Specially formulated plasticizer resistance enhances fit and adhesion on challenging shapes

#Trinseo, a specialty materials solutions provider, introduces LIGOS™ A9615, an innovative general-purpose adhesive specifically designed for film labels. Building on decades of expertise in adhesive development, LIGOS™ A9615, is a new acrylic product tailored for the GPL (General Purpose Label) market and designed with unique, in-demand features that enhance a wide range of performance attributes.

Key benefits of LIGOS™ A9615 include:

Aging Resistance: Ensures lasting adhesion without degradation over time.

Excellent cohesion: Facilitates easy label removability while maintaining repositioning capabilities.

Plasticizer Resistance: Enhances the adhesion performance on PVC films, allowing film labels to adapt seamlessly to various curved plastic surfaces.

Targeting the Southeast Asian market, LIGOS™ A9615 is ideal for a broad array of applications, including consumer goods and packaging. "We are excited to introduce LIGOS™ A9615 to the Southeast Asian market," said Jeffrey Li, Marketing and Product Manager, Latex Binders at Trinseo. "This product not only combines strong adhesion with the ability to reposition and remove labels cleanly, but its plasticizer resistance also ensures that labels can conform to various surfaces, meeting the diverse needs of our customers.

LIGOS™ A9615 is now available for purchase, ready to enhance labeling solutions across multiple industries.

source:Trinseo

Today's KNOWLEDGE Share Comparative Analysis of POM with Other Plastics:

Today's KNOWLEDGE Share

Comparative Analysis of POM with Other Plastics:

Some of the key advantages and limitations of POM compared to other plastics are highlighted below.

POM vs Nylon:

POM has lower moisture absorption and better dimensional stability than nylon

It has higher tensile strength, hardness and modulus than nylon

Nylon offers higher toughness, ductility and impact strength compared to POM

Nylon has better chemical resistance than POM, especially to bases, oils and greases

POM provides lower coefficient of friction than nylon

POM vs Polycarbonate:

POM has much higher strength, hardness and stiffness than polycarbonate

PC offers very high impact resistance compared to brittle

POMPolycarbonate has superior temperature resistance up to 140°C vs 90°C for POM

POM has lower moisture absorption and better dimensional stability

PC has higher ductility and fracture toughness compared to POM

POM vs Polyimide:

Polyimide can withstand much higher temperatures than POM

It has excellent strength retention at high temperatures vs POM

POM offers better impact strength and machinability

Polyimide has superior wear resistance and chemical resistance

POM has lower density and moisture absorption compared to polyimide.

source:beeplastic.com

Palsgaard launches anti-fouling additive to replace toxic EAs in polymer processing

Palsgaard introduces a safe, sustainable anti-fouling additive for the polypropylene and polyethylene polymerization process.

Developed from renewable raw materials, the food-grade additive Einar® 987 has been developed to address concerns about the ethoxylated amine (EA) chemistry currently used.

Regulatory-compliant solution to replace the incumbent EAs:

The active compound of Einar® 987, which is supplied as a clear, viscous liquid, is a polyglycerol ester (PGE) blend of fatty acids from vegetable oils. As a non-toxic and food-contact-approved anti-fouling additive, it offers a drop-in, regulatory-compliant solution to replace the incumbent EAs.

When developing Einar® 987, Palsgaard drew on its extensive knowledge of anti-static and food-safe chemistries. The company considered a number of parameters when developing this new formulation, focusing on creating an additive that would offer at least equal performance while also being both safer and more sustainable than currently available options.

“Polyolefin resin producers stand to benefit directly from this technology, as its anti-static properties help to ensure the polymer powder does not cling to the reactor wall during polymerization. This serves to stabilize the reaction temperature, sustain a high production performance and enable consistent product quality,” said Laura Juhl, application manager for Palsgaard’s Bio-Specialty Additives.

Safer alternative to amine-based catalysts

Safety concerns over amine chemistry have led resin makers to seek alternatives for some time now. Einar® 987 is effective at low dosages of just 100-300 ppm and helps to deliver long catalyst mileage without any compromise in performance.

Palsgaard, which has been developing plant-based solutions since 1917, has already conducted several successful trials of Einar® 987 with resin producers. Additional evaluations can be supported by the company’s technical team to facilitate smooth adoption of the new, safer chemistry.

