Sustainable Polyurethane Production Without Toxic Isocyanate

Polyurethanes (PUR) are found in many products, such as upholstered furniture, foam or insulation materials, flooring, paints and even medical catheter tubes. The production of these high-demand plastics, however, relies on toxic isocyanate. Fraunhofer researchers have now developed an alternative production process using harmless dicarbamate.

Chemical compounds like isocyanate are toxic and trigger allergies or asthma. However, they remain indispensable for the chemical industry. They are needed especially in the production of PUR. These plastics are highly versatile and are therefore used in many products. Although the end product no longer contains isocyanates, special safety precautions are necessary during manufacturing to keep them away from humans and to avoid health hazards.

For the first time, Fraunhofer researchers have now succeeded in producing polyurethanes without using isocyanates in the CO2NIPU (nonisocyanate polyurethane, NIPU) project.

Dicarbamate as a substitute for isocyanate

To achieve this, project manager Christoph Herfurth from the Fraunhofer Institute for Applied Polymer Research IAP and his team replaced isocyanate with harmless dicarbamate. The innovative process makes the production of plastics easier and safer. Employees no longer have to undergo special training to protect themselves from the toxic substance. A further benefit: The process results in lower greenhouse gas emissions. This is because the researchers are using carbon dioxide to produce dicarbamate. They are also developing recycling methods for used PUR materials.

In addition to Fraunhofer IAP, participants in the CO2NIPU project were the Fraunhofer Institute for Chemical Technologies ICT, the Fraunhofer Institute for Manufacturing Technology and Advanced Materials IFAM and the Fraunhofer Institute for Environmental, Safety and Energy Technology UMSICHT. Herfurth points out the advantages of this innovative project: “The molecular structures of polyurethanes made from dicarbamates are identical to those of conventional PU made from isocyanates. This means that existing expertise can be built upon to achieve the material properties required for the end product or application.

Modular system for material properties

The researchers have further developed the process with a view to industrial feasibility. Different chemicals are mixed in specific proportions to produce the desired properties. So-called chain extenders help to cross-link the molecular groups and ensure elastic or adhesive properties. Polymer diols serve to soften the plastic, while the dicarbamate, as a substitute for isocyanate, initiates the chemical process. After mixing, these chemicals are melted and stirred at temperatures between 180 and 190 degrees Celsius. After cooling, the experts test for characteristics such as tensile strength and elasticity.

Isocyanates are highly reactive, which is why polyurethanes often form within only a few minutes. Although using less reactive dicarbamates extends the same process out to six to eight hours, this makes it much easier to control and regulate. This reduces scrap and quality fluctuations in production.

Circular economy for the plastics industry

Dicarbamates are produced using a high-pressure process at project partner Fraunhofer UMSICHT. Methanol and CO2 are reacted with diamines at a pressure of 50 bar to synthesize dicarbamates. Fraunhofer ICT develops recycling processes for used polyurethanes, such as from old foam materials, which are then reprocessed to produce new PUR products. “We are thus contributing to the goal of a sustainable circular economy without greenhouse gas emissions,” Herfurth summarizes.

As an initial application, Fraunhofer researchers have set their sights on manufacturing biocompatible catheter tubes for medical applications. Fraunhofer IFAM uses the variable modular system to develop adhesives that enable bonding of cannulas to the tube.

The technology for producing isocyanate-free polyurethanes is now also working outside the laboratory. “We are now able to produce several kilograms of NIPU in our pilot plant. In the next step, it will be possible to produce several hundred kilograms of NIPU at the Fraunhofer Pilot Plant Center for Polymer Synthesis and Processing PAZ in Schkopau,” says Herfurth.

source : Fraunhofer-Gesellschaft

Today's KNOWLEDGE Share: Sometimes the best investment is the machine you didn’t buy

Today's KNOWLEDGE Share

Sometimes the best investment is the machine you didn’t buy.

It’s easy to measure ROI on machines that go into production. But what’s harder to see and just as important is the value of walking away from the wrong investment.

I’ve had plenty of discussions where we reviewed the application and decided not to move forward with a machine quote. Why? Because the tool wasn’t ready. The process wasn’t defined. Or the customer realized they were solving the wrong problem.

Sometimes the smarter move is to retool an existing press, modify an injection unit, or adjust the part design. Not because it’s the easy way, but because it avoids forcing a major equipment purchase that doesn’t solve the real issue.

