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05.02.2025

Sächsisches Textilforschungsinstitut STFI at JEC

JEC World will take place from 4 to 6 March 2025 under the motto ‘Pushing the Limits’. The leading trade fair for lightweight construction is a networking centre for creativity, vision and action. It shows how composite materials are pushing the boundaries of projects and ambitions.

The Sächsisches Textilforschungsinstitut e.V. (STFI) is building on this motto and will be presenting highly oriented semi-finished products and organic sheets made from recycled carbon fibres for aviation in Paris in 2025. These semi-finished products currently represent the limit in the field of rCF. In addition, the members of the MC4 consortium, in which the STFI optimises recycling solutions for composite materials made from glass and carbon fibres with European partners, will be presenting their results at their own stand. With the newly installed wetlaid nonwoven system, the Saxon institute also offers a nonwoven technology that will also be of interest for the reuse of short carbon fibres in the future. Visit us at the joint stand of the Saxony Economic Development Corporation and talk to our team of lightweight construction and recycling experts.

JEC World will take place from 4 to 6 March 2025 under the motto ‘Pushing the Limits’. The leading trade fair for lightweight construction is a networking centre for creativity, vision and action. It shows how composite materials are pushing the boundaries of projects and ambitions.

The Sächsisches Textilforschungsinstitut e.V. (STFI) is building on this motto and will be presenting highly oriented semi-finished products and organic sheets made from recycled carbon fibres for aviation in Paris in 2025. These semi-finished products currently represent the limit in the field of rCF. In addition, the members of the MC4 consortium, in which the STFI optimises recycling solutions for composite materials made from glass and carbon fibres with European partners, will be presenting their results at their own stand. With the newly installed wetlaid nonwoven system, the Saxon institute also offers a nonwoven technology that will also be of interest for the reuse of short carbon fibres in the future. Visit us at the joint stand of the Saxony Economic Development Corporation and talk to our team of lightweight construction and recycling experts.

Source:

Sächsisches Textilforschungsinstitut

23.01.2025

Kelheim Fibres: Sustainability Report Including EMAS Environmental Statement

Kelheim Fibres, a leading manufacturer of specialty viscose fibres, has published their comprehensive sustainability report. By doing so, the company is setting another milestone for transparency while simultaneously emphasizing its commitment to the goals of the UN Global Compact.

An integral part of the sustainability report is the EMAS Environmental Statement, which – as it has been annually since 2020 – was audited by independent environmental experts as part of the EMAS (Eco-Management and Audit Scheme) revalidation. This confirms Kelheim Fibres’ high environmental performance and its continuous efforts towards sustainable corporate governance.

The sustainability report goes beyond mere environmental performance and addresses all aspects of Corporate Social Responsibility (CSR).

Kelheim Fibres, a leading manufacturer of specialty viscose fibres, has published their comprehensive sustainability report. By doing so, the company is setting another milestone for transparency while simultaneously emphasizing its commitment to the goals of the UN Global Compact.

An integral part of the sustainability report is the EMAS Environmental Statement, which – as it has been annually since 2020 – was audited by independent environmental experts as part of the EMAS (Eco-Management and Audit Scheme) revalidation. This confirms Kelheim Fibres’ high environmental performance and its continuous efforts towards sustainable corporate governance.

The sustainability report goes beyond mere environmental performance and addresses all aspects of Corporate Social Responsibility (CSR).

“Credibility and trust are based on transparency. With our new sustainability report, we demonstrate how we fulfil our responsibility for both people and the environment – and the contribution we make with our biodegradable fibres to combating one of the biggest global problems of our time, the growing plastic waste,” explains Wolfgang Ott, Head of CSR at Kelheim Fibres. The viscose fibres made from 100% plant-based raw materials represent a powerful alternative to conventional plastics in numerous applications and thus help reduce global waste.

Source:

Kelheim Fibres GmbH

(c) nova Institut
21.01.2025

Six Innovations nominated for Cellulose Fibre Innovation of the Year 2025

It is getting exciting again in Cologne on 12 and 13 March for the cellulose fibres industry. Six new products have been nominated for the popular innovation award.

Every year, the conference organisator nova-Institute together with award sponsor GIG Karasek honours companies that impress with their creativity, technological progress and ecological impact. The aim of the award is not only to recognise the winners’ innovative products, but also to set an example for the courage to innovate.

The nominees’ presentations, the voting and the winner ceremony will take place on 12 March at the Cellulose Fibres Conference 2025. Participants of the conference can vote live for the three winners. More than 220 people are expected to attend.

The Nominees

It is getting exciting again in Cologne on 12 and 13 March for the cellulose fibres industry. Six new products have been nominated for the popular innovation award.

Every year, the conference organisator nova-Institute together with award sponsor GIG Karasek honours companies that impress with their creativity, technological progress and ecological impact. The aim of the award is not only to recognise the winners’ innovative products, but also to set an example for the courage to innovate.

The nominees’ presentations, the voting and the winner ceremony will take place on 12 March at the Cellulose Fibres Conference 2025. Participants of the conference can vote live for the three winners. More than 220 people are expected to attend.

The Nominees

Fibers365 (DE): Hemp365 – Agricultural Decorative and Carrier Material
The solution “hemp365” is characterised by the development of a cost-effective, plant-based decorative and carrier material through the chemical-free processing of a regional agricultural fibre and the use of resulting short fibres in a wet-laid process, allowing for a massive reduction in the amount of fossil based binders required for strength and functionality. The non fibre content is less than 7 % and is also made from biogenic and biodegradable material. Hemp365 is 100% natural and vegan. It has been designed for consumer (fashion) and industrial applications in cooperation with an automotive OEM.

Releaf Paper France (FR): Releaf Fiber – Eco-Friendly Paper from Urban Fallen Leaves
Releaf Paper France transforms urban fallen leaves into sustainable cellulose fibres, offering an eco-friendly alternative to traditional hardwood pulp. Using proprietary low-temperature extraction, high-quality fibres with excellent paper-forming properties are isolated. With a cellulose content of 32-48 % and properties similar to hardwood, RELEAF fibres are ideal for packaging materials like corrugated paper, boxes, and bags. This innovative process, which requires minimal water and non-aggressive solvents, aligns with circular economy principles, repurposing millions of tons of urban leaf waste annually and supporting global brands in achieving sustainable packaging solutions.

SA-Dynamics (DE): Cellulose Aerogel Textiles – Next-Generation Insulation Materials
Cellulose Aerogel Textiles are revolutionary insulation materials made from 100 % biodegradable cellulose aerogel fibres. These combine the flexibility and ease of processing of traditional fabrics with the superior thermal insulation properties of aerogels by utilising a novel aerogel fibre process. Lightweight, highly efficient, and compatible with conventional textile machinery, they provide a sustainable alternative to fossil-based and animal-derived insulation materials. Fully recyclable and free from microplastic emissions, Cellulose Aerogel Textiles set a new benchmark for circular economy solutions in the textile and construction industries. Initial functional demonstrators were developed through two projects, funded by Biotexfuture and RWTH Innovation, respectively.

Sci-Lume Labs (US): Bylon® – Renewable Circular Fibres from Agricultural Waste
Sci-Lume Labs makes Bylon®, a scalable, circular, biosynthetic fibre. Using highly efficient chemistries to valorise agricultural waste, Bylon® seamlessly integrates into every step of the global value chain – from raw material production through textile manufacturing. Bylon® is distinct from incumbent and next-gen materials because it is simultaneously bio-based; waste-derived; degradable; recyclable; downstream-compatible; and melt-spinnable. Bylon® also offers a unique performance profile by combining the mechanical properties and tunability of traditional synthetics with the moisture properties and circularity of natural fibres. By not requiring changes to the supply chain, Bylon® empowers the industry to reduce its environmental impact – without compromising on quality, performance, or cost.

