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KRAIBURG TPE Targets Sustainable TPE and Innovative Automotive TPE Solutions at T-PLAS 2023

KRAIBURG TPE Targets Sustainable TPE and Innovative Automotive TPE Solutions at T-PLAS 2023

KRAIBURG TPE has launched its new sustainable TPEs comprising of up to 48% PCR and 50% PIR recycled content. Together with its latest automotive TPE solutions, the company is set to impress in the T-PLAS 2023 Exhibition from 20 until 23 September at Hall 102, Booth no. Q15, BITEC Bangkok.

KRAIBURG TPE, a global TPE manufacturer of thermoplastic elastomer products and custom-engineered TPE solutions for a wide range of industries and applications, is set to present its sustainable TPE series and automotive innovative TPE series for the Asia Pacific market at the show.

High demand for more sustainable materials

More manufacturers are now incorporating sustainable materials into their products to meet increasing consumer demand for sustainable products. These have recycled content, are recyclable, or are produced with renewable materials. In a market saturated with new materials, thermoplastic elastomers (TPE) excel in meeting both the high-performance and sustainability criteria of manufacturers in contributing towards a more circular and sustainable economy.

Additionally, the rapid development of the automotive market has driven higher demand for new innovative materials, specifically in performance and vehicle aesthetics – providing solid support to automotive manufacturers via the latest TPE innovations in this competitive market.

New Sustainable TPE for food contact, consumer electronics and industrial applications

KRAIBURG TPE’s latest sustainable TPE series for the Asia Pacific targets the consumer electronics, wearable, consumer, and industry markets. The sustainable TPE series comprise up to 48% post-consumer recycled (PCR) and 50% post-industrial recycled (PIR) contents.

Furthermore, the series feature good adhesion to PP, PC and ABS with non-sticky surface, good mechanical properties, and temperature stability up to 80°C. It also complies with multiple global standards such as FDA raw material compliance, RoHS and REACH SVHC requirements. It is ideal for applications such as electric and electronic components, wearables, functional and design elements, connectors, cable clips, household articles, grip applications, toothbrushes, and more.

Innovative TPE for Automotive interior and new sustainable TPE for Automotive exterior market.

KRAIBURG TPE will showcase its latest Asia Pacific targeted TPE innovations for both interior and exterior automotive applications. The innovative sustainable automotive exterior TPE has a post-consumer recycled content of up to 20%, while the automotive interior TPE delivers good surface appearance and more.

Both TPEs series feature good adhesion to PP, low density, weather resistant, good flowability, controlled level of emission and odor, and more. This innovative automotive TPE series is ideal for applications such as cowl gaskets, window encapsulations, underbody applications, handles, functional and design elements, car mats, seals, grommet and more.

TPEs for diverse markets

KRAIBURG TPE’s comprehensive TPE portfolio offers innovative and customized solutions that meet the unique demands and specifications of each market. It provides reliable, high-performance materials to enhance products and experiences for numerous applications such as medical, healthcare, packaging, sports, and so forth.

Their commitment to quality, innovation, and customer satisfaction has established them as a trusted partner in delivering high-performance thermoplastic elastomer for a wide range of applications.

www.kraiburg-tpe.com

 

 

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SABIC Offers Bio-Based Versions of All NORYL Resin Grades to Further Advance the Bioeconomy of Plastics

SABIC Offers Bio-Based Versions of All NORYL Resin Grades to Further Advance the Bioeconomy of Plastics

SABIC, a global leader in the chemical industry, is now offering bio-based versions of all NORYL, Flexible NORYL, NORYL GTX and NORYL PPX resin grades to help customers meet increasingly rigorous sustainability goals. The bio-based versions, formulated with polyphenylene ether (PPE) resin feedstocks certified under International Sustainability & Carbon Certification (ISCC) PLUS, provide properties similar to those of fossil-based grades. Customers may select from multiple levels of bio-based content for their chosen NORYL product.

To demonstrate the feasibility of this bio-based approach, SABIC has proactively commercialized three popular NORYL grades; however, these example materials represent only a small percentage of the full offering. The availability of bio-based versions broadens the choice of environmentally responsible NORYL resins beyond the company’s recently introduced post-consumer recycled (PCR)-based materials containing more than 25 percent PCR content.

“We’re pleased to provide customers with new choices to reduce the global warming potential of both existing and new applications made with NORYL materials,” said Joshua Chiaw, director, Business Management, LNP & NORYL, Specialties, SABIC. “Bio-based PPE feedstocks enable SABIC to efficiently produce sustainable NORYL materials that can serve as drop-in replacements for traditional grades – with equivalent performance and processability. Expansion of our NORYL resin portfolio with bio-based versions is a key part of our strategy for helping brands, OEMs, tier suppliers and molders achieve their sustainability goals.”