Einar® 987 is one of several products that Palsgaard will be showcasing on its booth at the upcoming K 2025 trade show in Dusseldorf, Germany. Visit Palsgaard from October 8-15 in Hall 7, Level 1, Booth C15, to meet their product and market specialists and discuss the sustainable benefits and superior performance of Einar plant-based polymer additives.

Source: Palsgaard/polymer-additives.specialchem.com

 

Today's KNOWLEDGE Share : TR launches range of fasteners made of 100% recycled nylon

Today's KNOWLEDGE Share

TR advances sustainable engineering with new range of nylon fasteners made from 100% recycled materials

TR, part of the Trifast plc Group and a global leader in engineering, manufacturing and supply chain solutions, unveils a breakthrough in sustainable materials with the development of a range of plastic fasteners and components produced using 100% recycled nylon.

As environmental legislation and design standards evolve, particularly in sectors such as lighting, power, data and water infrastructure, the demand for durable, eco-efficient components is rising. Yet the global sustainable plastics market remains dominated by single-use applications. TR has identified a critical gap and opportunity in engineered fasteners.

Extensive trials and testing

TR conducted detailed material research, mechanical property analysis, moulding trials, and accelerated heat ageing tests on several materials. The standout performer was a 100% recycled nylon proven to deliver processability and mechanical characteristics on par with prime materials, while offering up to a 90% reduction in raw material CO₂ emissions.

Trials were conducted on a range of products, including:

 

Cable Ties, Fir Tree Mount

Push Lock Rivets

Drive Fasteners

Wire Saddles

Snap Rivets

Fir Tree Clips

Threaded Pillars

 

These components are commonly used across smart infrastructure applications, from securing data cabling to fastening control systems and enclosures.

Sustainable by design

Andrew Fletcher, Head of Plastics & Rubber (Commercial & Technical) at TR, commented: “We’ve achieved outstanding results with our sustainable nylon products, not only matching performance requirements but also offering a credible path to net zero. This initiative sits at the heart of our strategy to support our customers with engineering-led, environmentally responsible solutions.

Commercial availability

Following successful production trials, the recycled nylon parts are now undergoing final assessments for commercial launch. TR invites design and production engineers to engage with its technical teams to explore integration options and sample testing.

source: TR Fasteners

Today's KNOWLEDGE Share : New Ultramid® Advanced N for high-voltage connectors in electric cars

Today's KNOWLEDGE Share

New Ultramid® Advanced N for high-voltage connectors in electric cars

BASF is now complementing its polyphthalamide (PPA) portfolio by Ultramid® Advanced N3U42G6, a polyamide 9T with non-halogenated flame-retardant, which minimizes electro-corrosion of metal contacts in electric and electronics (E&E) parts for e-mobility. The PPA increases the safety and durability of high-voltage (HV) connectors in e.g. inverters, DC-DC converters and batteries of electric cars. Due to its high strength and stiffness over a broad temperature range, its outstanding chemical resistance and dimensional stability, the Ultramid® Advanced N grade enhances the robustness and reliability of thin-walled HV connectors meeting growing industry needs for halide-free E&E components used in warm and humid conditions. The new Ultramid® Advanced N3U42G6 is available in uncolored with UL-certified masterbatches but also as pre-colored version with high color stability for easy processing and excellent color retention after heat ageing.

As one of the first E&E expert companies, the automotive supplier KOSTAL Kontakt Systeme, Lüdenscheid, Germany, now uses the new Ultramid® Advanced N in several components in its high-voltage connector KS22 Class 4 for high-current modules. The HV-connector, the smallest in its performance class, benefits from the BASF PPA in several ways: It enables miniaturization and saves installation space as it shows good flowability at thin wall thickness. Ultramid® Advanced N3U42G6 provides the connector with very high electrical insulation which beats aliphatic polyamides, especially at elevated temperatures. In addition, it has a high elongation at break so that there is no stress whitening when the different components are mounted. In this way, automotive customers can rely on the safe, long-term performance of KOSTAL’s HV-connector with the best combination of electrical insulation and mechanical properties.

The flame-retardant Ultramid® Advanced N3U42G6 extends the lifetime of E&E components as it is halide-free according to EN 50642. It thus prevents contact corrosion and subsequent failure of sensitive electrical parts exposed to heat and moisture. The PPA achieves fire protection class UL94 with V-0 at 0.25 mm. It also enables long-lasting color coding which is safety-relevant in areas with high voltages: It meets all the criteria of color stability and heat aging resistance. In in-house tests, the color stability was confirmed after 1,000 hours at up to 150°C. Pre-colored variants like the e-mobility standard orange RAL 2003 are available directly from BASF. For self-coloring, more than 50 inorganic and organic colorants, which are approved for coloring PPAs and show a heat stability up to 350°C, can be used.

