes: Design for Recycling and Recycling Technology

Ding

Zhu

2023

Polymers

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Confronted with serious environmental problems caused by the growing mountains of plastic packaging waste, the prevention and control of plastic waste has become a major concern for most countries. In addition to the recycling of plastic wastes, design for recycling can effectively prevent plastic packaging from turning into solid waste at the source. The reasons are that the design for recycling can extend the life cycle of plastic packaging and increase the recycling values of plastic waste; moreover, recycling technologies are helpful for improving the properties of recycled plastics and expanding the application market for recycled materials. This review systematically discussed the present theory, practice, strategies, and methods of design for recycling plastic packaging and extracted valuable advanced design ideas and successful cases. Furthermore, the development status of automatic sorting methods, mechanical recycling of individual and mixed plastic waste, as well as chemical recycling of thermoplastic and thermosetting plastic waste, were comprehensively summarized. The combination of the front-end design for recycling and the back-end recycling technologies can accelerate the transformation of the plastic packaging industry from an unsustainable model to an economic cycle model and then achieve the unity of economic, ecological, and social benefits.

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Section: Design For Recycling Of Plastic Packagingmentioning

confidence: 99%

The Key to Solving Plastic Packaging Wastes: Design for Recycling and Recycling Technology

Ding

Zhu

2023

Polymers

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“…Descriptions of such materials as ‘critical’ or ‘endangered’ [120] and the policy interest shown in ‘strategic’ elements [121] represent signals that resilience strategies need to be developed. Part of the solution to scarcity must come from recovery and recycling of as much material as possible, with this being built into the design of products and processes from the outset [122], with key roles being played by policies [123] as well as by S&T. Examples of the science solutions being explored include recycling of lithium from batteries [124] and of rare earth metals that are critical to many current electronic devices [125]. However, material recovery itself requires expenditure of more energy and materials, and there is always some material dispersal that makes recovery impractical (material entropy), so that recycling needs to be coupled with, or as far as possible replaced by, minimizing material consumption and waste in the first place [126].…”

Section: How Does/can Chemistry Contribute To Resilience?mentioning

confidence: 99%

A shared future: chemistry's engagement is essential for resilience of people and planet

et al. 2022

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Strengthening resilience—elasticity or adaptive capacity—is essential in responding to the wide range of natural hazards and anthropogenic changes humanity faces. Chemistry's roles in resilience are explored for the first time, with its technical capacities set in the wider contexts of cross-disciplinary working and the intersecting worlds of science, society and policy. The roles are framed by chemistry's contributions to the sustainability of people and planet, examined via the human security framework's four material aspects of food, health, economic and environmental security. As the science of transformation of matter, chemistry is deeply involved in these material aspects and in their interfacing with human security's three societal and governance aspects of personal, community and political security. Ultimately, strengthening resilience requires making choices about the present use of resources as a hedge against future hazards and adverse events, with these choices being co-determined by technical capacities and social and political will. It is argued that, to intensify its contributions to resilience, chemistry needs to take action along at least three major lines: (i) taking an integrative approach to the field of ‘chemistry and resilience’; (ii) rethinking how the chemical industry operates; and (iii) engaging more with society and policy-makers.

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“…ref. 7). Incineration or biodegradation should only be applied when the quality of a chemical or material has decreased so much that further reuse or recycling is no longer an option (see Fig.…”

Section: Introductionmentioning

confidence: 99%

Fermentation for the production of biobased chemicals in a circular economy: a perspective for the period 2022–2050

et al. 2022

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

Cited by 32 publications

References 21 publications

The Key to Solving Plastic Packaging Wastes: Design for Recycling and Recycling Technology

The Key to Solving Plastic Packaging Wastes: Design for Recycling and Recycling Technology

A shared future: chemistry's engagement is essential for resilience of people and planet

Fermentation for the production of biobased chemicals in a circular economy: a perspective for the period 2022–2050

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