From the Sector

adidas have unveiled an innovation in the sport of wheelchair basketball. Born from extensive feedback and research with wheelchair athletes, the uniforms were developed by the adidas Innovation team in Portland in close collaboration with Adaptive Sports Northwest, a non-profit organization for adaptive athletics. The uniforms will be worn by the PNW Reign women’s wheelchair basketball team for the first time as they set out on a quest to win the NWBA Tournament on April 26-28, 2024.

Earlier in April, during the reveal of the adidas kits for the Paris 2024 Olympic and Paralympic Games, the sports brand announced that 86% of pieces of apparel worn on and off the field of play have been created using design principles that ensure they work for athletes with and without a disability alongside the development of adaptive training apparel.

The new wheelchair basketball jersey and shorts feature ergonomic advancements in pattern engineering, specifically tailored for seated positions to reduce bulk and increase comfort. Materials were selected based on detailed athlete feedback sessions and data analysis to unlock performance for seated athletes. The uniform features lightweight woven front panels for durability and full mesh back panels for breathability. Focus on the fit was paramount to deliver a uniform that felt light and comfortable.

Players of both genders have actively participated in rounds of feedback and ergometer testing sessions to measure maximum speed over pushes, providing the adidas team with invaluable insights into the mechanics of speed that will inform future research and development. In addition, the feedback was used to measure fit, performance, durability, and overall comfort to make the uniforms match the needed requirements. Finally, through the validation process, the PNW Reign basketball team confirmed that adapted patterns have been proven to reduce fabric bulk, decrease heat build-up and enhance confidence.

Using bio-based and bio-degradable, recyclable insulation textiles to sustainably insulate heat and reduce energy consumption and the carbon footprint - the Aachen-based start-up SA-Dynamics has developed a solution for this dream of many building owners together with industrial partners. SA-Dynamics won the second Innovation Award in the "New Technologies on Sustainability & Recycling" category at the leading textile trade fairs Techtextil and Texprocess for this development.

The bio-based recyclable insulation textiles consist of 100 percent bio-based aerogel-fibres. They contain up to 90 percent air, trapped in the nano-pore system of the aerogel-fibres. The bio-based raw material is sustainably sourced and certified. The insulation textiles made from bio-based aerogel fibres are said to insulate the same or even better than synthetic insulating materials of fossil origin like PET, PE or PP and mineral or stone wool.

"By using bio-based aerogels, we are doing away with fossil-based materials and doing something for the environment and climate," explains Maximilian Mohr, Chief Technical Officer (CTO) at SA-Dynamics. "We are thus meeting the regulatory measures of the EU and the governments of many countries for more climate and environmental protection. By using bio-based, recyclable aerogels, we can revolutionise the world of construction.“

The Aachen-based start-up SA-Dynamics is made up of researchers from the Institut für Textiltechnik (ITA) and the Institute of Industrial Furnace Construction and Heat Engineering (IOB) at RWTH Aachen University.

The bio-based aerogel fibres originate from the LIGHT LINING research project of the BIOTEXFUTURE innovation area. The LIGHT LINING research project focussed on sports and outdoor textiles. The research results are transferable to the construction sector.

The Techtextil and Texprocess Innovation Awards ceremony will take place on 23 April 2024 at 12.30 pm in Hall 9.0 in Frankfurt/Main, Germany.

INDA, the Association of the Nonwoven Fabrics Industry, announced three recipients for the INDA Lifetime Service Award and Lifetime Technical Achievement Awards. David Powling, Paul Latten, and Arnold Wilkie are being recognized for their key contributions to the advancement of the nonwovens industry and INDA.

David Powling and Paul Latten will receive their awards at the World of Wipes® (WOW) International Conference, June 18th beginning at 4:30 pm
Arnold Wilkie will receive his award at the RISE® Conference, October 1st at 4:30 pm.

The Award recipients are:

David Powling
David Powling has worked for Kimberly-Clark Corporation for nearly 25 years and has been a contributor to the Wipes Task Force and Technical Committees at INDA and EDANA for over 15 years. Powling served as Chairman of the INDA Wipes Task Force from 2009-2013. His work on these committees include developing the first and second edition of the Flushability Guidance Document (GD) and he was later instrumental in the roll out of the third and fourth edition GDs. Throughout this time, Powling coordinated activities with Kimberly-Clark Corporation to provide critical supporting data, as these flushability test protocols were developed.