TMG Automotive (PT): REFIBER – Sustainable Automotive Surface Material
Textile-based composite solutions are a growing trend in the automotive sector, especially for decorative and functional interior applications. Innovative plant-based leather demonstrates this trend, combining sustainability with advanced performance. Developed from a biopolymer matrix combined with cellulose waste, this material transforms waste into a premium, eco-friendly solution. Its textile backing and non-woven laminate backing are also made entirely from cellulose fibres, creating a fully integrated bio-based composite. Designed for car interiors and more, this lightweight, durable and aesthetically versatile material sets a new standard for sustainable design, while satisfying the industry’s growing demand for circular and renewable alternatives.

Uluu (AU): Replacing plastic in textiles with natural, seaweed-derived materials
Uluu is an Australian start-up set to replace plastics with natural polymers called PHAs. Uluu materials are made from a regenerative feedstock: farmed seaweed, thus ending reliance on fossil fuels and land crops. Uluu, in partnership with Deakin University, is developing textiles that perform like synthetic polyester but are truly biodegradable and biocompatible, thus eliminating persistent microplastic pollution in fashion. Importantly, Uluu materials are reusable, recyclable, and most importantly, compostable. They are naturally produced through a unique fermentation process that uses seaweed, saltwater microbes and seawater. Uluu pellets can be directly substituted for plastic (e.g., polyester, nylon) in existing melt spinning equipment, creating yarns that can be knitted or woven into textiles. In addition to fibre-grade pellets, Uluu is also producing other grades of pellets to replace plastics used in e.g., buttons, sunglasses, hair clips and packaging.

Labor Kelheim Fibres © Clemens Mayer
14.01.2025

Kelheim Fibres: Labore erreichen DAkkS-Akkreditierung

Die Kelheim Fibres GmbH hat die DAkkS-Akkreditierung nach DIN EN ISO/IEC 17025:2018 für ihre Labore für ausgewählte Parameter erfolgreich erhalten. Die international anerkannte Norm bestätigt die Kompetenz des Unternehmens zur Durchführung von Prüfungen, insbesondere in den Bereichen Abwasseranalysen und Raumluftuntersuchung, auf höchstem Qualitätsniveau.

Ein zentraler Erfolgsfaktor war die jahrzehntelange Erfahrung von Kelheim Fibres in der Durchführung von Umweltanalysen, Qualitätssicherung und Forschungsarbeiten. Auch die langjährige AQS-Zertifizierung der Labore hat eine solide Grundlage für die erfolgreiche DAkkS-Akkreditierung geschaffen.

Mit dieser Akkreditierung stärken die Labore von Kelheim Fibres ihre Rolle als verlässlicher Partner für hochwertige Prüfungen auch für externe Kunden aus den unterschiedlichsten Branchen. Das Unternehmen verspricht unabhängige und verlässliche Ergebnisse, die höchsten Ansprüchen gerecht werden und gleichzeitig eine besonders schnelle Bearbeitung von Prüfaufträgen.

Die Kelheim Fibres GmbH hat die DAkkS-Akkreditierung nach DIN EN ISO/IEC 17025:2018 für ihre Labore für ausgewählte Parameter erfolgreich erhalten. Die international anerkannte Norm bestätigt die Kompetenz des Unternehmens zur Durchführung von Prüfungen, insbesondere in den Bereichen Abwasseranalysen und Raumluftuntersuchung, auf höchstem Qualitätsniveau.

Ein zentraler Erfolgsfaktor war die jahrzehntelange Erfahrung von Kelheim Fibres in der Durchführung von Umweltanalysen, Qualitätssicherung und Forschungsarbeiten. Auch die langjährige AQS-Zertifizierung der Labore hat eine solide Grundlage für die erfolgreiche DAkkS-Akkreditierung geschaffen.

Mit dieser Akkreditierung stärken die Labore von Kelheim Fibres ihre Rolle als verlässlicher Partner für hochwertige Prüfungen auch für externe Kunden aus den unterschiedlichsten Branchen. Das Unternehmen verspricht unabhängige und verlässliche Ergebnisse, die höchsten Ansprüchen gerecht werden und gleichzeitig eine besonders schnelle Bearbeitung von Prüfaufträgen.

More information:
DAkkS Prüflabor Kelheim Fibres
Source:

Kelheim Fibres GmbH

(c) Messe Düsseldorf / ctillmann
09.01.2025

FET ends 2024 with COMPAMED success.

Fibre Extrusion Technology Ltd (FET) of Leeds, UK enjoyed a highly successful exhibition at COMPAMED 2024 in Düsseldorf. This was the first time that FET had exhibited at this leading international trade fair for the medical technology supplier sector, a reflection of the company’s growing role in the global medical sector. In 2023-24, over 60% of FET’s turnover was derived from the medical market.

“It is never certain whether a new exhibition will prove to be a successful venture until it is tested in practice” commented FET’s Managing Director Richard Slack, “but we are delighted to report that COMPAMED 2024 exceeded all expectations. In fact, we have already booked a stand for next year’s exhibition in November, albeit in a slightly different location”.

Fibre Extrusion Technology Ltd (FET) of Leeds, UK enjoyed a highly successful exhibition at COMPAMED 2024 in Düsseldorf. This was the first time that FET had exhibited at this leading international trade fair for the medical technology supplier sector, a reflection of the company’s growing role in the global medical sector. In 2023-24, over 60% of FET’s turnover was derived from the medical market.

“It is never certain whether a new exhibition will prove to be a successful venture until it is tested in practice” commented FET’s Managing Director Richard Slack, “but we are delighted to report that COMPAMED 2024 exceeded all expectations. In fact, we have already booked a stand for next year’s exhibition in November, albeit in a slightly different location”.

COMPAMED 2024 attracts suppliers of a comprehensive range of high-quality medical technology components, services and production equipment for the medical industry. FET’s expertise in this sector therefore proved to be a perfect fit. With almost 40 serious customer leads taken at the show from both existing and previously unidentified clients, the initial outlook is for a very successful exhibition which will be followed up by future participation at this annual event.

FET’s established expertise lies in laboratory and pilot melt spinning equipment for a vast range of applications, especially precursor materials used in high value medical devices and specialised novel fibres from exotic and difficult to process polymers. In cases where melt spinning solutions are not suitable, FET provides a viable alternative with pilot and small scale production wet spinning systems.

Central to FET’s success has always been its ability to provide customers with advanced testing facilities and equipment at its Fibre Development Centre in Leeds, complemented by unrivalled knowledge and expertise in research and production techniques.

FET has successfully processed over 100 different polymer types and its systems can melt spin resorbable polymers in multifilament, monofilament and nonwoven formats, collaborating with specialist companies worldwide to promote greater sustainability through innovative manufacturing processes.

Cotton Farmers from Tanzania (c) Martin J Kielmann for CmiA
07.01.2025

Dibella increases the purchase of CmiA Cotton

Dibella is again increasing the use of Cotton made in Africa cotton according to the mass balance system. In 2025, the company will purchase 825 tons of raw fibres. This corresponds to an increase of 10% compared to the previous year.

Dibella has been implementing Cotton made in Africa (CmiA) cotton in its supply chain in accordance with the mass balance system since 2017, thereby supporting socially and ecologically sustainable cotton production in Africa. With this further increase, Dibella is fulfilling its corporate goal of “increasing the use of sustainable fibers”.

The mass balance system allows the raw cotton to be easily implemented in the production process at Dibella's suppliers, while at the same time having a high impact on African cotton farmers. The license costs incurred are borne by Dibella and are not passed on to customers. In this way, Dibella aims to raise awareness for more sustainable raw fiber production, away from cost discussions.

