From the Sector

At this year's JEC Composites Innovation Awards ceremony, the award in the "Construction & Civil Engineering" category went to the "DACCUSS" project, coordinated by the DITF. TechnoCarbon Technologies GbR, the inventor of Carbon Fiber Stone (CFS), received the JEC Award together with its development partners. The award is for the development of house walls made of Carbon Fiber Stone (CFS), a CO2 negative composite material.

Each year, the JEC Composites Innovation Awards recognize innovative and creative projects that demonstrate the full potential of composite materials. With the help of a development team from 12 companies and research institutions, TechnoCarbon Technologies GbR successfully submitted its innovative DACCUSS building element for house walls made of Carbon Fiber Stone.

Carbon Fiber Stone is a building material made of natural rocks and bio-based carbon fibers. It serves as an environmentally friendly replacement for CO2-intensive concrete in the construction industry. While conventional concrete walls release large amounts of CO2 during production, the DACCUS building element binds 59 kg of CO2 per square meter and therefore has a negative carbon footprint. In addition, the panels weigh only one-third of equivalent reinforced concrete house walls.

Each DACCUS element consists of several high-strength natural stone slabs made from magmatic rock. Inside the construction are bio-based carbon fibers, which the DITF Denkendorf is working intensively to develop. They form the stiffening element that enables the high strength of the construction elements and, in turn, contribute to the negative CO2 balance. The layer between the natural rock slabs is filled with carbon-negative biochar granulate, which is responsible for the insulation of the building element. The mineral sawdust from the cut rock slabs can be used as a soil amendment and serves as a binder for free CO2 from the atmosphere. The strict focus on processes and materials that actively bind CO2 has made it possible to produce a building material with a negative CO2 balance.

Partners: Deutsche Institute für Textil- und Faserforschung Denkendorf (DITF), TechnoCarbon Technologies GbR, Universität Hamburg (UHH), Labor für Stahl- und Leichtmetallbau GmbH (LSL), AHP GmbH & Co. KG, Technische Universität München (TUM), GVU mbH, Silicon Kingdom Holding Ltd., Gallehr Sustainable Risk Management GmbH, Peer Technologies GmbH & Co. KG, GREIN srl, Convoris Group GmbH, RecyCoal GmbH, ITA, Institut für Textiltechnik der RWTH Aachen, LISD GmbH.

Die International Textile Manufacturers Federation (ITMF) hat auf der „ITMF & IAF Conference 2024 die Gewinner des ITMF Awards 2024 bekannt gegeben. Mit dabei sind in der Kategorie „ITMF International Cooperation Award 2024“ die DITF und ihr Partner, die französische Firma RBX Créations. Sie erhielten die Auszeichnung für die Einführung eines neu entwickelten, hanfbasierten Zellstoffs und dessen Weiterverarbeitung zu filamentgesponnenen Zellulosefasern. Die Konferenz fand vom 8. – 10. September in Samarkand, Usbekistan statt.

Neue Faserstoffe und textile Erzeugnisse aus Hanf – bei der Vorstellung einer neuartigen Produktionslinie steht für die Kooperationspartner DITF und RBX Créations der Nachhaltigkeitsgedanke in der textilen Wertschöpfungskette im Vordergrund. Denn das Ausgangsmaterial Hanf wird aus lokalem Anbau gewonnen und die Weiterverarbeitung zu textilen Fasern, Garnen und Stoffen aus Zellulose erfolgt mittels energie- und ressourcenschonender Verfahren.

Mit diesem Leitgedanken konnten sich die beiden Partner in Samarkand, Usbekistan, erfolgreich auf der ITMF & IAF Conference 2024 präsentieren. Gemeinsam stellten sie dem Fachpublikum und der Jury eine vollständige textile Herstellungskette vor – vom Rohmaterial über dessen Aufbereitung, der Spinntechnologie und der Verwirklichung textiler Produkte.

