From the Sector

In accordance with California’s Proper Labeling of Wet Wipes law (AB 818), state wastewater agencies and industry experts went deep to find out exactly what is passing through—and clogging up—municipal wastewater systems. The Responsible Flushing Alliance (RFA) alongside the California Association of Sanitation Agencies (CASA) and the Association of the Nonwoven Fabrics Industry (INDA) released the results from the largest known domestic sewage collection study conducted to reveal what’s really being flushed down the drain – and shouldn’t be.

“We took a forensic approach to this collection study, engaging industry and wastewater experts to examine our findings and determine what exactly is being flushed and how much of it,” said Adam Link, Executive Director at CASA, a co-sponsor of the Proper Labeling of Wet Wipes Law. “Now that we have the data to see what Californians are flushing and the types of non-flushable items that are causing issues within wastewater systems, local agencies can refine their public outreach and messaging to target specific problems and educate more efficiently.”

Collection and material investigation took place in October 2023 at two locations: Inland Empire Utilities Agency (IEUA) in Southern California and Central Contra Costa Sanitary District (Central San) in the greater San Francisco Bay Area in Northern California. Wastewater and wipes experts collected, sorted and identified more than 1,700 items pulled from the two locations during peak flow times. Kennedy Jenks, an independent engineering firm, designed the study and compiled the findings into the report.

Why Study What’s Being Flushed?
When products that aren’t meant to be flushed down the toilet wind up in the sewer system, it can cause serious threats to public and environmental health. In fact, estimates show that local public agencies throughout California (and the ratepayers they represent) are spending more than $47 million annually to repair wastewater treatment equipment and respond to sewer overflows caused by improper flushing.

“Part of keeping communities healthy requires not flushing things we shouldn’t,” said Lara Wyss, President of the RFA. “However, the data to support which non-flushable items to target as part of education campaigns has been lacking. That’s likely why when we surveyed Californians about what they are flushing, the results revealed that approximately 25% think baby wipes are flushable (which is never true) and 60% self-reported that they flushed something they knew they shouldn’t have.2 Our study results reinforce that finding, as more than 99% of materials collected were items that shouldn’t have been flushed.”

The breakdown of items collected from pipes at the two study locations included:
•    34.1% wipes labeled with the “Do Not Flush” symbol (baby wipes, cleaning wipes, makeup wipes, etc.)
•    64.9% other non-flushable items (paper towels, period products, trash, etc.)
•    0.9% wipes labeled as flushable

“We pulled material larger than 1-inch square directly from the bar screens, and it wasn’t until everything was sorted and identified that we could see what we actually had,” said Matt O’Sickey, Director of Education and Technical Affairs, INDA. “There were a lot of paper towels and baby wipes and all of the ‘Do Not Flush’ labeled wipes we collected were fully intact, showcasing why they should never be flushed.”

What Not to Flush—and How We Tell Consumers
According to the Proper Wet Wipes Labeling law, manufacturers of non-flushable wipes, including products such as baby wipes, cleaning wipes, makeup removal wipes and many others that are primarily used in a bathroom setting must include the “Do Not Flush” symbol on the front of the packaging.
The #FlushSmart consumer education campaign promotes the “Do Not Flush” symbol and provides information on what should and should not be flushed. The message shared with consumers is simple: Look for the “Do Not Flush” symbol on wipes packaging, and if you see it – throw the wipe out. Extrapolating from the results of this study, refraining from flushing “Do Not Flush” labeled wipes, paper products and feminine hygiene products would capture over 90% of items clogging sewers.

Fashion for Good's Sorting for Circularity framework expands to address the challenge of ensuring rewearable textiles remain in use as opposed to finding their way into global waste streams or landfills. This 18-month project tests automated sorting technologies using artificial intelligence and machine learning to optimise the sorting of rewearable garments and enable greater circularity.

This project will test automated sorting technologies using machine learning and artificial intelligence (AI) to collect product information — such as colour, style, garment type, and quality. This will enable sorters and brands to make better decisions and sort efficiently based on product data and criteria from local, European, and export resale market requirements, thus optimising the flow of textiles to achieve their highest value potential.