Dibella is again increasing the use of Cotton made in Africa cotton according to the mass balance system. In 2025, the company will purchase 825 tons of raw fibres. This corresponds to an increase of 10% compared to the previous year.

Dibella has been implementing Cotton made in Africa (CmiA) cotton in its supply chain in accordance with the mass balance system since 2017, thereby supporting socially and ecologically sustainable cotton production in Africa. With this further increase, Dibella is fulfilling its corporate goal of “increasing the use of sustainable fibers”.

The mass balance system allows the raw cotton to be easily implemented in the production process at Dibella's suppliers, while at the same time having a high impact on African cotton farmers. The license costs incurred are borne by Dibella and are not passed on to customers. In this way, Dibella aims to raise awareness for more sustainable raw fiber production, away from cost discussions.

Cotton made in Africa cotton causes up to 13% less greenhouse gas emissions compared to the global average. No artificial irrigation is used during cultivation. This not only saves drinking water, but also protects valuable water resources in regions that are often affected by water shortages. Not using genetically modified seeds protects natural biodiversity. This specific example shows just how much the cotton farmers benefit: In Côte d'Ivoire, the income of farming families from the sale of CmiA cotton increased by almost 18 percent between 2015 and 2020, according to an independent study* commissioned to assess CmiA's activities and their impact.

Source:

Dibella GmbH

AZL CAD Design and CAE analysis examples for type IV hydrogen pressure vessels, including an example of a winding scheme and relative weight results for different pressure vessel designs Graphic © AZL Aachen GmbH
19.12.2024

R&D project of Fibre-reinforced Hydrogen Pressure Vessels completed

Fibre-reinforced pressure vessels are increasingly becoming the cornerstone of the hydrogen economy, playing a key role in the transport, storage and use of hydrogen for both mobile and stationary applications. AZL Aachen GmbH, in collaboration with a consortium of 25 leading industry players, has successfully completed a 12-month R&D project entitled 'Trends & Design Factors for Hydrogen Pressure Vessels'.

The 550-pages report, presented to the 40 participants of the final project meeting in November, provides a comprehensive overview of the market and technology trends related to the development of thermoset and thermoplastic pressure vessels. By addressing material impacts, complex design considerations and advanced manufacturing technologies, the project provides business- and technology insights. Companies along the whole value chain of pressure vessels have been involved, resins, fibres, liners, production systems, vessel manufacturers, hydrogen system integrators and OEMs.

Fibre-reinforced pressure vessels are increasingly becoming the cornerstone of the hydrogen economy, playing a key role in the transport, storage and use of hydrogen for both mobile and stationary applications. AZL Aachen GmbH, in collaboration with a consortium of 25 leading industry players, has successfully completed a 12-month R&D project entitled 'Trends & Design Factors for Hydrogen Pressure Vessels'.

The 550-pages report, presented to the 40 participants of the final project meeting in November, provides a comprehensive overview of the market and technology trends related to the development of thermoset and thermoplastic pressure vessels. By addressing material impacts, complex design considerations and advanced manufacturing technologies, the project provides business- and technology insights. Companies along the whole value chain of pressure vessels have been involved, resins, fibres, liners, production systems, vessel manufacturers, hydrogen system integrators and OEMs.

The first phase of the project involved an in-depth review of regulations, requirements and safety standards, together with examples of state-of-the-art hydrogen pressure vessels. Key aspects covered included manufacturing processes, supply chains and production technologies, as well as a comprehensive patent analysis. In addition, the study examined winding patterns, design strategies, material models and software tools used in the development of pressure vessels.

The second phase of the project involved extensive engineering studies. Warden Schijve, Design Leader at AZL, explained the procedure: "Our team of experts developed CAE models for 12 different layouts of a two-metre, 350-litre Type IV pressure vessel designed for 700 respectively 350 bar applications. These models incorporated different resin and fibre types, layup variations and boss designs to evaluate the impact on mechanics, weight, cost and carbon footprint. We also explored hybrid fibre combinations and dome reinforcement using patch technologies. Detailed process chain modelling provided further insight into cost structures and CO2 footprints.”

The results of the project also show initial future trends: Through the targeted use of advanced material combinations, adapted designs and manufacturing techniques, it is possible to significantly reduce the weight and cost of the vessels while maintaining the necessary safety standards. Compared to state-of-the-art vessels, hydrogen over tank weight efficiencies could be improved from the standard 6 to 7% up to more than 11%. These developments could strengthen the competitiveness of hydrogen technology in various mobility and energy sectors in the future.

“The knowledge gained from the project provides a solid foundation for the use of new technologies to meet the hydrogen economy's requirements for safe and cost-effective pressure vessels,” commented Celal Beysel, Chairman of the Board at FLOTEKS Plastik San. Tic. A.Ş. Floteks, a Tier 1 supplier of plastic components, has launched numerous R&D initiatives in the design and development of Type IV vessels in recent years. In 2023, the company joined the AZL Composite Pipes and Vessels Working Group and the 'Trends and Design Factors for Hydrogen Pressure Vessels' project. Beysel added: "We are pleased to announce that Floteks has established a new company called Pressura in 2024, which will focus on the production of type 4 pressure vessels for buses and trucks."

Companies and organisations seeking detailed insights or collaboration opportunities are encouraged to contact AZL. AZL Aachen GmbH serves as an innovation partner for hydrogen tank development, prototyping and testing, and is dedicated to advancing composite technologies.

Source:

AZL Aachen GmbH

Poyang Lake Photo via Sateri
Poyang Lake
19.12.2024

Poyang Lake Ecosystem Restoration Initiative by Conservation International and Sateri

Conservation International and Sateri, a leading global producer of textile fibres, have announced the launch of the third phase of the Poyang Lake Ecosystem Restoration Initiative. This new phase marks a critical milestone in restoring China’s largest freshwater lake by integrating carbon neutrality efforts, building on the initiative’s significant success since its inception in 2019.

Located in Jiangxi Province, in the southeastern part of the country, Poyang Lake plays a critical role in regulating floods in the Yangtze River and supports the livelihoods of more than 45 million people living in the province, contributing more than 15% of the Yangtze River’s annual runoff. It is also a wetland of national and global importance, providing a habitat for flora and fauna of high conservation value, including the critically endangered Siberian crane and finless porpoise.

This new phase marks the fifth year of collaboration between Conservation International, a global non-profit organisation dedicated to protecting nature for the benefit of people and the planet, and Sateri. The initiative has seen significant successes since it began in 2019, including:

Conservation International and Sateri, a leading global producer of textile fibres, have announced the launch of the third phase of the Poyang Lake Ecosystem Restoration Initiative. This new phase marks a critical milestone in restoring China’s largest freshwater lake by integrating carbon neutrality efforts, building on the initiative’s significant success since its inception in 2019.

Located in Jiangxi Province, in the southeastern part of the country, Poyang Lake plays a critical role in regulating floods in the Yangtze River and supports the livelihoods of more than 45 million people living in the province, contributing more than 15% of the Yangtze River’s annual runoff. It is also a wetland of national and global importance, providing a habitat for flora and fauna of high conservation value, including the critically endangered Siberian crane and finless porpoise.

This new phase marks the fifth year of collaboration between Conservation International, a global non-profit organisation dedicated to protecting nature for the benefit of people and the planet, and Sateri. The initiative has seen significant successes since it began in 2019, including:

  • Strengthening the management of 473,000 hectares of protected areas across 50 ecological zones;
  • Enhancing the capability of 2,000 wetland rangers through capacity-building programme;
  • Improving the habitat management of 350 species of wildlife, including the critically endangered finless porpoise and Siberian crane;
  • Supporting the construction of five community artificial-wetlands for wastewater treatment, which can treat 56,000 tonnes of agricultural and domestic sewage; and
  • Benefiting 25,000 local community members through livelihood support, vocational capacity-building and environmental education programmes.

