From the Sector

Altri has awarded AFRY engineering, site selection and integrated environmental authorization services assignment for a greenfield textile fiber factory in Spain. In addition, AFRY will support Altri to conceive, create and implement foundations for Industry 4.0 technologies in this new plant.

The demand for sustainable textile fibres is growing quickly globally. To support this growth, the Portuguese pulp producer Altri has become the industrial partner to public-private consortium Impulsa (Society for the Development of Strategic Projects of Galicia) as the lead investor and technologist to study the wood-based textile fibers biofactory exclusively. This biofactory will use Galician wood as the primary raw material together with recycled remains from the textile industry to produce dissolving pulp and Lyocell fibre. The plant will be designed based on the best available techniques (BAT), best environmental practices, as well as cutting-edge proven technologies and the production will be fossil-fuel-free. The project is expected to benefit from the “Next Generation EU” program.

Altri is responsible for designing and developing the biofactory project to transform wood into a textile fiber, evaluating site locations and exploring alliances with the entire value chain. Altri has assigned AFRY to support the project development and planned project implementation.  

The industrial biorefinery to be built from scratch will be able to provide the textile cluster of the Iberian peninsula with sustainable cellulosic fibers, contributing to the strengthening of the circular economy and decarbonisation of an important economic sector such as the textile sector.

AFRY has been involved in the project development from the very early stages. AFRY supported the project concept idea initially developed by Altri and led the preliminary feasibility study. A multi-disciplinary team of AFRY’s engineering and consulting experts is currently supporting Altri on the site selection activities, engineering and permitting processes.

In a new study, Empa researcher Dominik Brunner, together with colleagues from Utrecht University and the Austrian Central Institute for Meteorology and Geophysics, is investigating how much plastic is trickling down on us from the atmosphere. According to the study, some nanoplastics travel over 2000 kilometers through the air. According to the figures from the measurements about 43 trillion miniature plastic particles land in Switzerland every year. Researchers still disagree on the exact number. But according to estimates from the study, it could be as much as 3,000 tonnes of nanoplastics that cover Switzerland every year, from the remote Alps to the urban lowlands. These estimates are very high compared to other studies, and more research is needed to verify these numbers

The study is uncharted scientific territory because the spread of nanoplastics through the air is still largely unexplored.

The scientists studied a small area at an altitude of 3106 meters at the top of the mountain "Hoher Sonnenblick" in the "Hohe Tauern" National Park in Austria.
Every day, and in all weather conditions, scientists removed a part of the top layer of snow around a marker at 8 AM and carefully stored it. Contamination of the samples by nanoplastics in the air or on the scientists' clothes was a particular challenge. In the laboratory, the researchers sometimes had to remain motionless when a colleague handled an open sample.

The origin of the tiny particles was traced with the help of European wind and weather data. The researchers could show that the greatest emission of nanoplastics into the atmosphere occurs in densely populated, urban areas. About 30% of the nanoplastic particles measured on the mountain top originate from a radius of 200 kilometers, mainly from cities. However, plastics from the world's oceans apparently also get into the air via the spray of the waves. Around 10% of the particles measured in the study were blown onto the mountain by wind and weather over 2000 kilometers – some of them from the Atlantic.

It is estimated that more than 8300 million tonnes of plastic have been produced worldwide to date, about 60% of which is now waste. This waste erodes through weathering effects and mechanical abrasion from macro- to micro- and nanoparticles. But discarded plastic is far from the only source. Everyday use of plastic products such as packaging and clothing releases nanoplastics. Particles in this size range are so light that their movement in the air can best be compared to gases.

Besides plastics, there are all kinds of other tiny particles. From Sahara sand to brake pads, the world is buzzing through the air as abrasion. It is as yet unclear whether this kind of air pollution poses a potential health threat to humans. Nanoparticles, unlike microparticles, do not just end up in the stomach. They are sucked deep into the lungs through respiration, where their size may allow them to cross the cell-blood barrier and enter the human bloodstream. Whether this is harmful or even dangerous, however, remains to be researched.

