Рубрика: Uncategorized

  • Ampacet’s Carbon Black-free Masterbatch Receives Plastics Recycling Award

    Ampacet’s Carbon Black-free Masterbatch Receives Plastics Recycling Award

    Reducing the Carbon Footprint with NIR Technology

    «We are honored to receive the Plastics Recycling Award, says Philippe Hugele, Ampacet Strategic Business Manager, Europe.

    «These carbon black-free solutions are part of our sustainable development program and can help to significantly reduce the carbon footprint by giving black plastic packaging a second life.» 

    While most black packaging cannot be sorted by recycling companies and can only be disposed of in a landfill or used for energy recovery, packaging using Ampacet’s REC-NIR-BLACK carbon black-free masterbatch is near-infrared (NIR) transparent to allow scanning by NIR technology for automated sorting at recovery facilities.

    [su_button url=»https://polymer-additives.specialchem.com/news/product-news/ampacet-carbon-blackfree-masterbatch-award-000218202?lr=ppa1905487&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ppa1905487&m_i=6BJaA5WGvuNEtjgyVuIgAm8Y74AdDDI4RfkGFHtAwcvIA3VilF11_%2B4UtJ0djepCfj4IpTUDft880CTy_6oIUtjHt_ws66″ target=»blank» size=»5″]Source[/su_button]

  • Shepherd Color Launches NTP Yellow 10G155 with Outstanding Color and Durability

    Shepherd Color Launches NTP Yellow 10G155 with Outstanding Color and Durability

    Color Matches without Compromising Weathering or Heat Stability

    The yellow color space has a wide range of pigment options that have a balance of chromaticity, opacity and durability. The new NTP Yellow (PY227) brings bright chromatic color, high opacity, and excellent durability all at the same time. This has lead a plastics engineer to call it ‘bullet-proof” colorant. To complement the NTP Yellow, improvements of the RTZ Orange (PY216) yield a true orange color unto itself, but also allows the addition of “a value” or redness to color matches without compromising weathering or heat stability.

    Pigment Chemistries

    Paint and coatings chemists, formulators, and color matchers face many challenges and options for coloring in the yellow color space. A wide range of pigment chemistries are available with different levels of opacity, durability, chromaticity, and economics. These four properties are often antagonistic to each other, forcing a compromise on two or more of these key properties. At the same time, historical pigments like lead chromate are facing increasing regulatory pressure and are being formulated out of products.

    Color matches that used to depend on blends of organic and inorganic pigments can now be matched with all inorganic pigments for the ultimate in durability and a true expansion of the durable color envelope.

    The NTP Yellow and RTZ Orange are compatible with a wide range of polymers in coatings and plastics for use in a wide range of applications, such as:

    • Engineering polymers
    • Laminates and co-extrusions
    • Pre-painted coil and extrusion
    • Powder coatings
    • Architectural and façade coatings

    Shepherd Color’s newest addition to their NTP Yellow product portfolio, NTP Yellow 10G155, brings the outstanding color, opacity, and durability that people have seen in NTP Yellow, but in a color shade closer to red-shade bismuth vanadate (PY184) pigments. It has higher heat stability and excellent weathering properties.

    Other key features of Yellow 10G155 include: inertness to acids, bases, solvent and UV, no chromium or lead in the formulation, halogen-free, and non-warping in polyolefins.

    [su_button url=»https://polymer-additives.specialchem.com/news/product-news/shepherd-color-new-ntp-yellow-10g155-000218017?lr=ppa1904484&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ppa1904484&m_i=ImrkxB5xTLos%2BiHrHumRI%2BAxPtHM5LAzwNbqyaBSRLn1U8qAD1wJ4_xX3rnR9ev_BVA%2BLBXRn88tHlMQGNuytSD_C2k9IS» target=»blank» size=»5″]Source[/su_button]

    Read also: Bioplastics Blending and Compounding in Practice

  • INEOS to Acquire Cristal’s North American TiO2 Business from Tronox

    INEOS to Acquire Cristal’s North American TiO2 Business from Tronox

    Transaction of USD 700 Million

    Cristal’s North American business includes two-plants located at the Ashtabula Ohio (US) complex. The deal forms the proposed remedy package submitted to the US Federal Trade Commission (FTC) by Tronox ahead of its proposed acquisition of Cristal’s global titanium dioxide business.