To ensure accuracy and representation in capturing data on the flow of textiles within the EU and export markets, this project will focus on specific geographical regions: Lithuania (Nordic/Baltic), the Netherlands (Western), Poland (Central-Eastern), and Spain (Southern Europe).

The findings will be shared in a report with a supporting business case and implementation roadmap to inform investment decisions in infrastructure, Circular Business Models (CBM) and repair centres.

The Rewear Project builds on Fashion for Good’s Sorting for Circularity framework initiated in 2021 and subsequently launched in Europe, India and the United States harmonising the collection, sorting and recycling industries in order to advance textile-to-textile recycling technologies and the resale industry.

It is funded by brand partners adidas, BESTSELLER, Bonprix, C&A, Inditex, Levi Strauss & Co., Otto Group, PVH Corp., and Zalando. Circle Economy Foundation leads the creation and implementation of the methodology, with support from Consumption Research Norway, Oslo Metropolitan University and Revaluate.

HeiQ introduces a 100% biobased and long-lasting cosmetic finishing technology for textiles to the market. The newest addition to the HeiQ portfolio harnesses the power of active probiotics and selected prebiotics to enhance the skin microbiome, turning the human’s largest organ into the best-looking one.

HeiQ Skin Care is a synbiotic textile finish aimed at providing a balanced microbiome for glowing skin, even after repeated use and washing of textiles. Unlike conventional products, HeiQ Skin Care utilizes slow-release prebiotics and probiotics seamlessly integrated into a biobased textile matrix, enriching the skin's microbiome diversity, and offering long-lasting cosmetic benefits.

The synergistic combination of prebiotics and probiotics, known as synbiotics, delivers a soothing cosmetic skin treatment while relaxing, working, or sleeping. Probiotics not only restore and improve the skin's natural balance but also enhance its self-repair capabilities. Synbiotics promote skin renewal, rebalancing, and improved appearance, reducing the signs of aging and establishing a favorable environment for the skin's natural repair mechanisms.

A second skin that takes care of the first
The skin, the largest organ in human body, is home to a diverse community of microorganisms called the skin microbiome. It plays a crucial role in maintaining good skin condition, acting as a protective barrier against harmful agents. However, various factors, such as hormones, diet, smoking, environmental exposures, and excessive UV radiation, can disrupt its balance, leading to skin conditions like rashes, acne, psoriasis, rosacea, skin irritation, redness, eczema, and odor. Maintaining a balanced skin microbiome is essential for preserving skin integrity.

HeiQ Skin Care is suitable for all textile fibers, both natural and synthetic, and can be applied to all textile items that come in direct contact with the skin. This versatility makes it an ideal choice for daily use- at work, during sports, leisure activities, or as bedding items like bed sheets and pillows.

Intensive wear trials conducted during the development stage have proven the consistent release of synbiotics (prebiotics and probiotics) onto the skin, creating conditions to foster a well-balanced microbiome.

Digital fashion outlet Otrium announces the launch of a dedicated garment refurbishment and repair programme for damaged returns following a successful pilot scheme. The initiative is being run in partnership with Bleckmann, experts in supply chain management for fashion and lifestyle brands. Working with Bleckmann’s team of circular fashion experts from The Renewal Workshop, Otrium is taking the next step in its strategic journey to help reduce the number of that might ultimately end up in landfills or destroyed.
 
Most of the returns that Otrium currently receives can be easily restored and put back on sale. However, in rare cases, returned items are damaged. “Preventing waste is an important part of Otrium’s DNA, and thanks to our partnership with Bleckmann and their Renewal Workshop team, we can now repair the majority of damaged returns and put them back into circulation,” said Kevin Carolan, Director of Logistics at Otrium. “We are happy that we can use our position in the fashion supply chain to create lasting change and accelerate towards our mission of reducing the volume of garments that go to landfill.”