• ADNOC and Borealis confirm final investment agreement to build Borouge 4 in Ruwais, United Arab Emirates (UAE), which will produce 1.4 million tons of polyethylene per annum
• Expansion project includes construction of a 1.5 million tonnes ethane cracker, two state-of-the-art Borstar® polyethylene plants and a cross-linked polyethylene plant
• Borouge 4 will meet growing customer demand across the Middle East, Africa and Asia with differentiated polyolefin solutions in energy, infrastructure, and advanced packaging
• New facility will benefit from industry-leading technologies to significantly improve energy efficiency and lower emissions, with carbon capture study underway
• Upon expansion, Borouge will be the world's largest single-site polyolefin complex and will supply feedstock to TA'ZIZ Industrial Chemicals Zone Body

ADNOC and Borealis AG signed an USD 6.2 billion investment agreement to build the fourth Borouge facility – Borouge 4 – at the polyolefin manufacturing complex in Ruwais, United Arab Emirates (UAE).

The world-scale expansion confirms both partners’ commitment to the growth of Borouge and to support chemical production, and advanced manufacturing and industry in Ruwais, a key pillar of Abu Dhabi and the UAE’s technology, innovation and industrial development strategy. Borouge produces crucial industrial raw materials, which are exported to customers globally and used by local companies, boosting local industrial supply chains and enhancing In-Country Value.

Borouge 4 will capitalize on the projected growth in customer demand for polyolefins, driven by their use in manufactured products in the Middle East, Africa and Asia. The facility will also enable the next phase of growth at the Ruwais Industrial Complex by supplying feedstock to the TA’ZIZ Industrial Chemicals Zone.

Borouge 4 will have an industry-leading focus on sustainability leveraging the capabilities of both shareholders. The facility will utilize Borealis’ proprietary Borstar technology, to produce a product portfolio focused on durable applications for energy, infrastructure, advanced packaging, and agriculture sectors. This unique technology, in combination with hexene co-monomer, will enable the production of advanced packaging grades with up to 50% recycled polyethylene content.

Subject to an in-depth study, a Carbon Capture unit that would reduce CO2 emissions by 80% could also be operational in time for Borouge 4’s start-up. The facility is also designed to capitalize on ADNOC’s recent initiatives on clean energy, decarbonizing its power supply through access to Abu Dhabi’s clean power sources. These initiatives are aligned with the UAE Net Zero by 2050 Strategic Initiative.

The first Borouge facility, producing 450,000 tons of polyethylene per annum was commissioned in 2001. Borouge 2 and Borouge 3 took capacity to 2 million tons and 4.5 million tons of polyethylene and polypropylene per annum in 2010 and 2014 respectively.  Borouge 4 will boost the company’s annual polyolefin production to 6.4 million tons, making Borouge one of the world’s largest single-site polyolefin facilities.

The new Borouge 4 facility will comprise:

• An ethane cracker, with 1.5 million tons ethylene output per annum, which will be the fourth cracker in Borouge’s integrated petrochemical complex in Ruwais
• Two additional Borstar® polyethylene (PE) plants, each with 700 thousand tons per annum capacity, using state-of-the-art Borealis Borstar third generation (3G) technology
• A cross-linked PE (XLPE) plant of 100 thousand tons per annum capacity.
• A hexene-1 unit, which will produce co-monomers for certain grades of polyethylene.

It looks like a normal shirt, but it has it all: The new SmartTex shirt uses integrated sensors to transfer physiological data from astronauts to Earth via a wireless communication network. In this way, the effects of the space environment on the human cardiovascular system will be evaluated and documented, especially with regard to long-term manned space missions. Developed by the German Aerospace Center (DLR) in cooperation with DSI Aerospace Technology, the Medical Faculty of Bielefeld University and textile research partner Hohenstein, SmartTex will be tested for the first time as part of the Wireless Compose-2 (WICO2) project by German ESA astronaut Dr. Matthias Maurer, who will leave for his ‘Cosmic Kiss’ mission on the International Space Station (ISS) for six months on October 30, 2021.