    The proposed sale of the North American business to INEOS, has received support from Cristal and Tronox’s North American customers and will make INEOS the second largest producer of this essential product in the country. The wider transaction and remedy proposal is subject to clearance by the Federal Trade Commission (FTC).

    Opportunity for INEOS to Enter Pigments Market

    Ashley Reed, CEO of INEOS Enterprises said, “This is a great opportunity for INEOS to enter the pigments market, by acquiring a competitive business, with excellent people and assets. INEOS has a strong track record of manufacturing excellence, running its businesses safely and reliably and working closely with customers to meet their growth aspirations.”

    Titanium dioxide is a white pigment found in a wide range of applications from plastics and paper as well as paints and varnishes. It is the most widely used white pigment because of its brightness. Pigment applications include printing inks, fibres, rubber, cosmetic products, glass and ceramics. The global titanium dioxide market is highly competitive, with players competing based on price, quality or product, technical service, and the availability of high-performance pigments.

    [su_button url=»https://polymer-additives.specialchem.com/news/industry-news/ineos-cristals-tio2-tronox-000217695?lr=ipa1903492&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ipa1903492&m_i=rEIP0mTBrQMesbNdAP57lXdusCK7kx8dNvxvSt__g7du%2BGYzIVi43Z3jUXDSktAV3T2onqfmPDXgUFzPmL%2BvnCGPfDHCri» target=»blank» size=»5″]Source[/su_button]

  • Bioplastics Blending and Compounding in Practice

    Bioplastics Blending and Compounding in Practice

    Why should you view this course?

    The main problems of bioplastics, especially biodegradable ones (PHA/PHB, PLA, PVOH, PBS…) are mechanical properties (especially toughness) & thermal resistance. While mechanical properties are relatively easier to achieve, thermal ones continue to be a challenge. And with new bioplastic chemistries available today, you need to understand the problems to foresee solutions.

    Join this course to learn how to improve the properties of your biopolymers:

    1. Select the right polymer to blend with your bioplastic by mapping the various possibilities depending on your material

    2. Formulate bioplastics with enhanced properties (impact, chemical resistance, processability, product uniformity…) by determining confidently the right formulation conditions (use of compatibilizers…)

    3. Mix properly your bioplastics with a structured method to process your compound

    Who should view this course?

    R&D professionals & Compounders needing help to improve their bioplastics performance (at par with or better than traditional plastics)

    Course Outline

    The following sections will be covered in this session:

      1. Bioplastic (biodegradable) blending
        • Bioplastics introduction
        • Polymer selection (PP, PLA/PLB, PHA, PBS, PBAT, PVOH & many more)
        • Properties identification
      1. Bioplastic additivation
        • Impact modification
        • Compatibilizers
        • Plasticizers
        • Cross linkers (Peroxides)
        • Nucleating agents
        • Chain extenders
      1. Bioplastic compounding
        • Micro-rheology
        • Blend Morphology
        • Processing conditions
        • Bioplastic compounds
    1. 30 Mins Q&A session— ask your questions directly to the expert !

    [su_button url=»https://polymer-additives.specialchem.com/online-course/10057-bioplastics-blending-compounding-processing-biopolymers?lr=MC_Mar_19&li=&utm_source=MKG&utm_medium=EML&utm_campaign=MC_Mar_19?lr=MC_Mar_19&li=&utm_source=MKG&utm_medium=EML&utm_campaign=MC_Mar_19&m_i=B6i2baxZu7E%2BsLniPIxXy6H6G7Fp4Yg%2BMyYVYOqmoDmodnoJfHQr_Q%2BAB8TK1lTGYvNcJUJ9rR2YeU15LSL5ofgjyCaNBi» target=»blank» size=»5″]Source[/su_button]

  • Emery Oleochemicals at PVC Formulations 2019: to Showcase Green Polymer Additives

    Emery Oleochemicals at PVC Formulations 2019: to Showcase Green Polymer Additives

    Deliver Outstanding Technical Performance

    This PVC Formulation Conference offers the perfect opportunity for you to discover why Emery Oleochemicals should be your First Choice in Sustainable Polymer Additives.

    Meet with Emery’s technical and industry experts at BOOTH 7 to learn about our best-in-class EDENOL® and LOXIOL® brand renewable solutions recognized for their ability to improve processing efficiencies, deliver outstanding technical performance and enhance environmental safety.

    Plan to attend Emery’s technical presentation by Dr. Sascha Simon, Head Technical Development Center, entitled “Recent developments in natural-based lubricants for PVC processing”, on Wednesday, February 27 at 11:50 am in the Tailoring Properties Session.

