Covestro & Partners Develop New Process for Bio-based Aniline Production

Covestro has scored a research breakthrough for the use of plant-based raw materials in plastics production: aniline, an important basic chemical, can now be derived from biomass. The materials manufacturer achieved this by collaborating with partners on the development of a completely new process, initially in the laboratory. Until now, only fossil raw materials had been used for the production of aniline, which plays an important role in the chemical industry and is used as starting material for numerous products. 

Unprecedented Achievement:

Following its success in the lab, Covestro plans to further develop the new process together with partners from industry and research. The first step is to upscale the process in a pilot plant with the ultimate goal of enabling the production of bio-based aniline on an industrial scale. That would be an unprecedented achievement in the chemical industry.

 Aniline as a Precursor for Rigid Polyurethane Foam

About five million metric tons of aniline are produced annually worldwide; the total volume has been increasing by an average of about five percent every year. With a production capacity of about one million metric tons, Covestro is among the leading producers. The company requires aniline as a precursor for rigid polyurethane foam, a highly efficient insulating material used in buildings and refrigeration systems.
“The market is showing great interest in ecologically beneficial products based on renewable raw materials,” said Covestro Chief Commercial Officer Dr. Markus Steilemann. “Being able to derive aniline from biomass is another key step towards making the chemical and plastics industries less dependent on fossil raw materials and market fluctuations. With this, we are pursuing our vision of making the world a brighter place.”
“The process currently under development uses renewable raw materials and produces aniline with a much better CO₂ footprint than that manufactured with standard technology,” said Covestro project manager Dr. Gernot Jäger. “This also enables our customers to markedly improve the CO₂ footprint of their aniline-based products.” And the reactions would take place under milder conditions. The ecological aspects of the process are also being thoroughly evaluated by external institutes.

100 Percent of Carbon from Biomass

The industry currently derives aniline from benzene, a petroleum-based raw material. But industrial sugar, which is already derived on large scale from, for example, feed corn, straw and wood, can be used instead. The newly developed process uses a microorganism as a catalyst to first convert the industrial sugar into an aniline precursor. The aniline is then derived by means of chemical catalysis in a second step. “This means one hundred percent of the carbon in the aniline comes from renewable raw materials,” explained Jäger.
Covestro is working with the University of Stuttgart, the CAT Catalytic Center at RWTH Aachen University, and Bayer AG to further develop the process. “This interdisciplinary, motivated team combines all the needed expertise at a very high level and is the basis for continued success,” said Jäger. The long-term research project will receive funding for a period of two and a half years through the FNR (Fachagentur Nachwachsende Rohstoffe e.V.), a project agency of Germany’s Federal Ministry of Food and Agriculture (funding code: 22010215).
Covestro is already using renewable raw materials in a number of different products. A hardener for coatings that the company developed is one example: up to 70 percent of its carbon content is derived from plants. And CO₂ is also increasingly being used an alternative raw material. Used in place of petroleum, CO₂ accounts for up to 20 percent of the raw materials used in a precursor for flexible polyurethane foam that Covestro began producing in 2016. The company is also researching and developing many more products based on CO₂.

Source: Covestro

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Plastics Re-Revolution since 1930's; WASTE(s) are New Crude Oil, MAY 23-25, NEW YORK area

There are 2-Compelling Reasons Why You Must Attend This Bio-Conference:

1. Traditional & New Polymers: Biobased building blocks are enabling the manufacture of traditional polymers (Polyolefins/Polyesters/Nylons) as well as newer polymers such as PEF (vs PET for packaging) and Nylon 410 to name a few.

2. Environment Re-Engineering: Bill Gates funds $14M for Plantro-Chemicals and heads-up a $1 Billion fund to fight climate change.

LAND Pollution: Building blocks for polymers are being made via forest and municipal WASTES as opposed to petro-based chemicals

CLIMATE Pollution: In further support to worldwide Paris-2015 agreement on climate control, Bill Gates will be heading a $1 Billion fund to fight climate change. Use of biobased-renewable raw materials to make polymers, especially the greenhouse gases (CO2 and CH4), is a step towards that goal.