Our new non-halogenated grade combines the excellent properties of our superhero Ultramid® Advanced N with better colorability, long color stability and outstanding anti-corrosion effect”, says Volker Zeiher from technical development engineering plastics at BASF. “With this optimized PA9T, our customers can develop innovative, best-in-class E&E components supported by BASF’s proven flame-retardant expertise and material know-how for electronics manufacturing. Ultramid® Advanced N3U42G6 is part of BASF’s tailored flame-retardant PPA portfolio for the E&E industry that advances the development of challenging parts in consumer electronics, automotive battery systems and electric powertrains.

Due to its low moisture uptake and high heat distortion temperature of 265°C, Ultramid® Advanced N3U42G6 is especially suited for connectors post-processed with surface mount technology (SMT): It guarantees a high dimensional stability and avoids blistering or changes in dimensions of the processed part during the SMT process. The new PPA grade is especially suited for SMT as it can withstand higher temperatures while maintaining its mechanical strength. This increases the quality of the post-processed E&E components and helps to reduce waste and costs.

source: BASF

Today's KNOWLEDGE Share : A new approach could fractionate crude oil using much less energy

Today's KNOWLEDGE Share

A new approach could fractionate crude oil using much less energy

MIT researchers’ new membrane separates different types of fuel based on their molecular size, eliminating the need for energy-intensive crude oil distillation.

Separating crude oil into products such as gasoline, diesel, and heating oil is an energy-intensive process that accounts for about 6 percent of the world’s CO2 emissions. Most of that energy goes into the heat needed to separate the components by their boiling point.

In an advance that could dramatically reduce the amount of energy needed for crude oil fractionation, MIT engineers have developed a membrane that filters the components of crude oil by their molecular size.

“This is a whole new way of envisioning a separation process. Instead of boiling mixtures to purify them, why not separate components based on shape and size? The key innovation is that the filters we developed can separate very small molecules at an atomistic length scale,” says Zachary P. Smith, an associate professor of chemical engineering at MIT and the senior author of the new study.

The new filtration membrane can efficiently separate heavy and light components from oil, and it is resistant to the swelling that tends to occur with other types of oil separation membranes. The membrane is a thin film that can be manufactured using a technique that is already widely used in industrial processes, potentially allowing it to be scaled up for widespread use.

Taehoon Lee, a former MIT postdoc who is now an assistant professor at Sungkyunkwan University in South Korea, is the lead author of the paper, which appears today in Science.

Oil fractionation

Conventional heat-driven processes for fractionating crude oil make up about 1 percent of global energy use, and it has been estimated that using membranes for crude oil separation could reduce the amount of energy needed by about 90 percent. For this to succeed, a separation membrane needs to allow hydrocarbons to pass through quickly, and to selectively filter compounds of different sizes.

Until now, most efforts to develop a filtration membrane for hydrocarbons have focused on polymers of intrinsic microporosity (PIMs), including one known as PIM-1. Although this porous material allows the fast transport of hydrocarbons, it tends to excessively absorb some of the organic compounds as they pass through the membrane, leading the film to swell, which impairs its size-sieving ability.

To come up with a better alternative, the MIT team decided to try modifying polymers that are used for reverse osmosis water desalination. Since their adoption in the 1970s, reverse osmosis membranes have reduced the energy consumption of desalination by about 90 percent - a remarkable industrial success story.

The most commonly used membrane for water desalination is a polyamide that is manufactured using a method known as interfacial polymerization. During this process, a thin polymer film forms at the interface between water and an organic solvent such as hexane. Water and hexane do not normally mix, but at the interface between them, a small amount of the compounds dissolved in them can react with each other.

In this case, a hydrophilic monomer called MPD, which is dissolved in water, reacts with a hydrophobic monomer called TMC, which is dissolved in hexane. The two monomers are joined together by a connection known as an amide bond, forming a polyamide thin film (named MPD-TMC) at the water-hexane interface.

While highly effective for water desalination, MPD-TMC doesn’t have the right pore sizes and swelling resistance that would allow it to separate hydrocarbons.

To adapt the material to separate the hydrocarbons found in crude oil, the researchers first modified the film by changing the bond that connects the monomers from an amide bond to an imine bond. This bond is more rigid and hydrophobic, which allows hydrocarbons to quickly move through the membrane without causing noticeable swelling of the film compared to the polyamide counterpart.