Schon die Auswahl des Rohstoffs Hanf ist für die Umwelt in vieler Hinsicht vorteilhaft: Er wird in lokalem Anbau gewonnen und zeichnet sich deshalb durch einen geringen CO2-Footprint aus: Denn üblicherweise wird für die Herstellung von Zellulosefasern Holz als Ausgangsmaterial verwendet, für dessen Verarbeitung große Transportwege in Kauf genommen werden. Den Anbau von Hanf kennzeichnen ein geringer Wasserverbrauch, kaum bis gar kein Chemikalieneinsatz wegen hoher Resistenz gegenüber Pflanzenkrankheiten und vorteilhafte Eigenschaften bei der Regeneration der Böden.

Der Nutzhanf wird in einem vom RBX Créations patentierten Verfahren zu einem feinfaserigen Zellstoff (pulp) aufbereitet. Er dient als Ausgangsmaterial für ein an den DITF entwickeltes und unter dem Namen HighPerCell® geschütztes Nassspinnverfahren. Der Hanf-Pulp wird in einer sogenannten ionischen Flüssigkeit gelöst. Die Lösung wird in einem Fällbad zu Zellulosefasern ausgesponnen. Das Lösungsmittel kann vollständig zurückgewonnen und wiederverwendet werden – ein besonders nachhaltiger und umweltfreundlicher Produktionsprozess. Hanfbasierte Zellulosefasern überzeugen durch ihre mechanischen Eigenschaften, die zum Teil sogar besser sind als diejenigen von etablierten holzbasierten Faserstoffen. Damit bieten sie beste Voraussetzungen für die mechanische Weiterverarbeitung in der Strickerei und Weberei.

Der Projektpartner RBX Création hat nicht nur die Prozesse für die Rohstoffaufbereitung entwickelt, sondern steuert nach der Herstellung der Fasern deren Weiterverarbeitung: Aufgrund ihrer herausragenden Vernetzung in der Textilbranche sorgt RBX Création für die Aufbereitung der Garne und koordiniert die Aufgabenverteilung mit textilen Herstellungsbetrieben. Die Garne und textilen Materialien werden von RBX Créations unter dem Namen Iroony™ gehandelt. Textile Gewirke und Gewebe sind aus diesem Material schon hergestellt worden. Ob Bekleidung oder technische Anwendungen – die Einsatzmöglichkeiten der hanfbasierten Materialien sind breit und haben großes Entwicklungspotential.

Die Preisverleihung in Samarkand würdigt den gesamten Herstellungsprozess: Ein neues und nachhaltiges Verfahren zur Herstellung natürlicher Fasern wird in einer Firmen- und Forschungskooperation vom Anbau des Rohmaterials bis zum Endprodukt gesteuert. Die Kooperation zeigt, wie Nachhaltigkeit in der Textilherstellung zu neuen und marktfähigen Produkten führen kann.

The German Institutes of Textile and Fiber Research Denkendorf (DITF) are coordinating the research project, which is funded as part of the European Union's Horizon Europe research and innovation program. The aim of BioFibreLoop is to develop recyclable outdoor and work clothing made from renewable bio-based materials. The kick-off event took place in Denkendorf on June 26 and 27, 2024.

The textile industry is facing two challenges: on the one hand, production must become more sustainable and environmentally friendly and, on the other, consumers are expecting more and more smart functions from clothing.

In addition, the production of functional textiles often involves the use of chemicals that are harmful to the environment and health and make subsequent recycling more difficult.

Intelligent innovations must therefore ensure that harmful chemicals are replaced, water is saved and more durable, recyclable bio-based materials are used, thereby reducing the usually considerable carbon footprint of textile products. Digitalized processes are intended to ensure greater efficiency and a closed cycle.

For example, the BioFibreLoop project uses laser technology to imitate natural structures in order to produce garments with water and oil-repellent, self-cleaning and antibacterial properties. At the end result of the research work will be affordable, resource and environmentally friendly, yet high-performance and durable fibers and textiles made from renewable sources such as lignin, cellulose and polylactic acid will be available. All processes are aimed at a circular economy with comprehensive recycling and virtually waste-free functionalization based on nature's example. In this way, greenhouse gas emissions could be reduced by 20 percent by 2035.