Example Bio-based NORYL Grades

The following bio-based products are available now. Customers wishing to order bio-based versions of other NORYL, NORYL GTX, Flex NORYL or NORYL PPX materials should contact their SABIC representative.

NORYL NH5120BIO4 resin is well suited for evaluation in housings and enclosures, heating/ventilation/air conditioning (HVAC) components and photovoltaic/solar junction boxes. It is a bio-based, non-brominated/non-chlorinated flame-retardant resin with a UL flame rating of V1 at 1.5mm with no intentionally added per- and polyfluorinated substances (PFAS). NORYL NH5120BIO4 resin delivers a balance of heat resistance, flow, hydrolytic and dimensional stability, and creep performance, and retains its good mechanical properties in harsh outdoor environments.

NORYL GFN2BIO3 resin features high strength, hydrolytic and dimensional stability, low warpage and low specific gravity. This bio-based material carries a UL746C outdoor suitability rating of F1 and is an excellent candidate for indoor and outdoor applications in the building & construction and lawn & garden industries.

NORYL GTX902BIO3 resin is a bio-based PPE alloy that provides excellent chemical resistance and paintability for potential use in applications such as automotive wheel covers, automotive electrical components and painted automotive trim.

ISCC PLUS Certification of Feedstock Production Facility and NORYL Materials

“Our Selkirk, New York, facility was one of the first production and compounding facilities to receive ISCC PLUS accreditation for the production of PPE resin and compounds based on renewable, bio-circular sources,” said Evelyn Pearson, senior manager, Process Technology, Technology & Innovation, Specialties, SABIC. “We plan for NORYL grades formulated with these bio-based feedstocks to be certified under ISCC PLUS at Selkirk and other global NORYL compounding plants. This achievement underscores SABIC’s commitment to building a circular plastics industry.”

www.sabic.com

 

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Lindner Micromats Helps Unifi, Inc. Transform Plastic Waste into High-Tech Recycled Fiber

Lindner Micromats Helps Unifi, Inc. Transform Plastic Waste into High-Tech Recycled Fiber

Of the 400 million tons of plastics produced worldwide each year, too much still ends up in our waterways and landfills. Unifi, Inc., the world’s leading manufacturer of high-performance synthetic and recycled fibers, has decided to tackle this global problem. They collect used plastics, primarily post-consumer PET bottles, and transform them into REPREVE, a high-performance recycled fiber. Three shredders from Lindner’s Micromat series work 24/7/365 to ensure that the plastics are optimally shredded for the downstream processes.

The topic of plastics recycling has received a tremendous amount of media attention recently. Higher recycling rates, improved collection systems and more efficient processing facilities ensure that plastic waste is recycled and repurposed. Yet, there is much work left to be done and much plastic still goes unrecycled. Unifi, the world’s leading manufacturer of recycled high-performance fibers, is making a difference. To date, the company has transformed 35 billion plastic bottles into its proprietary REPREVE recycled fiber. Unifi’s process ensures that plastics are returned to the consumer goods cycle as a valuable raw material and promotes a more circular and sustainable economy.

When Unifi was looking for a reliable partner to set up an efficient shredding process in 2018, they chose shredding solutions from Lindner. Today a total of three Lindner Micromat 2000 prepare plastic and textile waste for its journey to extrusion, spinning and finally winding the fibers used by some of the world’s best-known brands, such as Williams-Sonoma Inc., Levi’s, and Toms Shoes. Scott Trivette, Operations Manager of the Repreve Recycling Centre and Future Innovation Centre in Yadkinville, North Carolina, describes the relationship with Lindner as “a great partnership, which we require because of our 24/7/365 operating model. A provider who can only be there for us between 9 a.m. and 5 p.m. just doesn’t work for us. We need answers within hours, not days, and Lindner with its hub in Statesville, NC is always there for us.”

A Question of Performance

The Lindner shredders from the Micromat series are specially designed for the requirements of post-commercial and post-consumer plastics recycling. They have strong, high-torque motors for powerful shredding and are designed and built to optimize uptime and streamline maintenance tasks. “The lightning-fast safety clutch offers optimum machine protection and easy access to the rotor means that non-shreddables can be removed quickly and easily,” Trivette states. He continues that Unifi found the perfect solution in Lindner’s technology and service: “Lindner’s machines have enabled us to minimize downtime and maximize the throughput of the entire plant, which is essential with an average production of 1.5 million pounds of resin per week.”

www.lindner.com

 

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“Chemical Recycling is Competing With Incineration, Not Mechanical Recycling”

“Chemical Recycling is Competing With Incineration, Not Mechanical Recycling”

Industry-Interview with Ingemar Bühler, Managing Director PlasticsEurope Germany

Mr. Bühler, how long will it be before chemical recycling can take place on a large industrial scale?