"We were already able to gain valuable insights into the interaction of the body, clothing and climate under microgravity conditions during the previous projects Spacetex (2014) and Spacetex2 (2018)," explains Hohenstein Senior Scientific Expert Dr. Jan Beringer. The insights provided at the time by the mission of ESA astronaut Dr. Alexander Gerst have now been directly incorporated into the development of the new SmartTex shirt at Hohenstein. "Matthias Maurer can wear his tailor-made shirt comfortably on his body during his everyday work on the International Space Station. For this, we used his body measurements as the basis for our cut development and the production of the shirt. We integrated the necessary sensors as well as data processing and communication modules into the shirt's cut in such a way that they interfere as little as possible and are always positioned in the right place, regardless of the wearing situation. This is the prerequisite for reliably measuring the relevant physiological data." The SmartTex shirt is intended to provide a continuous picture of the vital functions of astronauts. This will be particularly relevant for future long-term manned space missions to the Moon and Mars.

For example, during the BEAT experiment (Ballistocardiography for Extraterrestrial Applications and long-Term missions), Matthias Maurer will be the first astronaut to wear a T-shirt equipped with sensors that measure his ballistocardiographic data such as pulse and relative blood pressure. For this purpose, the sensors were calibrated in the :envihab research facility at the DLR Institute of Aerospace Medicine in Cologne. Details on the contraction rate and opening and closing times of the heart valves, which are normally only accessible via sonography or computer tomography, can also be read from the data material. The goal is to study the effects of the space environment on the human cardiovascular system. To be able to analyse these effects realistically, Matthias Maurer's ballistocardiographic data will be recorded before, during and after his stay on the ISS. For the future, a technology transfer of the SmartTex shirt for application in the field of fitness or even in telemedicine is conceivable.

Wireless Compose-2 (WICO2)
The project was planned and prepared by the German Aerospace Center (DLR) and its cooperation partners DSI Aerospace Technology, Hohenstein and the University of Bielefeld. The wireless communication network reads sensor data and can determine the position of people and objects in space by propagation times of radio pulses. It is also available as a platform for several experiments on the ISS. The determined data is temporarily stored within the network and read out at regular intervals by the astronauts. These data packets are then transferred to Earth via the ISS link and analysed by the research teams. It can generate its own energy from artificial light sources via solar cells.

ESA astronaut Dr. Matthias Maurer in summer 2021 during preliminary talks on the Cosmic Kiss mission in DLR's :envihab in Cologne. © DLR

Sensors measure physiological data during a test run on Earth. © DLR

With the "SmartTex" shirt, astronauts can wear the necessary sensors comfortably on their bodies. © DLR

Dr. Jan Beringer, Hohenstein Senior Scientific Expert. © Hohenstein

Recycling is the key factor in achieving the EU climate targets. This is shown by the results of the "resources SAVED by recycling" study published today, which Fraunhofer UMSICHT prepared on behalf of the ALBA Group, one of the ten leading recycling companies worldwide. According to the study, 3.5 million tons of greenhouse gas emissions and 28.8 million tons of primary resources could be saved in 2020 alone. Further potential could be raised, for example, through minimum quotas for the use of recycled raw materials.

“Fit for 55” thanks to the circular economy: the recycling of raw materials leads to a systematic reduction in the greenhouse gas emissions of our civilisation – and can therefore make a key contribution to achieving the EU climate goals. This is the outcome of the “resources SAVED by recycling” study presented today, which the Fraunhofer Institute for Environmental, Safety and Energy Technology UMSICHT prepared on behalf of the ALBA Group. Thanks to the closed-loop circulation of 4.8 million tonnes of recyclable materials, the ALBA Group succeeded in preventing some 3.5 million tonnes of climate-damaging greenhouse gas emissions in the year 2020 alone. This amount is equivalent to the emissions from some five million return flights between Frankfurt am Main and Mallorca. At the same time, recycling also secures valuable raw materials for the industry: in 2020, in comparison with primary production, recycling saved 28.8 million tonnes of resources, such as crude oil and iron ore.

