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Borealis celebrates 30th anniversary (c) Borealis
05.03.2024

Borealis celebrates 30th anniversary

Borealis is commemorating its thirtieth year of operations. Born of a merger between Statoil and Neste, Borealis has expanded from its early Nordic roots to become one of the top polyolefins players. Its dedication to value creation through innovation has produced proprietary and transformative technologies which benefit society and accelerate the transition to a circular economy. The company is regularly ranked as Austria's top innovator in the European Patent Index and holds an extensive patent portfolio of around 8,900 granted patents. In Europe in particular, Borealis has for decades bolstered the industrial landscape by investing in its capital assets, and by providing thousands of jobs.

Borealis is commemorating its thirtieth year of operations. Born of a merger between Statoil and Neste, Borealis has expanded from its early Nordic roots to become one of the top polyolefins players. Its dedication to value creation through innovation has produced proprietary and transformative technologies which benefit society and accelerate the transition to a circular economy. The company is regularly ranked as Austria's top innovator in the European Patent Index and holds an extensive patent portfolio of around 8,900 granted patents. In Europe in particular, Borealis has for decades bolstered the industrial landscape by investing in its capital assets, and by providing thousands of jobs.

Innovations
Borealis uses technological innovation to add value to polyolefin-based applications, ensure that production processes are made more resource efficient, and to accelerate plastics circularity. Borstar®, the multi-modal proprietary technology for the manufacture of polyethylene (PE) and polypropylene (PP), has been a mainstay of Borealis success since the start-up of the first Borstar PE plant in Porvoo, Finland in 1995. Borstar has since been joined by other technology brands, like Borlink™, an innovation for the power cable industry; Borstar® Nextension Technology, an innovation that among other benefits facilitates the production of monomaterial applications designed for recycling; or the Borcycle™ M technology for mechanical recycling, which breathes new life into polyolefin-based, post-consumer waste, transforming it into applications with a lower carbon footprint.

Global Expansion
With the strong support of its two majority shareholders OMV (Austria) and The Abu Dhabi National Oil Company (ADNOC, UAE), Borealis continues to expand its global footprint. The joint venture Borouge, established in 1998 in the UAE, and listed on the Abu Dhabi Securities Exchange (ADX) since 2022, is one of the largest integrated polyolefin complexes. It is currently the site of the company’s largest-ever growth project: Borouge 4, the new USD 6.2 billion facility in Ruwais, which will serve customers in the Middle East and Asia. In North America, the Baystar™ joint venture, founded in 2017 and operated with partner TotalEnergies, entailed the construction of a new ethane cracker as well as the most advanced Borstar plant ever built outside of Europe. The PE Borstar 3G plant in Pasadena, Texas was started up in late 2023 and has brought Borstar to this continent for the first time. Borealis’ commitment to Europe as a production location is evidenced by the new, world-scale propane dehydrogenation (PDH) plant currently under construction at Borealis operations in Kallo, Belgium.

More information:
Borealis polyolefins Recycling
Source:

Borealis

26.01.2024

Solvay reduces transportation carbon footprint

Solvay is partnering with transportation providers KIITOSIMEON and ADAMS LOGISTICS to reduce the carbon footprint of its facility in Voikkaa, Finland. Known for its hydrogen peroxide technology, the site has a yearly capacity of 85 kilotons, making it the largest hydrogen peroxide unit in the country and one of the largest in Europe. However, the transportation of its products results in more than 850 tons of CO2 emissions annually, attributed to the several thousands deliveries conducted each year.

While the Voikkaa site has been operating on 100% wind-generated electricity since 2023, the journey towards decarbonization takes another step forward as it transitions transportation fuel from diesel to biofuel in the first quarter of 2024. This shift will result in a significant annual reduction of over 700 tons of CO2 emissions, representing more than 8O% reduction in the site's transportation carbon footprint.

Solvay is partnering with transportation providers KIITOSIMEON and ADAMS LOGISTICS to reduce the carbon footprint of its facility in Voikkaa, Finland. Known for its hydrogen peroxide technology, the site has a yearly capacity of 85 kilotons, making it the largest hydrogen peroxide unit in the country and one of the largest in Europe. However, the transportation of its products results in more than 850 tons of CO2 emissions annually, attributed to the several thousands deliveries conducted each year.

While the Voikkaa site has been operating on 100% wind-generated electricity since 2023, the journey towards decarbonization takes another step forward as it transitions transportation fuel from diesel to biofuel in the first quarter of 2024. This shift will result in a significant annual reduction of over 700 tons of CO2 emissions, representing more than 8O% reduction in the site's transportation carbon footprint.

As part of its commitment to carbon neutrality by 2050, Solvay has outlined a sustainability roadmap with around 40 energy transition projects. These projects focus on eliminating coal usage, emphasizing renewable energy sources, prioritizing energy efficiency, and driving process innovation. Solvay has further committed to reduce its emissions* along the value chain by 20% by 2030.

*scope 3 emissions, focus 5 categories, 2021 baseline

AZL Aachen GmbH: Kick-off meeting for "Trends and Design Factors for Hydrogen Pressure Vessels" project (c) AZL Aachen GmbH
21.12.2023

AZL Aachen GmbH: Kick-off meeting for "Trends and Design Factors for Hydrogen Pressure Vessels" project

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 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.

11.09.2023

Project and technology study: Trends and Design Factors for Hydrogen Pressure Vessels

Die AZL Aachen GmbH, bekannter Innovationspartner für Industriekooperationen auf dem Gebiet der Leichtbautechnologieforschung, startet eines neuen Projekts mit dem Titel "Trends und Designfaktoren für Wasserstoffdruckbehälter". Das Projekt wird Fragestellungen der Industrie in Bezug auf die Wasserstoffspeicherung adressieren.


AZL Aachen GmbH, a recognized innovator in lightweight technologies research and industry collaboration, announces the initiation of a new project titled "Trends and Design Factors for Hydrogen Pressure Vessels". The project aims to address industry needs surrounding hydrogen storage.

Hydrogen has gained significant attention as a key technological solution for decarbonization, with high pressure storage and transportation emerging as vital components. Its applications extend from stationary storage solutions to mobile pressure vessels employed in sectors such as transportation and energy systems.

Die AZL Aachen GmbH, bekannter Innovationspartner für Industriekooperationen auf dem Gebiet der Leichtbautechnologieforschung, startet eines neuen Projekts mit dem Titel "Trends und Designfaktoren für Wasserstoffdruckbehälter". Das Projekt wird Fragestellungen der Industrie in Bezug auf die Wasserstoffspeicherung adressieren.


AZL Aachen GmbH, a recognized innovator in lightweight technologies research and industry collaboration, announces the initiation of a new project titled "Trends and Design Factors for Hydrogen Pressure Vessels". The project aims to address industry needs surrounding hydrogen storage.