At present, there are about 140 chemical recycling projects worldwide. Most of the active plants are currently in pilot operation. Some companies, however, are already one step ahead. In Enningerloh, Westphalia, for example, the Carboliq company has a plant that produces an industrially usable pyrolysis oil from the input of an adjacent recycling yard. Other plant projects are also on the verge of reaching a new scale of between 40,000 and 150,000 tonnes of processed material per year. Two plants are currently planned on a large industrial scale. Lyondell Basell is planning a large plant in Belgium, and Dow Chemical is looking to build a large plant together with its partner Mura in Saxony. The prerequisite, however, is the approval of chemical recycling within EU law.

Should this be the case this year, then the plant would probably be ready for operation by 2025.

This approval is by no means certain in Brussels, however.

The reproval by politicians, both in Europe and in Germany, is often that chemical recycling does not work at all. That is simply nonsense. But there is also a fair criticism, namely that despite great progress, the energy input for chemical recycling is much higher than that for mechanical recycling.

Mechanical recycling is highly efficient: PET bottles, for example, can be mechanically recycled several dozen times until the polymer structures can no longer withstand further use.

In today’s legislation, the idea is to burn these polymers that are past their usability stage, and to generate energy from them. However, the cost of incineration is high, and the process releases CO2. Instead of incineration, it would be much better in our view to chemically recycle these polymers. In the best case, no CO2 is released, and the carbon continues to circulate. Chemical recycling is therefore not in competition with mechanical recycling, but with incineration.

Where else does it make sense?

With chemical recycling processes, we can also process waste fractions where mechanical recycling processes reach their limits. A good example is car tyres. We can already recycle parts of tyres mechanically, but we can apply complementary chemical processes to recover the carbon and keep it in the cycle. In our industry, we are therefore convinced that this will definitely happen. If we politically hamper chemical recycling in the EU, it will happen elsewhere in the world, but I am confident that eventually we will have chemical recycling in Europe as well.

What makes you so confident?

The strict separation and interest groups are softening. It is no longer just the plastics manufacturers who are investing in chemical recycling. Increasingly, it is also large mechanical recyclers. In turn, there are also chemical companies building mechanical recycling plants because they want the carbon back in both ways. It is becoming increasingly clear that the combination makes perfect sense if you want to get rid of the big waste mountains and establish a real circular economy.

However, many mechanical recyclers currently still fear competition for input streams.

My fear as a medium-sized mechanical recycler would not be that someone might build large chemical recycling plants and buy waste fractions away from me. My fear would be that someone with sufficient investment power might build mechanical plants that are much more efficient, or that are directly competing with mine, and I’m pretty sure that will happen. I think that’s a worry you can’t take away from any company. Herein lies the task for the political arena to set the right guidelines. Put simply, that would mean that everything that can be mechanically recycled must be mechanically recycled for as long as possible.

Fractions that cannot be mechanically recycled must be fed into other processes in order to keep the carbon within the cycle for as long as possible; then you are actually on the safe side. That’s all politics needs to regulate in the open market.

What should politics do and what should it not do?

It should seize the opportunity to lead the entire plastics system into a climate- neutral circular economy. Many of the technologies necessary for this, which are all already there, are not welcomed by politicians in many quarters. Our political culture – especially in Germany – does not welcome innovation. Instead, people focus on safety, on caution and things they know. But the transformation of the plastics industry, like other transformations, is a large venture. Politics must not slow down this change, it must accelerate it instead. And therefore, it must welcome innovation. The plastics bashing must stop. There is a good reason why plastic consumption continues to rise, namely because we can make many products more sustainable and recyclable. Major mistakes have been made in the past. We allowed plastic waste to be landfilled, and at the same time we have developed waste collection and sorting systems much too slowly. We could and should regret this, but along with that we should now turn the lever towards sustainability. The political rejection of plastic is not the path towards a climate-neutral circular economy.

www.vdma.org

 

 

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Design, Innovation, Sustainability: KURZ Set to Show Pioneering Design Concepts with a “Wow” Factor at the IAA Summit 2023

Design, Innovation, Sustainability: KURZ Set to Show Pioneering Design Concepts with a “Wow” Factor at the IAA Summit 2023

The IAA Summit 2023 is the most important international B2B platform for the automotive industry. The event will take place from September 5 to 8 as part of IAA MOBILITY 2023 at the Munich exhibition center. Leading automobile manufacturers, suppliers, and technology companies come together here to present the next generation of vehicles and mobility concepts.

Electromobility, autonomous driving, networked vehicles, and sustainable mobility – in no other industry is the transformation as great as in the automotive sector. LEONHARD KURZ is helping to shape this change and making innovative, sustainable brand statements tangible at the trade fair. Under the theme ‘empowering beautiful surfaces,’ the thin-film specialist from Fürth will be showing innovative solutions for decorative and functional surfaces from the Exterior and Interior Design, as well as Visionary Design segments, in Hall A2 (Stand C32). A special focus is placed on the aspect of sustainability. At the IAA Summit, KURZ will demonstrate how innovative decoration technologies can reduce the carbon footprint.