The technology for the functionalization and recycling of bio-based materials is being developed in three industrial demonstration projects in Austria, the Czech Republic and Germany. At the end of the project, a patented circular, sustainable and reliable process for the production of recyclable functional textiles will be established.

The BioFibreLoop project has a duration of 42 months and a total budget of almost 7 million euros, with 1.5 million going to the coordinator DITF.

The consortium consists of 13 partners from nine countries who contribute expertise and resources from science and industry:

• German Institutes of Textile and Fiber Research Denkendorf (DITF), Coordinator, Germany
• Next Technology Tecnotessile Società nazionale di ricerca R. L., Italy
• Centre Technologique ALPhANOV, France
• G. Knopf’s Sohn GmbH & Co. KG, Germany
• FreyZein Urban Outdoor GmbH, Austria
• BEES - BE Engineers for Society, Italy
• BAT Graphics Vernitech, France
• Interuniversitair Micro-Electronica Centrum, Belgium
• Idener Research & Development Agrupacion de Interes Economico, Spain
• Teknologian tutkimuskeskus VTT Oy, Finland
• Det Nationale Forskningscenter for Arbejdsmiljø, Denmark
• Steinbeis Innovation gGmbH, Germany
• NIL Textile SRO, Czech Republic

The “Cellulose Fibres Conference 2024” held in Cologne on 13-14 March demonstrated the innovative power of the cellulose fibre industry. Several projects and scale-ups for textiles, hygiene products, construction and packaging showed the growth and bright future of this industry, supported by the policy framework to reduce single-use plastic products, such as the Single Use Plastics Directive (SUPD) in Europe.

40 international speakers presented the latest market trends in their industry and illustrated the innovation potential of cellulose fibres. Leading experts introduced new technologies for the recycling of cellulose-rich raw materials and gave insights into circular economy practices in the fields of textiles, hygiene, construction and packaging. All presentations were followed by exciting panel discussions with active audience participation including numerous questions and comments from the audience in Cologne and online. Once again, the Cellulose Fibres Conference proved to be an excellent networking opportunity to the 214 participants and 23 exhibitors from 27 countries. The annual conference is a unique meeting point for the global cellulose fibre industry.  

For the fourth time, nova-Institute has awarded the “Cellulose Fibre Innovation of the Year” Award at the Cellulose Fibres Conference. The Innovation Award recognises applications and innovations that will lead the way in the industry’s transition to sustainable fibres. Close race between the nominees – “The Straw Flexi-Dress” by DITF & VRETENA (Germany), cellulose textile fibre from unbleached straw pulp, is the winning cellulose fibre innovation 2024, followed by HONEXT (Spain) with the “HONEXT® Board FR-B (B-s1, d0)” from fibre waste from the paper industry, while TreeToTextile (Sweden) with their “New Generation of Bio-based and Resource-efficient Fibre” won third place.

Prior to the event, the conference advisory board had nominated six remarkable innovations for the award. The nominees were neck and neck, when the winners were elected in a live vote by the audience on the first day of the conference.

First place
DITF & VRETENA (Germany): The Straw Flexi-Dress – Design Meets Sustainability
The Flexi-Dress design was inspired by the natural golden colour and silky touch of HighPerCell® (HPC) filaments based on unbleached straw pulp. These cellulose filaments are produced using environmentally friendly spinning technology in a closed-loop production process. The design decisions focused on the emotional connection and attachment to the HPC material to create a local and circular fashion product. The Flexi-Dress is designed as a versatile knitted garment – from work to street – that can be worn as a dress, but can also be split into two pieces – used separately as a top and a straight skirt. The top can also be worn with the V-neck front or back. The HPC textile knit structure was considered important for comfort and emotional properties.