Hydrogen has gained significant attention as a key technological solution for decarbonization, with high pressure storage and transportation emerging as vital components. Its applications extend from stationary storage solutions to mobile pressure vessels employed in sectors such as transportation and energy systems.

The AZL team, renowned for its high reputation in providing market and technology insights as well as developing component and production concepts in the format of Joint Partner Projects seeks for companies along the whole composite value chain interested in further developing their application know how in this economically highly relevant field.

The project will provide an in depth exploration of market insights, regulatory standards, and intellectual property landscapes. Beyond this, there is a dedicated focus on staying updated with state of the art and advancements in design, materials, and man ufacturing techniques.

An integral component of the project involves the creation of reference designs by AZL´s engineering team. The reference designs will encompass a variety of pressure vessel configurations and will consider a diverse range of materials and production concep ts.

With the scheduled project start in October 2023, and a project timeline of approximately nine months, AZL encourages companies active across the composite value chain to participate. Companies interested in participating or seeking further information should reach out directly to the AZL expert team.

Source:

Aachener Zentrum für integrativen Leichtbau

(c) A. Monforts Textilmaschinen GmbH & Co. KG
Members and associates of the WasserSTOFF consortium from Monforts, Pleva, NTB Nova Textil, TU Freiberg, Hochschule Niederrhein and Honeywell Thermal Solutions, at the launch meeting of the new project at the Monforts ATC in Mönchengladbach.
28.04.2023

Monforts presents green hydrogen project WasserSTOFF at ITMA 2023

At ITMA 2023 in Milan from June 8-14 this year, Monforts is organising two free-to-attend seminars and discussions on the potential of green hydrogen as a new energy source for textile finishing, drying and related processes.

Monforts is currently leading a consortium of industrial partners and universities in the three-year WasserSTOFF project, launched in November 2022, that is exploring all aspects of this exciting and fast-rising new industrial energy option.
The target of the government-funded project is to establish to what extent hydrogen can be used in the future as an alternative heating source for textile finishing processes. This will first involve tests on laboratory equipment together with associated partners and the results will then be transferred to a stenter frame at the Monforts Advanced Technology Center (ATC).

At ITMA 2023 in Milan from June 8-14 this year, Monforts is organising two free-to-attend seminars and discussions on the potential of green hydrogen as a new energy source for textile finishing, drying and related processes.

Monforts is currently leading a consortium of industrial partners and universities in the three-year WasserSTOFF project, launched in November 2022, that is exploring all aspects of this exciting and fast-rising new industrial energy option.
The target of the government-funded project is to establish to what extent hydrogen can be used in the future as an alternative heating source for textile finishing processes. This will first involve tests on laboratory equipment together with associated partners and the results will then be transferred to a stenter frame at the Monforts Advanced Technology Center (ATC).

To be considered “green”, hydrogen must be produced using a zero-carbon process that is powered by renewable energy sources such as wind or solar. Currently, the cleanest method of hydrogen production is electrolysis, using an electrically-powered electrolyzer to separate water molecules into hydrogen and oxygen. The purity of the hydrogen is also important, and impurities must be removed via a separation process.

“Despite all its advantages, there are obstacles to overcome on the way to widespread, economically-feasible green hydrogen use,” explains Monforts Textile Technologies Engineer Jonas Beisel. “Until there are widely available, reliable and economical sources of this clean power, the cost of producing it will remain prohibitive. The infrastructure is not yet there, and hydrogen also has a tendency to make steel brittle and subject to fracture, which is something that requires further investigation in both its transportation and use in industrial processing.
“Green energy’s potential as a clean fuel source is tremendous, but there is much we need to explore when considering its use in the textile finishing processes carried out globally on our industry-leading Montex stenter dryers and other machines.”

At its Advanced Technology Center (ATC) in Mönchengladbach, Monforts will be carrying out intensive tests and trials to assess the reliability of both processes and final products when different natural gas and hydrogen mixtures – up to 100% green hydrogen – are employed. The results will be closely analysed by the consortium partners because there are many parameters that at this stage remain unknown.

The aim, Beisel adds, is to both reduce CO2 emissions and – following the rising prices and industry turbulence experienced by manufacturers over the past year or so – to further reduce a dependency on natural gas.

The three-year WasserSTOFF project is sponsored by Germany’s Federal Ministry for Economic Affairs and Climate Action, and with Monforts at the helm brings together industrial partners Pleva and NTB Nova Textil, with academic input from the Hochschule Niederrhein and the Technical University of Freiberg.

30.12.2022

Composites United declares membership in Composites Germany

Society and the economy are facing existential challenges. In addition to the consequences of climate change, these include the realisation that energy and many resources are no longer available in the usual quantities, so that their efficiency must be significantly increased in the short term. Lightweight construction, especially with fibre composite materials, can and will make an important contribution here, e.g. in wind power plants or hydrogen storage systems. As an umbrella organisation, Composites Germany represents the capabilities and interests of the German fibre composite industry. With the re-entry of Composites United, Composites Germany will combine the forces of the two leading composites networks in Germany and its position will be significantly strengthened. Changed framework conditions make the re-entry possible and necessary.

Society and the economy are facing existential challenges. In addition to the consequences of climate change, these include the realisation that energy and many resources are no longer available in the usual quantities, so that their efficiency must be significantly increased in the short term. Lightweight construction, especially with fibre composite materials, can and will make an important contribution here, e.g. in wind power plants or hydrogen storage systems. As an umbrella organisation, Composites Germany represents the capabilities and interests of the German fibre composite industry. With the re-entry of Composites United, Composites Germany will combine the forces of the two leading composites networks in Germany and its position will be significantly strengthened. Changed framework conditions make the re-entry possible and necessary.

VDMA and Leichtbau BW will continue to support the work of Composites Germany as associate members and contribute the know-how of their members. Together, the organisations will promote sustainable lightweight construction as a key technology for Germany, focusing on composites materials, says Prof. Klaus Drechsler of Composites United, one of the two board members of Composites Germany. As a network and mouthpiece of the composites industry, Composites Germany bundles the interests of its members. The aim is to continuously expand activities, promote innovations and technologies, develop new markets and new value chains, and anchor training and further education, adds his board colleague Dr Michael Effing of AVK. The agreement was concluded on 29 November 2022 during the JEC Forum DACH in Augsburg, where both associations were cooperation partners of the event.