RIM Design.

Smart exhibits experienced interactively

An absolute eye-catcher at the KURZ stand is a rear-end cover concept, which consists of an innovative 2K material mix and is equipped (via in-mold electronics) with technical features such as smart touch functionality and Shy Tech design. The rear-end cover not only meets all the requirements that currently determine the market – especially regarding e-mobility – but also illustrates development opportunities. At the same time, the concept sets an example in terms of sustainability, as the large component (dimensions: W 85.29 cm x H 25.27 cm x D 7.7 cm) is manufactured in one production step to save CO2. It can also be recycled as a whole. The concept supports all technologies required for autonomous driving and communicates with other road users using backlighting and 3D light effects. The exhibit, which was developed together with the KURZ subsidiaries BURG DESIGN, PolyIC, and SCHÖFER, is displayed in front of a large screen, and visitors can explore all the highlights such as day/night designs or touch operation live. Haptics, lighting, and optics combine to create an extraordinary mobility experience.

With a combination of physical exhibit and screen presentation, KURZ is showing not only the rear-end cover but also an innovative front cover that follows the trend towards closed surfaces. The design concept for e-mobility models demonstrates the design possibilities that arise from laser engraving. The front panel on display was made translucent using a laser, for example. Further decoration options and variants – including day/night designs as well as different colors and animations for actions such as indicating, braking, or recharge – will be demonstrated digitally. Backlighting effects are not only used for brand identification, but also for communication with other road users. The front cover can be equipped with an extremely resistant, self-healing DECOPUR surface. Combined with a crystalline high-gloss finish, this creates a spectacular 3D effect. A special highlight is that the one-of-a-kind creations are backed up on the blockchain via NFT in cooperation with KURZ DIGITAL. A limited number of NFT Design Artworks will be handed out to customers at the stand.

The PC-based front end, which can be recycled as a complete component, was implemented using the most advanced IMD technology and injection molding tools from the specialist for plastic-based modules, Samvardhana Motherson Peguform (SMP).

Ready for the new requirements of e-mobility

Smart touch operation, Shy Tech, and partial backlighting are features that can also be found in KURZ’s innovative wallbox charging station. The charging station for electric vehicles, developed in cooperation with BURG DESIGN and PolyIC, offers a wide variety of customer-specific designs by using various finishing processes. In addition to a functional exhibit customized with laser technology, the KURZ stand will also feature an augmented reality demonstration of the product concept. Visitors can select different designs and finishing techniques live at the stand and then receive a virtual representation of the individualized wallbox in the relevant environment. The e-dispenser can be made from post-consumer recycled material and is, in turn, also 100 percent recyclable.

With the transition to electromobility, the requirements for components such as tires and wheels are also changing. At the IAA Summit 2023, KURZ will be showing a revolutionary project example in cooperation with wheel manufacturer Ronal Group. The aerodynamic rim insert combines art and automotive design and can already be mass produced. Thanks to 3D hot stamping decoration, curved shapes can be perfectly decorated. The (plastic) inlay in combination with the wheel and design ensures lower air resistance. This in turn not only ensures a lower noise level, but also enables more efficient aerodynamics, which leads to a better range especially for e-vehicles.

Collaborative project with Swarovski Mobility

KURZ demonstrates what it can look like when luxurious design and cutting-edge technologies merge, with a futuristic steering wheel concept created in collaboration with Swarovski Mobility. On the side of the centrally positioned display, there are precious real crystals which, thanks to integrated sensors from PolyIC, enable various vehicle functions to be controlled. Despite the integrated sensor technology, the surface is completely transparent, anti-reflective, scratch-resistant, and easy to clean. The high-grade crystals can also be used to create three-dimensional surfaces. They are backlit, can be color-coordinated with the interior of the vehicle, and create breathtaking visual highlights.

Surfaces and light as a unit

The days of unwanted light scattering and blurring in lighting design are finally over. In cooperation with Mentor, the specialist for integrated lighting solutions and HMI components, KURZ is presenting dynamic and true-color lighting design at its stand, which can be adapted to a brand’s Corporate Identity (CI) with full color fidelity. Four interactive light panels, which visitors can control using an iPad, show a variety of design options such as day/night moods, dynamic light, and countless colors and patterns.

Visionary Design: Inspiration and experimentation

Under the umbrella term ‘Visionary Design,’ KURZ will be showcasing extraordinary inspiration in terms of haptics, appearance, and functionality. True to its name, the Spacewood Experiment project merges wood and space and goes beyond anything previously associated with wood. Completely rethinking the natural material is definitely a bold venture. The exhibited designs appear to be from a different world. Their structure is largely reminiscent of wood, but they are made of 100 percent post-consumer and post-industrial recycled materials, and are themselves recyclable.