Second place
Honext Material (Spain): HONEXT® Board FR-B (B-s1, d0) – Flame-retardant Board made From Upcycled Fibre Waste From the Paper Industry
HONEXT® FR-B board (B-s1, d0) is a flame-retardant board made from 100 % upcycled industrial waste fibres from the paper industry. Thanks to innovations in biotechnology, paper sludge is upcycled – the previously “worthless” residue from paper making – to create a fully recyclable material, all without the use of resins. This lightweight and easy-to-handle board boasts high mechanical performance and stability, along with low thermal conductivity, making it perfect for various applications in all interior environments where fire safety is a priority. The material is non-toxic, with no added VOCs, ensuring safety for both people and the planet. A sustainable and healthy material for the built environment, it achieves Cradle-to-Cradle Certified GOLD, and Material Health CertificateTM Gold Level version 4.0 with a carbon-negative footprint. Additionally, the product is verified in the Product Environmental Footprint.

Third Place
TreeToTextile (Sweden): A New Generation of Bio-based and Resource-efficient Fibre
TreeToTextile has developed a unique, sustainable and resource efficient fibre that doesn’t exist on the market today. It has a natural dry feel similar to cotton and a semi-dull sheen and high drape like viscose. It is based on cellulose and has the potential to complement or replace cotton, viscose and polyester as a single fibre or in blends, depending on the application.
TreeToTextile Technology™ has a low demand for chemicals, energy and water. According to a third party verified LCA, the TreeToTextile fibre has a climate impact of 0.6 kg CO2 eq/kilo fibre. The fibre is made from bio-based and traceable resources and is biodegradable.

The next conference will be held on 12-13 March 2025.

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).

Textiles for technical applications often derive their special function via the application of coatings. This way, textiles become, for example wind and water proof or more resistant to abrasion. Usually, petroleum-based substances such as polyacrylates or polyurethanes are used. However, these consume exhaustible resources and the materials can end up in the environment if handled improperly. Therefore, the German Institutes of Textile and Fiber Research Denkendorf (DITF) are researching materials from renewable sources that are recyclable and do not pollute the environment after use. Polymers that can be produced from bacteria are here of particular interest.

These biopolymers have the advantage that they can be produced in anything from small laboratory reactors to large production plants. The most promising biopolymers include polysaccharides, polyamides from amino acids and polyesters such as polylactic acid or polyhydroxyalkanoates (PHAs), all of which are derived from renewable raw materials. PHAs is an umbrella term for a group of biotechnologically produced polyesters. The main difference between these polyesters is the number of carbon atoms in the repeat unit. To date, they have mainly been investigated for medical applications. As PHAs products are increasingly available on the market, coatings made from PHAs may also be increasingly used in technical applications in the future.

The bacteria from which the PHAs are obtained grow with the help of carbohydrates, fats and an increased CO₂ concentration and light with suitable wavelength.

The properties of PHA can be adapted by varying the structure of the repeat unit. This makes polyhydroxyalkanoates a particularly interesting class of compounds for technical textile coatings, which has hardly been investigated to date. Due to their water-repellent properties, which stem from their molecular structure, and their stable structure, polyhydroxyalkanoates have great potential for the production of water-repellent, mechanically resilient textiles, such as those in demand in the automotive sector and for outdoor clothing.

The DITF have already carried out successful research work in this area. Coatings on cotton yarns and fabrics made of cotton, polyamide and polyester showed smooth and quite good adhesion. The PHA types for the coating were both procured on the open market and produced by the research partner Fraunhofer IGB. It was shown that the molten polymer can be applied to cotton yarns by extrusion through a coating nozzle. The molten polymer was successfully coated onto fabric using a doctor blade. The length of the molecular side chain of the PHA plays an important role in the properties of the coated textile. Although PHAs with medium-length side chains are better suited to achieving low stiffness and a good textile handle, their wash resistance is low. PHAs with short side chains are suitable for achieving high wash and abrasion resistance, but the textile handle is somewhat stiffer.