Source:

Composites Germany

Freudenberg´s gas diffusion layer production Photo: Freudenberg´s gas diffusion layer production.
20.10.2022

Freudenberg supplies gas diffusion layers for fuel cell stacks

Freudenberg Performance Materials (Freudenberg) has concluded a high-volume, multi-year contract with a global automotive tier one supplier to supply high-performance gas diffusion layers for the stacks forming the core of the fuel cell systems produced by the leading automotive supplier. Global target applications are mid-sized and heavy commercial vehicles as well as buses. Freudenberg is supporting the customer’s global fuel cell activities, thereby also accelerating the breakthrough of mass-produced fuel cell stacks.

Fuel cell technology is an important element of a successful energy transition. Gas diffusion layers play a key role in this context: they are indispensable for the functioning of a fuel cell and have a significant impact on the performance of a fuel cell stack.

Freudenberg Performance Materials (Freudenberg) has concluded a high-volume, multi-year contract with a global automotive tier one supplier to supply high-performance gas diffusion layers for the stacks forming the core of the fuel cell systems produced by the leading automotive supplier. Global target applications are mid-sized and heavy commercial vehicles as well as buses. Freudenberg is supporting the customer’s global fuel cell activities, thereby also accelerating the breakthrough of mass-produced fuel cell stacks.

Fuel cell technology is an important element of a successful energy transition. Gas diffusion layers play a key role in this context: they are indispensable for the functioning of a fuel cell and have a significant impact on the performance of a fuel cell stack.

A fuel cell converts the chemical energy of hydrogen and atmospheric oxygen into electricity. Functionally-optimized gas diffusion layers made of carbon-fiber based nonwoven are installed on both sides of a catalyst-coated membrane positioned in the middle of the fuel cell. The gas diffusion layers distribute hydrogen and oxygen evenly to the membrane and remove the electricity, heat and water generated by the CO2-free chemical reaction. They also protect the sensitive membrane and are optimized to suit the bipolar plate. A fuel cell stack is made up of several individual fuel cells.

Freudenberg already has more than 20 years of unique expertise in the development and production of gas diffusion layers for fuel cell applications in the mobility sector and for porous transport layers used in electrolyzers. Freudenberg is currently expanding its production capacity at its Weinheim headquarters by installing additional lines. Further investments are on the verge of implementation.

© Freudenberg Performance Materials
19.09.2022

Freudenberg hosts German National Hydrogen Council meeting

Freudenberg Performance Materials – the Freudenberg Group’s nonwovens specialist – was hosting a meeting of the German National Hydrogen Council at the Freudenberg headquarters in Weinheim, Germany, on September 16. As a leading global supplier of technical textiles, Freudenberg Performance Materials provides fuel cell components for mobility applications and for electrolyzers used to produce CO2-free hydrogen.

Freudenberg Performance Materials – the Freudenberg Group’s nonwovens specialist – was hosting a meeting of the German National Hydrogen Council at the Freudenberg headquarters in Weinheim, Germany, on September 16. As a leading global supplier of technical textiles, Freudenberg Performance Materials provides fuel cell components for mobility applications and for electrolyzers used to produce CO2-free hydrogen.

The German National Hydrogen Council was appointed by the German government and acts as an independent, non-partisan advisory board. The council board currently consists of 25 high-ranking experts in the fields of economy, science and civil society. The objective is to assist and advise the State Secretaries’ Committee on Hydrogen in the further development and implementation of Germany’s National Hydrogen Strategy. Council meetings are hosted by one of the board members to enable the council to deepen its knowledge of the relevant technologies, value chain roles and challenges. Dr. Silke Wagener is a member of the council board, and represents the Freudenberg technology group, giving input on suppliers’ know-how as well as contributing her decades-long expertise in technological solutions for the hydrogen industry.

During a tour of the factory organized for the council board members, Freudenberg Performance Materials explained the development and production of performance-critical gas diffusion layers manufactured from carbon fiber-based nonwovens for fuel cells and porous transport layers for electrolyzers. The tour highlighted the potential for improvements from a supplier’s perspective, such as the need for very timely exchange and collaboration along the value chain. Functioning, unbroken and scalable value chains, in parallel with the development and scaling of hydrogen infrastructure, are key prerequisites for the hydrogen industry to fulfill its vital role in the transformation to climate neutrality.

Gas diffusion layers are one of the main components at the heart of the fuel cell. Their function is to transport gases and liquids in the cells. They have a significant impact on system performance and costs, and are indispensable for the functioning of fuel cells. The same applies for porous transport layers that are the key component of electrolyzers for the CO2-free production of what is called green hydrogen.

Fuel cells in combination with green hydrogen are an important technology for CO2-free mobility, in particular with reference to buses, heavy-duty trucks and trains. Other uses include stationary applications such as stationary power generation or heat generation in buildings or industry.
Apart from mobility, green hydrogen also plays a key role in climate-neutral energy supplies in the industrial sector, particularly in the chemical and steel industries.

Source:

Freudenberg Performance Materials

13.09.2022

New technology purifies wastewater from textile dyeing by using graphene

The substance graphene can become increasingly important as a component in textile catalysts when purifying water from textile dyeing as has been shown in a recently completed doctoral project at the University of Borås.

In his project, Milad Asadi, a new doctor in Textile Technology, has modified conventional yarn by encapsulating iron particles in graphene and developed a multifunctional smart e-textile. The focus was on developing a method for purifying wastewater from textile dyeing. The smart e-textile acts as a catalyst that causes the substance hydrogen peroxide to be formed, which is needed in order to break down pollutants in wastewater.

The project has generated a complete textile reactor for the treatment of wastewater through the so-called electro-Fenton technology, which is mainly used industrially to purify wastewater. The novelty of the technology is to use the properties of both graphene and iron, which is the main catalyst.

The substance graphene can become increasingly important as a component in textile catalysts when purifying water from textile dyeing as has been shown in a recently completed doctoral project at the University of Borås.

In his project, Milad Asadi, a new doctor in Textile Technology, has modified conventional yarn by encapsulating iron particles in graphene and developed a multifunctional smart e-textile. The focus was on developing a method for purifying wastewater from textile dyeing. The smart e-textile acts as a catalyst that causes the substance hydrogen peroxide to be formed, which is needed in order to break down pollutants in wastewater.

The project has generated a complete textile reactor for the treatment of wastewater through the so-called electro-Fenton technology, which is mainly used industrially to purify wastewater. The novelty of the technology is to use the properties of both graphene and iron, which is the main catalyst.

“Previous research has mainly been about the treatment of wastewater by using chemicals to break down the textile dyes. My project is the first where graphene, which is electrically conductive, is used to encapsulate iron. The e-textile can also be used several times, unlike when chemicals are used and which are then rinsed off. The challenge in the project was to scale up the technology so that the treated yarn can be fed into automatic knitting machines”, explained Milad Asadi.

The e-textile catalyst can be reused and hydrogen peroxide is formed internally inside the reactor, which reduces the use of biological catalysts, making the technology more sustainable compared to chemical methods.