The ‘Naturals’ project, developed together with BURG DESIGN, takes a very similar line. The material boasts impressive designs inspired by nature. At the same time, it offers significantly greater flexibility in terms of design and functionality. Natural Designs are ideal for creating natural interior designs in vehicles. This can include amazing 3D shapes with backlighting and fascinating touch effects. This decor can also be equipped with KURZ BIOFENSE hygiene protection.

 

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“Chemical Recycling is Still in Its Infancy, But Has Huge Potential”

“Chemical Recycling is Still in Its Infancy, But Has Huge Potential”

Industry Interview with Jochen Schofer, Head of Sales of the Recycling Business Unit at Coperion GmbH

Mr. Schofer, what contribution can chemical recycling make to the circular economy?
In principle, it can make a big contribution. But it only works properly together with mechanical recycling. And it will only work if the circular economy is accepted not just in Germany or Europe, but throughout the world. In many parts of the world however, there are still either only fragmented waste collection systems, depositing systems and similar systems, or none at all, that are able to generate a sufficient waste stream for recycling. At the moment an increasing number of large corporations are jumping on the chemical recycling bandwagon, all of them operating internationally. There is hope that they will contribute considerably towards the implementation of the necessary infrastructure in all parts of the world.

Chemical recycling has huge potential. The results that have been achieved so far are very promising. Nevertheless, chemical recycling is still in its infancy, while mechanical recycling is already established. Chemical recycling has particular potential because there are many plastics that cannot be processed mechanically, and more and more will be added. For example, in the construction sector, think of the many mixed plastics that are released when a house is demolished, or in the automotive industry. That is precisely why chemical recycling has to make a big contribution to the circular economy.

In which areas is chemical recycling superior to mechanical recycling? The major advantage of chemical recycling over mechanical recycling is that it can be used to recycle all types of plastic. You no longer need a single type of material stream, as you do with mechanical recycling – for example, only polyethylene or polypropylene. Chemical recycling can also be used to recycle

composites. However, the prerequisite is that you have a large material stream, because only then can the process be operated economically. Some large plants for chemical recycling with throughputs of up to 25 tonnes per hour are already being planned.

Which recycling method does the machine manufacturer Coperion primarily rely on?
As a machine builder, we have made it our goal to support the plastics industry as best we can on its path to a circular economy. We develop solutions for chemical recycling, mechanical recycling, and even for many other processes, such as solvent-based recycling. Here, two different polymers are separated from each other, and the solvent is degassed in the extruder. We offer technologies for processing all plastic material streams, for well-sorted as well as poorly sorted ones. But the question is whether you put the energy into pre- sorting or, in the case of chemical recycling, into processing the oil quality afterwards. Because the worse the product to come out of the reactor, the more processing it requires. Here, too, it’s all about economic efficiency in the end.
Because the chemical recycling process is very energy-intensive, it is advisable to focus more on the upstream steps in the case of high throughputs. For smaller plants, it may also make economic sense to invest in processing the recovered oil.

Were there any technological challenges?
As pioneers in processing technology for virgin plastics, we have modified our product range in such a way that we can also serve the recycling market with innovative solutions. In recycling, we deal with contaminated materials, low bulk weights or high moisture contents. Therefore, we have made many developments, adjustments and optimisations to our technologies. Especially for chemical recycling, for example, we have developed a new technique that makes it possible to reliably degas chlorides directly in the extruder.

Will the waste problem be solved through the circular economy?
Both systems, mechanical and chemical recycling, are not silver bullets. Both make a great contribution to solving our waste problem, but much more needs to be done. Above all, product design should completely avoid poorly recyclable plastics. Because if more and more poorly recyclable plastics enter the market, they threaten to end up being burned instead of recycled. A great contribution would therefore be to simply not produce and use the poorly recyclable plastics in the first place. That should be our first goal for a functioning circular economy.

www.vdma.org

 

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The Full Range of Advanced Masterbatch Technology

The Full Range of Advanced Masterbatch Technology

Tosaf will be presenting their latest developments in masterbatches for applications ranging from agricultural films to rigid and soft packaging and technical parts on stand B4-4402 in hall B4. For example, Tosaf’s new additives for contour-sharp laser marking are also suitable for transparent plastics in a wide range of applications. Also in focus are a new masterbatch carrier system with approval for direct food contact as well as masterbatches to produce light-diffusing elements, for example for covers of LED lights. Adapted to growing sustainability requirements are blowing agents for foamed plastics that help to reduce the ecological footprint, as well as colour and functional masterbatch solutions for compounds containing recycled materials.