Powling has been actively involved in collection studies where he was key in framing the work packages of those studies, collating and analyzing the data, and drafting reports. These collection studies include: Moraga, CA (advisor); Maine – Part #1 and Part #2 (hands-on); Jacksonville (hands-on); and the Northern and Southern California studies in 2023, which combined, was the largest study to date. Powling led the charge in the California study and was personally involved in identifying 1,745 samples.

Powling has been a key technical contributor to the INDA Government Relation efforts that has resulted in labelling regulations in multiple U.S. states. He has also been an active participant in efforts to develop an ISO standard for flushable products.  In this effort, he was a test method sub-team leader during the preparation of the proposed ISO standard responsible for organizing appendices of existing flushability methodologies. Additionally, Powling has been awarded, or has pending, 25+ U.S. patents, including many covering the development of dispersible wet wipes.

Paul Latten
Paul Latten has been an active member of the nonwoven and fiber industries for over 35 years. Most recently he has led innovation at Southeast Nonwovens, commercializing more than 75 new nonwoven products per year. Prior to joining Southeast Nonwovens, Latten held senior leadership positions with Basofil, Consolidated Fibers, Invista, and KoSa (and Trevira and Hoechst Celanese precursors to KoSa.)

Latten has a successful career of reinvigorating company R&D efforts by instilling a focus on customer-centric innovation. He is an inventor of record for a number of patents and pending applications. Latten has given numerous presentations on innovative nonwoven materials, at events such as INDA’s World of Wipes® (WOW) International Conference, RISE® (Research, Innovation & Science for Engineered Fabrics), the VISION International Conference, and the Converting and Bonding (CAB) Conference.

His recent innovations have been diverse in scope and include nonwovens for use in hydrogen fuel cells, moisture detection media, proprietary wipe designs, and natural fiber-based packaging. Aside from new fiber and nonwoven products, Latten has championed process innovation that has resulted in tangible output gains that broadened the market opportunity for his current and prior companies.

Latten’s portfolio of innovations has spanned across the nonwoven markets, often involving wetlaid and drylaid nonwovens. These include materials for moisture detection, synthetic papers, fuel cell cathodes, protective covers for treats, melamine nonwovens for surface treatment, and the development of binder fibers. His work also touched upon disposable hygiene applications entailing dry-laid web containing hollow synthetic fibers to improve absorbent core fluid uptake.

Latten has been a board member of INDA for multiple terms and served as Chairman in 2008-2010. Additionally, he has contributed to many INDA conference planning committees, helping drive the success of these events.

Arnold Wilkie
Arnold Wilkie has a distinguished career in advancing yarn, fiber, and nonwoven technologies since 1970. Since 1988, he has been President and Owner of Hills, Inc. where he has sustained their innovative culture. Wilkie has over 40 patents and applications covering yarns, bicomponent fibers, ultra-fine fibers, nanofibers, dissolvable filaments, meltblown nonwovens, and polymer processing innovations. He established Hills as a leading innovator in bicomponent fiber nonwovens and in the equipment to produce these materials. During Wilkie’s time leading Hills, their pilot capabilities have become well-known and highly regarded for enabling material innovations.

Many of his patents pertain to the development of equipment solutions that enable the production of complex bi- and multi-component fiber structures. These solutions include the method of forming a continuous filament spun-laid web, the method and apparatus for producing polymer fibers and fabrics including multiple polymer components, the method and apparatus for controlling airflow in a fiber extrusion system, and controlling the dissolution of dissolvable polymer components in plural component fibers.

Arnold Wilkie, President, Hills, Inc., earned his bachelor’s degree in Mechanical Engineering from the University of Tennessee and an MBA from the University of West Florida. He is a licensed Professional Engineer in Florida, and has been engaged in the synthetic fibers industry since 1970. The first 17 years were with the Monsanto Company, where he held positions in Fiber Process Engineering, Fiber Product R&D, and Product Management. Since 1988, he has been a majority Owner and President of Hills, Inc., a 52-year-old company located in West Melbourne, Florida, specializing in the development, manufacture, and supply of advanced custom fiber extrusion equipment. Wilkie has been involved with and supported The Nonwovens Institute, since its founding in 1991 as the Nonwovens Cooperative Research Center (NCRC), with Hills joining as a Member in 2001

The DITF is leading the joint project "DACCUS-Pre*". The basic idea of the project is to develop a new building material that stores carbon in the long term and removes more CO₂ from the atmosphere than is emitted during its production.       