Source:

University of Borås - The Swedish School of Textiles

(c) Adient
As a symbol for a sustainable cooperation, Michel Berthelin (Executive Vice President EMEA, 2nd from left) and Henrik Henriksson (CEO H2 Green Steel, 1st from right) planted a ginkgo tree together with their teams in front of the Adient EMEA headquarters in Burscheid, Germany.
01.09.2022

Adient: Cooperation with H2 Green Steel to reduce carbon footprint

Adient, a supplier of seating systems for the automotive industry, has entered into a cooperation with Swedish steelmaker H2 Green Steel (H2GS) to reduce the carbon footprint in its value chain.
 
On 1st September Michel Berthelin, Executive Vice President Adient EMEA, and Henrik Henriksson, CEO of H2 Green Steel, have mutually signed an agreement to supply fossil-free steel with low carbon footprint from 2026 on and subsequently use it in Adient's metal products.

Adient, a supplier of seating systems for the automotive industry, has entered into a cooperation with Swedish steelmaker H2 Green Steel (H2GS) to reduce the carbon footprint in its value chain.
 
On 1st September Michel Berthelin, Executive Vice President Adient EMEA, and Henrik Henriksson, CEO of H2 Green Steel, have mutually signed an agreement to supply fossil-free steel with low carbon footprint from 2026 on and subsequently use it in Adient's metal products.

Michel Berthelin explains the background to the cooperation: “As a company, we are committed to the Science Based Targets Initiative, a collaboration between leading global institutions to set a science-based climate target. We also support the Carbon Disclosure Project, which helps companies and cities to understand and disclose their environmental impacts. The decision to shift parts of the steel volume sourced for our production to a steel with low carbon footprint is part of our sustainability strategy. It is our goal to reduce emissions at our production sites that are caused directly by our own sources or indirectly by our energy suppliers by 75% by 2030. In parallel, we aim to reduce emissions along our supply chains by 35% over the same period. In doing so, Adient actively fosters the industry's transformation towards a more responsible use of natural resources.”

Steel from H2 Green Steel is produced with up to 95% less CO2 emissions compared to conventional steel production. The company achieves this by replacing coal with green hydrogen in production and by the use of electricity from non-fossil sources. In this way, mainly water and heat are produced as waste products.

Source:

Adient

(c) Fraunhofer UMSICHT/Mike Henning
Prof. Christian Doetsch (l.) and Prof. Manfred Renner (r.)
09.08.2022

Fraunhofer UMSICHT: New institute directors

Prof. Manfred Renner and Prof. Christian Doetsch will take joint leadership of the Fraunhofer Institute for Environmental, Safety and Energy Technology UMSICHT from August 2022. As renowned scientists, they have most recently shaped the direction of the institute as heads of the Products division and Energy division respectively, and will now follow in the footsteps of Prof. Eckhard Weidner, who has entered retirement.

This is the first time in its history that Fraunhofer UMSICHT is led by two directors. Both institute directors began their professional careers at the institute and from August they will have a joint hand in its future.

Prof. Manfred Renner and Prof. Christian Doetsch will take joint leadership of the Fraunhofer Institute for Environmental, Safety and Energy Technology UMSICHT from August 2022. As renowned scientists, they have most recently shaped the direction of the institute as heads of the Products division and Energy division respectively, and will now follow in the footsteps of Prof. Eckhard Weidner, who has entered retirement.

This is the first time in its history that Fraunhofer UMSICHT is led by two directors. Both institute directors began their professional careers at the institute and from August they will have a joint hand in its future.

Prof. Manfred Renner holds a doctorate in mechanical engineering, specializing in process engineering and business development. Since 2006, he has held various roles at Fraunhofer UMSICHT, most recently heading up the Products division and overseeing its 126 employees and its budget of 14.8 million euros. He has set international standards through his award-winning research into a free of water tanning leather tanning process that uses compressed carbon dioxide. With the development of innovative aerogel-based insulation materials for building facades, he has made a significant contribution to environmentally friendly, circular applications in the construction industry and initiated a number of industrial projects. One of the notable technological breakthroughs made by his team was the development of a new type of fire-resistant glass, which can withstand even the most extreme heat. This won his development team the Joseph von Fraunhofer Prize in October 2020.

Alongside becoming institute director, Prof. Renner will also take over the leadership of the Fraunhofer Cluster of Excellence Circular Plastics Economy CCPE in August 2022. In this role, he will represent the Fraunhofer-Gesellschaft on a national and international level with regard to the transformation of industry and society to a circular economy. In addition, he will start his professorship in Responsible Process Engineering at the Faculty of Mechanical Engineering of the Ruhr-Universität Bochum. Over the course of his professorship, he will shape the systemic development of the circular economy at a corporate, regional and European level.

Prof. Christian Doetsch has worked in energy research for more than 25 years, spending most of this time at Fraunhofer UMSICHT. As head of the Energy division, he managed a team of around 145 employees and was responsible for a budget of approximately 10.4 million euros. His technological focal points are energy storage, Power-to-X technologies including hydrogen electrolysis and chemical conversion, catalysts, and energy system modeling and optimization. His overarching aim is the integration of renewable energies into a cross-sectoral, resilient energy system.

In 2015, Doetsch co-founded the award-winning start-up Volterion GmbH & Co. KG, which develops redox flow batteries. He attained high visibility on a global scale by redesigning stacks, one of the main components of redox flow batteries, an achievement for which he, his team and Volterion representatives were awarded the Joseph von Fraunhofer Prize in May 2021. The energy expert also acts as deputy spokesperson for the Fraunhofer Energy Alliance and task manager for the energy storage group at the International Energy Agency (IEA). He also co-founded the “Open District Hub e. V.,” an association that promotes the energy transition in the sector by means of energy systems integration.

Since January 2020, he has been Professor of Cross Energy Systems at the Faculty of Mechanical Engineering of the Ruhr-Universität Bochum. In this role, he conducts research into ecological evaluation and resilience of cross-sectoral energy systems.

Source:

Fraunhofer UMSICHT

06.07.2022

DOMO Chemicals und Hynamics: Production of polyamides from low-carbon hydrogen

DOMO Chemicals, a producer of engineered polyamide materials, and Hynamics, a 100% subsidiary of EDF Group specializing in the production of low-carbon hydrogen, have entered into a partnership project with the objective of achieving zero-carbon for 100% of the hydrogen used at the Belle-Étoile industrial site, in Saint-Fons (south of Lyon, France), in the heart of the French Vallée de la Chimie (“Chemistry Valley”).