The team is currently investigating how the properties of PHAs can be changed in order to achieve the desired resistance and textile properties in equal measure. There are also plans to formulate aqueous formulations for yarn and textile finishing. This will allow much thinner coatings to be applied to textiles than is possible with molten PHAs.

Other DITF research teams are investigating whether PHAs are also suitable for the production of fibers and nonwovens.

From Resource-efficient and Recycled Fibres for Textiles and Building Panels to Geotextiles for Glacier Protection: Six award nominees present innovative and sustainable solutions for various industries in the cellulose fibre value chain. The full economic potential of the cellulose fibre industry will be introduced to a wide audience that will vote for the winners in Cologne (Germany), and online.

Again nova-Institute grants the “Cellulose Fibre Innovation of the Year” award in the context of the “Cellulose Fibres Conference”, that will take place in Cologne on 13 and 14 March 2024. In advance, the conferences advisory board nominated six remarkable products, including cellulose fibres from textile waste and straw, a novel technology for dying cellulose-based textiles and a construction panel as well as geotextiles. The innovations will be presented by the companies on the first day of the event. All conference participants can vote for one of the six nominees and the top three winners will be honoured with the “Cellulose Fibre Innovation of the Year” award. The Innovation award is sponsored by GIG Karasek (AT).

In addition, the ever-growing sectors of cellulose-based nonwovens, packaging and hygiene products offer conference participants insights beyond the horizon of traditional textile applications. Sustainability and other topics such as fibre-to-fibre recycling and alternative fibre sources are the key topics of the Cellulose Fibres Conference, held in Cologne, Germany, on 13 and 14 March 2024 and online. The conference will showcase the most successful cellulose-based solutions currently on the market or those planned for the near future.

The nominees:

The Straw Flexi-Dress: Design Meets Sustainability – DITF & VRETENA (DE)
The Flexi-Dress design was inspired by the natural golden colour and silky touch of HighPerCell® (HPC) filaments based on unbleached straw pulp. These cellulose filaments are produced using environmentally friendly spinning technology in a closed-loop production process. The design decisions focused on the emotional connection and attachment to the HPC material to create a local and circular fashion product. The Flexi-Dress is designed as a versatile knitted garment – from work to street – that can be worn as a dress, but can also be split into two pieces – used separately as a top and a straight skirt. The top can also be worn with the V-neck front or back. The HPC textile knit structure was considered important for comfort and emotional properties.

HONEXT® Board FR-B (B-s1, d0) – Flame-retardant Board made From Upcycled Fibre Waste From the Paper Industry – Honext Material (ES)
HONEXT® FR-B board (B-s1, d0) is a flame-retardant board made from 100 % upcycled industrial waste fibres from the paper industry. Thanks to innovations in biotechnology, paper sludge is upcycled – the previously “worthless” residue from paper making – to create a fully recyclable material, all without the use of resins. This lightweight and easy-to-handle board boasts high mechanical performance and stability, along with low thermal conductivity, making it perfect for various applications in all interior environments where fire safety is a priority. The material is non-toxic, with no added VOCs, ensuring safety for both people and the planet. A sustainable and healthy material for the built environment, it achieves Cradle-to-Cradle Certified GOLD, and Material Health CertificateTM Gold Level version 4.0 with a carbon-negative footprint. Additionally, it is verified in the Product Environmental Footprint.

LENZING™ Cellulosic Fibres for Glacier Protection – Lenzing (AT)
Glaciers are now facing an unprecedented threat from global warming. Synthetic fibre-based geotextiles, while effective in slowing down glacier melt, create a new environmental challenge: microplastics contaminating glacial environments. The use of such materials contradicts the very purpose of glacier protection, as it exacerbates an already critical environmental problem. Recognizing this problem, the innovative use of cellulosic LENZING™ fibres presents a pioneering solution. The Institute of Ecology, at the University of Innsbruck, together with Lenzing and other partners made first trials in 2022 by covering small test fields with LENZING™ fibre-based geotextiles. The results were promising, confirming the effectiveness of this approach in slowing glacier melt without leaving behind microplastic.

