Textile Recycling

Another alternative to recycling operation is the recovery process, where the textile waste is subjected to thermal recovery by employing a recovery operation in waste-to-energy power plants. It is still being practiced; however, it is very likely to be commercialized at full scale in a few years down the lane.

Current and future recycling technologies

The future recycling methods will essentially focus on the molecular separation of the different components in the fabric by employing a combination of existing chemical recycling with fast, simple, and energy-intensive engineering that makes the process continuous and reliable. Also, the emergence of new technologies such as the internet of things will enable textile waste sorting and identification in an efficient manner, which will aid the textile recycling value chain. Exhibit 3 provides a detailed overview of future textile recycling methods.

Some of the existing/ current technologies are:

• Advanced mechanical recycling:
  • Closed-loop mechanical recycling: It involves the disintegration of waste textiles into discrete fibres. Unlike the existing mechanical methods, it yields fibres without losing its mechanical properties, especially rigidity and strength
  • Open-loop mechanical recycling: It employs cutting fibres before subjecting them to the melt-blowing process, where it is broken down to individual fibres. After which, it is web formed and then dried to obtain the final product. it is used, for instance, to make individual pads for mattresses
• Thermal recycling methods:
  • It aims in generating energy products like fuel or the heat itself. The three prominent technologies to be used for this purpose are hydrothermal treatment, pyrolysis, and gasification.

Some of the promising future technologies are:

• Chemical recycling methods
  • Glycolysis: The glycolysis products from the PET waste will be used to synthesize degradable co-polyesters.
  • Ammonolysis: Being carried out in the presence of amino acids, it will be primarily used to convert nylon 6 and nylon 6,6 to other value-added chemicals
  • Hydrolysis: It is very versatile, as it can be used to process mixed fabrics like cotton, wool, and polyester. Even though it is of different types, the three main kinds which are gaining more traction in the recent days are – enzymatic hydrolysis, alkali hydrolysis, and acid hydrolysis
• Enzymatic treatment:
  • Enzymes are biocatalysts that increase the rate of chemical reactions. Also, they are highly selective so they only act on particular substrates and produce only the desired products. For instance, cellulose which can be obtained from both fungi and bacteria category can be used in cellulose hydrolysis

Players involved in the textile recycling ecosystem

Some of the most prominent players in the textile recycling sector on a global scale are given in this section. Exhibit 4 provides an overview of various players in the market and their key figures.

• Ambercycle: Their technology enables them to synthesize virgin grade raw materials from textile waste. This way, the need for fossil-based materials can be eliminated.
• BlockTexx: It owns separation of fibre technology, a proprietary technology that separates polyester and cotton materials of any condition or color back into its high-value raw materials of cellulose and PET.
• FENC: It launched the TopGreen ChemCycle Process development project, which aims to develop the chemical recycling and treatment technology to recycle only polyester textile
• Infinited fibre: Their patented technology is used to convert cellulose-rich waste to premium-quality super fibres for the textile industry
• Ioncell: They use a technology that can process worn-out garments by mechanically grounding it before dissolving it in an ionic liquid, and subsequent steps to generate new fabrics.
• Lenzing: Their REFIBRA technology upcycles pre-consumer cotton and post-consumer garments to produce new Lyocell fibers.
• Tyton Bioscience: They can convert PET, poly-cotton blends to the original fibre materials, which can be used as raw material for the new fabrics.

Many global nations, especially Europe have come up with new projects to upscale the textile recycling initiatives. Some of the most prospective projects are as follows:

• RESYNTEX: It is funded by the European Union’s Horizon 2020 innovation program, and the project involves the biochemical processing of waste textiles to create new polyester bottles, resins or adhesive, and value-added chemicals.
• TEX2MAT: It is an Austrian research project aimed at developing circular economy-based recycling processes for multi-material textiles. Especially focussing on, cotton/polyester textile wastes, separated from pre-and post-consumer sources.

With the technological advancement, it is now possible for many mills to produce virgin quality textiles via mechanical recycling, without the need to blend in virgin content. Good examples are EcoSimple, a producer of a variety of patterned recycled linen and cotton fabrics, and Euromaglia, which specializes in recycled wool and cashmere. Recycle leather has developed technologies to convert leather garden gloves to different types of leather suited for valued accessories like shoes and handbags.

Conclusion

Fiber production is projected to rise in the future, while the lifetime of textile products is continuously declining. Without consumers’ contribution, these trends will only be aggravated. General awareness for sustainable action should be established to begin for changes in these trends. For an efficient textile waste management strategy, it is essential that textiles are collected, separately from the waste.

To reach the circular economy goals, the end-of-life textiles must be recycled in such a way that the produced fiber materials must possess similar properties to the virgin material. While this is a technically achievable strategy for single-material textile wastes, multi-material textiles are a problem for recycling purposes. These materials should therefore be circumvented and a design for recycling approach must be established in the textile and apparel industry.

Nowadays novel recycling techniques, like further development of biochemical recycling processes, chemical recycling of synthetics, combined mechanical-chemical recycling are on the rise due to the combined efforts of government legislation and high-tech companies, which are striving for innovation in this field.

Though there are some obstacles to recycling, such as ineffectual waste collection and sorting systems, low priced virgin materials in the market weakening demand for recycled materials, upcoming textile waste recycling innovations are gaining more traction in recent years and funding gaps are being bridged to speed up the scaling of these technologies in a commercial scale.

References

1. Recent trends in sustainable textile waste recycling methods: current situation and future prospects
2. Possibility routes for textile recycling technologies
3. Breakthroughs in textile recycling technologies
4. Life cycle assessment for reuse/recycling of donated waste textiles compared to use of virgin material: An UK energy-saving perspective
5. Enzymatic hydrolysis of waste cellulose
6. Acid hydrolysis of cellulose-based waste textiles
7. Top 30 clothing and textile recycling start-ups