“The circular economy is one of the strongest pace-setters on the journey to achieving climate neutrality,” highlights Dr. Axel Schweitzer, CEO of the ALBA Group. “We will only achieve the goal of reducing greenhouse gas emissions by at least 55 per cent throughout Europe by 2030 if we make consistent use of recycled raw materials.” This includes the area of plastics, for example: compared with primary plastics made from crude oil, the use of high-quality recycled plastics achieves a reduction of greenhouse gas emissions of more than 50 per cent. “It is now necessary to lever this potential,” explains Schweitzer. “We are expecting the new Federal Government in Germany to act decisively and push ahead directly with the transition to a circular economy. The environmental benefits of recycling due to its clearly superior CO2 balance should also find reflection in prices. As immediate climate protection measures, clear industry standards for recyclates combined with minimum quotas on the use of recycled raw materials in products and packaging are also urgently necessary. Last but not least, the state sector is also called upon to prioritise resource protection in the area of procurement. Sustainable procurement can ultimately provide a significant boost to the circular economy”.

Plastics, metals, waste electrical (and electronic) equipment, wood, paper, cardboard, cartons or glass: the Fraunhofer UMSICHT has now been researching the specific benefits of recycling for 14 years. Detailed comparisons have also been made of the primary processes and recycling processes for the various material flows. “This means we can precisely quantify the extent to which the recycling activities of the ALBA Group can contribute to reducing the burden on the environment,” explains Dr.-Ing. Markus Hiebel, Director of the Department for Sustainability and Participation at Fraunhofer UMSICHT. Hiebel believes that the greatest savings can be achieved if the entire value chain is aligned consistently with the circular principle: “The transformation towards a genuine circular economy requires completely new thinking. Products should be designed and managed to ensure that they contain recycled raw materials right from the start – which enables them to be recycled appropriately.”

After starting the first "Dibella up" circular-flow concept in August 2020, thousands of high-quality bags have already been made from used hotel textiles. Now the company is presenting another upcycling project: As part of a feasibility study, organic Fairtrade napkins that could no longer be rented out by the company were turned into jeans.

The second "Dibella up" project promises successful recycling of used object textiles. Within the framework of a feasibility study, almost 5,000 discarded napkins were used for jeans production in Pakistan. The special feature of the process is the traceability of the raw materials through all processing stages.

The napkins made of pure organic Fairtrade cotton originated in India. There, the fibres were grown and harvested by micro-farmers of the Chetna cooperative and then processed into durable textiles by a certified company. From Dibella, the napkins went to Lamme Textile Management, where they went through the use process in laundry and catering for many years. All stages were traceable by means of a "Respect Code" with which each piece was marked.

In the recycling project, the original supply chain was reversed: Dibella transported the organic Fairtrade napkins discarded by Lamme Textile Management to Pakistan. There, the goods were shredded and the organic Fairtrade cotton fibres recovered in a full-scale textile plant specialising in sustainability. In the next step, they were mixed with "fresh fibres", spun into yarns for denim production, woven, finished with sustainable processes, subjected to quality tests and then made up into jeans.

Dibella has been selected by the German Federal Ministry for Labour and Social Affairs (BMAS) as a model case study for due diligence in the context of human rights. The showpiece for responsible supply chain management is presented on the Ministry’s homepage.

For many years now, Dibella has been engaged in developing a fair and ecologically responsible textile supply chain and was therefore one of 25 enterprises nominated for the prestigious CSR award of the German government in the year 2020. The responsible Federal Ministry of Labor and Social Affairs (BMAS) has now selected the human rights due diligence activities implemented by Dibella as a positive case study. A presentation of the company's extensive activities for sustainable action is now available on the BMAS website.

An encouraging, positive example
"Corporate social responsibility means illuminating the impacts of one's own entrepreneurial actions at all levels and integrating responsible action into all business activities. We have been consistently implementing this philosophy for many years. We attach great importance to the sustainable production of our textiles and to good working conditions throughout our value chain. It therefore makes us proud that our approach is presented by the BMAS as a good example of a positive contribution to society, which can serve as motivation for sustainable commitment in all industries," says Ralf Hellmann, Managing Director of Dibella.