The RENU Jacket – Advanced Recycling for Cellulosic Textiles – Pangaia (UK) & Evrnu (US)
PANGAIA LAB was born out of a dream to reduce barriers between people and the breakthrough innovations in material science. In 2023, PANGAIA LAB launched the RENU Jacket, a limited edition product made from 100% Nucycl® – a technology that recycles cellulosic textiles by breaking them down to their molecular building blocks, and reforming them into new fibres. This process produces a result that is 100% recycled and 100% recyclable when returned to the correct waste stream – maintaining the strength of the fibre so it doesn’t need to be blended with virgin material.
Through collaboration with Evrnu, the PANGAIA team created the world’s first 100% chemically recycled denim jacket, replacing a material traditionally made from 100% virgin cotton. By incorporating Nucycl® into this iconic fabric construction, dyed with natural indigo, the teams have demonstrated that it’s possible to replace ubiquitous materials with this innovation.

Textiles Made from Easy-to-dye Biocelsol – VTT Technical Research Centre of Finland (FI)
One third of the textile industry’s wastewater is generated in dyeing and one fifth in finishing. But the use of chemically modified Biocelsol fibres reduces waste water. The knitted fabric is made from viscose and Biocelsol fibres and is only dyed after knitting. This gives the Biocelsol fibres a darker shade, using the same amount of dye and no salt in dyeing process. In addition, an interesting visual effect can be achieved. Moreover, less dye is needed for the darker colour tone in the finished textile and the possibility to use the salt-free dyeing is more environmentally friendly.
These special properties of man-made cellulosic fibres will reassert the fibres as a replacement for the existing fossil-based fibres, thus filling the demand for more environmentally friendly dyeing-solutions in the textile industry. The functionalised Biocelsol fibres were made in Finnish Academy FinnCERES project and are produced by wet spinning technique from the cellulose dope containing low amounts of 3-allyloxy-2-hydroxypropyl substituents. The functionality formed is permanent and has been shown to significantly improve the dyeability of the fibres. In addition, the functionalisation of Biocelsol fibres reduces the cost of textile finishing and dyeing as well as the effluent load.

A New Generation of Bio-based and Resource-efficient Fibre – TreeToTextile (SE)
TreeToTextile has developed a unique, sustainable and resource efficient fibre that doesn't exist on the market today. It has a natural dry feel similar to cotton and a semi-dull sheen and high drape like viscose. It is based on cellulose and has the potential to complement or replace cotton, viscose and polyester as a single fibre or in blends, depending on the application.
TreeToTextile Technology™ has a low demand for chemicals, energy and water. According to a third party verified LCA, the TreeToTextile fibre has a climate impact of 0.6 kg CO2 eq/kilo fibre. The fibre is made from bio-based and traceable resources and is biodegradable.

Climate change is causing temperatures to rise and storms to increase. Especially in inner cities, summers are becoming a burden for people. While densification makes use of existing infrastructure and avoids urban sprawl, it increases the amount of sealed surfaces. This has a negative impact on the environment and climate. Green facades bring more green into cities. If textile storage structures are used, they can even actively contribute to flood protection. The German Institutes of Textile and Fiber Research (DITF) have developed a corresponding "Living Wall".

The plants on the green facades are supplied with water and nutrients via an automatic irrigation system. The "Living Walls" operate largely autonomously. Sensory yarns detect the water and nutrient content. The effort for care and maintenance is low.

Innovative hydraulic textile structures regulate water flow. The rock wool plant substrate on which the plants grow has a large volume in a small space thanks to its structure. Depending on how heavy the precipitation is, the rainwater is stored in a textile structure and later used to irrigate the plants. In the event of heavy rainfall, the excess water is discharged into the sewage system with a time delay. In this way, the "Living Walls" developed at the DITF help to make efficient use of water as a resource in post-densified urban areas.