Contour sharp marking with the laser beam

A new laser additive family from Tosaf can be used for transparent applications without affecting the optical properties. It enables contour-sharp, high-contrast markings on thermoplastics that originally show poor or no colour change during laser marking, as well as on compounds with fillers such as calcium carbonate, talcum, titanium dioxide or carbon black. Depending on the substrate, optional settings for marking colours ranging from white to grey to black are possible. Since very low dosages are sufficient and the laser marking process can be fully automated, the new masterbatches help to reduce production costs compared to conventional processes such as labelling or embossing. By eliminating the need for chemicals, varnishes or stickers, their use is also non-critical and more sustainable. Typical applications include pipes, fittings, profiles and irrigation systems as well as, thanks to their suitability for food contact, caps and closures for beverages and other food packaging. Customised combi-masterbatches are also possible.

Food compliant masterbatch carrier system

A new universally applicable masterbatch carrier system from Tosaf Color Service meets all common food contact requirements, including those in Germany, the USA and China. Masterbatches based on this carrier system can thus be used without hesitation across continents for applications ranging from translucent and opaque materials for rigid and flexible packaging, toys and household items to components for food processing machinery and equipment.

Light diffusing Masterbatches

To achieve uniform light distribution even with point-shaped LED light sources, Tosaf Color Service has developed light diffusing (LD) masterbatches that contain microfillers. Even very small amounts in the range of 1 to 2 % result in highly efficient scattering of light in originally transparent material, mainly polymethyl methacrylate (PMMA) and polycarbonate (PC). The light transmission and mechanical properties of the base material are almost completely retained. Both colour-neutral grades and combinations with specific colours and functional additives such as UV stabilisers are available.

Sustainability in mind

In the spirit of the circular economy, Tosaf has developed colour masterbatches specifically for recyclates, with a focus on post-consumer plastics. They compensate for origin-related inconsistencies that are typical for such materials. A special additive masterbatch range from Tosaf is based on biodegradable carriers such as polylactic acid (PLA) and resin (rosin) and gives corresponding agricultural films properties such as increased UV stability, anti-fogging and IR filtering.

Also geared towards sustainability in plastics processing are chemically active blowing agents that Tosaf has developed for the material-saving foaming process. The portfolio includes endothermic and exothermic types for a wide range of thermoplastics. Endothermic grades are considered safe to use, are approved for food contact and generally require relatively low temperatures for activation. Their applications range from thin-walled films and moulded parts with high surface quality as well as PP tapes to XPS and XPE trays for food packaging and large and thick-walled parts. The exothermic grades combine a high foaming effect with very good dispersibility. Exothermic and endothermic blowing agents combined in one concentrate are particularly suitable for PVC applications such as sheets, profiles and pipes.

Beyond colour and foaming agents, Tosaf’s portfolio includes other additives that can contribute to greater sustainability, including antioxidants, moisture and odor absorbers, processing aids and chain extenders.

www.konsens.de

 

 

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Lightweight But With a Substantial Effect

Lightweight But With a Substantial Effect

  • Krones wins German Packaging Prize in the “Sustainability” category
  • The jury gave the accolade to the ShoulderFlex bottle weighing a mere 5.9 grams

5.9 grams – The extremely low weight of the ShoulderFlex bottle was the deciding factor for this year’s jury of the German Packaging Prize in the “Sustainability” category. That is because the ShoulderFlex makes a crucial contribution towards reducing the carbon footprint of water bottlers by yielding material savings of up to 50 per cent compared to conventional 0.5-litre water bottles on the market.

Krones’ revolutionary bottle design can be used to make containers that are sustainable and weigh very little, but its advantages are also apparent during the bottle production and processing stages. The bottles have excellent stackability even without the stabilising effect of nitrogen pressurisation, with a filled topload of up to 40 kilograms.

“One of the key messages in Krones’ vision is the responsible use of packaging materials. And that includes developing sustainable packaging solutions that are not only resource-economical but also practicable. ShoulderFlex meets those requirements in full,” explain Martin Loistl and Jochen Forsthövel, both members of the development team. “Despite the smaller amounts of PET needed to produce them, these containers are in no way inferior to conventional bottles currently on the market as far as stability and convenience are concerned.”

www.krones.com

 

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Chemical Recycling of Polycarbonates Reaches a Major Milestone

Chemical Recycling of Polycarbonates Reaches a Major Milestone

  • Robust process developed on a laboratory scale
  • Pilot-scale technical implementation starts
  • Recycled monomer can be used for the production of polycarbonate

Covestro has developed an innovative process for recycling polycarbonate, i.e. polychain plastics. In this process, plastics are converted back into their monomers, a precursor of plastics, so that they can be fed back into the production process as alternative raw materials. At Covestro in Leverkusen, the technical implementation of chemical recycling is now beginning on a pilot scale. On the way to industrial scale, the process is still being optimized and is undergoing further development stages.

“As a manufacturer of plastics such as polycarbonate, we naturally have a responsibility in dealing with these important materials, including at the end of their product life. Our advantage is: we know how our products are designed and can therefore conduct targeted research into recycling solutions,” says Dr. Thorsten Dreier, Covestro’s Chief Technology Officer. “The chemical recycling of polycarbonate is another example with which our colleagues in development show that closed cycles are possible in the future. We need to use end-of-life plastics as a resource and reuse them as alternative raw materials to close the loop.”