Since 2020, Otrium is exploring refurbishment and repairs with their third-party logistics provider Bleckmann. In April 2023, both partners started a three-month pilot at Bleckmann’s facility in Almelo, the Netherlands, to expand the programme with a broader range of repairs and optimised processes through data use. During the pilot, the Renewal Workshop team at Bleckmann refurbished more than 1,000 returned garments, shoes and accessories for Otrium each month.

“With hundreds of high-end labels on the platform, we needed an efficient solution tailored to the needs of a wide range of products – from shoes and coats to bags,” explained Marlot Kiveron, Head of Sustainability at Otrium. “The Renewal Workshop team worked closely with us to develop a streamlined and scalable process that could grow in line with our ambitions, delivering like-new repairs at the speed of e-commerce. Their combination of purpose, professionalism, agility and expertise makes them the ideal partner for this kind of project.”
 
Bleckmann’s integrated data capabilities were also crucial to the success of the partnership. “Data collection and analysis can be vital in demonstrating the commercial viability of sustainability initiatives,” said Tamara Zwart, Director of Renewal at Bleckmann. “Using our advanced stock tracking systems, we determined that 70% of the renewed Otrium stock had been sold within seven weeks. We’re all delighted with the results!”
Furthermore, carbon-tracking software Vaayu calculated that on average, a refurbished return sold on Otrium avoids 2.760kg of carbon emissions and 69g of waste proofing that this programme can have a positive impact on both: the planet and the business.

Having established the business case, the team decided to expand the initiative beyond the pilot phase. “This project is a milestone in our sustainability journey,” concluded Marlot. “It’s a key part of our ongoing commitment to finding more ways to reduce our environmental impact while helping to ensure that more clothes get worn. By the end of 2023, we aim to repair at least 25,000 damaged garments. Together with Bleckmann and their renewal experts, we’re well on our way to proving that this circular business model can be a valuable part of our future growth.”

From April 25^th to 27^th, 2023, the Institute of Textile Machinery and High Performance Material Technology (ITM) of TU Dresden will be exhibiting at the pavilion SAXONY! at JEC World 2023.

The ITM will provide a comprehensive overview of its current research in the field of machine and product development along the entire textile process chain.

The upcoming JEC 2023 exhibition will highlight innovative Customised Connective Cores (CCC), which are custom-made core-insert structures additively manufactured using cellular metal and a form-fit integrated insert. These CCCs can be seamless integrated either as patches or as full-surface core material into lightweight panels, offering significantly improved load-bearing behavior (especially 4 times the load-bearing capacity and fail-safe behavior) compared to existing technologies. This breakthrough opens up new possibilities for fastening lightweight panels.

Another highlight at the exhibition is the repair process for fibre-reinforced composites (FRP) developed at the ITM. Instead of mechanically grinding the damaged area, the matrix in the repair area is locally dissolved using a UV-rays-induced depolymerisation process. Damaged fibres can thus be replaced by a customized repair patch. Free yarn ends on the textile repair patches are spliced with the UV-exposed yarn ends in the repair area using an adapted splicing process. In this way, a very clean, simplified and mechanically improved repair area can be achieved compared to the state of the art.

The diverse possibilities offered by the structure and process simulation of textile high-performance materials and textile manufacturing processes will also be presented. By means of multi-scale modelling and simulation, a profound understanding of materials and processes is achieved at the ITM. Finite element models on the micro, meso and macro scale have been developed and validated for this purpose. Examples from current ITM research projects demonstrate the various possibilities and areas of application of modern simulation methods in the field of textile technology.

Moreover, an innovative process for the integral manufacturing of 3D rib-stiffened preforms with complexly arranged stiffeners in 0°, 90° and ± 45° orientation was developed and successfully implemented at the ITM. Due to the process-integrated structure fixation and the continuous fibre reinforcement between shell and rib structure, the 3D preforms are perfectly suited for the production of highly load-bearing FRP components with increased bending stiffness, which will be exhibited at JEC. Hence, the lightweight construction potential of high-performance fibres can be fully exploited.

