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25.10.2023

Carbios: Appointment of Bénédicte Garbil as Senior Vice President of Corporate Affairs and Sustainability

Carbios announced the strengthening of its leadership team with the appointment of Bénédicte Garbil as Senior Vice President of Corporate Affairs and Sustainability. Bénédicte Garbil oversees three strategic areas: Public Affairs, Corporate Affairs, and Sustainability. In her Corporate Affairs role, she supervises Communication, Regulatory, Project Management, and Innovation Funding functions. In her Sustainability role, she oversees CSR, QHSE, and LCA functions. Bénédicte Garbil also joins the Group’s Executive Committee.

Carbios announced the strengthening of its leadership team with the appointment of Bénédicte Garbil as Senior Vice President of Corporate Affairs and Sustainability. Bénédicte Garbil oversees three strategic areas: Public Affairs, Corporate Affairs, and Sustainability. In her Corporate Affairs role, she supervises Communication, Regulatory, Project Management, and Innovation Funding functions. In her Sustainability role, she oversees CSR, QHSE, and LCA functions. Bénédicte Garbil also joins the Group’s Executive Committee.

Bénédicte Garbil started as a public affairs advisor at the French Federation of Healthcare Industries before becoming Director of Public Affairs at a pharmaceutical laboratory. In 2013, she joined the public sector, first working at the General Directorate of Enterprises (DGE) as Head of the Health, Biotechnology, and Agri-food Industries Bureau, and then at the General Investment Commissioner’s Office (CGI) from 2014 to 2017 as Deputy Director of Health and Biotechnology. Her experience allowed her to gain expertise in public policies and funding innovative projects, contributing to the creation of public funding mechanisms supported by the French Program of Investments for the Future (PIA). After her public service, she led Edwards Lifesciences in France for 4 years, then founded a consulting company accompanying biotechnology and healthcare companies in their development, from valuation to market access, including industrial development in France. A graduate of Sciences Po Lille, she holds a master’s degree in health law and a university degree in pharmacoeconomics.

More information:
Carbios management
Source:

Carbios

02.06.2023

Carbios receives funding for PET biorecycling plant and R&D activities

Carbios will receive grants totaling €54 million from French State via France 2030 and Grand-Est Region to finance construction of world’s first PET biorecycling plant and accelerate R&D activities

Carbios announces that its project has been selected by the French State for funding of €30 million from the French State as part of the investment plan France 2030, and €12.5 million from the Grand-Est Region.  The implementation of this funding is conditional to the European Commission’s approval of the corresponding state aid scheme, followed by the conclusion of national aid agreements. As part of the national call for projects on “Plastics Recycling” operated by ADEME[1], Carbios’ project to finalize the industrialization of its unique PET biorecycling process has been selected. The reference plant in Longlaville in the Grand-Est region will be the world’s first PET biorecycling plant and is due for commissioning in 2025. This plant will make it possible to relocate to France the production of the two basic components of PET, PTA and MEG[2], both derived from the Carbios process.

Carbios will receive grants totaling €54 million from French State via France 2030 and Grand-Est Region to finance construction of world’s first PET biorecycling plant and accelerate R&D activities

Carbios announces that its project has been selected by the French State for funding of €30 million from the French State as part of the investment plan France 2030, and €12.5 million from the Grand-Est Region.  The implementation of this funding is conditional to the European Commission’s approval of the corresponding state aid scheme, followed by the conclusion of national aid agreements. As part of the national call for projects on “Plastics Recycling” operated by ADEME[1], Carbios’ project to finalize the industrialization of its unique PET biorecycling process has been selected. The reference plant in Longlaville in the Grand-Est region will be the world’s first PET biorecycling plant and is due for commissioning in 2025. This plant will make it possible to relocate to France the production of the two basic components of PET, PTA and MEG[2], both derived from the Carbios process.

Carbios also announces that it has been granted total funding of €11.4 million from the French State as part of France 2030, of which €8.2 million directly for Carbios (€5 million in repayable advances) and €3.2 million for its academic partners INRAE[3], INSA[4] and CNRS[5] via the TWB[6] and TBI[7] joint service and research units. This funding will enable to continue its research into the optimization and continuous improvement of Carbios’ enzymatic technologies.