The return of plastics through recycling replaces primary fossil raw materials in production. Comprehensive recycling thus contributes to climate neutrality and the protection of natural resources and the environment. Mechanical recycling of polycarbonate is already an important component of Covestro’s recycling strategy. The mechanical recycling process is used whenever waste streams are sufficiently pure and the recycled polycarbonate meets the requirements profile of the future application.

Chemical recycling works in a complementary way to mechanical recycling – it converts plastic building blocks back into monomers, i.e. their individual building blocks. These can be separated and serve as raw materials for future plastic. Chemical recycling can therefore make larger waste streams that are unsuitable for mechanical processes in particular accessible for recycling; it allows the production of plastics that meet the highest quality requirements. Covestro is therefore actively developing chemical recycling.

Chemolysis can directly close the polycarbonate cycle

The newly developed process, which was driven by an international team, is a specific chemolysis process adapted to polycarbonate. “Pre-sorted waste streams containing a product content of more than 50 percent polycarbonate can be recycled this way. This has been successfully demonstrated with various polycarbonate-containing plastic waste streams,” explains Markus Dugal, Head of Process Technology at Covestro. “With the help of this chemolysis, the cycle can be closed to a direct precursor of polycarbonate. This makes the recycling process very sustainable.”

Direct use of recycled product as raw material possible

The recycled product, a precursor of polycarbonate, can be mass-balanced and reused as a raw material for the production of polycarbonate without further processing. “Such high-quality recycled raw materials are needed for applications that require top quality. These include, for example, applications in the automotive sector with special requirements in terms of safety, optical transparency or aesthetics, and products in our everyday lives such as consumer electronics,” says Lily Wang, Head of the Engineering Plastics Business Entity.

Millions of euros will be invested

Following successful development in the laboratory, the next stage of development, the technical implementation of a continuous process, has already started. A pilot plant, which is currently in the planning stage, will be used to gather the experience needed for further expansion to industrial scale. Millions of euros will be invested in this over the next few years. The pilot plant will be built in Leverkusen, Germany.

At the same time, Covestro is driving forward further processes for innovative recycling of polycarbonate in its research laboratories. These include chemolytic alternatives, recycling with enzymes that break down the plastic, and smart pyrolysis. Promising alternatives can also be tested with the pilot plant.

Plastics are key to sustainable growth and a green future. To ensure that plastic products do not become waste at the end of their life, they must be reused as alternative raw materials. Innovative recycling is one of the four fields Covestro is actively driving forward on the road to a circular economy. Covestro is therefore stepping up its research into recycling methods, with an open approach to technology, and promoting innovative approaches such as chemical recycling.

www.covestro.com

 

 

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Integrating 3D Printing Into Prototyping & Production Scenarios — An Interview With Iterate Design and Innovation

Integrating 3D Printing Into Prototyping & Production Scenarios — An Interview With Iterate Design and Innovation

At the recent TCT 3Sixty event in Birmingham, 3DPRINTUK ran a competition offering vouchers to be used against the cost of future 3D printing work, which was won by leading design consultancy ITERATE Design and Innovation. Subsequent to this, we have worked with ITERATE to consider the use of 3D printing from the point of view of an eminent design agency, when it is a useful technology to be used in prototyping and production scenarios, and when it is best to bring 3D printing in-house, or to outsource to an expert 3D printing subcontract bureau such as 3DPRINTUK. In this article, we discuss all things 3D printing with Gethin Roberts, Managing Director at ITERATE, and a 20 year plus veteran working in the rapid product development / 3D printing niche.

Q. Can we start by getting a feel for what ITERATE do, and the sort of services that you offer?

GR. Well at ITERATE, I guess we are what would best be described as a dynamic team of design engineers that blends creative and technical expertise in order to develop new products from a design concept right through to production. ITERATE is unique within the industry as we enable customers to be ‘first-to-market’ through specialist knowledge of the discipline of Rapid Product Development. After studying a Masters degree in Rapid Product Development and spending a decade working in manufacturing I identified that many businesses are slow to respond to market demands as they take too long to conceive new products. As a result, I developed the ‘RPD Pathway’, which focuses on removing many of the barriers that prevent new products from getting to market. By following this stage-by-stage process, ITERATE can create exciting product experiences within a compressed time-frame, which helps customers to better manage their risk. Using this proven approach, we have successfully developed an array of products for the technology, consumer, industrial and healthcare sectors.

Q. Within this rapid product development framework, how fundamental is 3D printing / additive manufacturing, and how do you as a company use it?