Zhang Cheng, Program Director at Conservation International China, emphasized the project’s broader impact, "This initiative has truly enhanced biodiversity conservation and ecological education, while empowering local communities with sustainable livelihoods. It demonstrates the value of collaborative approaches in balancing ecological protection with human well-being."

In line with Sateri’s 2030 aspiration of becoming a ‘net positive impact’ company, the newly-launched third phase will advance these successes by focusing on:

  • Research on the Freshwater Health Index (FHI) for the basin
  • Protection and restoration of small wetlands
  • Better climate change mitigation and adaptation for resilience

This collaboration, supported by the Jiujiang Municipal Government of the Jiangxi Province, underscores the shared commitment of both organisations to advancing biodiversity and sustainable development in one of China’s most vital freshwater ecosystems.

The Poyang Lake Basin Ecological Protection Project highlights Sateri’s efforts to address environmental challenges through practical actions and partnerships. The company continues to prioritize biodiversity conservation and sustainability while encouraging collaboration to achieve these goals.

Cai Zhichao, Vice President of Operations at Sateri, emphasised the initiative’s alignment with the company’s sustainability goals, "At the heart of our operations lies a commitment to the bioeconomy, where we aim to protect the natural resources we use. This conservation initiative not only helps us meet our internal sustainability targets but also contributes to advancing the United Nations Sustainable Development Goals (UNSDGs) 6 – Clean Water and Sanitation; 11 – Sustainable Cities and Communities; 12 – Responsible Consumption and Production; 13 – Climate Action and 15 – Life on Land. We accomplish this through innovation, advanced technology and low-carbon practices.”

More information:
ecology water Sateri China
Source:

Sateri

26.11.2024

Cellulose Fibres Conference 2025: Preliminary Program released

The upcoming conference on 12-13 March 2025 in Cologne, Germany, will pave pathways to a sustainable textile industry.

Over the past few weeks, the Conference Advisory Board, and the experts from the nova-Institute, have thoroughly reviewed and evaluated over 40 submitted abstracts. The selected external experts bring new insights and perspectives from the pulp, fibre and further developing industries, promising to spark and deepen discussions at the event. Their expertise across the entire fibre value chain will enrich the topics covered and ensure a dynamic and insightful exchange of ideas. The presentations will provide a platform for the discussion at the conference after each session, and the Advisory Board members will foster a lively debate to drive innovation industry-wide.

The upcoming conference on 12-13 March 2025 in Cologne, Germany, will pave pathways to a sustainable textile industry.

Over the past few weeks, the Conference Advisory Board, and the experts from the nova-Institute, have thoroughly reviewed and evaluated over 40 submitted abstracts. The selected external experts bring new insights and perspectives from the pulp, fibre and further developing industries, promising to spark and deepen discussions at the event. Their expertise across the entire fibre value chain will enrich the topics covered and ensure a dynamic and insightful exchange of ideas. The presentations will provide a platform for the discussion at the conference after each session, and the Advisory Board members will foster a lively debate to drive innovation industry-wide.

Biosynthetics on the rise
Besides cellulose fibres, bio-based polymer fibres ("biosynthetics") are an excellent option to reduce fossil fibres in textiles. Biosynthetics offer a powerful alternative to traditional synthetic fibres, bringing both performance and technical properties that make them drop-in replacements. Derived wholly or partially from natural, renewable sources like lactic acids, sugar beet, sugarcane or wood, biosynthetics represent a bio-based option compared to fossil-based counterparts. In a special session “Biosynthetics - Replacing Traditional Synthetic Fibres”, experts will explore the latest advances, challenges and opportunities in the field. Discussing innovative approaches like biosynthetics is essential to drive sustainable transformation within the fashion and textile industries.

Fibre-to-Fibre Recycling: A Path to a Sustainable Textile Industry
The textile industry is at a crucial crossroad. The need for sustainable solutions to meet the EU's ambitious climate change targets is becoming increasingly urgent. Fibre-to-fibre recycling, which transforms discarded textiles into new, virgin fibres, holds great promise for reducing waste and resource consumption and helps to close the loop in textile production. While Europe has made progress in this area, challenges remain – in particular the management of mixed fibre textiles and the scaling up of recycling technologies. As new approaches are needed to tackle climate change, one session of the conference will focus on fibre-to-fibre recycling from textiles, exploring the latest innovations and technological advances, as well as the opportunities and barriers that need to be addressed to move the industry towards a circular, sustainable future.

Fibre Microplastic Formation versus Marine Biodegradability
The environmental impact of textiles extends far beyond landfill, with microplastics from synthetic fibres becoming a growing concern in marine ecosystems. A session at the conference will focus on the complex relationship between microplastic formation and marine biodegradability. While synthetic fibres shed microplastics during washing, these tiny particles, known as microfibres accumulate in the oceans and pose a serious threat to marine life. This session will explore the factors that influence fibre degradation in the marine environment and examine the potential of biodegradable fibres to reduce long-term pollution. Leading research institutes will discuss the challenges of balancing the prevention of microplastics with the development of fibres that can degrade naturally in marine ecosystems, and provide insights into innovative solutions that could help mitigate this pressing environmental issue.

Innovation Award “Cellulose Fibre Innovation of the Year 2025”
The nova-Institute, together with GIG Karasek, is looking for the best fibre innovations of the year. Applicants from the area of cellulose fibres as well as biosynthetics are welcome to submit their innovations. Technologie providers, research institutes or producers can apply until 30 November 2024. The innovation award “Cellulose Fibre Innovation of the Year 2025” is sponsored by GIG Karasek.

Apply for the “Cellulose Fibre Innovation of the Year 2025” award: cellulose-fibres.eu/award-application

Call for Posters
The poster exhibition is a highly anticipated scientific event at the conference, especially for early career scientists. Poster submission is open until 31 January 2025.

More information:
Cellulose Fibres Conference
Source:

nova-Institut für politische und ökologische Innovation GmbH

26.11.2024

Cellulose Fibres Conference 2025: Preliminary Program released

The upcoming conference on 12-13 March 2025 in Cologne, Germany, will pave pathways to a sustainable textile industry.

Over the past few weeks, the Conference Advisory Board, and the experts from the nova-Institute, have thoroughly reviewed and evaluated over 40 submitted abstracts. The selected external experts bring new insights and perspectives from the pulp, fibre and further developing industries, promising to spark and deepen discussions at the event. Their expertise across the entire fibre value chain will enrich the topics covered and ensure a dynamic and insightful exchange of ideas. The presentations will provide a platform for the discussion at the conference after each session, and the Advisory Board members will foster a lively debate to drive innovation industry-wide.

The upcoming conference on 12-13 March 2025 in Cologne, Germany, will pave pathways to a sustainable textile industry.

Over the past few weeks, the Conference Advisory Board, and the experts from the nova-Institute, have thoroughly reviewed and evaluated over 40 submitted abstracts. The selected external experts bring new insights and perspectives from the pulp, fibre and further developing industries, promising to spark and deepen discussions at the event. Their expertise across the entire fibre value chain will enrich the topics covered and ensure a dynamic and insightful exchange of ideas. The presentations will provide a platform for the discussion at the conference after each session, and the Advisory Board members will foster a lively debate to drive innovation industry-wide.

Biosynthetics on the rise
Besides cellulose fibres, bio-based polymer fibres ("biosynthetics") are an excellent option to reduce fossil fibres in textiles. Biosynthetics offer a powerful alternative to traditional synthetic fibres, bringing both performance and technical properties that make them drop-in replacements. Derived wholly or partially from natural, renewable sources like lactic acids, sugar beet, sugarcane or wood, biosynthetics represent a bio-based option compared to fossil-based counterparts. In a special session “Biosynthetics - Replacing Traditional Synthetic Fibres”, experts will explore the latest advances, challenges and opportunities in the field. Discussing innovative approaches like biosynthetics is essential to drive sustainable transformation within the fashion and textile industries.