The plant will secure the sales of the first volumes of recycled PET produced with Carbios’ technology, and to offer its partners recycled PET of the same quality as virgin PET. Once the necessary permits have been obtained, which should be granted by the end of 2023, in line with the announced start of construction before the end of the year, the plant is scheduled to be commissioned in 2025. This will be followed by a period of ramp-up to full capacity. The plant will have a nominal processing capacity of 50,000 tonnes of PET waste per year, equivalent to 2 billion bottles or 2.5 billion food trays.

Selection for funding by the French State through France 2030 and the Grand-Est Region complements the recent announcement of an exclusive, long-term partnership with Novozymes[8], a leader in enzyme production, one of the main aims is to ensure the supply of enzymes to Carbios’ Longlaville plant and future licensed plants. In addition, Carbios recently secured a first supply source for its future plant by winning part of the CITEO tender for the biorecycling of multilayer trays[9].


[1] The French Agency for Ecological Transition
[2] PTA = purified terephthalic acid; MEG = monoethylene glycol
[3] French National Research Institute for Agriculture, Food and the Environment
[4] French National Institute of Applied Sciences
[5] French National Center for Scientific Research
[6] Toulouse White Biotechnology – UMS INRAE 1337 / UAR CNRS 3582
[7] Toulouse Biotechnology Institute – UMR INSA/CNRS 5504 / UMR INSA/INRAE 792
[8] Cf. press release dated 12 January 2023
[9] Cf. press release published by Citeo dated 26 April 2023

More information:
Carbios biorecycling plastics France
Source:

Carbios

(c) Carbios
05.05.2023

Carbios accelerates enzyme optimization

  • Carbios has developed an ultra-high throughput microfluidic screening of PET-depolymerizing enzymes in partnership with the Paul Pascal Research Center[1], a joint research unit of the CNRS[2] and the University of Bordeaux
  • Microfluidics enables millions of enzymes to be screened in a day, compared with a few thousand a week with conventional technologies
  • Future polymers of interest will benefit from this acceleration of the R&D phase, enabling Carbios to develop its portfolio of innovations on different types of plastic more rapidly

Carbios has accelerated its enzyme screening process with a microfluidic technology developed in partnership with the Paul Pascal Research Centre (a joint research unit of the CNRS and the University of Bordeaux, which specializes in microfluidics). This technology enables the screening of millions of enzymes in just one day, speeding up the process to optimize enzymes breaking down PET.

  • Carbios has developed an ultra-high throughput microfluidic screening of PET-depolymerizing enzymes in partnership with the Paul Pascal Research Center[1], a joint research unit of the CNRS[2] and the University of Bordeaux
  • Microfluidics enables millions of enzymes to be screened in a day, compared with a few thousand a week with conventional technologies
  • Future polymers of interest will benefit from this acceleration of the R&D phase, enabling Carbios to develop its portfolio of innovations on different types of plastic more rapidly

Carbios has accelerated its enzyme screening process with a microfluidic technology developed in partnership with the Paul Pascal Research Centre (a joint research unit of the CNRS and the University of Bordeaux, which specializes in microfluidics). This technology enables the screening of millions of enzymes in just one day, speeding up the process to optimize enzymes breaking down PET. This competitive advantage enables Carbios to reduce the time between the R&D phase and the production of its proprietary enzymes, and therefore to develop concrete solutions to plastic pollution even faster.

Microfluidics
Microfluidics allows the production of devices handling very small amounts of liquid. Each droplet generated can be considered as an independent microreactor having a volume in the picoliter range (10-12 liters) and containing a particular enzyme whose PET depolymerization activity will be screened. These droplets move through analysis units the size of a microchip allowing ultra-high throughput screening of 150 enzymes per second.

Previously, conventional robotic systems allowed screening in microplate format with a volume in the milliliter range (10-3 liters) and with rates of around one enzyme per minute.