A successfully established development are partially flowable 2D textile reinforcement fabrics that are continuously manufactured in one single process step. For this purpose, the entire process chain was developed at the ITM, which allows a cost-effective and high-volume production of load-bearing thermoplastic 3D FRP components with continuous fibre reinforcement between shell and stiffeners.

At JEC 2023, the ITM will also present a partially embedded textile latice girder as reinforcement for carbon concrete applications, which was produced by means of an innovative textile manufacturing process based on the multiaxial warp knitting technology. Through the development of a customized warp insertion, manipulation and take-off system as well as appropriate shaping methods, it is now possible to produce tailored textile semi-finished products, e.g. for use in wall and ceiling panels. These textile latice girders represent a resource-saving alternative to conventional steel girders due to the reduced among of concrete required and the additional cavity for media and cable guidance.

The integration of textile actuators and sensors in FRP provides structures with additional functionalities. The research and application of such interactive FRP with different matrix materials (e.g. with thermoset, elastomer or concrete matrix systems) for structural health monitoring or adaptive systems is one of the key research areas of the ITM.

Moreover, the development and implementation of innovative yarn constructions based on recycled high-performance fibres (e.g. rCF, rGF, rAR) for sustainable FRPs is successfully promoted at ITM. By use of a special carding machine, recycled fibres are opened up, separated and joined to form a wide, uniform ribbon. Subsequently, innovative hybrid yarn constructions made of evenly mixed recycled high-performance and thermoplastic fibres with variable fibre volume fractions can be manufactured by means of various spinning technologies. Selected yarn constructions and components will be showcased at JEC.

Launched this September, the new Horizon Europe project CISUTAC will support the transition to a circular and sustainable textile sector. As part of a consortium of 27 partners working on the project, TEXAID will among others support the project with sorting, disassembly and repair trials.

The production and consumption of textile products continue to grow, together with their impact on the environment, due to a lack of reuse, repair and recycling of materials. Quality, durability, and recyclability are often not being set as priorities in the design and manufacturing of clothing (EU Strategy for Sustainable and Circular Textiles, March 2022).  

CISUTAC aims to remove current bottlenecks in order to increase textile circularity in Europe. The objective is to minimise the sector’s total environmental impact by developing sustainable, novel, and inclusive large-scale European value chains.  

The project will cover most parts of the textile sector by working on two material groups representing almost 90% of all textile fibre materials (polyester, and cotton/cellulosic fibres), and focusing on products from three sub-sectors experiencing varying circularity bottlenecks (fashion garments, sports and outdoor goods, and workwear).  

CISUTAC will follow a holistic approach covering the technical, sectoral and socio-economic aspects, and will perform three pilots to demonstrate the feasibility and value of:

• Repair and disassembly
• Sorting (for reuse and recycling)
• Circular garments through fibre-to-fibre recycling and design for circularity

To realise these pilots, the consortium partners will:

• Develop semi-automated workstations
• Analyse the infrastructure and material flows
• Digitally enhance sorting operations (for reuse and recycling)
• Raise awareness among the consumers and the textile industry

As part of the CISUTAC consortium, TEXAID, will conduct different trials of sorting, repair, and disassembly, and be active in the LCA and Standardisation work packages.

Bodyshops can now take advantage of the vehicle refinish industry’s first repair calculator to measure, manage and reduce carbon emissions, which has been developed by AkzoNobel.

Designed to help customers improve their carbon footprint when using the company’s premium refinish products, the CO₂eRepairCalculator* is part of a new initiative which aims to encourage bodyshops to become more sustainable.

The tool is the latest digital innovation from AkzoNobel focused on making a long-lasting difference to customers. It identifies the carbon levels associated with the painting and drying process – including the energy consumed – and is linked directly to the vehicle refinishing products being used. It also provides data relating to the emission of volatile organic compounds (VOCs), therefore helping customers to understand where improvements can be made.