Fibre-to-Fibre Recycling: A Path to a Sustainable Textile Industry
The textile industry is at a crucial crossroad. The need for sustainable solutions to meet the EU's ambitious climate change targets is becoming increasingly urgent. Fibre-to-fibre recycling, which transforms discarded textiles into new, virgin fibres, holds great promise for reducing waste and resource consumption and helps to close the loop in textile production. While Europe has made progress in this area, challenges remain – in particular the management of mixed fibre textiles and the scaling up of recycling technologies. As new approaches are needed to tackle climate change, one session of the conference will focus on fibre-to-fibre recycling from textiles, exploring the latest innovations and technological advances, as well as the opportunities and barriers that need to be addressed to move the industry towards a circular, sustainable future.

Fibre Microplastic Formation versus Marine Biodegradability
The environmental impact of textiles extends far beyond landfill, with microplastics from synthetic fibres becoming a growing concern in marine ecosystems. A session at the conference will focus on the complex relationship between microplastic formation and marine biodegradability. While synthetic fibres shed microplastics during washing, these tiny particles, known as microfibres accumulate in the oceans and pose a serious threat to marine life. This session will explore the factors that influence fibre degradation in the marine environment and examine the potential of biodegradable fibres to reduce long-term pollution. Leading research institutes will discuss the challenges of balancing the prevention of microplastics with the development of fibres that can degrade naturally in marine ecosystems, and provide insights into innovative solutions that could help mitigate this pressing environmental issue.

Innovation Award “Cellulose Fibre Innovation of the Year 2025”
The nova-Institute, together with GIG Karasek, is looking for the best fibre innovations of the year. Applicants from the area of cellulose fibres as well as biosynthetics are welcome to submit their innovations. Technologie providers, research institutes or producers can apply until 30 November 2024. The innovation award “Cellulose Fibre Innovation of the Year 2025” is sponsored by GIG Karasek.

Apply for the “Cellulose Fibre Innovation of the Year 2025” award: cellulose-fibres.eu/award-application

Call for Posters
The poster exhibition is a highly anticipated scientific event at the conference, especially for early career scientists. Poster submission is open until 31 January 2025.

More information:
Cellulose Fibres Conference
Source:

nova-Institut für politische und ökologische Innovation GmbH

Ibrahim Fibers is using the Trützschler Autoleveller Draw Frame TD 10. Photo TRÜTZSCHLER GROUP
Ibrahim Fibers is using the Trützschler Autoleveller Draw Frame TD 10
11.11.2024

Ibrahim Fibres: Lighthouse Solutions in Pakistan with Trützschler

Ibrahim Fibres operates nearly 200 Trützschler cards, which is more than any other business in Pakistan. The leading yarn and Polyester Staple Fiber (PS) manufacturer has partnered with Trützschler for over two decades - and recently wanted to start processing long polyester and viscose fibers. It's an unusual request that brings unique challenges.

Pakistan is the eighth largest exporter of textiles in Asia and has the third largest spinning capacity in the continent. Ibrahim Fibres, located in Faisalabad, is a big contributor to that economic strength. The pioneering company produces a wide range of yarns for woven, and knitted fabrics. This includes various blends of cotton, viscose and polyester in different proportions and combinations with yarn counts ranging from Ne 8 to Ne 50. Ibrahim Fibres uses its own polyester via 240,000 spindles at four factories, mainly to produce poly-viscose and poly-cotton combed yarn. In total, the company manufactures 1,200 tons of PSF per day and consumes around 100 tons of its own materials per day. The remaining material is sold to other textile manufacturers.

Ibrahim Fibres operates nearly 200 Trützschler cards, which is more than any other business in Pakistan. The leading yarn and Polyester Staple Fiber (PS) manufacturer has partnered with Trützschler for over two decades - and recently wanted to start processing long polyester and viscose fibers. It's an unusual request that brings unique challenges.

Pakistan is the eighth largest exporter of textiles in Asia and has the third largest spinning capacity in the continent. Ibrahim Fibres, located in Faisalabad, is a big contributor to that economic strength. The pioneering company produces a wide range of yarns for woven, and knitted fabrics. This includes various blends of cotton, viscose and polyester in different proportions and combinations with yarn counts ranging from Ne 8 to Ne 50. Ibrahim Fibres uses its own polyester via 240,000 spindles at four factories, mainly to produce poly-viscose and poly-cotton combed yarn. In total, the company manufactures 1,200 tons of PSF per day and consumes around 100 tons of its own materials per day. The remaining material is sold to other textile manufacturers.

An unusual challenge
Teams from Ibrahim Fibres often approach Trützschler with fresh ideas and new expectations. They recently set the challenge of producing top-quality yarns from unusually long polyester and viscose fibers. These fibers are used for luxury textiles, high-performance fabrics, fine bedding and advanced nonwoven materials. The end products benefit from the fibers outstanding strength and durability. Often, people in the textile industry talk about the problems with processing short fibers. But long fibers also present difficulties because they have a tendency to wrap or clog carding elements. Their length also makes them more tightly bound, which means they are more difficult to open.

What was the answer to this unusual challenge? Collaboration! Experts from Trützschler worked closely with partners at Ibrahim Fibres to explore potential solutions. "Our technical teams regularly collaborate with Trützschler’s R&D department to enhance production using Industry 4.0 principles, Al, and the latest technology," says Zafar Iqbal. "We’ve now developed a method for handling longer fibers that improves yarn consistency, end-product performance, and cost efficiency, while reducing waste. Our ongoing partnership with Trützschler continues to drive innovation and efficiency in our operations."

TC 30Si is here to help...
Ibrahim Fibres wanted to process 51mm polyester with 51 mm viscose fibers. In line with these requirements, Trützschler engineers optimized the TC 30Si carding machine for processing long polyester and viscose fibers. This machine is specifically customized for man-made fibers and can process these fibers more effectively due to its larger drum diameter, which results in a 14 % extended carding length. The machine also has 35 % more active flats. It has one licker-in and its cylinder, doffer wire, flat tops and stationary flats are all designed for processing man-made fibers.

"We chose TC 30Si for its advanced features, such as its 1400 mm cylinder diameter, extended carding lengths, and the automatic T-GO gap optimizer," says Zafar Iqbal. "These attributes support our Industry 4.0 goals by enhancing technology integration, data use, and operational efficiency, making it ideal for modernizing production and staying competitive in the textile industry."

And Ibrahim Fibres has even more reasons for choosing the TC 30Si: "It has user-friendly software and an intuitive Human Machine Interface (HMI), making it easy to maintain with minimal adjustments. This card boosts productivity and reduces energy consumption, while also improving consistency and reducing defects."

 

Source:

TRÜTZSCHLER GROUP

Photo NASA
05.11.2024

Fibre-reinforced materials for next-generation space missions

A new generation of space materials left Earth November. 5 as they head to the International Space Station (ISS) to undergo testing in the brutal conditions of low Earth orbit.

Developed at the University of Bristol, these high-performance materials could be used to build future space stations, spacecraft for interplanetary travel or a new ISS.

They will be placed on the Bartolomeo platform, located on the front of the ISS, where they will orbit Earth up to 9,000 times over the next 12 to 18 months at speeds of 17,000 mph.

The carbon fibre reinforced composites will need to survive temperatures between -150ºC and +120ºC, space debris travelling seven times faster than a bullet, severe electromagnetic radiation, high vacuum and atomic oxygen, which erodes even the toughest materials.