The use of microfluidics to screen for more efficient or new enzymes will become widely adopted in the coming years, therefore accelerating the development of bioprocessing. Currently used by Carbios for the development of its PET depolymerization process, microfluidics should be used to accelerate the development of new enzymes for other types of plastic such as polyamide.

Carbios researchers specialized in microfluidics
Microfluidic processes require special expertise. At present, two researchers at Carbios are dedicated to microfluidics and based in the cooperative laboratory with TBI[3] hosted by INSA[4] Toulouse.  Alexandra Tauzin, Researcher in Enzyme Engineering and Microfluidics, and Alexandre Gilles, Engineer specialized in robotics, work in partnership with the Paul Pascal Research Center.

[1] Centre de Recherche Paul Pascal (CRPP)
[2] Centre National de la Recherche Scientifique (CNRS) = National Center for Scientific Research
[3] Toulouse Biotechnology Institute
[4] National Institute of Applied Sciences

More information:
Carbios plastics Enzyme polymers
Source:

Carbios

24.03.2023

Carbios: Scientific publication on enzymatic degradation of plastics

Carbios announces the publication of an article entitled “Enzymes’ power for plastics degradation” in Chemical Reviews. The article is a comprehensive and critical review of research published to date on the enzymatic degradation of all types of plastics (PET, PLA, polyolefins, polyurethanes, polyamides) and includes almost 700 references. Co-authored by biotechnology researchers from Carbios and its academic partner Toulouse Biotechnology Institute (TBI), as well as two eminent professors in polymer science from the University of Bordeaux, the work brings together expertise in the fields of enzymology, polymer science and industry in order to accelerate the transition to a circular economy for plastic.

Beyond the comprehensive bibliographical study, the authors analyzed the data to discuss the scope, limitations, challenges and opportunities of enzymatic plastic recycling with a view to developing innovations and industrial processes. The article’s standpoint and added value with regard to issues surrounding plastic pollution is its critical view on technology transfer and industrial scalability.

Carbios announces the publication of an article entitled “Enzymes’ power for plastics degradation” in Chemical Reviews. The article is a comprehensive and critical review of research published to date on the enzymatic degradation of all types of plastics (PET, PLA, polyolefins, polyurethanes, polyamides) and includes almost 700 references. Co-authored by biotechnology researchers from Carbios and its academic partner Toulouse Biotechnology Institute (TBI), as well as two eminent professors in polymer science from the University of Bordeaux, the work brings together expertise in the fields of enzymology, polymer science and industry in order to accelerate the transition to a circular economy for plastic.

Beyond the comprehensive bibliographical study, the authors analyzed the data to discuss the scope, limitations, challenges and opportunities of enzymatic plastic recycling with a view to developing innovations and industrial processes. The article’s standpoint and added value with regard to issues surrounding plastic pollution is its critical view on technology transfer and industrial scalability.

To read the article in Chemical Reviews, click here.

Source:

Carbios

(c) Carbios
20.10.2022

Carbios publishes results of consumer research study about plastic circularity

  • Carbios’ biorecycling and biodegradation technologies internationally recognized by consumers as promising answers to their top environmental concerns
  • Carbios’ innovations considered one of the best for solving recycling effectively and achieving a real plastic circularity
  • Consumer research including qualitative and quantitative fields was conducted between March and August 2022. The research institute, Strategic Research, conducted 6000 interviews in Europe and USA

Carbios’ biorecycling and biodegradation technologies acclaimed by consumers
During the first research field study, respondents were exposed to Carbios’ biorecycling process; a new enzyme-based biotechnology that enables biological recycling of all types of PET plastic waste (including bottles, packaging and textiles), and pushes the boundaries of recycling in terms of the number of cycles.

  • Carbios’ biorecycling and biodegradation technologies internationally recognized by consumers as promising answers to their top environmental concerns
  • Carbios’ innovations considered one of the best for solving recycling effectively and achieving a real plastic circularity
  • Consumer research including qualitative and quantitative fields was conducted between March and August 2022. The research institute, Strategic Research, conducted 6000 interviews in Europe and USA

Carbios’ biorecycling and biodegradation technologies acclaimed by consumers
During the first research field study, respondents were exposed to Carbios’ biorecycling process; a new enzyme-based biotechnology that enables biological recycling of all types of PET plastic waste (including bottles, packaging and textiles), and pushes the boundaries of recycling in terms of the number of cycles.