When using the tool, the emissions and energy consumed are calculated based on a controlled two-panel repair in a spray booth to Greenhouse Gas Protocol accounting standards. The results are presented in an online dashboard, which allows local energy prices to be factored in.

The launch means it will now be easier for bodyshops to take positive action in an effort to meet their sustainability and carbon reduction targets. This is becoming increasingly important, as insurance companies are putting greater pressure on preferred bodyshop partners to cut their emissions in line with supply chain ambitions that meet the UN Sustainable Development Goals.

The CO₂eRepairCalculator is currently being introduced in the UK market to Sikkens customers (with Lesonal to follow shortly). It will be rolled out across markets in Europe during the next few months.

*CO₂e stands for carbon dioxide and equivalent gases. The tool measures carbon dioxide (CO₂) and equivalent gases such as methane (CH₄) and nitrous oxide (N₂O), which all fall under the term greenhouse gases (GHGs).

Five players in the textile service industry announce the establishment of Cibutex (Circular Business Textiles). This new cooperative is dedicated to the recycling and recovery of fibres from discarded textiles. Cibutex wants to contribute to a circular textile chain through cooperation in the whole sector.

The textile service has been implementing key Circular Economy solutions for some time: rental, care, repair and reuse of textiles for professional use. "As an industry, we are in a position to delve even deeper into the world of the circular economy. Every linen rental company has many of the same products, which go through the same process every time: the textiles are washed, sorted and collected again after the period of use. After many washes, the textiles are rejected. With this rejected textile, we see a unique opportunity to finally put the idea of a closed textile chain into practice. The used textiles that have reached the end of their useful life can be recycled on an industrial scale and the fibre raw materials can be recovered to make new textiles. We want to exploit this potential to the full by founding Cibutex, a cooperative for all textile service providers in Europe," says Cibutex director Jan Lamme, explaining the background of the unique project.

Cross-competitive goal
The founders of Cibutex are four well-known, competing textile service companies and one supply partner: Blycolin Textile Services (Zaltbommel, NL), Dibella (Aalten), Edelweiss Groep (The Hague), Lamme Textile Management (Amsterdam, NL) and Nedlin (Elsloo, NL). The companies have deliberately joined forces in order to implement sustainability in textiles and clothing by means of closed material cycles throughout the sector.

"Important resources are hidden in our B2B used textiles. We want to recover these in cooperation with relevant recycling companies and thus promote textile recycling as demanded by the EU Commission. We have come together to achieve sufficient critical mass to determine the final recycling of our discarded laundry, with the goal of moving from textiles to textiles," says co-founder Luuk de Win (Nedlin).

Sustainable eco-balance
"By recycling the raw materials of our used textiles, we contribute to reducing the social, environmental and climate impacts of the textile industry related to cultivation and production, and this leads to a long-term improvement of the ecological footprint of our industry," adds co-founder Marc van Boekholt (Blycolin).

Increasing value
To make the final transformation step of the circular economic model "textile service" a success, any European textile service company can become a member of Cibutex. The cooperative takes care of the collection, transport to the recycling partners and remuneration for the old textiles, which are now limited to bed linen, table linen and bath linen. In the future, however, the group wants to develop solutions for other textiles as well. For example, the recycling of workwear is also on the agenda. The founders of Cibutex agree that this too is a treasure trove of resources that must be addressed.

118 organisations signed today the TCLF (= Textiles, Clothing, Leather and Footwear) Pact for Skills, an initiative promoted by the European Commission and coordinated by EURATEX. The signatories acknowledge the skills challenge in the textiles ecosystem, and commit to invest in reskilling and upskilling workers, integrating green and digital skills and improving the attractiveness of the sector. Members of the Pact will benefit from networking, guidance and resources offered by the EC to implement the targets which are proposed in the Pact.

The Pact for Skills is part of the EU Industrial Strategy, addressing the competitiveness of 14 critical ecosystems, including textiles. The main aim of the Pact is maximising the impact of investments in improving existing skills (upskilling) and training in new skills (reskilling). To reach such an ambitious goal, the Pact gathers various actors in the TCLF sectors: industry, employers, social partners, national and regional authorities, education and training providers. These actors should work together and invest in large-scale skills partnerships, guarantee exchange of best practices and increase the attractiveness of the sector.