Prof Ian Hamerton, Professor of Polymers and Sustainable Composites in the University of Bristol’s world-leading Bristol Composites Institute, said:  

A new generation of space materials left Earth November. 5 as they head to the International Space Station (ISS) to undergo testing in the brutal conditions of low Earth orbit.

Developed at the University of Bristol, these high-performance materials could be used to build future space stations, spacecraft for interplanetary travel or a new ISS.

They will be placed on the Bartolomeo platform, located on the front of the ISS, where they will orbit Earth up to 9,000 times over the next 12 to 18 months at speeds of 17,000 mph.

The carbon fibre reinforced composites will need to survive temperatures between -150ºC and +120ºC, space debris travelling seven times faster than a bullet, severe electromagnetic radiation, high vacuum and atomic oxygen, which erodes even the toughest materials.

Prof Ian Hamerton, Professor of Polymers and Sustainable Composites in the University of Bristol’s world-leading Bristol Composites Institute, said:  

“Space is the most challenging environment for which to design new materials. You’re pitting your materials expertise, skills and ingenuity against extremes of temperature, mechanical stress, radiation, high speed impacts and more.

“Any one of those might be difficult, and, unfortunately, gaining access to repair them is not an easy option, so the materials we build must survive without maintenance.  

“The opportunity to test our materials in the proving ground of space is priceless and will help our University of Bristol scientists on the ground improve fibre-reinforced materials for next-generation space missions.”

There are four laboratory-made polymers heading to the ISS, each of which has been reinforced with carbon fibres and two contain nanoparticles. All four are the result of University of Bristol research and one is patented.

 If the materials cope in the harsh environment, they could be used to create longer-lasting space components, allowing spacecraft to travel further, and spend more time in space.

Future communities on new planets will need protection against galactic cosmic radiation. Dr Ali Kandemir, Senior Research Associate at the University of Bristol, is one of several Bristol researchers, supported by the UK Space Agency (UKSA), examining the effects of simulated galactic cosmic radiation on the materials, in a European Space Agency (ESA) project.

Dr Kandemir said: “We want materials that are resilient in the space environment and, importantly, materials that can shield humans from that radiation.

“We also want to make these materials sustainable, so that when they reach the end of their life they can be recycled and used again for the same purpose.”

The launch of the Space X Dragon CRS-2 spacecraft this morning is the culmination of five years of work for Prof Hamerton and his team.

It has included the efforts of early career researchers, postgraduates and several Aerospace Engineering undergraduates at the University of Bristol, whose final year research projects have been linked to the space materials project.

The practical support of the University of Bristol-hosted National Composites Centre (NCC) was crucial to the scale up of the composite materials.

Prof Kate Robson Brown, Vice-President for Research, Innovation and Impact at University College Dublin, and a collaborator on the project, said:

“After nearly five years of research to develop novel composite materials for space applications it is very exciting to see our experiment launch to the International Space Station.

“I am proud to be part of this mission, and to be working with the multidisciplinary and multisector research team to deliver integrated real world and digital testing for innovative materials which will help to drive growth in the new space economy.

“This mission also demonstrates how space research funding creates career changing opportunities for early career researchers and PhD students in a sector of huge value to both Ireland and the UK.”

Funding to support the project was supplied by the ESA, the UKSA, Oxford Space Systems and others.

 

Source:

University of Bristol

25.09.2024

Kelheim Fibres Achieves the Highest Level in the ZDHC MMCF Module

The Bavarian specialist for viscose fibres, Kelheim Fibres, is reinforcing its commitment to the "Roadmap to Zero" initiative of the non-profit organization ZDHC, which aims to eliminate hazardous substances throughout the entire textile value chain.

In this context, Kelheim Fibres has recently successfully completed the ZDHC MMCF Guideline module, achieving the highest level, "Aspirational." This module, established in 2024, assesses manufacturers of Man-Made Cellulosic Fibres (MMCF) for their compliance with the guideline through independent third-party audits.

Advanced environmental management is the foundation of this success, with a particular focus on reducing water and air pollution in the MMCF production process and improving chemical recovery.

The Bavarian specialist for viscose fibres, Kelheim Fibres, is reinforcing its commitment to the "Roadmap to Zero" initiative of the non-profit organization ZDHC, which aims to eliminate hazardous substances throughout the entire textile value chain.

In this context, Kelheim Fibres has recently successfully completed the ZDHC MMCF Guideline module, achieving the highest level, "Aspirational." This module, established in 2024, assesses manufacturers of Man-Made Cellulosic Fibres (MMCF) for their compliance with the guideline through independent third-party audits.

Advanced environmental management is the foundation of this success, with a particular focus on reducing water and air pollution in the MMCF production process and improving chemical recovery.

Theresa Schreiner, Environmental Engineer at Kelheim Fibres, said: " Achieving the highest level, 'Aspirational,' in the ZDHC MMCF Module right from the start confirms that we are on the right path toward an even more sustainable, eco-friendly viscose fibre. Our efforts and investments over the past years are bearing fruit and can be substantiated with concrete data. As part of our environmental management system EMAS, we continue our work to continuously improve our environmental performance and to maintain our leading role in eco-friendly fibre production in the future."

More information:
Kelheim Fibres ZDHC viscose fibers
Source:

Kelheim Fibres

FET at COMPAMED 2024 (c) FET
FET extrusion system
06.09.2024

FET at COMPAMED 2024

Fibre Extrusion Technology Ltd (FET) of Leeds, UK will be exhibiting for the first time at COMPAMED 2024 in Düsseldorf, taking place between between 11 – 14 November 2024, to reflect the company’s increasing profile in the medical sector. COMPAMED is a international trade fair for the medical technology supplier sector, showcasing a range of high-quality medical technology components, services and production equipment for the medical industry.

FET are experts in medical fibre technology and innovations, designing and delivering high performance equipment for a range of precursor medical products. This includes turnkey solutions for nonwoven medical devices, wound care and dressings and synthetic absorbable sutures.

Fibre Extrusion Technology Ltd (FET) of Leeds, UK will be exhibiting for the first time at COMPAMED 2024 in Düsseldorf, taking place between between 11 – 14 November 2024, to reflect the company’s increasing profile in the medical sector. COMPAMED is a international trade fair for the medical technology supplier sector, showcasing a range of high-quality medical technology components, services and production equipment for the medical industry.

FET are experts in medical fibre technology and innovations, designing and delivering high performance equipment for a range of precursor medical products. This includes turnkey solutions for nonwoven medical devices, wound care and dressings and synthetic absorbable sutures.

FET’s expertise lies in laboratory and pilot melt spinning equipment for a vast range of applications, especially precursor materials used in high value medical devices and specialised novel fibres from exotic and difficult to process polymers. FET has processed over 100 different polymer types and its systems can melt spin resorbable polymers in multifilament, monofilament and nonwoven formats, collaborating with specialist companies worldwide to promote greater sustainability through innovative manufacturing processes. Where melt spinning solutions are not suitable, FET provides an alternative with pilot and small scale production wet and gel spinning systems.

Source:

Fibre Extrusion Technology Ltd (FET)

Cooperation between CARBIOS and Nouvelles Fibres Textiles (c) CARBIOS
(L-R) Emmanuel Ladent (CEO, CARBIOS), Eric Boël (Co-director of Nouvelles Fibres Textiles) and Mathieu Berthoud (Strategic Sourcing Director, CARBIOS)
26.07.2024

Cooperation between CARBIOS and Nouvelles Fibres Textiles

CARBIOS and Nouvelles Fibres Textiles, a French company specializing in the recovery of end-of-life textiles, announce the signing of a Memorandum of Understanding to establish a contract for the supply of polyester textiles to the world's first PET biorecycling plant currently under construction in Longlaville, France. The polyester textiles supplied will come from used or end-of-life textiles prepared in France by Nouvelles Fibres Textiles for recycling using CARBIOS' enzymatic depolymerization technology. This contract will enable 5,000 tons a year of these textiles to be redirected towards biorecycling from 2026 onwards, over an initial 5-year period, demonstrating the commitment of industrial players all along the value chain to achieving textile circularity for a more sustainable textile sector.