Machine decisions aren’t just about hardware. They’re about what stage the project is in, what flexibility is needed down the road, and whether the capital investment is really aligned with the business case.

If you’re in a position where you're not sure whether to buy, retrofit, or wait, I can help walk through the logic. No pressure. Just clarity on what makes sense and what doesn’t, based on where your project stands today.

source : Roman Malisek

Hydrogen Storage: China’s First Type IV Composite MEGC Debuts in Hebei

Earlier this year, we saw a joint venture led by CIMC-Hexagon Hydrogen Energy Development (Hebei) Co., Ltd. unveil China’s first homegrown 20-foot Type IV Composite Cylinder Multi-Element Gas Container at their sprawling Shijiazhuang plant in Hebei. It’s a big deal—switching from niche imports to domestic mass production of hydrogen storage gear. With national goals locked on carbon peak and neutrality, bolstering our hydrogen infrastructure isn’t just smart, it’s essential.

What’s New? Picture a 20-foot frame loaded with multiple carbon-fiber–wrapped cylinders, each rated for 38 MPa. In a standard 40-foot equivalent unit, you’re looking at over one metric ton of hydrogen—about four times what those old Type I tube trailers could carry. Until now, Chinese operators had to wait months (and shell out big bucks) for imported MEGCs. Localizing production slashes lead times and costs, clearing the way for wide-scale rollout.

Key Specifications

Operating Pressure: 38 MPa with fully composite Type IV cylinders.

Capacity: More than 1 metric ton of hydrogen per 40-foot equivalent container.

Weight Savings: Roughly 40% lighter than Type III designs—hello, better volumetric efficiency.

Payload Advantage: Up to 4× the hydrogen per trip versus Type I tube trailers.

Modularity: Options from 10 to 45 feet, compliant with ADR 6.8 and TPED (2010/35/EU).

Production Scale: Hebei facility is Asia’s largest site for Type IV composite cylinder manufacturing, primed for rapid ramp-up.

Why It Matters Strategically

Cutting procurement time from months to weeks and slashing logistics costs is a game-changer if you’re rolling out regional refueling networks or feeding hydrogen into industrial parks. As sustainable energy gains traction, affordable hydrogen storage and transport become linchpins for decarbonizing steel, chemicals, and heavy haul.

Fewer trips, lighter containers, and higher capacity directly translate to lower emissions compared to diesel haulage—and a stronger business case for hydrogen fuel cells in trucks, ships, and stationary power. In short: better total cost of ownership for big hydrogen users.

Technology Evolution

Hydrogen transport has come a long way. The early Type I steel tubes were heavy and prone to fatigue. Type II and III added a composite wrap around steel or aluminum liners—an improvement, but still heftier than you’d like. Now the fully plastic and carbon-fiber–lined Type IV composite cylinder nails the best strength-to-weight ratio, zero corrosion worries, and a stellar cycle life. That leap is crucial for moving bulk hydrogen cost-effectively.

Joint Venture Dynamics

Hexagon Purus brings six decades of composite storage expertise and validation from over 700 MEGC deployments worldwide. CIMC ENRIC offers end-to-end industrial chain integration in hydrogen equipment and decades of manufacturing scale. Together, they’ve sketched a blueprint for rapid localization—one we’ll likely see replicated in electrolyzer and fuel cell ventures across Asia.

Comparative Context

Sure, pilots in Japan and Europe are testing Type IV trailers and containers. But China’s sheer manufacturing heft, local certification know-how, and cost advantages give it the upper hand. Chinese-made MEGCs can undercut imports on both price and delivery time, positioning domestic suppliers for home-market sales and exports to Southeast Asia.

Industry Implications

With hardware bottlenecks easing, the commercial rollout of hydrogen networks can really take off. Logistics firms tell us imported containers took up to six months to arrive—local production could shrink that to a few weeks. Regulators have flagged hydrogen transport as strategic, and CIMC-Hexagon is already helping shape domestic safety and performance standards.

Economically, the Hebei site will create roles for composite technicians, engineers, and integration specialists. Downstream, it supports growth in refueling stations, fuel cell fleets, and industrial hydrogen users—driving the ecosystem forward.