For the first time in France, the “HyDom” project will enable the installation of an 85-megawatt (MW) hydrogen production plant using the water electrolysis process at the Belle-Étoile site, with a production capacity of 11,000 metric tons of low-carbon hydrogen per year. The plant will be powered by the French low-carbon electric power mix. By 2027, it will supply 100% of the annual production of hexamethylene diamine, a key component used in the production of plastics.

DOMO Chemicals, a producer of engineered polyamide materials, and Hynamics, a 100% subsidiary of EDF Group specializing in the production of low-carbon hydrogen, have entered into a partnership project with the objective of achieving zero-carbon for 100% of the hydrogen used at the Belle-Étoile industrial site, in Saint-Fons (south of Lyon, France), in the heart of the French Vallée de la Chimie (“Chemistry Valley”).

For the first time in France, the “HyDom” project will enable the installation of an 85-megawatt (MW) hydrogen production plant using the water electrolysis process at the Belle-Étoile site, with a production capacity of 11,000 metric tons of low-carbon hydrogen per year. The plant will be powered by the French low-carbon electric power mix. By 2027, it will supply 100% of the annual production of hexamethylene diamine, a key component used in the production of plastics.

The project will eventually prevent the emission of 84 kilotons of carbon dioxide (CO2) each year. Hexamethylene diamine, and ultimately, durable and low-carbon polyamides, will be used in various applications in major industry sectors, such as automotive, electronics, and heating & cooling.
This project is a major step towards the decarbonization of industrial sites that use grey hydrogen (produced from fossil fuels). The location in the Vallée de la Chimie within the vicinity of major transport routes opens up opportunities for the creation of a more complete hydrogen ecosystem.

The first phase of the project will consist of building up and ascertaining technical concepts and integrating the low-carbon hydrogen production plant within the larger production process of hexamethylene diamine.

Considering the high-power scale of the future electrolytic hydrogen production facility, the HyDom project is being developed in close collaboration with RTE (an organization in charge of managing the French power grid), to solve connection issues. As a priority project for the industry's zero-carbon strategy and for the “France 2030” investment plan, HyDom is supported by the French government and has been presented to the European Commission for public funding.

Source:

DOMO Chemicals / Marketing Solutions NV

(c) Borealis
28.06.2022

Borealis introduces portfolio of circular base chemicals

  • The Borvida™ portfolio introduces sustainable base chemicals to Borealis’ range of product offering
  • The range will initially be based on non-food waste biomass, and chemically-recycled waste; in the future it will also draw from atmospheric carbon capture
  • The traceability of the content will be based on Mass Balance, which is ISCC PLUS certified
  • This is the next step in an ambitious sustainability journey, which will see Borealis move away from traditional fossil-based feed

Borealis is strengthening its EverMinds™ circular product offering with Borvida™, a range of sustainable base chemicals.

The Borvida portfolio will offer base chemicals or cracker products (such as ethylene, propylene, butene and phenol) with ISCC Plus-certified sustainable content from Borealis sites in Finland, Sweden and Belgium. The move is part of Borealis’ broader commitment to a Future-Positive Revolution, in which the unrivalled benefits of base chemicals and polymers can be enjoyed at minimal impact to the planet.   

  • The Borvida™ portfolio introduces sustainable base chemicals to Borealis’ range of product offering
  • The range will initially be based on non-food waste biomass, and chemically-recycled waste; in the future it will also draw from atmospheric carbon capture
  • The traceability of the content will be based on Mass Balance, which is ISCC PLUS certified
  • This is the next step in an ambitious sustainability journey, which will see Borealis move away from traditional fossil-based feed

Borealis is strengthening its EverMinds™ circular product offering with Borvida™, a range of sustainable base chemicals.

The Borvida portfolio will offer base chemicals or cracker products (such as ethylene, propylene, butene and phenol) with ISCC Plus-certified sustainable content from Borealis sites in Finland, Sweden and Belgium. The move is part of Borealis’ broader commitment to a Future-Positive Revolution, in which the unrivalled benefits of base chemicals and polymers can be enjoyed at minimal impact to the planet.   

The portfolio will initially comprise Borvida B, from non-food waste biomass, and Borvida C, from chemically-recycled waste. In the future, the range will evolve to include Borvida A, sourced from atmospheric carbon capture. Borvida is complementary and is the building block to Bornewables™, a portfolio of polyolefins based on renewably-sourced second generation feedstocks, and Borcycle™, which offers circular polyolefins produced from mechanically- and chemically-recycled plastic waste.

Borealis produces a wide range of base chemicals for use in numerous industries based on various feedstock, such as naphtha, butane, propane and ethane. Through its olefin units (steam cracker and propane dehydrogenation), it converts these into the building blocks of the chemical industry: ethylene, propylene and C4 hydrocarbons (butylenes, ethyl tertiary-butyl ether (ETBE) and butadiene), and C5-6 hydrocarbons (pygas, phenol) among others.

The basis of the Borvida portfolio is Mass Balance, a Chain of Custody model that enables sustainable content to be tracked, traced, and verified through the entire value chain, offering sustainability-assured products from feedstock to end product. Using this model, circular alternatives can be offered in a cost-effective and environmentally-conscious way, which can be scaled up quickly without compromising on quality or efficiency.

Borvida can be used for a wide range of different polymer and chemical applications, also beyond polyolefins (PO). Non-PO polymers, such as polycarbonates, acrylonitrile butadiene styrene (ABS), super absorbant polymer (SAP) and other chemicals, are utilised for various end applications including coatings, plasticizers, adhesives, automotive, electronics, lubricants, detergents, appliances and sports equipment.

Together with key strategic partners, including Neste and Covestro, Borealis strives to provide a long-term solution in order to allow value-chain partners to meet their sustainability goals. Borvida will enable our customers to increase the sustainability of their products, keeping them ahead of forthcoming legislative changes, and meeting their customers’ demands for climate-conscious products.

Introduced on a smaller scale in early 2020, early renewable base chemicals customers include Covestro. “The use of alternative sustainable raw materials is one important pillar of our strategic ambition to become fully circular”, comments Frank Dörner, Managing Director Covestro Procurement Services GmbH & Co. KG. “The new product line is a good example for joint solutions, another strategic pillar, in order to establish new and reliable supply chains creating benefits for our customers.”

Source:

Borealis

27.06.2022

Indorama Ventures enters world-first China license agreement

Indorama Ventures Public Company Limited (IVL), a global sustainable chemical company, has signed a license agreement with Shandong Binhua New Material Co., Ltd. (Binhua), a subsidiary of Befar Group, a leading petroleum and chemical enterprise in China, to build, own and operate a propylene oxide (PO), t-Butanol (TBA) and t-Butyl methyl ether (MTBE) co-production unit.

Featuring the world’s only MTBE ‘single-step’ reaction technology, IVL’s proprietary innovation, the project is part of the ‘C3 and C4’ comprehensive utilization project in Shandong, China. It is one of the largest in the province, covering an area of over one million square meters.