CARBIOS and Nouvelles Fibres Textiles, a French company specializing in the recovery of end-of-life textiles, announce the signing of a Memorandum of Understanding to establish a contract for the supply of polyester textiles to the world's first PET biorecycling plant currently under construction in Longlaville, France. The polyester textiles supplied will come from used or end-of-life textiles prepared in France by Nouvelles Fibres Textiles for recycling using CARBIOS' enzymatic depolymerization technology. This contract will enable 5,000 tons a year of these textiles to be redirected towards biorecycling from 2026 onwards, over an initial 5-year period, demonstrating the commitment of industrial players all along the value chain to achieving textile circularity for a more sustainable textile sector.

Nouvelles Fibres Textiles and its various partners opened a semi-industrial site with an annual capacity of 1,000 tons in November 2023, the first step towards building a 20,000-to-30,000-ton unit in 2026. This first site, a research center for textile recycling, combines the know-how of Andritz Laroche (a leader in textile recycling), Pellenc ST (French leader in intelligent sorting solutions), Synergie TLC (a French player in collection and first sorting for solidarity) and the Tissages de Charlieu group (a French player in weaving, garment manufacturing and textile recycling). This unit transforms used textiles into high-quality raw materials, supplying the various industries that use textile fibers (non-wovens, insulation, plastic, textiles, etc.) by automatically sorting them by composition, while eliminating hard points (buttons, zips, patches, etc.).

CARBIOS' biorecycling technology uses enzymes to break down polyester fibers into their basic components. These components are then used to produce high-quality recycled PET materials, such as fibers for the textile industry. This “fiber-to-fiber” solution will enable polyester to become a truly circular fiber on a large scale.

Source:

CARBIOS

Cellulose Fibres Conference 2025 - Call for Abstracts (c) nova-Institut GmbH
24.07.2024

Cellulose Fibres Conference 2025: Call for Abstracts

Latest developments in the sustainable textile industry will be introduced and discussed at the “Cellulose Fibres Conference 2025 – New with Biosynthetics” in Cologne, Germany and online, on 12-13 March 2025. Abstract submission is now open.

In 2024, 214 participants enjoyed two conference days in Cologne or online. The highlights were 40 presentations with lively panel discussions afterwards, the innovation award “Cellulose Fibre Innovation of the Year”, an exhibition, the poster session and plenty of networking possibilities. All of this will be repeated in 2025, including new topics, new speakers and new inputs. The “Cellulose Fibres Conference 2025” will again cover the entire value chain, from lignocellulose, chemical pulp, cellulose fibres such as rayon, viscose, modal or lyocell and new developments to a wide range of applications, e.g. textiles from renewable fibres, nonwovens such as wet wipes and composites, hygiene and packaging. The conference will further address topics like circular economy, fibre-to-fibre recycling and sustainable carbon cycles, biosynthetics, new technologies and feedstocks.

Latest developments in the sustainable textile industry will be introduced and discussed at the “Cellulose Fibres Conference 2025 – New with Biosynthetics” in Cologne, Germany and online, on 12-13 March 2025. Abstract submission is now open.

In 2024, 214 participants enjoyed two conference days in Cologne or online. The highlights were 40 presentations with lively panel discussions afterwards, the innovation award “Cellulose Fibre Innovation of the Year”, an exhibition, the poster session and plenty of networking possibilities. All of this will be repeated in 2025, including new topics, new speakers and new inputs. The “Cellulose Fibres Conference 2025” will again cover the entire value chain, from lignocellulose, chemical pulp, cellulose fibres such as rayon, viscose, modal or lyocell and new developments to a wide range of applications, e.g. textiles from renewable fibres, nonwovens such as wet wipes and composites, hygiene and packaging. The conference will further address topics like circular economy, fibre-to-fibre recycling and sustainable carbon cycles, biosynthetics, new technologies and feedstocks.

Call for Abstracts
Enterprises and research institutes are invited to contribute to the program and present their innovative products, technologies or developments. Deadline for submission is 30 September 2024.
cellulose-fibres.eu/call-for-abstracts

Call for Innovations
The conference will conclude with the innovation award “Cellulose Fibre Innovation 2025” whose winner can join the ranks of amazing innovations. The deadline for innovation submissions is 30 November 2024. The innovation award “Cellulose Fibre Innovation of the Year 2025” is sponsored by GIG Karasek.
cellulose-fibres.eu/award-application

Call for posters
The poster exhibition is highly anticipated event at the conference. Poster submissions are open until 31 January 2025.
cellulose-fibres.eu/call-for-posters

BioTurf Bild TFI - Institut für Bodensysteme an der RWTH Aachen e.V.
BioTurf
01.07.2024

Aachen researchers develop sustainable artificial turf

The current European Football Championships 2024 in Germany will be played on natural turf, which is very costly to maintain, does not tolerate high frequency of use and has a limited service life of only 6 months in some cases. Artificial turf is easier to maintain and correspondingly popular. In Germany, there are estimated to be more than 5,000 artificial turf pitches and as many as 25,500 across the EU. The drawback: the enormous annual emission of microplastics in the form of infill material, the high CO2 impact and the not environmentally friendly disposal. Researchers in Aachen presented a sustainable alternative: BioTurf is a new artificial turf system made from bio-based polymers that no longer requires polymer infill material!

The current European Football Championships 2024 in Germany will be played on natural turf, which is very costly to maintain, does not tolerate high frequency of use and has a limited service life of only 6 months in some cases. Artificial turf is easier to maintain and correspondingly popular. In Germany, there are estimated to be more than 5,000 artificial turf pitches and as many as 25,500 across the EU. The drawback: the enormous annual emission of microplastics in the form of infill material, the high CO2 impact and the not environmentally friendly disposal. Researchers in Aachen presented a sustainable alternative: BioTurf is a new artificial turf system made from bio-based polymers that no longer requires polymer infill material!

"Every year, around 500 kilograms of plastic granules are produced per artificial turf pitch, which have to be refilled as infill. This also corresponds to the amount that potentially enters the environment as microplastics per sports pitch," explains Dr Claudia Post from TFI. With an estimated 25,000 artificial turf pitches in the EU, artificial turf in Europe alone produces 12,750 tonnes of microplastics that end up in the environment every year! The TFI - Institut für Bodensysteme an der RWTH Aachen e.V., Institute for Research, Testing and Certification in Europe for Indoor Building Products, has developed the innovative artificial turf system together with the ITA (Institute for Textile Technology at RWTH Aachen University) and in collaboration with the company Morton Extrusionstechnik (MET), a specialist in artificial turf fibres.

"New artificial turf pitches will be phased out by 2031 at the latest due to the ban on plastic granules. Even now, artificial turf pitches with infill material are no longer being subsidised," says Dr Claudia Post. For grassroots sports, clubs, cities and local authorities, converting their existing artificial turf pitches will be a mammoth task in the coming years, as artificial turf pitches have to be replaced every 10-15 years. With BioTurf, an environmentally friendly alternative is now available! The surface can be played on like any other, whether running, passing or kicking. Short, heavily crimped blades support longer blades and this simple approach increases playing comfort. BioTurf fulfils all quality requirements and standards for the highest footballing demands.

"BioTurf is an innovative, holistic solution," emphasises Dirk Hanuschik from TFI. "We use rapeseed oil and agricultural waste that does not compete with food production. BioTurf is also almost completely recyclable".
This is in stark contrast to conventional artificial turf, which can currently only be thermally utilised, i.e. burned to generate heat.