Environmental & Policy Angle

Hydrogen logistics feature prominently in China’s clean energy roadmap. While precise incentive schemes for MEGCs are still emerging, local governments are backing hydrogen corridor pilots and low-carbon transport demos. By collaborating with regulators, CIMC-Hexagon ensures its containers align with evolving policy frameworks for robust hydrogen infrastructure.

Forward Look

We’ll be watching production ramp rates, export orders, and new high-pressure variants that could extend applications from small on-site storage to ultra-high-pressure long-haul shipments. If volumes climb as planned, expect steeper cost declines for green hydrogen production and stronger incentives for heavy industries to switch fuels.

Bottom line: China’s first domestically produced 20-foot Type IV MEGC isn’t just a container—it’s a cornerstone for a self-sufficient, cost-effective hydrogen storage network. The supply chain’s shorter, delivery’s faster, and the path to decarbonization is clearer than ever.

source : Hydrogen Fuel News

Today's KNOWLEDGE Share : PVC Compounding

 Today's KNOWLEDGE Share

🔧 PVC Compounding: The Real Rheology Challenges Nobody Talks About

Rheology in PVC is far more complex than viscosity curves on a datasheet. Unlike many polymers, PVC does not melt cleanly. Its flow behaviour depends on fusion, lubricant interactions, stabilizer efficiency and how the polymer breaks down under shear and temperature. This makes process control both critical and difficult.

Two compounds with identical formulations can behave very differently in the extruder simply because of particle size distribution, porosity or plasticizer absorption rate. Small changes in shear stress or temperature profile can shift the melt from too elastic to too fragile, affecting die swell, surface finish and dimensional accuracy. The challenge grows when recyclate, fillers or impact modifiers are added, each altering the melt’s elasticity and flow resistance in its own way.

Consistent rheology is what separates a stable production line from one that struggles with pressure fluctuations, chatter marks or unpredictable melt quality. It requires collaboration between resin producers, stabilizer suppliers, compounders and machinery experts to understand how every component influences flow under real processing conditions.

In your experience, which factor affects PVC rheology the most during processing: shear profile, lubrication balance or the presence of recyclate?

source : Orbimind AB

#PVCCompounding #Rheology #Extrusion

Lummus and Sumitomo Chemical Announce Commercial Availability of PMMA Chemical Recycling Technology

Lummus Technology and Sumitomo Chemical today announced the commercial availability of their highly-efficient Polymethyl Methacrylate Chemical Recycling (PMMA-CR) technology. This builds on the strategic partnership between Lummus and Sumitomo Chemical, first announced in May 2024, to co-develop and commercialize technologies that support circularity and carbon-neutral society across the petrochemical value chain.

“By uniting Lummus’ process expertise with Sumitomo Chemical’s materials innovation, we’re delivering a scalable, economically viable PMMA recycling solution,” said Leon de Bruyn, president and chief executive officer, Lummus Technology. “This gives our customers a clear pathway to reduce waste, lower emissions and unlock new value from recycled materials—turning sustainability into a competitive advantage.

We are proud to deliver this innovative PMMA-CR technology to market together with our trusted partner, Lummus Technology.

Since establishing the partnership in 2024, Lummus and Sumitomo Chemical advanced development and commercialization of the PMMA-CR technology, including successful validation at Sumitomo Chemical’s pilot plant in Japan. The technology recycles end‑of‑life PMMA back into high‑purity methyl methacrylate (MMA) monomer. Its depolymerization system, developed by The Japan Steel Works, Ltd. and Sumitomo Chemical, produces recycled MMA that matches the quality of fossil‑derived material. The process is also expected to cut life‑cycle greenhouse gas emissions by approximately 50%*, reducing plastic waste and reliance on fossil‑based feedstocks.

Key Technology Features:

->Highly Efficient PMMA Recycling Process: Converts post-consumer and post-industrial PMMA waste into circular MMA monomer with high yield and high purity.

->Advanced Depolymerization System: Utilizes an efficient system featuring a twin-screw extruder and a heating system for uniform temperature and excellent thermal efficiency with further optimization specifically tailored for PMMA depolymerization.

->Continuous Operation: Self-cleaning extruder system ensures high equipment utilization and simple operability.

->Scalable and Modular: Capacity can be adjusted by duplicating trains; available as modular ISBL packages.

->Circular Integration: Produces recycled MMA monomer equivalent in quality to MMA monomer manufactured from fossil resources, enabling true closed-loop recycling for PMMA applications in automotive, electronics, construction, and more.