The research project also scientifically investigated the cooling performance of a green facade. Modern textile technology in the substrate promotes the "transpiration" of the plants. This creates evaporative cooling and lowers temperatures in the surrounding area.

The work of the Denkendorf research team also included a cost-benefit calculation and a life-cycle analysis. Based on the laboratory and outdoor studies, a "green value" was defined that can be used to evaluate and compare the effect of greening buildings as a whole.

Gemeinsam mit den Projektpartnern CG TEC, Cordenka, ElringKlinger, Fiber Engineering und Technikum Laubholz entwickeln die DITF einen neuen Faserverbundwerkstoff (CELLUN) mit Verstärkungsfasern aus Cellulose. Die Matrix des Werkstoffs ist ein thermoplastisches Cellulosederivat, das sich in industriellen Verarbeitungsverfahren wie Heißpressen oder Pultrusion verarbeiten lässt. CELLUN aus nachwachsenden Biopolymeren ermöglicht den Ersatz von Glas- oder Carbonfasern in der Herstellung industrieller Formteile.

Innerhalb des schnell wachsenden Segments des Faserverbund-Leichtbaus werden zunehmend Organosheeets eingesetzt. Organosheets sind vorkonsolidierte Platten-Halbzeuge mit einer Matrix aus thermoplastischen Kunststoffen und verschiedenen Verstärkungsfasern in unterschiedlichster textiler Ausführung. Die Thermoplastmatrix erlaubt die Verarbeitung der Organosheets mit in der Industrie etablierten „schnellen“ Verfahren wie Heißpressen, Thermoformen, Spritzgießen mit Organoblech-Einlegern oder Pultrusion. Die Verfahren erzeugen sehr gut recycelbare, hoch funktionalisierte Bauteile mit reproduzierbarer Qualität.

Die textile Verstärkung der Organosheets besteht vor allem aus Glas-, Carbon-, Basalt- oder Aramidfasern. Diese Fasern besitzen hohe Steifigkeiten und Zugfestigkeiten, sind jedoch in ihrer Herstellung und im Recycling energieintensiv und können nur in einem zunehmend minderwertigen Zustand recycelt werden.

Im Gegensatz dazu ist der an den DITF entwickelte CELLUN-Verbundwerkstoff eine wesentlich nachhaltigere Alternative. Für die Herstellung von CELLUN wird die Verstärkungskomponente aus nicht schmelzbaren Cellulosefasern sowie thermoplastischen, derivatisierten Cellulosefasern als Matrix zu einem Hybridroving kombiniert. Als cellulosische Verstärkungsfasern kommen Regeneratfasern der Firma Cordenka und die an den DITF entwickelten HighPerCell®-Cellulosefasern zum Einsatz.

CELLUN wird nun im Rahmen eines vom Bundesministerium für Wirtschaft und Klimaschutz (BMWK) geförderten Verbundprojekts zur industriellen Reife weiterentwickelt. Die Aufgaben der DITF im CELLUN-Verbundprojekt sind vor allem die Herstellung von geeigneten Verstärkungsfasern auf Basis von Cellulose und die Einbettung der Fasern in die thermoplastische Cellulose-Derivat-Matrix. Das Material wird in den hauseigenen Technika zu technischen Hybridrovingen und zu Hybridtextilien weiterverarbeitet. Über Pultrusions- und Thermoformverfahren oder im Spritzguss können schließlich Formteile hergestellt werden, die die technischen Einsatzmöglichkeiten des neuen Materials veranschaulichen.

Im weiteren Projektverlauf liegt der Fokus auf der vollständigen Kreislaufführung des CELLUN-Materials nach dem End of Life (EOL). Dazu werden zwei unterschiedliche Ansätze erforscht. Einerseits besteht die Möglichkeit, CELLUN-Formteile ohne Qualitätsverlust thermisch umzuformen. Ein zweiter möglicher Weg besteht darin, das CELLUN-Material wieder chemisch in die einzelnen Komponenten zu trennen. Diese können dann erneut wieder zu 100% als neue Ausgangsmaterialien eingesetzt werden.