In collaboration with the company TechnoCarbon Technologies, the project is now well advanced - a first demonstrator in the form of a house wall element has been realized. It consists of three materials: Natural stone, carbon fibers and biochar. Each component contributes in a different way to the negative CO₂ balance of the material:

Two slabs of natural stone form the exposed walls of the wall element. The mechanical processing of the material, i.e. sawing in stone cutting machines, produces significant quantities of stone dust. This is very reactive due to its large specific surface area. Silicate weathering of the rock dust permanently binds a large amount of CO₂ from the atmosphere.

Carbon fibers in the form of technical fabrics reinforce the side walls of the wall elements. They absorb tensile forces and are intended to stabilize the building material in the same way as reinforcing steel in concrete. The carbon fibers used are bio-based, produced from biomass. Lignin-based carbon fibers, which have long been technically optimized at DITF Denkendorf, are particularly suitable for this application: They are inexpensive due to low raw material costs and have a high carbon yield. In addition, unlike reinforcing steel, they are not susceptible to oxidation and therefore last much longer. Although carbon fibers are more energy-intensive to produce than steel, as used in reinforced concrete, only a small amount is needed for use in building materials. As a result, the energy and CO₂ balance is much better than for reinforced concrete. By using solar heat and biomass to produce the carbon fibers and the weathering of the stone dust, the CO₂ balance of the new building material is actually negative, making it possible to construct CO₂-negative buildings.

The third component of the new building material is biochar. This is used as a filler between the two rock slabs. The char acts as an effective insulating material. It is also a permanent source of CO₂ storage, which plays a significant role in the CO₂ balance of the entire wall element.

From a technical point of view, the already realized demonstrator, a wall element for structural engineering, is well developed. The natural stone used is a gabbro from India, which has a high-quality appearance and is suitable for high loads. This has been proven in load tests.  Bio-based carbon fibers serve as the top layer of the stone slabs. The biochar from Convoris GmbH is characterized by particularly good thermal insulation values.

The CO₂ balance of a house wall made of the new material has been calculated and compared with that of conventional reinforced concrete. This results in a difference in the CO₂ balance of 157 CO₂ equivalents per square meter of house wall. A significant saving!

* (Methods for removing atmospheric carbon dioxide (Carbon Dioxide Removal) by Direct Air Carbon Capture, Utilization and Sustainable Storage after Use (DACCUS).

INDA, the Association of the Nonwoven Fabrics Industry, announced a call for presentations and award nominations for the RISE® (Research, Innovation & Science for Engineered Fabrics) Conference. RISE will be held October 1-2, 2024, at the James B. Hunt, Jr. Library, North Carolina State University, Raleigh, North Carolina. RISE is a two-day conference presenting new research and science that drives innovation and product development. The theme for this year’s event is “The Other Sustainability Story: Extended Use and Reduced Consumption.”

Nonwoven professionals are encouraged to submit their technical abstracts by Friday, April 12, 2024. Topics being considered are raw materials, equipment and processing, product-related technologies, and applications.  Abstracts may be submitted via the RISE website. For questions about abstract submissions, contact Deanna Lovell.

RISE® Innovation Award
In addition, INDA is requesting nominations for innovative nonwoven products and technologies for the RISE® Innovation Award. INDA will consider categories such as raw materials, roll goods, converting, packaging, active ingredients, binders, additives and end products for nominations. This Award recognizes innovation in areas within and on the periphery of the nonwovens industry, utilizing advanced science and engineering principles to develop solutions to problems and advance the usage of nonwovens.

Three finalists will be chosen to present their innovations to technology scouts, scientists, researchers, and industry professionals on Tuesday, October 1st. Nominations may be submitted via the INDA website. The Award submission deadline is July 29, 2024. For questions about the Award, contact Vickie Smead.

Last year, the RISE® Innovation Award was presented to TiHive for their SAPMonit technology.

Solvay awarded a scholarship to facilitate an educational alliance between the Massachusetts Institute of Technology (MIT) and Fermi High School in Cecina. The initiative unfolded during an event held at Solvay's Rosignano site in Italy, providing a platform for students and faculty. Through this partnership, 200 Fermi High School students participated in STEM* and digital lessons from MIT's Global Teaching Labs project, emphasizing the teaching of scientific disciplines by the American university.

Beyond the scholarship award ceremony, students received a tour of Solvay's factory in Rosignano. The tour highlighted the company's dedication to safety, sustainability, and bridging the gap between academia and industry challenges. The experience illustrated the practical application of academic studies in an industrial context, showcasing Solvay's advanced control procedures, safety protocols, technological innovations, digital transformation efforts, and sustainability measures.

