Henan Ankai New Materials Co.,Ltd-LSAK Feldspar’s Post

Defining quality by quantifying degradation in the mechanical recycling of polyethylene “Polyolefins have a multitude of uses across packaging, automotive and construction sectors. Their resistance to degradation during reprocessing enables recyclability, but variability in recycled polymer feedstocks renders it difficult to assure their manufacturing suitability. The lack of quality control methods has disabled circular economy pathways; product failure is costly, wasteful and time-intensive. Using rheology-simulated and extrusion-based recycling experiments, we explore the degradation pathways of high-density poly-ethylene (HDPE). Chain scission dominates during the initial degradation of HDPE, and increasing exposure to O2 shifts the dominant mechanism to long- chain branching. Importantly, extending this method to post-consumer recyclate (PCR), the results show potential as a methodology to assess recyclate quality to enable a circular plastics economy. In this study, we establish the validity of this rheology simulation to define a characteristic degradation parameter, relating it to the structural evolution under different environments defined for virgin HDPE and post-consumer recyclate (PCR).” This is why we need chemical or molecular upcycling next to mechanical downcycling to upcycle (mixed) waste plastics into virgin quality polymers…and yes that comes at the cost of a higher energy consumption. Link to the research paper: https://lnkd.in/eSQaH-ZH #mechanicalrecycling #properties #functionality #quality #downcycling #degradation #polyethylene #plastics #circulareconomy #hdpe #polyolefins #packaging #automotive #construction

Additives vs. Fillers in Plastics: Understanding the Key Differences In the plastics industry, understanding the difference between plastic additives and fillers is crucial for both manufacturers and consumers. These two elements play a pivotal role in enhancing performance and reducing production costs. Plastic Additives are used in small amounts (typically less than 5% of the total weight) to improve specific properties of the material. These additives can enhance durability, fire resistance, thermal stability, or UV protection. For instance, UV stabilizers protect plastic from sunlight, extending the lifespan of outdoor products. Other common additives include plasticizers, lubricants, colorants, and antioxidants. On the other hand, Plastic Fillers are used in larger quantities (ranging from 10% to 50% or more) to reduce production costs or modify the physical properties of the product. Fillers not only lower costs by partially replacing more expensive base plastics but also improve properties such as hardness, impact resistance, and dimensional stability. For example, calcium carbonate is used in PVC pipe production, and fiberglass enhances the strength of plastics used in automotive and aerospace applications. Understanding the difference between additives and fillers helps in accurately assessing the quality and performance of plastic products. Additives fine-tune specific properties, while fillers reduce costs and alter the fundamental characteristics of the material. Both play essential roles in producing effective and sustainable plastic products. Discover more about how Starpoly utilizes additives and fillers to create top-quality products. Learn how we balance performance, cost, and production efficiency! 📞 Contact Details: Mr. Henry WhatsApp: +84 39 226 9140 LinkedIn: Henry’s Linkedin Website: StarPoly JSC #StarPoly #FillerMasterbatch #Plastics #CostSaving #HighQuality

Additives vs. Fillers in Plastics: Understanding the Key Differences In the plastics industry, understanding the difference between plastic additives and fillers is crucial for both manufacturers and consumers. These two elements play a pivotal role in enhancing performance and reducing production costs. Plastic Additives are used in small amounts (typically less than 5% of the total weight) to improve specific properties of the material. These additives can enhance durability, fire resistance, thermal stability, or UV protection. For instance, UV stabilizers protect plastic from sunlight, extending the lifespan of outdoor products. Other common additives include plasticizers, lubricants, colorants, and antioxidants. On the other hand, Plastic Fillers are used in larger quantities (ranging from 10% to 50% or more) to reduce production costs or modify the physical properties of the product. Fillers not only lower costs by partially replacing more expensive base plastics but also improve properties such as hardness, impact resistance, and dimensional stability. For example, calcium carbonate is used in PVC pipe production, and fiberglass enhances the strength of plastics used in automotive and aerospace applications. Understanding the difference between additives and fillers helps in accurately assessing the quality and performance of plastic products. Additives fine-tune specific properties, while fillers reduce costs and alter the fundamental characteristics of the material. Both play essential roles in producing effective and sustainable plastic products. Discover more about how Starpoly utilizes additives and fillers to create top-quality products. Learn how we balance performance, cost, and production efficiency! 📞 Contact Details: Mr. Henry WhatsApp: +84 39 226 9140 LinkedIn: Henry’s Linkedin Website: StarPoly JSC #StarPoly #FillerMasterbatch #Plastics #CostSaving #HighQuality