CELLUN-Werkstoffe werden als umweltfreundliche, ressourcenschonende und kostengünstige Alternative zu etablierten Verbundwerkstoffen im Leichtbau- und Automotivsektor Vorteile im Markt der technischen Halbzeuge bieten. Durch die Verwendung nachwachsender Biopolymere soll ein wesentlicher Beitrag zum Umwelt- und Klimaschutz geliefert werden: Einerseits können herkömmliche Kunststoffe auf Rohölbasis substituiert werden, andererseits können CELLUN-Verstärkungs- und Matrixfasern mit nur geringem Energieeinsatz und aus natürlichen Rohstoffen hergestellt werden.

Start für ein EU-weites Verbundprojekt: Unter der Leitung des französischen Unternehmens Fairbrics SAS finden sich 17 Projektpartner aus sieben europäischen Ländern zusammen. Gemeinsames Ziel ist es, in einem geschlossenen Kreislauf Endprodukte aus Polyester unter Verwendung von industriellen CO₂-Emissionen zu erzeugen und zur Marktreife zu führen. Die DITF stellen dabei Synthesefasern aus Kunststoffen nicht fossilen Ursprungs her.

Um die europäischen Klimaziele zu erreichen, müssen Treibhausgase langfristig und nachhaltig reduziert werden. CO₂-Emissionen müssen hierfür in der Energiewirtschaft, in der Industrie sowie bei Haushalten und Kleinverbrauchern gesenkt werden. Hieran knüpft das EU-weite Verbundprojekt ‚Threading CO2‘ an, welches im Rahmen des Horizon-Förderprogramms der EU finanziert wird. Bei dem Projekt werden Produkte aus umweltfreundlich hergestelltem Polyester (PET) in die Marktreife überführt.

Die technologische Grundlage hat Firma Fairbrics SAS aus Frankreich entwickelt. Es geht um die Herstellung von Monoethylenglycol (MEG), dem Ausgangsstoff für die Herstellung von Polyester, unter Verwendung von CO₂, das aus industriellen Abgasen gewonnen wird - ein neuer Ansatz, denn im klassischen Verfahren werden fossile Rohstoffe für die Produktion von Polyester verbraucht. Auf diese Weise wird nicht nur direkt die Freisetzung von CO₂ in die Atmosphäre verhindert. Das CO₂ trägt zusätzlich einer erhöhten Wertschöpfung bei, indem es bei der Erzeugung von hochwertigen textilen Produkten eingebunden wird. Der Kern des Projektes ist die technologische Aufskalierung des neuen MEG-Syntheseprozesses in Pilotanlagen, die den Weg für die industrielle Fertigung ebnen.

In dem EU-Verbundprojekt werden sich 17 Projektpartner mit ihrem speziellen Fachwissen einbringen und den Prozess technologisch weiterentwickeln und industriefähig machen. Die DITF Denkendorf übernehmen innerhalb des Konsortiums die Aufgabe, das Upscaling zu begleiten und den Schritt ‚vom Molekül zum Material‘ zu gehen: Aus dem nachhaltig hergestellten Monoethylenglykol werden in eigenen Laboratorien Polyester synthetisiert, zu Fasern versponnen, texturiert und weiterverarbeitet. Dabei soll überprüft werden, ob die Qualität des Polyesters sowie dessen Verspinn- und Verarbeitbarkeit in der textilen Wertschöpfungskette vergleichbar mit konventionellem Polyester ist.

Die Projektpartner Faurecia und Les Tissages de Charlieu verarbeiten die Fasern und Textilien zu Autositzen und Bekleidung, um die Qualität auch im Endprodukt beurteilen zu können. Die anschließende Rezyklierfähigkeit der Produkte wird an den DITF überprüft. Außerdem soll eine Sicherheitsmarkierung für diesen CO₂-basierten Polyester entwickelt werden, um ihn vor Produktpiraterie zu schützen.