With PMMA‑CR technology now available for licensing, Lummus and Sumitomo Chemical are ready to support customers’ transition toward circular PMMA, help improve resource efficiency and reduce environmental impact.

* Sumitomo Chemical’s calculated value based on a life cycle assessment (LCA) methodology, in comparison with materials derived from fossil resources.

source : Lummus Technology

DUNLOP Signs MoU with Cabot Corporation to Explore Commercial Adoption of Circular Reinforcing Carbon

DUNLOP has entered into a Memorandum of Understanding (MOU) with #Cabot Corporation to evaluate the commercial adoption of circular reinforcing carbons made with Cabot’s patented regenerated carbon technology. This innovative circular reinforcing carbon powered by Cabot’s EVOLVE Sustainable Solutions incorporates reclaimed carbon derived from the pyrolysis of end-of-life tires and is being considered as a sustainable raw material for Sumitomo Rubber’s tire production.

Cabot’s circular reinforcing carbon leveraging regenerated carbon technology is a new material that Sumitomo Rubber has not previously utilized in tire production. Recognized as a key enabler for reducing carbon emissions for both companies, this material will undergo evaluation for use in mass-produced tires by Sumitomo Rubber. Concurrently, Cabot will focus on scaling regenerated carbon technology to meet anticipated market demand.

"As a brand committed to continuous innovation, #DUNLOP will accelerate its efforts toward the commercialization of circular reinforcing carbon through our collaboration with Cabot," said Takuya Horiguchi, general manager, Material Research & Development Headquarters, Material Department IV, Sumitomo Rubber Industries, Ltd. "By harnessing and integrating the full breadth of technologies and expertise of both companies, DUNLOP will expedite the path toward mass production and actively contribute to the realization of a decarbonized society.

As a leading producer of reinforcing carbons, enabling sustainability through innovation and collaboration is core to our work. We are committed to investing in technologies that advance the sustainability and performance of our products and their use.

The adoption of sustainable raw materials is part of Sumitomo Rubber’s effort to realize the circular economy concept for its tire business, known as "TOWANOWA". This concept consists of two interconnected rings: the "Sustainable Ring," which covers five processes across the value chain, and the "Data Ring," which integrates big data collected from each process. By sharing and utilizing data between these rings, Sumitomo Rubber aims to deliver new value. Based on this concept, Sumitomo Rubber has been actively promoting the use of sustainable materials and other initiatives to reduce its environmental impact.

Looking ahead, Sumitomo Rubber will continue working towards the realization of "TOWANOWA" by reducing its environmental impact, enhancing tire performance and safety, and expanding solution services. Through these activities, Sumitomo Rubber aims to deliver new value to its end customers to contribute to a sustainable future.

source : Cabot

Today's KNOWLEDGE Share : TGA or DSC

 Today's KNOWLEDGE Share

💡 “Most polymer QC decisions miss the hidden threats until your customers notice.”

Quality Control is not just about running instruments; it’s about capturing the right insight at the right time.

In many polymer production lines, over 90% of QC decisions rely solely on TGA. While powerful, this single tool mindset can miss subtle polymer structural changes, which often only appear as customer complaints.

This is where DSC makes the difference. Thermal transitions and structural drifts may leave mass unchanged. TGA stays silent while DSC detects early warning signals long before failures reach the market.

🔍 Choosing the right tool depends on your Critical-to-Quality (CTQ) attributes:

1️⃣ TGA → Mass defines quality

Example: NBR latex QC: Ensuring 45 ± 2 wt% total solids (polymer + stabilizers vs. water) keeps viscosity and film formation consistent in glove-dipping applications.

2️⃣ DSC → Structure defines performance

Example: Pharmaceutical tablets: Detecting polymorphic transitions that alter dissolution rates, even with identical composition.

🌱 For sustainable QC systems:

Budget for both instruments, but use them strategically, one for routine control, the other for verification.

🚀 For organizations pursuing excellence:

Invest in simultaneous TGA-DSC (STA): one experiment, two perfectly correlated datasets, mass change and thermal behavior captured in real time. Not redundancy, it’s insight density.

Quality failures rarely come from what we measured wrong; they come from what we never measured at all.

🧰 What tools are you using in your QC process, and how have they impacted your results❓

Insight credit: Dr. Leila E. Scientist & Researcher | Chemical Process & Technology

source : Peyman Ezzati