The research results demonstrated that European and US respondents find Carbios’ biorecycling technology more unique and innovative than traditional PET recycling (i.e. thermo-mechanical recycling), as well as more relevant in its ability to address their concerns and challenges regarding recycling.

In the second research study, conducted in the US, respondents were also exposed to Carbios’ biodegradation technology: an innovative enzymatic solution by which an enzyme is incorporated into plastics during the production process of bio-sourced PLA plastics (corn, sugar cane). This approach makes the material made from plants 100% compostable at ambient temperatures and degradable like plants with the built-in enzyme biologically breaking the bioplastic down in less than eight weeks without microplastics or toxic residues; creating a fully organic circularity.

Similarly to Carbios’ biorecycling technology, Carbios’ PLA biodegradation innovation caught US respondents’ attention with 64% overall liking it. Additionally, 93% of the respondents sampled described the concept as innovative, unique, easy to understand (49%), and believable (43%). Up to 82% of the most environmentally engaged respondents declared they would definitely buy more products made with Carbios’ fully circular biodegradable bioplastic.

Consumers: No other choice but to make plastic fully circular
The research says 99% of the respondents consider it important to protect the environment, while plastic pollution is now ranked the third most-concerning environmental issues after climate change and ocean pollution.

This awareness brings most of these consumers to be environmentally active when it comes to purchasing goods and sorting. For the US respondents, eco-friendly packaging comes in the fourth place in terms of purchase drivers for packaged goods and 65% of them declare sorting plastic from general waste on a regular basis, which makes plastic the most sorted type of waste.

Nevertheless, for a vast majority of the respondents across geographies, even if they would like to reduce their plastic consumption most of the time there is no suitable alternative that is as convenient, light, and cost-efficient as plastics. Hence in an ideal world, consumers would like all plastic waste in landfills and oceans to be collected, cleaned, reused and recycled.

More information:
Carbios study circularity plastics
Source:

Carbios

01.08.2022

Stahl joins CLIB biotechnology network

Stahl, an active proponent of responsible chemistry, has joined CLIB, an international open innovation cluster of stakeholders in the biotechnology space. CLIB is committed to providing networking opportunities for its members across different industries and sectors with a view to using biotechnology to foster sustainability. Stahl’s membership of the network underlines the company’s commitment to open innovation and to working with partners across value chains to reduce its Scope 3 emissions.

Stahl, an active proponent of responsible chemistry, has joined CLIB, an international open innovation cluster of stakeholders in the biotechnology space. CLIB is committed to providing networking opportunities for its members across different industries and sectors with a view to using biotechnology to foster sustainability. Stahl’s membership of the network underlines the company’s commitment to open innovation and to working with partners across value chains to reduce its Scope 3 emissions.

CLIB members include large companies, SMEs, start-ups, academic institutes, universities, and other stakeholders engaged in biotechnology and the circular- and bioeconomy as a whole. As part of this cluster, Stahl seeks to connect with likeminded contacts and partners to explore opportunities for increasing the use of bio-based and bio-derived solutions in its chemistries, products, and applications. In turn, Stahl hopes to add value to other members of the network by providing a route to market for biotechnology solutions through the company’s extensive range of industrial products and applications.
 
Stahl’s first face-to-face interaction with its fellow CLIB members will take place at the CLIB Networking Day in October 2022.

More information:
Stahl CLIB biotechnology
Source:

Stahl Holdings B.V.