Discussions during the event included key sustainability topics such as water conservation, energy efficiency, waste management, and Solvay's commitment to promoting a balanced work-life culture and diversity within the workplace.

This collaboration aligns with Solvay's global Corporate Citizenship program. Through this program, Solvay supports individuals and communities, channeling efforts to tackle worldwide societal challenges through strategic investments in education, sustainability, and local community initiatives.

*STEM stands for science, technology, engineering and mathematics

RadiciGroup announced the appointment of Stefano Pigozzi to the Board of Directors of Radici Partecipazioni SpA, the parent company overseeing all the Group's business activities in the chemicals, engineering polymers and advanced textile solutions sectors.
 
A professional with proven experience in the chemical industry, Mr. Pigozzi will complement the Board with his strategic vision acquired in international organizations.
 
Stefano Pigozzi graduated from the University of St. Gallen in Switzerland with a degree in Business Administration and started his work experience in the finance division of BASF in the late 1980s. Since then, chemistry has remained at the centre of his career: over the years, he has held marketing and sales positions of increasing responsibility in various business sectors (plastics and inorganics), moving up to more strategic and managerial roles within BASF, including president of the Monomers Division and, most recently, head of the Group Global Purchasing Division at the Ludwigshafen headquarters.
 
During his more than 30-year career at BASF, Mr. Pigozzi has consistently demonstrated his leadership capability, his financial analysis skills and his dedication to corporate business success. He has also contributed significantly to the positioning of BASF as a global leader in the chemical industry.
 
Mr. Pigozzi’s appointment to the Board of Directors of Radici Partecipazioni is aimed at strengthening RadiciGroup's presence in the market and helping to guide the company towards new goals.

A lot of waste is generated in the trade fair and event industry. It makes sense to have furniture that can quickly be dismantled and stored to save space - or simply disposed of and recycled. Paper is the ideal raw material here: locally available and renewable. It also has an established recycling process. The German Institutes of Textile and Fiber Research (DITF) and their project partners have jointly developed a recycling-friendly modular system for trade fair furniture. The "PapierEvents" project was funded by the German Federal Environmental Foundation (DBU).

Once the paper has been brought into yarn form, it can be processed into a wide variety of basic elements using the structure winding process, creating a completely new design language.

The unusual look is created in the structure winding process. In this technology developed at the DITF, the yarn is deposited precisely on a rotating mandrel. This enables high process speeds and a high degree of automation. After the winding process, the individual yarns are fixed, creating a self-supporting component. A starch-based adhesive, which is also made from renewable and degradable raw materials, was used in the project for the fixation.

The recyclability of all the basic elements developed in the project was investigated and confirmed. For this purpose the research colleagues at the project partner from the Department of Paper Production and Mechanical Process Engineering at TU Darmstadt (PMV) used the CEPI method, a new standard test procedure from the Confederation of European Paper Industries.

Sensor and lighting functions were also implemented in a recycling-friendly manner. The paper sensor yarns are integrated into the components and detect contact.

Also, a modular system for trade fair and event furniture was developed. The furniture is lightweight and modular. For example, the total weight of the counter shown is well under ten kilograms and individual parts can easily be shipped in standard packages. All parts can be used several times, making them suitable for campaigns lasting several weeks.

A counter, a customer stopper in DIN A1 format and a pyramid-shaped stand were used as demonstrators. The research work of the DITF (textile technology) and PMV (paper processing) was supplemented by other partners: GarnTec GmbH developed the paper yarns used, the industrial designers from quintessence design provided important suggestions for the visual and functional design of the elements and connectors and the event agency Rödig GmbH evaluated the ideas and concepts in terms of usability in practical use.

Carbon fiber-reinforced polymer lamellas are an innovative method of reinforcing buildings. There are still many unanswered questions regarding their recycling, however. A research project by Empa's Mechanical Systems Engineering lab is now set to provide answers. Thanks to the support from a foundation, the project could now be launched.

The construction sector is responsible for around 60 percent of Switzerland's annual waste. The industry's efforts to recycle demolition materials are steadily increasing. Nevertheless, there are still end-of-life materials that, for the time being, cannot be reused as recycling would be too time-consuming and expensive. One of these are carbon fiber-reinforced polymer (CFRP) lamellas.