As BioTurf does not require the traditional latex process at all, the energy-intensive drying process can be dispensed with, which has a positive effect on the price. Latex is also difficult to recycle. In contrast, BioTurf uses the new thermobonding technology. Here, the thermoplastic pile yarns are thermally fused to the backing. Further development steps still need to be taken in the endeavour to develop a 100% mono-material artificial turf, as a few percent polypropylene still needs to be processed in the backing in addition to the polyethylene fibre material in order to protect it during thermobonding. However, this does not hinder its recyclability.

Source:

TFI - Institut für Bodensysteme an der RWTH Aachen e.V.

Bcomp’s natural fibre materials in CUPRA (c) CUPRA, SEAT, S.A.
03.06.2024

Bcomp’s natural fibre materials in CUPRA

  • The fully electric vehicle sport EV to incorporate sustainable, flax-based composites to decarbonise manufacturing
  • CUPRA Born VZ to have full natural fibre front seats with Bcomp’s high-performance ampliTex™
  • Bcomp’s natural fibre materials enable a reduction of 49% of CO2 emissions in seats’ production compared to previous version

CUPRA announces the use of Bcomp’s innovative natural fibre composite solutions for the new CUP Bucket seats in the CUPRA Born VZ electric vehicles, the latest addition to the Spanish brand’s vehicle line-up.

CUPRA focuses on innovation and sustainability to redefine the automotive industry. This approach is exemplified by the CUPRA Born VZ, which combines powerful performance with eco-friendly design, aiming to inspire a new generation of drivers with its progressive and responsible engineering.

  • The fully electric vehicle sport EV to incorporate sustainable, flax-based composites to decarbonise manufacturing
  • CUPRA Born VZ to have full natural fibre front seats with Bcomp’s high-performance ampliTex™
  • Bcomp’s natural fibre materials enable a reduction of 49% of CO2 emissions in seats’ production compared to previous version

CUPRA announces the use of Bcomp’s innovative natural fibre composite solutions for the new CUP Bucket seats in the CUPRA Born VZ electric vehicles, the latest addition to the Spanish brand’s vehicle line-up.

CUPRA focuses on innovation and sustainability to redefine the automotive industry. This approach is exemplified by the CUPRA Born VZ, which combines powerful performance with eco-friendly design, aiming to inspire a new generation of drivers with its progressive and responsible engineering.

For the car’s interior design, CUPRA’s collaboration with Bcomp and Sabelt, has resulted in the creation of the first full natural fibre CUP Bucket seats in the CUPRA vehicle line-up. By replacing the seatbacks currently made from carbon and glass fibres, the new all-natural fibre seatbacks offer significant reductions in emissions. The use of Bcomp’s proprietary ampliTex™ technical material reduces CO2 emissions by 49% compared to the hybrid version, while also offering end-of-life options. The incorporation of natural fibres offers other benefits including enhanced vibration damping and increased safety, providing a blend of sustainability and high performance.

Source:

Bcomp

colouring process Photo (c) Hypetex
22.05.2024

First technical coloured flax fibre replacing carbon fibre?

British technology company Hypetex has been awarded a significant grant from Innovate UK to develop the world’s first technical coloured flax fibre, which will have applications in the sustainable manufacturing of cars, boats and other products that are usually made with carbon fibre.

Called FlaxTex the material is strong, lightweight and 100 per cent biodegradable, having a net positive carbon footprint at point of manufacturing. It can be colourised whilst enhancing its performance properties, with the process adding some important manufacturing attributes compared to standard flax fibre.

As such, FlaxTex’s mechanical properties represent the closest sustainable substitute for robust and lightweight materials like glass fibre and carbon fibre in composite structures.  

The performance of standard flax fibre is often hindered by its high moisture absorption, resulting in reduced structural integrity when used in composite construction. In addition, the natural brown colour of flax has been deemed unappealing for product use.

British technology company Hypetex has been awarded a significant grant from Innovate UK to develop the world’s first technical coloured flax fibre, which will have applications in the sustainable manufacturing of cars, boats and other products that are usually made with carbon fibre.

Called FlaxTex the material is strong, lightweight and 100 per cent biodegradable, having a net positive carbon footprint at point of manufacturing. It can be colourised whilst enhancing its performance properties, with the process adding some important manufacturing attributes compared to standard flax fibre.

As such, FlaxTex’s mechanical properties represent the closest sustainable substitute for robust and lightweight materials like glass fibre and carbon fibre in composite structures.  

The performance of standard flax fibre is often hindered by its high moisture absorption, resulting in reduced structural integrity when used in composite construction. In addition, the natural brown colour of flax has been deemed unappealing for product use.

Flaxtex solves these issues by removing moisture through the colouring process and sealing the fibres, which waterproofs them and enabling their core mechanical properties. Hypetex’s patented nano-pigment technology changes the colour adding an aesthetic quality to the material.  

This colouring process is set to transform industrial design possibilities of Flax natural fibres by enhancing the strength and performance while simultaneously reducing post-processing requirements and total energy usage. This also aligns with Hypetex's commitment to supporting the green transition and helping manufacturers meet government expectations on the path to UK Net Zero targets and the European Green Deal.

Over the course of a 12-month industrial research project, Hypetex will further optimize its resin systems and processes, expanding the use of FlaxTex across various markets.  

FlaxTex has a range of industry uses, including on construction, automotive, sports equipment and furniture products.

More information:
HYPETEX® flax carbon fibers
Source:

Hypetex

Nyon traceability Grafik RadiciGroup
23.04.2024

RadiciGroup: a Physical and digital nylon traceability

RadiciGroup announced the launch of the first physical and digital nylon traceability project at Techtextil 2024. A gilet made from the yarn manufactured in one of the Group’s European industrial sites, which, thanks to a QR code on the garment, can reveal its origin and display information about its production process.

Product traceability is a key element in guaranteeing transparency along the entire supply chain, as it means each stage of production – from spinning to weaving and from packaging through to retail – can be monitored and recorded. The project, made possible by a partnership with FibreTrace, allows manufactured nylon yarns to be traced both physically and digitally. In fact, RadiciGroup inserts a tracer (an inorganic additive) that is uniquely associated with the yarn and remains identifiable throughout all stages of processing – on both the fabric and the finished garment. Naturally, the tracer does not alter the esthetical, functional and technical performance of the yarns in any way.

RadiciGroup announced the launch of the first physical and digital nylon traceability project at Techtextil 2024. A gilet made from the yarn manufactured in one of the Group’s European industrial sites, which, thanks to a QR code on the garment, can reveal its origin and display information about its production process.

Product traceability is a key element in guaranteeing transparency along the entire supply chain, as it means each stage of production – from spinning to weaving and from packaging through to retail – can be monitored and recorded. The project, made possible by a partnership with FibreTrace, allows manufactured nylon yarns to be traced both physically and digitally. In fact, RadiciGroup inserts a tracer (an inorganic additive) that is uniquely associated with the yarn and remains identifiable throughout all stages of processing – on both the fabric and the finished garment. Naturally, the tracer does not alter the esthetical, functional and technical performance of the yarns in any way.

In terms of digital traceability, during the production stages a scanner detects the presence of the tracer and can transmit the data relating to provenance onto a dedicated digital platform. Finally, the consumer, via a QR code, can access the digital platform that provides all information concerning the provenance of the product and its journey through the supply chain.
 
“This project is the result of almost two years’ work by our Research & Development team. We’re very proud to bring to the market the first physical and digital nylon traceability solution and we plan to extend this initiative to other fibres produced by the Group,” emphasised Filippo Bona, R&D Manager of RadiciGroup Advanced Textile Solutions.

More information:
Radici RadiciGroup nylon
Source:

RadiciGroup