“The polyimine material has porosity that forms at the interface, and because of the cross-linking chemistry that we have added in, you now have something that doesn’t swell,” Smith says. “You make it in the oil phase, react it at the water interface, and with the crosslinks, it’s now immobilized. And so those pores, even when they’re exposed to hydrocarbons, no longer swell like other materials.”

The researchers also introduced a monomer called triptycene. This shape-persistent, molecularly selective molecule further helps the resultant polyimines to form pores that are the right size for hydrocarbons to fit through.

This approach represents “an important step toward reducing industrial energy consumption,” says Andrew Livingston, a professor of chemical engineering at Queen Mary University of London, who was not involved in the study.

“This work takes the workhorse technology of the membrane desalination industry, interfacial polymerization, and creates a new way to apply it to organic systems such as hydrocarbon feedstocks, which currently consume large chunks of global energy,” Livingston says. “The imaginative approach using an interfacial catalyst coupled to hydrophobic monomers leads to membranes with high permeance and excellent selectivity, and the work shows how these can be used in relevant separations.

Efficient separation

When the researchers used the new membrane to filter a mixture of toluene and triisopropylbenzene (TIPB) as a benchmark for evaluating separation performance, it was able to achieve a concentration of toluene 20 times greater than its concentration in the original mixture. They also tested the membrane with an industrially relevant mixture consisting of naphtha, kerosene, and diesel, and found that it could efficiently separate the heavier and lighter compounds by their molecular size.

If adapted for industrial use, a series of these filters could be used to generate a higher concentration of the desired products at each step, the researchers say.

“You can imagine that with a membrane like this, you could have an initial stage that replaces a crude oil fractionation column. You could partition heavy and light molecules and then you could use different membranes in a cascade to purify complex mixtures to isolate the chemicals that you need,” Smith says.

Interfacial polymerization is already widely used to create membranes for water desalination, and the researchers believe it should be possible to adapt those processes to mass produce the films they designed in this study.

“The main advantage of interfacial polymerization is it’s already a well-established method to prepare membranes for water purification, so you can imagine just adopting these chemistries into existing scale of manufacturing lines,” Lee says.

The research was funded, in part, by ExxonMobil through the MIT Energy Initiative. 

source: MIT News

Today's KNOWLEDGE Share : A new line of shoes made with recycled blades

Today's KNOWLEDGE Share

A new line of shoes made with recycled blades

The blades come from a wind turbine dismantled during the repowering of a wind farm in Tahivilla in Cádiz (Spain), which will go from 98 to 13 turbines.

Acciona Energía and El Ganso have announced the launch of a new line of sneakers made with recycled blades from a wind farm currently undergoing repowering: Tahivilla in Cádiz (Spain). 

The new sneakers stand out for their sustainable nature, as they give a second life to materials from dismantled wind turbine blades, as well as for their design, intended for work environments and daily use. In addition, they incorporate a waterproof and stain-resistant fabric developed by Spanish company Sepiia.

Following the success of the first launch of shoes made using recycled wind turbine blades in 2023, Acciona and El Ganso contribute to the circular economy again with this new limited edition, now available for purchase through El Ganso’s official website and at its stores.

Second life:

The shoes were manufactured using a blade dismantled from the Tahivilla wind farm, which Acciona Energía is currently repowering. The company is replacing 98 old turbines with 13 modern, more powerful and efficient Nordex turbines, which will optimise the wind farm’s performance and increase its renewable energy output by 72%.

With this initiative, Acciona Energía repurposes dismantled wind turbine blades at the end of their useful life into a new product, while advancing the development of blade recycling solutions, one of the main challenges for the wind energy sector as thousands of turbines approach the end of their operational life.

While around 90% of a wind turbine can be recycled through well-established processes, blades–made from complex materials such as resins, fibreglass and/or carbon fibre–require specific solutions. The main challenge lies in developing sustainable and scalable recycling methods at an industrial level.

In recent years, Acciona Energía has carried out several pilot projects to reuse materials from recycled blades: from its first sneaker collaboration with El Ganso, to the construction of structural beams for photovoltaic plants, and the launch of a surfboard collection in Australia.

Additionally, the company is developing an industrial-scale wind blade recycling plant in Lumbier (Navarra), to process 6,000 tonnes per year and convert them into new raw materials for sectors such as automotive and construction.

source: Acciona