Making buildings "live" longer
The reinforcing method developed by Urs Meier, former Empa Director at Dübendorf, has been used in infrastructure construction for 30 years. CFRP lamellas are attached with epoxy adhesive to bridges, parking garages, building walls and ceilings made of concrete or masonry. As a result, the structures can be used for 20 to 30 years longer. The method is increasingly being applied worldwide – mainly because it massively improves the earthquake resistance of masonry buildings.

"By significantly extending the lifespan of buildings and infrastructure, CFRP lamellas make an important contribution to increasing sustainability in the construction sector. However, we need to find a way how we can further use CFRP lamellas after the buildings are being demolished," explains Giovanni Terrasi, Head of the Mechanical Systems Engineering lab at Empa. To achieve this, he wants to develop a method for recycling CFRP lamellas. Convinced by this idea, a foundation supported it with a generous donation. The project officially launched in October.

Gentle separation
First, a mechanical process will be developed to detach the CFRP lamellas from the concrete without damaging them. Initial tests at Empa are encouraging: After the lamellas were separated from the concrete, they still had a strength of 95 percent – even if they had already been used for 30 years.

Then, the demolished CFRP lamellas shall be used to produce reinforcement for prefabricated components. Terrasi's goal: saving thousands of tons of CFRP lamellas from ending up in landfills after the demolition of old concrete structures and reuse them in low-CO₂ concrete elements. After completion of the project, Giovanni Terrasi and his team – consisting of Zafeirios Triantafyllidis, Valentin Ott, Mateusz Wyrzykowski and Daniel Völki – want to produce railroad sleepers from recycled concrete, which will be reinforced and prestressed with demolition CFRP lamellas. This would give the "waste-to-be" material a second life in Swiss infrastructure construction.

The kick-off meeting for the "Trends and Design Factors for Hydrogen Pressure Vessels" project, recently held at AZL Aachen GmbH, was a successful event, bringing together more than 37 experts in the field of composite technologies. This event laid a solid foundation for the Joint Partner Project, which currently comprises a consortium of 20 renowned companies from across the composite pressure vessel value chain: Ascend Performance Materials, C evotec GmbH, Chongqing Polycomp International Corp. (CPIC), Conbility GmbH, Elkamet Kunststofftechnik GmbH, F.A. Kümpers GmbH & Co. KG, f loteks plastik sanayi ticaret a.s., Formosa Plastics Corporation, Heraeus Noblelight GmbH, Huntsman Advanced Materials, Kaneka Belgium NV, Laserline GmbH, Mitsui Chemicals Europe GmbH, Plastik Omnium, Rassini Europe GmbH, Robert Bosch GmbH, Swancor Holding Co. Ltd. Ltd., TECNALIA, Toyota Motor Europe NV/SA, Tünkers do Brasil Ltda.

The project follows AZL´s well proven approach of a Joint Partner Project, aiming to provide technology and market insights as well as benchmarking of different material and production setups in combination with connecting experts along the value chain.

The kick-off meeting not only served as a platform to foster new contacts and get informed about the expertise and interests of the consortium members in the field of hydrogen pressure vessels, but also laid the groundwork for steering the focus of the upc oming project's ambitious phases. As a basis for the interactive discussion session, AZL outlined the background, motivation and detailed work plan. The central issues of the dialogue were the primary objectives, the most pressing challenges, the contribut ion to competitiveness, and
the priorities that would best meet the expectations of the project partners.

Discussions covered regulatory issues, the evolving value chain and the supply and properties of key materials such as carbon and glass fibres and resins. The consortium defined investigations into different manufacturing technologies, assessing their matu rity and potential benefits. Design layouts, including liners, boss designs and winding patterns, were thoroughly considered, taking into account their implications for mobile and stationary storage. The group is also interested in cost effective testing m ethods and certification processes, as well as the prospects for recycling into continuous fibres and the use of sustainable materials. Insight was requested into future demand for hydrogen tanks, OEM needs and strategies, and technological developments to produce more economical tanks.

The meeting highlighted the importance of CAE designs for fibre patterns, software suitability and the application dependent use of thermoset and thermoplastic designs.

The first report meeting will also set the stage of the next project phase, which will be the creation of reference designs by AZL's engineering team. These designs will cover a range of pressure vessel configurations using a variety of materials and production concepts. The aim is to develop models that not only re flect current technological capabilities, but also provide deep insight into the cost analysis of different production technologies, their CO₂ footprint, recycling aspects and scalability.

AZL's project remains open to additional participants. Companies interested in joining this initiative are invited to contact Philipp Fröhlig.