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1. Recycling of Blended Fabrics for a Circular Economy of Textiles: Separation of Cotton, Polyester, and Elastane Fibers

   https://doi.org/10.3390/su16146206  

   Choudhury, Khaliquzzaman; Tsianou, Marina; Alexandridis, Paschalis (July 2024, Sustainability)

   The growing textile industry is polluting the environment and producing waste at an alarming rate. The wasteful consumption of fast fashion has made the problem worse. The waste management of textiles has been ineffective. Spurred by the urgency of reducing the environmental footprint of textiles, this review examines advances and challenges to separate important textile constituents such as cotton (which is mostly cellulose), polyester (polyethylene terephthalate), and elastane, also known as spandex (polyurethane), from blended textiles. Once separated, the individual fiber types can meet the demand for sustainable strategies in textile recycling. The concepts of mechanical, chemical, and biological recycling of textiles are introduced first. Blended or mixed textiles pose challenges for mechanical recycling which cannot separate fibers from the blend. However, the separation of fiber blends can be achieved by molecular recycling, i.e., selectively dissolving or depolymerizing specific polymers in the blend. Specifically, the separation of cotton and polyester through dissolution, acidic hydrolysis, acid-catalyzed hydrothermal treatment, and enzymatic hydrolysis is discussed here, followed by the separation of elastane from other fibers by selective degradation or dissolution of elastane. The information synthesized and analyzed in this review can assist stakeholders in the textile and waste management sectors in mapping out strategies for achieving sustainable practices and promoting the shift towards a circular economy. 

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2. Theoretical Method for Characterizing Textile Failure Mechanics in Mechanical Recycling With Carded Drums

   https://doi.org/10.1115/MSEC2023-104361  

   Teixeira França Alves, Paulo Henrique; Clarke-Sather, Abigail; Carlson, Sam; Martini, Angela (June 2023, American Society of Mechanical Engineers)

   Due to the increasing speed of production, sale, and discard of home and apparel products, recycling of textiles is important for supporting the UN’s Sustainable Development Goal of Responsible Consumption and Production. In 2020, textile production was estimated to be responsible for 35% of primary microplastics released into the environment, 20% of global clean water pollution, and 10% of global greenhouse gas emissions. In 2018 the US generated around 17 million tons of textile waste and only 14.7% was recycled. Drum-operated textile shredding, a commonly utilized mechanical textile recycling technique, is not yet fully characterized. Even though there are many shredding machines that perform this process, the parameters that influence high-quality fiber output have not been researched; discovering ways to improve reusable fiber output is still a challenge. This research investigates the theory behind carded (toothed) drum textile shredding including how to improve the process outcome in order to obtain more reusable fiber and fewer textile pieces and dust. The mechanics of the textiles and fibers under tensile and shear stresses from the drums and drum teeth respectively were described to relate the textile material failure behavior to shredding process fiber outputs. Focusing on the interactions of the feeding drums and shredding drum, the drum-textile and tooth-yarn failure mechanics were characterized. By decreasing the teeth size and increasing the relative speed between drums, it is expected to increase the shear failure ratio, thus improving the shredding system. With this, it is expected that manufacturing new and better materials from recycled fibers becomes a possibility. 

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3. ReSpool : Scaling a circular supply chain for recycled textiles

   https://doi.org/10.1002/amp2.70000  

   Thomas, Kedron; Clarke‐Sather, Abigail_R; Cobb, Kelly; Cao, Huantian (February 2025, Journal of Advanced Manufacturing and Processing)

   Abstract ReSpool is a transdisciplinary partnership among academia, government, industry, and nonprofit entities created in 2022 to develop and demonstrate a transferable model for the recycling of postconsumer textile and apparel waste into new textile products. ReSpool's engineering and creative teams have innovated proprietary technologies including the Fiber Shredder, which enables textile‐to‐fiber shredding for high‐value applications, and a set of processes for the manufacture of yarns and nonwoven textiles from recycled fibers. ReSpool's circular supply chains begin with discarded clothing collected by Goodwill organizations in the two test regions and involves partnerships with Goodwill to recruit and train workers and install in‐house recycling operations. ReSpool then works with textile manufacturers and home goods and apparel retailers on high‐value applications through waste‐led materials and product development. ReSpool takes a systems‐based approach to sustainability research and problem‐solving. This article briefly overviews the “systems thinking” framework and demonstrates how core principles of this framework structure the team's objectives, activities, and innovations. Finally, the article contributes to current debates regarding systems thinking and circularity by presenting a rationale for systems‐based sustainability research and practice ratcheted to regional systems. By focusing on regional factors, connections, and opportunities, ReSpool aims to maximize its flexibility, relevance, and impact while enabling tailored replication of the model across diverse communities. In this way, ReSpool offers an innovative, circular materials model for the textile and apparel industries, turning textile waste into a source of business innovation, sustainable economic development, and skills training for communities across the country. 

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4. Unfabricate: Designing Smart Textiles for Disassembly

   https://doi.org/10.1145/3313831.3376227  

   Wu, Shanel; Devendorf, Laura (January 2020, Proceedings of the 2020 CHI Conference on Human Factors in Computing Systems)

   Smart textiles development is combining computing and textile technologies to create tactile, functional objects such as smart garments, soft medical devices, and space suits. However, the field also combines the massive waste streams of both the digital electronics and textiles industries. The following work explores how HCI researchers might be poised to address sustainability and waste in future smart textiles development through interventions at design time. Specifically, we perform a design inquiry into techniques and practices for reclaiming and reusing smart textiles materials and explore how such techniques can be integrated into smart textiles design tools. Beginning with a practice in sustainable or "slow" fashion, unravelling a garment into yarn, the suite of explorations titled "Unfabricate" probes values of time and labor in crafting a garment; speculates how a smart textile garment may be designed with reuse in mind; and imagines how electronic and textile components may be given new life in novel uses. 

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5. PunchPrint: Creating Composite Fiber-Filament Craft Artifacts by Integrating Punch Needle Embroidery and 3D Printing

   https://doi.org/10.1145/3544548.3581298  

   Del Valle, Ashley; Toka, Mert; Aponte, Alejandro; Jacobs, Jennifer (April 2023, 2023 CHI Conference on Human Factors in Computing Systems (CHI '23))

   New printing strategies have enabled 3D-printed materials that imitate traditional textiles. These filament-based textiles are easy to fabricate but lack the look and feel of fiber textiles. We seek to augment 3D-printed textiles with needlecraft to produce composite materials that integrate the programmability of additive fabrication with the richness of traditional textile craft. We present PunchPrint: a technique for integrating fiber and filament in a textile by combining punch needle embroidery and 3D printing. Using a toolpath that imitates textile weave structure, we print a flexible fabric that provides a substrate for punch needle production. We evaluate our material’s robustness through tensile strength and needle compatibility tests. We integrate our technique into a parametric design tool and produce functional artifacts that show how PunchPrint broadens punch needle craft by reducing labor in small, detailed artifacts, enabling the integration of openings and multiple yarn weights, and scaffolding soft 3D structures. 

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