Six Carbon Capture and Utilisation technologies for a sustainable chemical and fuel production nominated for the innovation award “Best CO2 Utilisation 2022”
CCU-2022 Award-Nominees
14.03.2022

“Best CO2 Utilisation 2022” Award Nominees

  • Six Carbon Capture and Utilisation technologies for a sustainable chemical and fuel production nominated for the innovation award “Best CO2 Utilisation 2022”
  • Conference on CO2-based Fuels and Chemicals 2022 – Cologne (Germany) and online, hybrid conference, 23-24 March 2022

Carbon Capture and Utilisation (CCU) Innovations of the Year 2022: A lot of technologies are in place and in development to face the challenges of a sustainable chemicals and fuels production based on the utilisation of captured CO2 from industrial off-gases or directly from the atmosphere. To honor these, nova-Institute grants its annual award, “Best CO2 Utilisation”, within the framework of the “Conference on CO2-based Fuels and Chemicals” taking place in Cologne on 23-24 March 2022. Great submissions reached the nova-Institute and six nominees now get the chance to demonstrate their full potential to a wide audience in Cologne (Germany) and online.

Here are the six nominees:

  • Six Carbon Capture and Utilisation technologies for a sustainable chemical and fuel production nominated for the innovation award “Best CO2 Utilisation 2022”
  • Conference on CO2-based Fuels and Chemicals 2022 – Cologne (Germany) and online, hybrid conference, 23-24 March 2022

Carbon Capture and Utilisation (CCU) Innovations of the Year 2022: A lot of technologies are in place and in development to face the challenges of a sustainable chemicals and fuels production based on the utilisation of captured CO2 from industrial off-gases or directly from the atmosphere. To honor these, nova-Institute grants its annual award, “Best CO2 Utilisation”, within the framework of the “Conference on CO2-based Fuels and Chemicals” taking place in Cologne on 23-24 March 2022. Great submissions reached the nova-Institute and six nominees now get the chance to demonstrate their full potential to a wide audience in Cologne (Germany) and online.

Here are the six nominees:

  • Acies Bio (SI) – OneCarbonBio
  • Air Company (US) – Air Eau de Parfum
  • Avecom (BE) – Power To Protein
  • CleanO2 Carbon Capture Technologies (CA) – CleanO2 Soap
  • Fraunhofer Institute for Interfacial Engineering and Biotechnology IGB (DE) – eBioCO2n Technology
  • Nordic Electrofuel (NO) – E-Fuel 1
04.01.2022

AMSilk & Mercedes-Benz: Sustainable car door pulls

  • AMSilk Partners with Mercedes-Benz to Present a Sustainable Bio-Based Product
  • The use of a biotechnology-based and certified-vegan silk-like fabric marks a first in the automotive sector

AMSilk GmbH (“AMSilk”), a leader in supplying innovative high-performance bio-based silk materials, announced a partnership with Mercedes-Benz, for the development of novel, sustainable car door pulls, as part of the car manufacturer’s latest technology programme, the VISION EQXX.

The new concept car, VISION EQXX, features innovative interior materials, revealing a way forward for luxury design that conserves resources and is in balance with nature. Among the organic interior design features are new door pulls made from AMSilk’s Biosteel® fiber. This high-strength, certified-vegan, silk-like fabric is made using AMSilk’s proprietary biotechnology expertise. AMSilk is the world’s first industrial supplier of vegan silk biopolymers which are 100% biodegradable, recyclable, renewable and zero-waste.

  • AMSilk Partners with Mercedes-Benz to Present a Sustainable Bio-Based Product
  • The use of a biotechnology-based and certified-vegan silk-like fabric marks a first in the automotive sector

AMSilk GmbH (“AMSilk”), a leader in supplying innovative high-performance bio-based silk materials, announced a partnership with Mercedes-Benz, for the development of novel, sustainable car door pulls, as part of the car manufacturer’s latest technology programme, the VISION EQXX.

The new concept car, VISION EQXX, features innovative interior materials, revealing a way forward for luxury design that conserves resources and is in balance with nature. Among the organic interior design features are new door pulls made from AMSilk’s Biosteel® fiber. This high-strength, certified-vegan, silk-like fabric is made using AMSilk’s proprietary biotechnology expertise. AMSilk is the world’s first industrial supplier of vegan silk biopolymers which are 100% biodegradable, recyclable, renewable and zero-waste.