Under the contract, IVL will provide a design package, technology, operational know-how and training to enable the construction and operation of a PO co-production with MTBE and TBA units for Binhua. The plant is part of a larger complex comprising propane dehydrogenation to propylene, butane isomerization, synthetic ammonia, and other installations.

Indorama Ventures Public Company Limited (IVL), a global sustainable chemical company, has signed a license agreement with Shandong Binhua New Material Co., Ltd. (Binhua), a subsidiary of Befar Group, a leading petroleum and chemical enterprise in China, to build, own and operate a propylene oxide (PO), t-Butanol (TBA) and t-Butyl methyl ether (MTBE) co-production unit.

Featuring the world’s only MTBE ‘single-step’ reaction technology, IVL’s proprietary innovation, the project is part of the ‘C3 and C4’ comprehensive utilization project in Shandong, China. It is one of the largest in the province, covering an area of over one million square meters.

Under the contract, IVL will provide a design package, technology, operational know-how and training to enable the construction and operation of a PO co-production with MTBE and TBA units for Binhua. The plant is part of a larger complex comprising propane dehydrogenation to propylene, butane isomerization, synthetic ammonia, and other installations.

More information:
Indorama
Source:

Indorama Ventures Public Company Limited 

12.05.2022

JEC World 2022 shows the dynamism of the composites industry

The global composites community reunited at JEC WORLD 2022 on May 3rd to 5th for three days of innovation, networking and knowledge sharing. The industry was excited to reconnect in Paris after three years and the show exceeded all expectations in terms of product launches, content, business activity and attendance. Overall, the event welcomed 32,000+ professional visits, in Paris and online, from more than 115 countries and featured 1,201 exhibitors and 26 pavilions, whilst the JEC World Connect platform offered an additional way to explore the show this year.

The global composites community reunited at JEC WORLD 2022 on May 3rd to 5th for three days of innovation, networking and knowledge sharing. The industry was excited to reconnect in Paris after three years and the show exceeded all expectations in terms of product launches, content, business activity and attendance. Overall, the event welcomed 32,000+ professional visits, in Paris and online, from more than 115 countries and featured 1,201 exhibitors and 26 pavilions, whilst the JEC World Connect platform offered an additional way to explore the show this year.

While fewer Asian participants were able to join the show this year due to travel complexities, the attendance of a high level of decision makers from 117 countries and all key players along the value chain resulted in a dynamic environment for networking and business. As a consequence, companies were keen to confirm their presence next year; by the time the show closed its doors, 50% of JEC World 2023 exhibition space had already been booked.  Exhibitors and attendees have expressed very positive feedback about the quality of the exhibition and such a successful come-back of JEC World as the pinnacle event of the industry.

Innovations at JEC World
With more than 500 product launches during this year’s show, JEC World remains a popular venue to introduce new products to the global market.

The JEC Composites Innovation Awards celebrated 10 collaborative projects, reflecting the dynamism and the resilience of our industry, and two Innovation Planets displayed 80 impressive applications.

Celebrating its five-year anniversary, the JEC Composites Startup Booster competition is now established to discover startups in the advanced composites sector.

JEC World contributing to a more sustainable world
JEC World’s conference program shone a light on this year’s theme and most impactful topic: Composites for a Sustainable World. Sustainability continues to rise as a key growth driver for the composites industry, enabling diverse application sectors to achieve ambitious sustainability goals, from energy and transportation, to building and infrastructure, and so many more. JEC World highlighted how the growing application of composites will open up exciting new horizons for human activities, improving people’s lives and leading to a better, more sustainable world.

International community
Three Country on Stage presentations showcased the structure and strengths of the composites industries of South Korea, the Netherlands and the United States. The program featured keynote presentations and business cases which demonstrate the countries’ composites expertise  in hydrogen, in sustainable excellence, and innovation in building and mobility, respectively.

Ministers, ambassadors and official representatives from 16 countries also visited the show as part of dedicated official delegation tours from the United States, Turkey, Hungary, Taiwan, Portugal, Croatia, the Netherlands, the United Kingdom, North Macedonia, Germany, Slovakia, Luxembourg, Belgium, Sweden and Spain.

Thus, JEC World was the opportunity for government representatives to meet the leading composites actors of their respective regions or markets and show their support. Official inaugurations also took place on the Dutch, American and British pavilions.

Bohrgerät Schiefergas Bohrhaken Photo: Pixabay
26.04.2022

Natural gas embargo against Russian Federation would mean the end for man-made fibre producers

With its current position paper, the Industrievereinigung Chemiefaser e.V. takes a stand on the intense discussions about an embargo against Russian natural gas supplies. The association believes that Germany's economic and global political future can only be secured with a strong industrial base and therefore, weighing up all positions and influencing factors and assessing the consequences for labour and the market economy, cannot support a short-term natural gas embargo on Russia.

An interruption of the continuous supply of natural gas would result in immense losses for the chemical fibre companies, which could even lead to the destruction of the industry in Germany. The losses are made up of technical damage caused by an uncoordinated shutdown of plants on the one hand and market-related consequential damage caused by lost production and a lack of product sales on the other.

With its current position paper, the Industrievereinigung Chemiefaser e.V. takes a stand on the intense discussions about an embargo against Russian natural gas supplies. The association believes that Germany's economic and global political future can only be secured with a strong industrial base and therefore, weighing up all positions and influencing factors and assessing the consequences for labour and the market economy, cannot support a short-term natural gas embargo on Russia.

An interruption of the continuous supply of natural gas would result in immense losses for the chemical fibre companies, which could even lead to the destruction of the industry in Germany. The losses are made up of technical damage caused by an uncoordinated shutdown of plants on the one hand and market-related consequential damage caused by lost production and a lack of product sales on the other.

Depending on the location and size of the plants, a short-term outage due to a lack of natural gas would result in average losses of EUR 5 million/plant. In addition, an ongoing daily loss would have to be expected which could be in the order of e.g. 250 000 EUR/day/plant, depending on the location. Furthermore, restarting the plants is questionable if supply chains could no longer be serviced and customers globally look for other suppliers in the meantime. Thus, entire sites would be at risk. With China's global market share in man-made fiber production already exceeding 70 %, a scenario is more than realistic that China will also take over these supply chains, thus leading to an even greater dependence on China.