GR. 3D Printing is at the forefront of our business. Every product we develop goes through an extensive phase of rapid prototyping in order to validate the design and prove every element; from its aesthetic appearance to its mechanical performance. We have an extensive in-house array of AM technologies that include Fuse Deposition Modelling (FDM) and Stereolithography (SLA) as well as injection moulding. Each process offers different strengths and should be applied based on individual customer requirements. For example, FDM leverages engineering polymers such as ABS, PC and PA6; however, surface finish is limited due to its layer upon layer bonding method. SLA utilises light cured polymers that perform less like engineering polymers; however, its laser based system enables a very high degree of accuracy to be achieved. Through a number of our production partners, we are able to offer additional processes such as vacuum casting, which is ideal for batch production of your product and will provide fantastic likeness to a fully manufactured item.

Q. So when you look at how you leverage AM in the product design process, what advantages does it offer over traditional manufacturing processes and do you still use those, or is it now very much AM being the go to technology when you’re looking at prototyping and production runs?

GR. Yes, we do still use traditional methods. It depends on the nature of the product we are working on. There are some really nice applications where we do actually use AM as the production method. But I think it is important to view AM realistically. It fits within a rapid product development process, just one of a number of tools and management processes that must work together to achieve timely and cost-effective new product introductions. Used in isolation, it can produce parts quickly. But unless you focus on streamlining the whole product development process this may mean you just end up with a part sitting on your desk for weeks waiting for other process steps to catch up. At ITERATE we do have in-house desktop SLA and FDM technologies, but these are only used for part validation, to check if parts fit together etc…, but they are not suitable for volume production. For this step we typically outsource to a qualified expert 3D printing subcontract bureaux.

As a company, we do a lot of work in the wearables sector. One customer we have been working with for five or six years, and during that time their product has evolved massively, with maybe 20 or 30 iterations over the period. For this client, all production is via AM, as it would be financially suicidal to retool every time a new iteration was developed. 3D printing is a perfect fit for product development in such dynamic sectors. It has afforded this company the ability to be able to introduce a small batch (maybe a few hundred), go to market, get customer feedback, and then respond with agility to changing customer or market requirements. Traditional manufacturing wouldn’t have allowed, so AM has really provided them with a competitive edge, and has allowed them to enter new markets at low risk.

Q. So obviously you’re playing on the agility of the manufacturing technique there, but how about its ability to promote design freedom?

GR. Absolutely, that’s of huge importance. The wearables product I’m talking about could not be manufactured using traditional production methods. It just wouldn’t have been possible because of the geometry and if using traditional processes would have to have been designed in a completely different way.

Q. So from your client’s perspective, the ability to offer AM as a production process, opens up all sorts of innovative possibilities for them?

GR. Yes definitely. If you put the production time savings by using AM to one side, I think the design time to actually create something for AM requires less thought in many ways than if you are designing for say injection moulding or casting. There are design rules for AM, but they are not so onerous. You can design, make a part, revise, make another part etc.. etc.. and so ultimately design time itself is considerable faster.

Q. Do you find there are limitations to the technology as well?

GR. Yes, surface finish is one, they still often still look like printed parts in my view. You know, they’re not looking as good as moulded parts.

Q. That plays obviously to a big issue at the moment in the sector, which is post processing. When you select a bureau, do you interrogate them about the post processing technologies they have?

GR. Yes, we often have that conversation. It is vitally important now when we are using AM to produce end-use production parts.

Q. What else informs your decision to choose one subcontract bureau over another?

GR. I wouldn’t underestimate the importance of delivery times, because that’s been a huge problem for us lately. Particularly with Brexit. Some 3D printing agencies are sintering most of their parts in continental Europe. That’s a pain as it adds hugely to the delivery time. For some of our customers they require parts a maximum of 48 hours after design completion. 5 days is impossible, but is increasingly what some prominent players are offering. Cost is also important, but I would argue today perhaps a close second to delivery times.

Q. In general terms, what level of understanding of AM do customers have when they work with you. Do they see it as a magic bullet, or today, do they understand that its usefulness needs to be curated intelligently?

GR. There are so many more of our customers today that have actually got 3D printers in-house. And so they’ll come to us and they might have a proof of concept that they think is suitable, but in many instances this is not enough. The wrong material may have been selected for example, or the part is being built in a sub-optimal way in the 3D printer, causing it to fail in certain areas. So I think that certainly people understand the benefits of AM more than they ever have, but beyond dabbling, they need the intervention of experts like us and 3DPRINTUK to optimise outcomes.

Q. Finally, in terms of what you’re doing, what would tip the balance for you to actually invest in the machines to fulfil AM production in-house?

GR. I don’t feel that we could be as efficient as a company that’s doing it every single day like 3DPRINTUK. We use bureaux so we can focus on what we do well, designing products. And you know, by using bureaux, we don’t have to worry about setting up the machine, optimizing parameters, getting into a whole load of things that we probably could if we wanted to, but we’ve got so many other things to be getting on with.

www.3dprint-uk.com

 

 

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