    [su_button url=»https://polymer-additives.specialchem.com/news/product-news/emery-oleochemicals-polymer-additives-pvc-formulations-000217215?lr=ppa1902475&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ppa1902475&m_i=WXNWVj9fFOsntKp8CYNXQwg0HQeApBSoYIXEjpQDoI1jYzD_tnD2VzO7h37yvbLpElsAWXNJnJOUBcmHNwRxntrUrSr8Wh» target=»blank» size=»5″]Source[/su_button]

  • BASF Inaugurates Antioxidants Manufacturing Plant in Shanghai

    BASF Inaugurates Antioxidants Manufacturing Plant in Shanghai

    World-scale Plant with a Capacity of 42,000 Tons p.a.

     

    inauguration-BASF

    With this investment, we strengthen our position as the leading global supplier of antioxidants,” said Dr. Markus Kamieth, Member of the Board of Directors, BASF SE. “Asia is the world’s largest antioxidants market and China accounts for almost 65% of the market in Asia. We expect the market will show attractive growth rates in the medium to long term.”

    Unique Expertise in the Chemical Industry

    BASF wants to be the leading chemicals supplier for our customers,” said Dr. Stephan Kothrade, President, Functions Asia Pacific, President and Chairman Greater China, BASF. “By investing in advanced production plants in China, we want to anticipate and fulfill our customers’ needs even better. We will combine our unique expertise in the chemical industry with our customers’ competencies, and jointly develop solutions that are both profitable and responsible.”

    Located at BASF’s Caojing site in the Shanghai Chemical Industry Park, the new plant will benefit from its proximity to BASF’s regional research and development center in Shanghai; a hub that provides technical support to polymer producers across the region.

    Importance of Antioxidants

    • Antioxidants help prevent thermal oxidation reactions when plastics are processed at high temperatures.
    • Oxidation can cause the loss of impact strength, elongation, surface cracks and discoloration of the material.
    • Almost all polymer materials undergo oxidative degradation reactions at one or all of the manufacturing, processing and end-use stages.

    BASF runs a global production network and is the only supplier of plastic additives with production sites in Asia, Europe, North America and the Middle East.

    [su_button url=»https://polymer-additives.specialchem.com/news/industry-news/basf-antioxidants-manufacturing-plant-shanghai-000217113?lr=ipa1901485&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ipa1901485&m_i=iJBhVHaBJkAGRafaDPPTZBj4Xo0ZS4nKJ7LTv70ubknf53Z6jYAsrNFJjNsrvzBUmkpKthK4zcIfmWshF%2BoQU1F2Ux4QiP» target=»blank» size=»5″]Source[/su_button]

  • DCC LANSCO Unveils Bismuth Vanadate Pigment for Polymer Market

    DCC LANSCO Unveils Bismuth Vanadate Pigment for Polymer Market

    Bright Lemon Shade Yellow Pigment

    DCClansco-yellow-pigment

    DCC® Yellow RMXS is a bright lemon shade yellow pigment that was designed to have the highest color strength of any Bismuth Vanadate pigment in the market with outstanding hiding power, exceptional durability and superior dispersibility that can be incorporated into a multitude of coatings systems.

    Because of these key features, this pigment offers maximum value in use requiring less pigment in formulations creating significant cost savings for customers and providing a lower impact on the environment.

    DCC LANSCO is constantly striving to improve pigment technologies to satisfy customer’s needs.

    [su_button url=»https://polymer-additives.specialchem.com/news/product-news/dcc-lansco-bismuth-vanadate-pigment-000217055?lr=ppa1901471&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ppa1901471&m_i=ehGf4pxKKohmk7DLD4P%2BacbZMyNhTE8foeZSUukk9AoUbI13%2Bcet9hVhrdDQftSOulxJWTOSQPw9aZIx0DIjxpRqHDnzes» target=»blank» size=»5″]Source[/su_button]

  • New Method to Prevent Clumping of BNNTs Using Common Surfactants

    New Method to Prevent Clumping of BNNTs Using Common Surfactants

    BNNTs with “Super Cool Properties”

    A dispersion of BNNTs as seen through a microscope shows 
    individual tubes and small bundles separated by a surfactant

    The research led by Rice chemist Angel Martí appears this month in the Royal Society of Chemistry journal Nanoscale Advances.

