Textile recycling is the process of recovering fiber, yarn, or fabric and reprocessing the material into new, useful products.[1] Textile waste is split into pre-consumer and post-consumer waste and is sorted into five different categories derived from a pyramid model.[2][3] Textiles can be either reused or mechanically/chemically recycled.[4][5]

There has been a shift in recent years toward recycling textiles because of new regulations in several countries[6]. In response, companies are developing products from both post-consumer waste and recycled materials such as plastics. Results from academic studies demonstrate that textile reuse and recycling are more advantageous than incineration and landfilling.[7]

Waste

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Most materials used in textile recycling can be split into two waste categories: pre-consumer and post-consumer.[2]

Pre-consumer

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Pre-consumer waste involves secondary materials from textile, fiber, and cotton industries.[2] These products are repurposed for other industries i.e. furniture, mattress, coarse yarn, home building, automotive, paper, and apparel.[2]

Post-consumer

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Post-consumer waste consists of textile garments and household articles that have been discarded by their owners. These textile articles are typically discarded because they are damaged, worn out, or outdated. 85% of post-consumer waste in the United States, however, is found in landfills.[2] The remaining post-consumer waste can be directed towards second-hand retailers to be resold or passed on to warehouses dedicated to textile recycling.

Categories

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Textiles are sorted into categories according to the pyramid model, which organizes textiles by their quality and usability.[3] These category placements determine which processes are used to recycle or reuse the textile.[3] Such categories are: textiles for used clothing markets, textiles for conversion, wiping and polishing clothes, textiles sent to landfills and incinerators, and diamonds.[3]

Diamonds

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Diamonds make up 1-2% of recycled textiles.[2] Despite being the smallest category, diamonds generate the largest amount of profit per item for recycling companies.[2] Diamonds are older, trendier clothing items that are from high-end, well-known brands.[2] Clothing and accessories that are considered diamonds include couture, Harley Davidson, Levi’s, Ralph Lauren, and luxury fibers (i.e. cashmere).[2] These second-hand clothing articles are in high demand and can be sold online, in retail boutiques, or in vintage shops.[2]

Landfill and incineration

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Around 7% of recycled textile products are either incinerated or placed in a landfill.[2] Textiles that are placed in landfills have no value and are unable to be repurposed; this process is costly and is avoided when possible.[2] Textiles can also be incinerated to produce electrical energy.[2] This practice is more common in Europe than in the United States because European boiler systems have higher capabilities than American boiler systems.[2] Though incinerating municipal solid waste (MSW) is not yet feasible in the United States, over two thirds of MSW is incinerated in countries such as Denmark, Japan, and Switzerland.[8] The energy values of burning MSW have been comparable with oil in terms of calories; however, there are obstacles to this process. These obstacles include increasing incineration efficiency and reducing harmful byproducts of incineration.[8]

Wiping and polishing cloths

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Around 17% of used textiles are sorted into the wiping and polishing cloth category.[2]  These textiles are deemed un-wearable and are then used to create wiping and polishing cloths.[2] Wiping and polishing cloths can be made from a combination of oleophilic and hydrophilic fibers which are often useful in industrial application.[2] Textiles, such as T-shirts, are commonly used to create these cloths due to its naturally absorbent cotton fibers.[2]

Conversion to new products

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29% of textile waste is reengineered into new products if deemed unusable.[2] Usability depends on whether or not the textiles are stained or torn beyond repair.[2] Shoddy and mungo are the two main results of the reengineering process.[2]

Shoddy involves creating new yarn products from the old materials, and is one of the most historical examples of textile recycling[8]. One of the largest producers of shoddy yarn is Panipat in North India with over 300 mills.[9] The majority of shoddy in Panipat is used to create knit blankets, making up over 90% of the blankets that are given to communities in disaster relief[9].

Mungo was invented after shoddy and refers to the process of using textile clippings to make wool. This wool is exported to European countries, whose cooler climates and flammability regulations result in a greater need for mungo[8].

Shoddy and mungo can be utilized for both high and low quality products. These reengineered fibers have been used in cashmere sweaters and in stuffing for furniture, automobiles, and punching bags.[2]

Used clothing markets

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48% of textiles are sorted into the used clothing markets category.[2] Western countries export used textiles to developing countries or to disaster relief.[2] In developing nations, used Western textiles are highly valued as they are often more affordable than local textiles.[2] Used Western textiles are also sold to the lower and middle classes in more developed countries whose incomes are not large enough to purchase more-expensive, local textiles.[2] Because textile exportation is a global industry, exporters must be conscious of the varying trade regulations and restrictions in different countries.[3]

Processing - ADDED TO WIKI

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Reuse

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Textile reuse is the preferable processing method because it extends original product's lifetime.[4] Reuse occurs when textile owners rent, trade, swap, borrow, inherit products through second-hand stores, garage sales, online/flea markets, or charities.[4]

Recycling

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Mechanical

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Mechanical processing is a recycling method in which textile fabric is broken down while the fibers are still preserved.[5] Once shredded down, these fibers can be spun to create new fabrics.[5] This is the most commonly used technique to recycle textiles and is a process that is particularly well developed for cotton textiles.[5] Mechanical processing protocols can differ depending on the material, so it also requires several levels of sorting before the process begins.