WATER Pollution: About 50Blbs / year of plastic leaks into ocean with potentially adverse effects on humans via seafood. Commercialization of PHA can address that issue as it biodegrades in river and ocean waters
……………………………………………………………………………………
Please register via the link below:
http://innoplastsolutions.com/bio/registration/join/12-biobased-re-invention-of-plastics

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New Promising Way to Recycle Carbon Fiber-reinforced Plastics: WSU

A research team from WSU for the first time has developed a promising way to recycle the popular carbon fiber plastics that are used in everything from modern airplanes and sporting goods to the wind energy industry.

The work, reported in Polymer Degradation and Stability, provides an efficient way to re-use the expensive carbon fiber and other materials that make up the composites.

Planes, Windmills, Many Products

Jinwen Zhang with his Carbon Fiber Recycling Research Team

Carbon fiber reinforced plastics are increasingly popular in many industries, particularly aviation, because they are light and strong. They are, however:

• Very difficult to break down or recycle, and disposing of them has become of increasing concern. 
• Thermoplastics - type of plastic used in milk bottles, can be melted and easily re-used whereas, composites used in planes are thermoset plastics which are cured and can’t easily be undone and returned to their original materials.

Caustic Chemicals Eliminated

• To recycle them, researchers mostly have tried grinding them down mechanically or breaking them down with very high temperatures or harsh chemicals to recover the expensive carbon fiber. Oftentimes, however, the carbon fiber is damaged in the process. 
• The caustic chemicals used are hazardous and difficult to dispose of. 
• They also destroy the matrix resin materials in the composites, creating a messy mixture of chemicals and an additional waste problem.

Mild Chemicals, Low Temperatures

In their project, Jinwen Zhang, a professor in the School of Mechanical and Materials Engineering, and his team developed a new chemical recycling method that used mild acids as catalysts in liquid ethanol at a relatively low temperature to break down the thermosets. In particular, it was the combination of chemicals that proved effective, said Zhang, who has a chemistry background. To break down cured materials effectively, the researchers raised the temperature of the material so that the catalyst-containing liquid can penetrate into the composite and break down the complex structure. Zhang used ethanol to make the resins expand and zinc chloride to break down critical carbon-nitrogen bonds.

Jinwen Zhang said:
“It is critical to develop efficient catalytic systems that are capable of permeating into the cured resins and breaking down the chemical bonds of cured resins.”

The researchers were able to preserve the carbon fibers as well as the resin material in a useful form that could be easily re-used. They have filed for a patent and are working to commercialize their methods.

The work was funded by the Joint Center for Aerospace Technology Innovation (JCATI) in collaboration with industry partner, Global Fiberglass Solutions. The state-funded JCATI works to support the Washington’s aerospace industry by pursuing research that is relevant to aerospace companies and by providing industry-focused research opportunities. In addition to Zhang, researchers on the project included Junna Xin, assistant research professor, Tuan Liu, postdoctoral research associate, and graduate student Xiaolong Guo. The research is in keeping with WSU’s Grand Challenges initiative stimulating research to address some of society’s most complex issues. It is particularly relevant to the challenge of “Smart Systems” and its theme of foundational and emergent materials.

Source: Washington State University (WSU)

Plastics Re-Revolution since 1930's; WASTE(s) are New Crude Oil, MAY 23-25, NEW YORK area

There are 2-Compelling Reasons Why You Must Attend This Bio-Conference:

1. Traditional & New Polymers: Biobased building blocks are enabling the manufacture of traditional polymers (Polyolefins/Polyesters/Nylons) as well as newer polymers such as PEF (vs PET for packaging) and Nylon 410 to name a few.
2. Environment Re-Engineering: Bill Gates funds $14M for Plantro-Chemicals and heads-up a $1 Billion fund to fight climate change.

LAND Pollution: Building blocks for polymers are being made via forest and municipal WASTES as opposed to petro-based chemicals
CLIMATE Pollution: In further support to worldwide Paris-2015 agreement on climate control, Bill Gates will be heading a $1 Billion fund to fight climate change. Use of biobased-renewable raw materials to make polymers, especially the greenhouse gases (CO2 and CH4), is a step towards that goal.
WATER Pollution: About 50Blbs / year of plastic leaks into ocean with potentially adverse effects on humans via seafood. Commercialization of PHA can address that issue as it biodegrades in river and ocean waters
……………………………………………………………………………………
Please register via the link below:
http://innoplastsolutions.com/bio/registration/join/12-biobased-re-invention-of-plastics

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