    BNNTs are like their better-known cousins, carbon nanotubes, because both are hydrophobic – that is, they avoid water if at all possible. So in a solution, the nanotubes will seek each other out and stick together to minimize their exposure to water.

    But unlike carbon nanotubes, which can be either metallic conductors or semiconducting, BNNTs are pure insulators: Current shall not pass.

    They have super cool properties,” said lead author Ashleigh Smith McWilliams, a Rice graduate student. “They’re thermally and chemically stable and they’re a great fit for a bunch of different applications, but they’re inert and difficult to disperse in any solvent or solution.»

    “That makes it really difficult to make macroscopic materials out of them, which is what we would eventually like to do,”
     she said.

    Surfactants Separating BNNTs Effectively

    Surfactants are amphiphilic molecules, with parts that are attracted to water and parts repelled by it. BNNTs are hydrophobic, so they attract the similar part of the surfactant molecule, which wraps around the nanotube. The surfactant’s other half is hydrophilic and keeps the wrapped nanotubes separated and dispersed in solution.

    Of the range of surfactants they tried, cetyl trimethyl ammonium bromide (CTAB) was best at separating BNNTs from each other completely, while Pluronic F108 put the most nanotubes – about 10 percent of the bulk – into solution.

    Once separated, they can be turned into films or fibers through processes like those developed by co-author Matteo Pasquali and his Rice lab, or mixed into composites to add strength without increasing conductivity, McWilliams said. The surfactant itself can be washed or burned off when no longer needed, she said.

    A side benefit is that cationic surfactants like CTAB are particularly good at eliminating impurities like flakes of hexagonal boron-nitride (aka white graphene) from BNNTs. “That was a benefit we didn’t expect to see, but it will be useful for future applications,” McWilliams said.

    Boron Nitride Nanotubes: The Great Building Block

    Rice University graduate student Ashleigh Smith McWilliams 
    holds a vial of boron nitride nanotubes in solution

    “Boron nitride nanotubes are a great building block, but when you buy them, they come all clumped together,” Martí said. “You have to separate them before you can make something usable. This is what Ashleigh has achieved.”

    He envisions not only ultrathin coaxial cables with carbon nanotube fibers like those from Pasquali’s lab surrounded by BNNT shells, but also capacitors of sandwiched carbon and BNNT films.

    Enhanced Electronics with Insulating BNNTs

    We’ve had metallic and semiconducting carbon nanotubes for a long time, but insulating BNNTs have been like the missing link,” Martí said. “Now we can combine them to make some interesting electronics. It’s remarkable that a common surfactant found in everyday products like detergents and shampoo can also be used for advanced nanotechnology.”

    Co-authors of the paper are Rice graduate student Carlos de los Reyes and undergraduate student Selin Ergülen; graduate student Lucy Liberman and Yeshayahu Talmon, professor emeritus of chemical engineering, at Technion – Israel Institute of Technology; and Pasquali, a Rice professor of chemical and biomolecular engineering, of materials science and nanoengineering and of chemistry. Martí is an associate professor of chemistry, of bioengineering and of materials science and nanoengineering. 

    The National Science Foundation, the Air Force Office of Scientific Research, the U.S.-Israel Binational Science Foundation and the Welch Foundation supported the research.

    [su_button url=»https://polymer-additives.specialchem.com/news/industry-news/separate-bnnts-composites-surfactants-000216925?lr=ipa1901482&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ipa1901482&m_i=he3hM0eOVtnZC4G8bMS5n8bmAW8wIo1DaiEozBU7NO4zDcMGeBmiajfaHlcsj8TGxi4jqvj7pmsbuDNwU4Z6EkoeTrDxh5″ target=»blank» size=»5″]Source[/su_button]

  • New Catalysis Concept to Obtain Polyester from Castor Oil

    New Catalysis Concept to Obtain Polyester from Castor Oil

    The development of future technologies that are not based on mineral oil and can be used for producing chemicals and plastics is one of the major tasks in modern materials science and a key challenge that needs to be addressed if sustainable industrial production is to have a future. 

    Synthetic Polyester from Plant Oil Feedstock

    A range of theoretical concepts and laboratory processes must be devised and tested to resolve challenges and problems arising in connection with the natural materials before potential applications for materials obtained from renewable resources can be probed. 

    One such concept has just been described by Professor Stefan Mecking in a current study on obtaining polyester from castor oil entitled “Synthetic Polyester from Plant Oil Feedstock by Functionalizing Polymerization” in the journal “Angewandte Chemie”.