Textiles must be separated by fabric composition and by color to avoid re-dying and bleaching of materials.[9] Once sorted, the textile materials can then be shredded, washed, and separated into smaller fibers.[9] These individual fibers are then aligned together in a process known as carding in preparation to be spun together. Some fibers, including cotton, must be spun along with a carrier fiber to maintain higher quality.[9] These carrier fibers are most commonly cotton, organic cotton, or polyester. Once the fibers are spun into new yarn, they can be used to create new textiles.[5] This process functions as a semi-closed loop of recycling.[5]The number of times a material can be recycled is dependent on the quality of the fibers, which decreases with each cycle of mechanical processing.

Mechanical processing can also be used with materials other than textiles. One common example of this is polyester.[9] With the case of polyester, the recycled materials are plastic bottles made of polyethylene terephthalate (PET).[9] In a similar manner to textiles, plastics are sorted by color and type when they arrive at recycling facilities.[9]The plastic is then shredded and washed to break it down and remove contaminants.[9] The dried plastic remnants are molded into PET pellets and then undergo extrusion to create new fibers.[9]These new fibers can then be used to create new textiles.

Chemical

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Chemical processing occurs when textile reuse is infeasible. [2] This process is not yet widely implemented, but there are companies that are researching and integrating chemical recycling.[2] The major small scale production sites are from Eco Circle, Worn Again, Evrnu, and Ioncell.[2]

Chemical recycling is used on synthetic fibers, such as Polyethylene terephthalate (PET).[2] These synthetic fibers can be broken down to create fibers, yarn, and textiles.[2] For PET, the starting materials are first broken down to the molecular level by using chemicals that facilitate glycolysis, methanolysis, hydrolysis, and/or ammonolysis.[2] This act of depolymerization also removes contaminants from the starting material such as dyes and unwanted fibers.[10] From here, the material is polymerized and used to produce textile products.[9]

Unlike the mechanical method of recycling, chemical recycling produces high-quality fibers similar to the original fiber used.[9] Therefore, no new fibers are needed to support the product of the chemical process.[9] Different chemicals and processes are used for other materials such as nylon and cellulose-based fibers, but the overall structure of the process is the same.[9]

Textiles made from recycled materials - ADDED TO WIKI

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Many companies such as Patagonia, Everlane, Heavy Eco, and Girlfriend Collective now develop their products from a combination of recycled post-consumer textile waste as well as other recycled materials such as plastics.[23][11][12][13] This can be done for textiles other than clothing as well. For example, Egetæpper is a Danish carpet manufacturing company that makes their carpets using the fibers from recycled fishnets[25].

Many of these companies also develop programs specifically designed to reduce manufacturing waste and allow their customers to recycle old articles of clothing through the same company. Glen Raven, Inc., a fabric manufacturer, engineered such a program which collects unused pieces during production and recycles them into a new fabric.[14]


One specific region that is more progressive in applications of recycled textiles is Scandinavia, which has created mainstream market products.[25] In Sweden, companies such as Lindex and H&M are including pre-consumer and post-consumer waste fibers within their new clothing lines. [25] Similarly in Finland, Pure Waste is a clothing enterprise that creates t-shirts from recycled fibers in their 95% wind powered factories [26].

Growth - ADDED TO WIKI

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A shift toward recycled textiles

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New regulations for the textile industry have been introduced in several countries that favor the use of recycled materials. On March 30th, 2022, the European Commission published the EU Strategy for Sustainable and Circular Textiles which outlines the EU’s action plan to achieve better sustainability and regulation within the textile industry.[6] The European Commission’s goal for 2030 is to encourage consumers to invest in high quality products rather than “fast-fashion”, and to ensure all textile products are durable, whether they are recycled materials or not.[6] The EU's strategy includes regulations on overproduction, reducing the release of microplastics during production, and utilizing EU Extended Producer Responsibility to ensure producers are acting sustainably.[6]

In response to shifting consumer expectations, investments in textile recycling companies have increased to achieve better sustainability in the textile industry.[15] Inditex and Bill Gates’ Breakthrough Energy Ventures invested in the start-up recycling company Circ in July 2022, which has patented new technologies to reengineer used fibers.[16] In July 2021, H&M and Adidas invested in the chemical recycling company Infinited Fiber Company (IFC) which produces a reengineered fiber that is similar to cotton and is biodegradable.[17] Goldman Sachs led an investment in mechanically recycled cotton company Recover Textile Systems in June 2022.[18]

Many luxury fashion brands are publicly displaying their investment in sustainability approaches, with a common goal to shift towards circular systems and utilizing re-engineered and/or biodegradable materials in their collections.[19]