Sustainability and environmental responsibility are important developments for the current design of productions and products. In order to obtain a comprehensive evaluation of the potential of bio-based composites, the AZL, together with an industry consortium, is investigating the market potential, future applications and relevant technologies for bio-based composite materials. The 5-month market and technology study will start on October 22nd, 2020 and is open to interested companies. Companies such as REHAU, an Automotive Tier 1, Asahi Kasei, Johns Manville, Mahr Metering Systems and several material manufacturers are participating in the study.

Bio-plastics are well established in industry, especially in packaging applications. The market for biopolymers is expected to grow from USD 10.5 billion in 2020 to USD 27.9 billion in 2025. At the same time, bio-based raw materials, such as natural fibers, are available on the market in a cost-effective manner. Composites with wood or natural fiber content are also increasingly used in products.

Dr. Michael Emonts, Managing Partner of AZL: "Together with our partner companies we want to identify hidden business potential for composites with bio-based materials. To do so, we will reapply our established approach for market and technology studies: Based on a detailed market analysis, we will dive deep into the technological evaluation of technologies, applications and business cases.”

Based on a detailed market segmentation, AZL's technology experts analyze the various market segments in terms of their size, growth potential, relevant players and existing and future applications. For the identified applications, the participants in the study will receive detailed insight into the respective technical and legal requirements as well as an overview of value chains, processes and materials. In the following, the strengths and challenges of bio-composites compared to conventional materials are elaborated. The consortium will select the components with the highest potential, for which suitable production scenarios will be developed and analyzed in terms of costs in a business case analysis.

"We are participating in the AZL study to identify and evaluate new product areas with bio-materials. The technological analyses of the AZL studies have already helped us in the past to initiate new developments," says Dr. Steven Schmidt, Director Technology Platforms Materials at REHAU, explaining the motivation for working with the AZL and the industry consortium. "As one of the 50 Sustainability & Climate Leaders, we at REHAU are incorporating environmentally friendly materials into more and more products. Wherever the company is active - from the furniture and construction industries to the automotive industry - REHAU is already developing and manufacturing high-quality products from recycled raw materials. By 2025, REHAU plans to increase its recycling rate across the Group to significantly more than 15 percent and at the same time reduce CO2 emissions by at least 30 percent," adds Dr. Steven Schmidt.

Bio-composites will also be the topic of the upcoming Lightweight TechTalk by AZL on September 29, 2020. Experts from industry and academia will give technology and market insights on sustainability and recycling of composites in 6 presentations. Registration is free of charge at: https://azl-aachen-gmbh.de/termine/recycling-of-composites/.

The kick-off of the project will take place on October 22nd, 2020 in the form of a video conference. Further background information on the project can be found under the following link: https://azl-aachen-gmbh.de/wp-content/uploads/2020/09/2020-251_OP_Bio-Bases_Composites.pdf

• Bemberg™ presents a great deal of novelties with a true key-statement for sustainability: Let’s Make it Circular!
• The lifespan of Bemberg™’s regenerated cellulose fiber Cupro derived from cotton is fully circular: from the source to manufacturing.

“Sustainability is the founding pillar of our company,” says SHUNSUKE SATO, sales manager of Bemberg™ by Asahi Kasei. “Indeed, the smart fiber is made from a cotton linter which is pre-consumer material, a natural derived source, that doesn’t deplete forestry resources”.

In Bemberg™’s production the whole sustainable closed-loop process is supported by the LCA study, signed by ICEA (Istituto per la Certificazione Etica e Ambientale) and validated by President of Ecoinnovazione Paolo Masoni ex Research Director of ENEA (Ente per le Nuove tecnologie, l’Energia e l’Ambiente).

While recyclability is granted by the Global Recycle Standard - GRS certification by the renown Textile Exchange (an influential guarantee that involves the whole production process and supply chain behind the company’s smart yarns), Bemberg™ yarns are also entirely biodegradable and ecotoxicity-free - meaning that at the end of their life circle they break down into the environment leaving no trace in terms of toxic substances as attested by the Innovhub-SSI report.