Specifically, the TCLF Pact for Skills focuses on 5 objectives and for each of them, the signatories identified a certain number of target actions:

1. Promoting a culture of lifelong learning for all: one of the actions is to design and roll out courses promoting latest technologies and digital tools such as VR and AI (digital skills) and promoting durability, repair and waste management activities (green skills), in particular circular design skills.
2. Building a strong skills partnership with relevant stakeholders: signatories foresee to build regional and cross-sectoral partnerships between industry, education providers and authorities, which are adapted to their specific needs. .
3. Monitoring skills supply/demand and anticipating skills needs: to reach it, industry, policy and education stakeholders will establish the TCLF Skills Observatory.
4. Working against discrimination and for gender equality and equal opportunities: signatories will launch a TCLF manifesto of diversity and a supporting initiatives to improve the gender balance and ensure equal opportunities for all.
5. Raising awareness & attractiveness on the TCLF industries, i.a. though dedicated information campaigns, showcasing the opportunities in the sector and promoting mobility for young workers.

As of early 2022, the European Commission will offer signatories of the Pact for Skills to benefit from collaboration at EU, national and regional levels and in particular gain access to networking, knowledge and guidance & resource hubs.

“EURATEX is proud to coordinate this initiative” says Alberto Paccanelli, EURATEX President. “Our companies’ success is based on finding the right people with the right set of skills. This becomes increasingly difficult, so this Pact is a wake-up call to work together and develop a forward looking strategy, where people are put at the heart of our sector.”

Kai-Chieh Kuo, PhD student at the Institut für Textiltechnik (ITA) of RWTH Aachen University, was awarded the German Textile Mechanical Engineering 2021 Best Master's Thesis Award for his master's thesis entitled "Modification of the tube weaving process of fine yarns for the production of woven ultra-low profile stent grafts". The prize is endowed with 3,500€. Peter D. Dornier, Chairman of the Board of the Walter Reiners-Stiftung (Foundation), virtually presented the award on the occasion of the ADD International Textile Conference on 9 November 2021.

Minimally invasive endovascular aortic repair (EVAR) with textile stent-graft systems is nowadays a clinically established therapy procedure for the treatment of abdominal aortic aneurysms (AAA) – pathological bulges of the aorta. Due to the thick profile of the folded stent graft systems, there is currently a high risk of injuring narrowed or highly angulated access vessels from the inside during implantation. Stent graft systems with smaller profiles could provide an improvement, which could overcome complicated access routes through a lower bending stiffness. One possible approach for reducing the system profiles is the use of thin-walled tubular woven fabrics made of ultrafine multifilament yarns (≤20 dtex) as graft material.

Up to now, it has not been possible to process the fine yarns with the required high thread density (>200 threads/cm) and the available weaving technology in order to guarantee sufficient tightness against blood.

In his master's thesis, Kai-Chieh Kuo made high-density tubular weaving of ultra-fine filament yarns possible for the first time by means of suitable modifications to a shuttle loom as well as adaptations in the weaving preparation. In particular, he developed a new innovative reed technology that reduces warp thread friction during the shedding process and thus improves the process stability of the dense tube weaving process of fine yarns.

With the help of the process modification, it was then possible to produce high-density, thin-walled tubular woven fabrics, which were positively evaluated with regard to their suitability for a stent graft. Above all the potential of these tubular fabrics lies in their extremely thin-walled fabric profile, which seals well against blood. By using these new types of tubular fabrics as graft material for stent grafts, the system profile of the folded stent graft system can be reduced without having to compromise the blood tightness of the implant. The technology developed by Mr Kuo is not only applicable to stent graft systems, but also offers great possibilities for use in all other endovascular implants such as trans catheter heart valves, covered stents and small-lumen vascular prostheses.