    With his colleague Dr Ye Liu, an Alexander von Humboldt Fellow and the first author of the study, Stefan Mecking presents a new way of obtaining polyester from fats and oils, more specifically, from castor oil. A well-known and chemically established building block that can be obtained from castor oil is Undecenol. 

    Our idea was to interlink many of these molecules to form one large molecule, a plastic molecule. We wanted the whole process to be effective and readily accomplishable ‘in one go’”, Stefan Mecking elaborates. 

    Suitable Catalysts to Create Polyester Effectively

    Undecenol has a group of alcohols at one end of the molecule and a double bond at the other. It was decisive to interlink these two groups to form an ester group in such a way as to enable simultaneous linkage with long-chain molecules, i.e. plastics. Such long-chain bonds are required to obtain the desired material properties. One of the major general challenges in regard to these procedures is to identify suitable catalysts. 

    They are especially important because the reaction leading up to the formation of the desired long-chain molecules must be incredibly effective and proceed without any variance”, explains Stefan Mecking.

    For the production of polyester as described in their study, the chemists used carbonylation to obtain the ester groups. “The problem is that Undecenol reacts with another smaller molecule, an aldehyde. If this happens, it does not become part of the molecule chain, which means that it gets lost”, says Stefan Mecking, summarizing the gist and great success of his research. 

    By using suitable catalysts, the researchers were able to prevent this loss and to create polyester effectively. While developing the catalysts, they also worked out the conceptual steps required for adjusting the melting point of the products. “Due to the insights we gained, we should be able to infer how to handle the melting points of other long-chain substrates”, concludes Stefan Mecking, alluding to potential transfer applications of his concept for other renewable resources that are even more readily available than castor oil.

    [su_button url=»https://polymer-additives.specialchem.com/news/industry-news/new-catalysis-concept-polyester-castor-oil-000216856?lr=ipa1901481&li=70111412&utm_source=NL&utm_medium=EML&utm_campaign=ipa1901481&m_i=8UYRi6Nve85NfrVS4T7AxwkGLIyr%2B7thptOnLreD4eBIFR_7rJ2HA9XmIdz2g%2BF4m1s2HhGsTiJQg6JH6AMqbSiH0ztQ8Q» target=»blank» size=»5″]Source[/su_button]

  • Medical Plastics: Innovations & Opportunities

    Medical Plastics: Innovations & Opportunities

    Why should you attend?

    Plastics now represent the largest group of materials used in medical technology. Strong market drivers continue to support its constant penetration and may require new technologies: growing use of disposable medical products, increasing demand for bacteria-fighting surfaces, adoption of implantable applications…

    1. Save time with a structured overview of recent advances in innovative materials & application developments for next generation of medical plastics
    2. Identify opportunities to grow into medical plastics market with PEEK, PP, PVC, ABS, PE, PS, thermoplastics, nanotubes, shape memory polymers…
    3. Speed up your future R&D decisions with a clearer view on material requirements, technology adoption & unmet needs
    4. Feed your creativity by seeing successful / promising innovations (thanks to low cost, new designs…) & imagine whether it could be transposed to your own case

    Boast about your Skills- Get a participation certificate on joining the Live Online Course !

    Who should attend?

    R&DSales & Marketing as well as Executive managers… involved in technical & market watch, NPD/ innovation, business development.

    Course Outline

    1. Opportunities for Plastics in Medical Applications 
          • Medical Plastics Applications Market Drivers 
          • Certification and Legislation 
          • Medical Plastics Technology Trends
    2. New Material Opportunities in Medical Applications 
          • Protective Additives and Coatings 
          • Bioresorbables and Biocompatibles 
          • High Purity Medical Plastics 
          • Engineered & High Performance Plastics
    3. Medical Plastic Material and Process Developments 
          • Recycled Medical Waste Plastic 
          • Medical Microfibers and Yarns (Biotextiles) 
          • Medical Plastics Welding 
          • Automation in Medical Plastics
    4. Plastics in Medical Applications 
          • Implantable Devices and Drug Delivery Systems 
          • Fluid Administration and Collection 
          • Other Disposable Medical Devices 
          • Metal Replacement in Medical Applications 
          • Other Durable Medical Devices
    5. Future Plastics Opportunities in Medical Applications
    6. Major Plastics/Medical Players and Related References
    7. 30 Mins Q&A— Ask your questions directly to the expert !