The vast majority of power plants used for the production of man-made fibers, especially the highly efficient combined gas-and-steam power plants based on the principle of cogeneration with efficiencies of 90 %, are designed exclusively for the use of natural gas. Quite often, there are no technical facilities for operating gas turbines or steam boilers with fuels other than natural gas. Only in exceptional cases could a switch be made to mineral oil. However, even in these cases, the necessary stockpiling of mineral oil is designed only for a short-term failure of the gas burners. A change to base-load supply with mineral oil could take a time window of between 3 and 56 months, depending on the type of plant and taking into account licensing requirements. The use of hydrogen as an energy source is only possible in the very long term. In the few cases where natural gas can be substituted, investment costs of EUR 250 million/plant can be incurred, depending on the emission level of the converted plant.

A natural gas embargo imposed by the European Union on the Russian Federation would not only mean the cessation of production and the end for man-made fiber producers, but also for other industries such as basic chemicals, paper, metal production and glass and ceramics manufacturing, as well as their related sectors. As the German economic institute Institut der Deutschen Wirtschaft Köln e. V. (IW Köln) concluded in its summary report 40/2022 of April 2022: "No one can accurately predict what future these businesses would then still have in Germany. That would be an unprecedented development."

Source:

Industrievereinigung Chemiefaser e.V.

24.02.2022

Renewable Carbon as a Guiding Principle for Sustainable Carbon Cycles

  • Renewable Carbon Initiative (RCI) published a strategy paper on the defossilisation of the chemical and material industry with eleven policy recommendations

The Renewable Carbon Initiative, an interest group of more than 30 companies from the wide field of the chemical and material value chains, was founded in 2020 to collaboratively enable the chemical and material industries to tackle the challenges in meeting the climate goals set by the European Union and the sustainability expectations held by societies around the globe.

RCI addresses the core of the climate problem: 72% of anthropogenic climate change is caused directly by extracted fossil carbon from the ground. In order to rapidly mitigate climate change and achieve our global ambition for greenhouse gas emission reductions, the inflow of further fossil carbon from the ground into our system must be reduced as quickly as possible and in large scale.

  • Renewable Carbon Initiative (RCI) published a strategy paper on the defossilisation of the chemical and material industry with eleven policy recommendations

The Renewable Carbon Initiative, an interest group of more than 30 companies from the wide field of the chemical and material value chains, was founded in 2020 to collaboratively enable the chemical and material industries to tackle the challenges in meeting the climate goals set by the European Union and the sustainability expectations held by societies around the globe.

RCI addresses the core of the climate problem: 72% of anthropogenic climate change is caused directly by extracted fossil carbon from the ground. In order to rapidly mitigate climate change and achieve our global ambition for greenhouse gas emission reductions, the inflow of further fossil carbon from the ground into our system must be reduced as quickly as possible and in large scale.

In the energy and transport sector, this means a vigorous and fast expansion of renewable energies, hydrogen and electromobility, the so-called decarbonisation of these sectors. The EU has already started pushing an ambitious agenda in this space and will continue to do so, for instance with the recently released ‘Fit for 55’ package.

However, these policies have so far largely ignored other industries that extract and use fossil carbon. The chemical and material industries have a high demand for carbon and are essentially only possible with carbon-based feedstocks, as most of their products cannot do without carbon. Unlike energy, these sectors cannot be “decarbonised”, as molecules will always need carbon. The equivalent to decarbonisation via renewable energy in the energy sector is the transition to renewable carbon in the chemical and derived materials industries. Both strategies avoid bringing additional fossil carbon from the ground into the cycle and can be summarised under the term “defossilisation”.

To decouple chemistry from fossil carbon, the key question is which non-fossil carbon sources can be used in the future. Rapid developments in biosciences and chemistry have unlocked novel, renewable and increasingly affordable sources of carbon, which provide us with alternative solutions for a more sustainable chemicals and materials sector. These alternative sources are: biomass, utilisation of CO2 and recycling. They are combined under the term “renewable carbon”. When used as a guiding principle, renewable carbon provides a clear goal to work towards with sufficient room to manoeuvre for the whole sector. It enables the industry to think out of the box of established boundaries and stop the influx of additional fossil carbon from the ground.

The systematic change to renewable carbon will not only require significant efforts from industry, but must be supported by policy measures, technology developments and major investments. In order to implement a rapid and high-volume transition away from fossil carbon, and to demonstrate its impact, a supportive policy framework is essential. The emphasis should be put on sourcing carbon responsibly and in a manner that does not adversely impact the wider planetary boundaries nor undermines societal foundations. An overarching carbon management strategy is required that also takes specific regional and application-related features into account, to identify the most sustainable carbon source from the renewable carbon family. This will allow for a proper organisation of the complex transition from today’s fossil carbon from the ground to renewable energy and to renewable carbon across all industrial sectors.

RCI has developed eleven concrete policy recommendations on renewable carbon, carbon management, support for the transformation of the existing chemical infrastructure and the transformation of biofuel plants into chemical suppliers. The policy paper “Renewable Carbon as a Guiding Principle for Sustainable Carbon Cycles” is freely available for download in both a short version and a long version.


Link for Download: https://renewable-carbon-initiative.com/media/library/

Source:

Renewable Carbon Initiative (RCI)

01.02.2022

EURATEX: High energy costs undermine crucial transformation of the textile and clothing industry

The current energy crisis is impacting on the competitiveness of the European textile and clothing industry. Because there are limited alternatives to the use of gas in different parts of the production process, production costs increase sharply. EURATEX asks the European Commission and Member States to urgently support the industry to avoid company closures. At the same time, we need a long term vision to move towards climate neutrality, while keeping the T&C industry internationally competitive.

EURATEX presented ten key requirements to Kadri Simson, European Commissioner for Energy, to develop such a vision:

The current energy crisis is impacting on the competitiveness of the European textile and clothing industry. Because there are limited alternatives to the use of gas in different parts of the production process, production costs increase sharply. EURATEX asks the European Commission and Member States to urgently support the industry to avoid company closures. At the same time, we need a long term vision to move towards climate neutrality, while keeping the T&C industry internationally competitive.