Marking a first in the automotive sector, AMSilk’s Biosteel® provides a solution to the car industry whose need to replace petroleum-based content by natural, bio-based materials is increasingly growing.
This new project is the most efficient electric vehicle Mercedes-Benz has ever built and marks a new expression of efficiency and sustainability in interior design. The all-electric VISION EQXX was unveiled in a digital world premiere on the “Mercedes me” media online platform.

Ulrich Scherbel, Chief Executive Officer of AMSilk said: “We are extremely proud to partner with Mercedes-Benz on the technology programme VISION EQXX, providing sustainable interior design solutions from our best-in-class bio-based fibers. Amid a fresh wave of ambitious climate pledges, we are proud to be playing a leading role in providing solutions for a zero-waste future.”

Source:

Optimum Strategic Communications for AMSilk GmbH

(c) lululemon
18.08.2021

Genomatica partners with lululemon bring bio-nylon to apparel

  • Renewably Sourced Materials to Help Replace Petrochemicals in Apparel for a Healthier Planet

lululemon athletica inc. (NASDAQ:LULU) announced a multi-year collaboration with sustainable materials leader Genomatica to bring renewably-sourced, bio-based materials into lululemon’s products. This represents lululemon’s first-ever equity investment in a sustainable materials company and Genomatica’s largest partnership within the retail industry. Together, the two companies will create a lower-impact, plant-based nylon to replace conventional nylon, which is the largest volume of synthetic material currently used to make lululemon products.

Genomatica uses biotechnology and fermentation to convert plant-based ingredients into widely used chemical building blocks, like those used to make nylon. These building blocks are converted to pellets and yarns, and the companies will be working closely with lululemon’s fabric supply chain to incorporate this material into future products. Through this collaboration, the companies seek to create positive change within the $22B global nylon market by building more sustainable supply chains.  

  • Renewably Sourced Materials to Help Replace Petrochemicals in Apparel for a Healthier Planet

lululemon athletica inc. (NASDAQ:LULU) announced a multi-year collaboration with sustainable materials leader Genomatica to bring renewably-sourced, bio-based materials into lululemon’s products. This represents lululemon’s first-ever equity investment in a sustainable materials company and Genomatica’s largest partnership within the retail industry. Together, the two companies will create a lower-impact, plant-based nylon to replace conventional nylon, which is the largest volume of synthetic material currently used to make lululemon products.

Genomatica uses biotechnology and fermentation to convert plant-based ingredients into widely used chemical building blocks, like those used to make nylon. These building blocks are converted to pellets and yarns, and the companies will be working closely with lululemon’s fabric supply chain to incorporate this material into future products. Through this collaboration, the companies seek to create positive change within the $22B global nylon market by building more sustainable supply chains.  

More information:
lululemon Genomatica bio-based nylon
Source:

Method Communications

RUDOLF HUB1922 : Innovation rooted into Aspirational Chemistry (c) RUDOLF Group
26.10.2020

RUDOLF HUB1922 : Innovation rooted into Aspirational Chemistry

The textile industry, one of the major industrial sectors worldwide, is going through a significant revolution, with changes taking place in various sections of textile processing. Biotechnology and biomimicry, for example, are continuously playing an important role in redefining the influence of the textile industry on society, and so is progress made in auxiliary chemistry, with advances investigated and then applied in almost every section of textile processing.  The outcome is amazingly promising.

Modern, real science is inextricably intertwined with environmental consciousness and they are definitely not mutually exclusive.

The textile industry, one of the major industrial sectors worldwide, is going through a significant revolution, with changes taking place in various sections of textile processing. Biotechnology and biomimicry, for example, are continuously playing an important role in redefining the influence of the textile industry on society, and so is progress made in auxiliary chemistry, with advances investigated and then applied in almost every section of textile processing.  The outcome is amazingly promising.

Modern, real science is inextricably intertwined with environmental consciousness and they are definitely not mutually exclusive.