A special focus deserves Velutine™ Evo, the new fibrillation finishing technology for Bemberg™ fabrics only that guarantees another level of sustainable benefits without sacrificing the Bemberg™ amazing and unique touch. As part of the company’s continuous innovation, Velutine™ Evo brings better environmental, energy and water profiles for the benefit of Bemberg™ partners in the manufacture of their ranges.
The sustainable achievements of the new finishing technology have been measured by LCA - Life Cycle Assessment study by ICEA and proved to guarantee environmental benefits such as -16.5% of greenhouses gas emissions and -21% of overall consumption of energy resources. On top of that Velutine™ Evo means also -20.5% of electricity savings, -15.9% of steam production and -19.5% of water consumption.

The first Bemberg™ partner to present a commercial collection enriched by Velutine™ Evo is the Portuguese Matias & Araújo. With an innovative spirit, dynamism and a determined entrepreneurial spirit, the company is a leading knitwear producer for the textile industry.

Bemberg™ collaborated also with the premium brand CAALO that is making its mark in the outerwear market with its Sustainably produced Functional-Luxury proposal. For SS20, CAALO uses Bemberg™ lining because of the sustainability properties and it’s unique colour.

CAALO uses as much eco-friendly and sustainable materials as possible without compromising on design or quality. This Bemberg™ lining was a perfect fit. This versatile blazer features a removable hood, hidden welt pockets, button closure, and removable cargo pockets.

Bemberg™ gears up for Première Vision - February 11th-13th, Paris, France; with a great deal of novelties and a key statement on sustainability: Let’s Make it Circular! That’s why the Japanese brand of regenerated cellulose fibers joins the fair with two booths, one in the yarn-focused sector – Hall 6 C52 6D53 – the other one in the Smart Creation area, the curated district showcasing cutting-edge sustainable innovation for the textile and fashion business. Hall3 S14.

“We simply could not miss out on the Smart Creation Area as sustainability is the founding pillar of our company,” says SHUNSUKE SATO, sales manager of Bemberg™ by Asahi Kasei. “Indeed, the smart fiber is made from a cotton linter which is pre-consumer material, a natural derived source, that doesn’t deplete forestry resources. The strategy beyond our double presence is to highlight our deep commitment to responsible innovation to a larger target of professionals.”

Let’s take it circular! is the motto at the Smart Creation booth. The lifespan of Bemberg™’s regenerated cellulose fiber derived from cotton is fully circular: from the source to manufacturing. The whole sustainable closed-loop process is supported by the LCA study, signed by ICEA and validated by Paolo Masoni. Recyclability is granted by the Global Recycle Standard - GRS certification by the renown Textile Exchange. An influential guarantee that involves the whole production process and supply chain behind the company’s smart yarns. Bemberg™ yarns are entirely biodegradable and ecotoxicity-free – meaning that at the end of their life circle they break down into the environment leaving no trace in terms of toxic substances as attested by the Innovhub-SSI report.

On show at Première Vision some of the most recent collaborations with GRS-certified partners such as FIVEOL, SMI TESSUTI, TESSITURA UBOLDI, INFINITY, SIDONIOS, MATIAS & ARAUJO, TINTEX, IPEKER, EKOTEN, for fashion fabrics as well as PEZZETTI and BRUNELLO & G.CRESPI from lining partners.

The first Bemberg™ partner to present a commercial collection enriched by Velutine™ Evo is the Portuguese Matias & Araújo. With an innovative spirit, dynamism and a determined entrepreneurial spirit, the company is a leading knitwear producer for the textile industry.

In the Hall 6 Bemberg™ displays key commercial items developed by premium brands such as CAALO that is making its mark in the outerwear market with its Sustainably produced Functional-Luxury proposal. For SS20, CAALO utilized Bemberg™ lining because of the sustainability properties and it's unique colour.

CAALO looks to utilize as much eco-friendly and sustainable materials as possible without compromising on design or quality. This Bemberg™ lining was a perfect fit.