EURATEX presented ten key requirements to Kadri Simson, European Commissioner for Energy, to develop such a vision:

  1. The apparel and textile industry needs a safe supply with sufficient green energy (electricity and gas) at internationally competitive prices.
  2. The transformation of industry requires access to very significant amounts of renewable energy at competitive costs. Additional investments in infrastructure will also be needed to guarantee access to new renewable energy supplies.
  3. Until a global (or at least G 20 level) carbon price or other means for a global level playing field in climate protection are implemented, competitive prices for green energy must be granted at European or national levels (e.g. CCfDs, reduction on levies, targeted subsidies).
  4. As the European textile and clothing sector faces global competition mainly form countries/regions with less stringent climate ambitions, it is of utmost importance that the European textile and clothing companies are prevented form direct and indirect carbon leakage.
  5. EU-policy should support solutions, e.g. through targeted subsidies (for hydrogen, energy grids, R&D, technology roadmap studies etc.).
  6. A dedicated approach for SMEs might be appropriate as SMEs do not have the skills/know-how to further improve their energy efficiency and/or becoming carbon neutral.
  7. CAPEX and OPEX support will be necessary for breakthrough technologies, like hydrogen.
  8. The Fit-for-55-Package must support the European Textile and Clothing industry in decarbonization and carbon neutrality. The EU must therefore advocate a global level playing field more than before. The primary goal must be to establish an internationally uniform, binding CO2 pricing, preferably in the form of a standard at G-7 / G-20 level.
  9. EU-policy must not hinder solutions, e.g. we need reasonable state aid rules (compensating the gap between national energy or climate levies and a globally competitive energy price should not be seen as a subsidy).
  10. The European Textile and Clothing industry has made use of economically viable potentials to continuously improve energy efficiency over many years and decades. The obligation to implement further measures must be taken considering investment cycles that are in line with practice. Attention must be paid to the proportionality of costs without weakening the competitive position in the EU internal market or with competitors outside the EU.

Please see the attached position paper for more information.

Source:

EURATEX

(c) Composites Evolution
19.01.2022

Composites Evolution launches new Evopreg® thermoplastic tapes

  • Evopreg® range expanded with unidirectional fibre-reinforced thermoplastic tapes

Composites Evolution, a developer, manufacturer and supplier of prepregs for the production of lightweight structures from composite materials, has announced the launch of a new range of unidirectional thermoplastic tapes, to sit alongside its existing line-up of Evopreg® prepregs. The first product families being launched are Evopreg® PA polyamide tapes, and Evopreg® PP polypropylene tapes, with further product lines expected as new customer requirements emerge.

Thermoplastic tapes, also known as thermoplastic prepregs, can be used in a wide variety of markets and applications, including flexible pipes for oil & gas and water transportation, pressure vessels (for example; hydrogen storage tanks and compressed natural gas tanks), and for providing local reinforcement to pre-formed components.

  • Evopreg® range expanded with unidirectional fibre-reinforced thermoplastic tapes

Composites Evolution, a developer, manufacturer and supplier of prepregs for the production of lightweight structures from composite materials, has announced the launch of a new range of unidirectional thermoplastic tapes, to sit alongside its existing line-up of Evopreg® prepregs. The first product families being launched are Evopreg® PA polyamide tapes, and Evopreg® PP polypropylene tapes, with further product lines expected as new customer requirements emerge.

Thermoplastic tapes, also known as thermoplastic prepregs, can be used in a wide variety of markets and applications, including flexible pipes for oil & gas and water transportation, pressure vessels (for example; hydrogen storage tanks and compressed natural gas tanks), and for providing local reinforcement to pre-formed components.

Marketing Director, Ben Hargreaves, explains further: “Our state-of-the-art manufacturing line gives us the capability to produce tapes on an industrial scale, using a variety of combinations of fibre and polymer. This is complemented by a pilot-scale line that allows us to carry out development trials, or manufacture small quantities of tape if required.”

“Because they can be repeatedly re-formed (via the application of heat and pressure), Evopreg® thermoplastic tapes are also very well-suited to multi-stage processing, meaning they are an excellent choice for producing hybrid structures, inserts or over-moulded components. In addition, this ability to be repeatedly re-formed opens the door to much easier recycling than is currently possible with thermoset composites.”

 

Source:

Composites Evolution

(c) BioRECO2ver Project
19.01.2022

nova-Institute: BioRECO2VER project - Conversion of CO2 into chemical building blocks

CO2 as renewable carbon source
Carbon is the main element in numerous materials used in industrial processes and in our daily lives. It is currently mostly provided from fossil sources. But what if carbon could be used directly from CO2 emissions? Biotechnology shows particularly great potential for the eco-effective conversion of climate-damaging CO2 emissions into valuable basic chemicals. A consortium of 12 partners investigated this pathway in the EU-funded BioRECO2VER project, examining the conversion of CO2 emissions from refineries and the cement industry into the chemical building blocks isobutene (C4H8) and lactate (C2H6O3).

CO2 as renewable carbon source
Carbon is the main element in numerous materials used in industrial processes and in our daily lives. It is currently mostly provided from fossil sources. But what if carbon could be used directly from CO2 emissions? Biotechnology shows particularly great potential for the eco-effective conversion of climate-damaging CO2 emissions into valuable basic chemicals. A consortium of 12 partners investigated this pathway in the EU-funded BioRECO2VER project, examining the conversion of CO2 emissions from refineries and the cement industry into the chemical building blocks isobutene (C4H8) and lactate (C2H6O3).

Innovative chemo-enzymatic concept for CO2 Capture
Project partner Luleå University of Technology (LTU) focused on the first process step of capturing and concentrating CO2 from industrial point sources. Their team developed a hybrid chemo-enzymatic process consisting of a novel solvent blend and an ultrastable carbonic anhydrase (CA) enzyme. The solvent blend included an amino acid ionic liquid and a tertiary amine and displayed a good compromise between enzyme compatibility, absorption rate, capacity and desorption potential. In addition, LTU generated ultrastable enzyme mutants that showed 50% increased resistance to selected flue gas inhibitors compared to the original CA. This 3-component CO2 capture process was scaled up in a pilot rig, and the set-up further used for real off gas pre-treatment in the project.

Two unique pilots for biotechnological CO2 Conversion/Utilization
The biotechnological conversion of (captured) CO2 and the co-substrate hydrogen by microorganisms poses technical and economic challenges because it takes place in the liquid phase and the substrates are gases which are poorly soluble. The BioRECO2VER project investigated two approaches to address this: fermentation under elevated pressure and bio-electrochemistry with in situ production of hydrogen.

Pressurized fermenter
Project coordinator VITO designed a flexible and multifunctional high-pressure fermenter, customized for research activities with advanced online sensors, monitoring and control, and also including a membrane filtration unit to achieve high concentrations of the microbial biocatalysts. The set-up was broadly tested in the BioRECO2VER project both with pure CO2 and CO2-rich off-gases but can also be used for investigations involving other poorly soluble gases, such as methane, oxygen, or synthesis gas. Pressures up to 10 bar can be applied.

First solely CO2-based bio-electrochemical platform
University of Girona designed and tested a bio-electrochemical platform. The key differentiators of the pilot plant are:

  • Two parallel lines to test engineered strains and bio-electrochemical systems
  • Fully automated pilot plant capable to control key operational parameters (pCO2, pO2, pH2, pH, Temperature) to intensify the process performance
  • Solid-liquid separation unit (membrane) to recover the planktonic cells and return them into the bio-electrochemical systems.

This unique infrastructure will be used beyond the project to support further research and development activities in the broad area of CO2 capture and conversion.

Source:

nova-Institut GmbH