At RUDOLF GROUP modern, real science means pushing R&D so to constantly explore new technology and innovations that help transform the textile and fashion industries. We work to reduce the overall dependency on traditional and virgin resources.  Getting textile manufacturers as well as brand and retailers on board is key to achieve real change. By 2030 we aim for a significant fraction of our products to be either sourced through paths alternative to the traditional petrochemicals, or by upcycling waste and/or byproducts from other industries.

“This is the kind of genuine, tangible, environmental consciousness that truly defines us and that entails that RUDOLF GROUP has a responsibility for the needs of society as a whole.” Said Alberto De Conti, Head of Rudolf Fashion Division “We have a maniacal attention to the environmental impact of our operations and products. We have truly embedded in ourselves the notion that “sustainability” is a key issue and critical to the long-term survival of our company and of society at large. “

The combination of modern, real science and environmental consciousness leads to what RUDOLF GROUP call aspirational chemistry something unique and something that positions us as shining example and guiding light throughout the industry. That is, in fact, BETTER CHEMISTRY.

Two are the innovations rooted in aspirational chemistry that RUDOLF HUB1922 presents. The first one is our WASHLESS technology and the second one is a brand new launch: LASER SMOOTHER, which supports laser technology and helps creating much better denim looks.

WASHLESS

HUB1922 WASHLESS, which can be applied to both denim and non-denim, is the simultaneous application of
-    proprietary fluorine-free DWR (Durable Water Resistance) based on biomimicry to repel dirt
-    anti-microbial, anti-bacteria and anti-viral, non-migrating chemistry to stop body odour.
The combination of the 2 translates into garments that don’t require to be washed as much.

Life cycle assessment studies on clothes, detergents and washing machines show that home laundering is always the most energy‐demanding period during these products' life cycle, even higher than production or transportation phases.

“WASHLESS aims at changing consumer habits in clothing maintenance to a more environmentally friendly direction and represents a change that is the most feasible and efficient. Making washing machines obsolete is impossible, but even though the technologies in clothes cleaning have improved greatly, the washing frequency has not been reduced. We own more and more clothing and wash it more frequently. This increased amount of washing counteracts the technological improvements in home laundry. “ said De Conti.

It is only by understanding the climate change impact associated with home laundering that product innovations and consumer education can be explored. Studies consistently show that a carbon dioxide reduction of 105 MT and electricity savings of 142 thousand GWh can be obtained by reducing home laundering, on average, by 1/3. This is roughly equivalent to removing 12% of the 140 M passenger cars in the US, or taking 23 coal power plants off the grid. In addition, more than 60% of water consumed while laundering (2,000 billion liters) can be reduced through these strategies.

LASER SMOOTHER

Laser denim is the current dominant technology available to the denim industry to create locally abraded areas, vintage effects, whiskers, patterns, patches, and even intentional holes and tears in a garment. Laser technology uses less water, harmful chemicals (such as potassium permanganate) and energy to create a wide variety of denim looks.

However, laser is not always able to produce the desired look, on the desired fabric, in the desired time. Therefore, chemical companies have been developing laser boosters that can be pre-applied to the garments in order to intensify the effect of the laser to mimic heavier bleaching applications. Unfortunately, laser boosters can create blurred images where the definition is lower and the overall image less natural.

The brand new RUDOLF HUB1922 LASER SMOOTHER is an all-in-one formulation, very easy to pre-apply to garments before laser burning and that return a very natural image which is very similar to the highly desirable hand scraping. Laser smoother can be applied by traditional exhaust or through nebulization and it dries at normal temperature in normal tumble driers.  Advantages of LASER PRIMER are:

•    Remarkable enhancement of the fabric’s characteristics (heightening of material)
•    Overall effect much more natural and similar to manual scraping (craftsmanship dimension)
•    Reduced required laser power to achieve the wanted effect (conspicuous energy saving)
•    A faster laser burning process (significant time saving, depending on the final effect)
•    Any other chemical spray is not required (environmental friendliness)
•    Reduced cost compared to other solution (financial viability)

More information:
Rudolf Group HUB1922 Denim
Source:

EFFE-BI SRL PR & COMMUNICATION