Environmental impact

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Textile reuse and textile recycling processes are the most environmentally friendly methods of processing textiles, while incineration and landfilling are considered to be the least environmentally friendly.[7] When comparing textile reuse to textile recycling, textile reuse is more advantageous.[7] A Swedish study found that for each tonne of textile waste, textile reuse can save 8 tonnes of CO2 in terms of global warming potential (GWP) and 164 GJ of energy usage.[20] In comparison, textile recycling saves 5.6 tonnes of CO2 in terms of GWP and 116 GJ of energy usage.[20]

See Also

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References

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  1. ^ Hawley, J. M. (2009-01-01), Blackburn, R. S. (ed.), "8 - Understanding and improving textile recycling: a systems perspective", Sustainable Textiles, Woodhead Publishing Series in Textiles, Woodhead Publishing, pp. 179–199, ISBN 978-1-84569-453-1, retrieved 2022-11-02
  2. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z Hawley, J. M. (2006-01-01), Wang, Youjiang (ed.), "2 - Textile recycling: a system perspective", Recycling in Textiles, Woodhead Publishing Series in Textiles, Woodhead Publishing, pp. 7–24, ISBN 978-1-85573-952-9, retrieved 2022-11-02
  3. ^ a b c d e Hawley, Jana M. (2014-01-01), Worrell, Ernst; Reuter, Markus A. (eds.), "Chapter 15 - Textile Recycling", Handbook of Recycling, Boston: Elsevier, pp. 211–217, ISBN 978-0-12-396459-5, retrieved 2022-10-24
  4. ^ a b c Juanga-Labayen, Jeanger P.; Labayen, Ildefonso V.; Yuan, Qiuyan (2022-03). "A Review on Textile Recycling Practices and Challenges". Textiles. 2 (1): 174–188. doi:10.3390/textiles2010010. ISSN 2673-7248. {{cite journal}}: Check date values in: |date= (help)CS1 maint: unflagged free DOI (link)
  5. ^ a b c d e f Ribul, Miriam; Lanot, Alexandra; Tommencioni Pisapia, Chiara; Purnell, Phil; McQueen-Mason, Simon J.; Baurley, Sharon (2021-12-01). "Mechanical, chemical, biological: Moving towards closed-loop bio-based recycling in a circular economy of sustainable textiles". Journal of Cleaner Production. 326: 129325. doi:10.1016/j.jclepro.2021.129325. ISSN 0959-6526.
  6. ^ a b c d "Textiles strategy". environment.ec.europa.eu. Retrieved 2022-11-02.
  7. ^ a b c Sandin, Gustav; Peters, Greg M. (2018-05-20). "Environmental impact of textile reuse and recycling – A review". Journal of Cleaner Production. 184: 353–365. doi:10.1016/j.jclepro.2018.02.266. ISSN 0959-6526.
  8. ^ a b Wang, Youjiang (2010-03-01). "Fiber and Textile Waste Utilization". Waste and Biomass Valorization. 1 (1): 135–143. doi:10.1007/s12649-009-9005-y. ISSN 1877-265X.
  9. ^ a b c d e f g h i j k l Cattermole, Amanda (2019-06-10). "Fiber recycling using mechanical and chemical processes". Cattermole Consulting Inc. Retrieved 2022-11-02.
  10. ^ "A New Textiles Economy: Redesigning fashion's future". ellenmacarthurfoundation.org. Retrieved 2022-11-02.
  11. ^ "Prison Couture Mainlines Eco-Ethics | Culture | News | ERR". web.archive.org. 2012-03-24. Retrieved 2022-11-02.
  12. ^ "Environmental Responsibility - Patagonia". www.patagonia.com. Retrieved 2022-11-02.
  13. ^ "Home". Girlfriend Collective. Retrieved 2022-11-02.
  14. ^ "Sunbrella Shows Us All How Recycling Should Be Done | Waste Wise Products". www.wastewiseproductsinc.com. Retrieved 2022-11-02.
  15. ^ TFL (2022-10-10). "A Running Timeline of Sustainable Investments and M&A". The Fashion Law. Retrieved 2022-11-02.
  16. ^ Douglass, Rachel (2022-07-12). "Circular textile company Circ secures funding with backing from Inditex". FashionUnited. Retrieved 2022-11-02.
  17. ^ WW, FashionNetwork com. "H&M, Bestseller and Adidas invest in circular fibre innovation". FashionNetwork.com. Retrieved 2022-11-02.
  18. ^ Armental, Maria (2022-06-09). "Goldman Sachs Leads $100 Million Investment in Sustainable Textile Company Recover". Wall Street Journal. ISSN 0099-9660. Retrieved 2022-11-02.
  19. ^ Muthu, Subramanian Senthilkannan; Gardetti, Miguel Angel (2020-03-19). Sustainability in the Textile and Apparel Industries: Consumerism and Fashion Sustainability. Springer Nature. ISBN 978-3-030-38532-3.
  20. ^ a b Zamani, Bahareh; Svanström, Magdalena; Peters, Gregory; Rydberg, Tomas (2015-08). "A Carbon Footprint of Textile Recycling: A Case Study in Sweden: Carbon Footprint of Textile Recycling". Journal of Industrial Ecology. 19 (4): 676–687. doi:10.1111/jiec.12208. {{cite journal}}: Check date values in: |date= (help)