Pultruded thermoplastic profiles: the recyclable alternative to thermosets ♻️   Once cured, always cured. This is how manageable and limited the service life of thermosets is. Compared to #thermoplastics, they have a decisive disadvantage: they can no longer be moulded after a single heat treatment. The strong cross-linking of the molecular chains also makes recycling impossible. Profiles made from thermoplastics, on the other hand, can be processed into recyclates after use, i.e. they can be recycled and reused. Thermoplastics are sustainable plastics because they can be repeatedly heated and processed. The material diversity of high-performance thermoplastics such as PEEK opens up a wide range of applications with outstanding mechanical and very good chemical properties. Convince yourself of the advantages of pultruded thermoplastic profiles.   #pultrusion #profiles #ensingerplastics #highperformanceplastics

🌟 Unlock the Power of #PolyethyleneWax! 🌟Are you ready to elevate your product game? Discover the transformative role of polyethylene wax in enhancing performance across numerous industries. From boosting the durability of coatings and plastics to optimizing adhesives and personal care products, polyethylene wax is the game-changer you've been searching for! 🚀🔍 But what makes this wax so special? Let's dive in:1️⃣ **Versatility & Unique Properties**: With its low viscosity and high melting point, polyethylene wax integrates seamlessly into various formulations, providing unmatched chemical resistance and thermal stability. 🔬2️⃣ **Industrial Applications**: Enhance the flow and gloss of coatings, improve polymer processing, and stabilize personal care products with polyethylene wax. Its applications in industries like coatings, plastics, and adhesives highlight its indispensability. 🏭3️⃣ **Efficiency & Cost-Effectiveness**: Not only does polyethylene wax enhance product quality, but it also reduces production costs by minimizing waste and boosting efficiency. A sustainable choice that aligns with today's eco-conscious values! 🌍Explore the science, benefits, and future prospects of polyethylene wax in our latest article: [Read More]( https://lnkd.in/gRqQtqUG us in harnessing the potential of #PolyethyleneWax to innovate and lead in your sector. Engage with us by sharing your thoughts or questions in the comments below. Let's pioneer excellence together! 🔗💬#Innovation #Sustainability #ProductDevelopment #IndustrialSolutions #ChemicalEngineering

Today, I want to discuss Propylene, a versatile petroleum product that is at the heart of many industrial processes and plastic manufacturing. At Sperlux-Energy, we provide high-quality propylene that supports the production of essential materials used in countless industries. What is Propylene? Propylene is a colorless, flammable gas that is widely used as a building block in the petrochemical industry. It is a key raw material in the production of polypropylene, one of the most commonly used plastics, and is involved in various chemical manufacturing processes. Key Benefits of Propylene: Polypropylene Production: Propylene is the primary raw material for producing polypropylene, a durable plastic used in packaging, textiles, automotive parts, and consumer goods. High Chemical Reactivity: Propylene’s chemical structure makes it highly reactive, making it a valuable feedstock in chemical synthesis. Sustainability: Polypropylene, derived from propylene, is lightweight and recyclable, supporting the global shift towards sustainable packaging solutions. Versatile Applications: Propylene’s versatility allows it to be used in the production of various industrial chemicals, including acrylonitrile, propylene oxide, and cumene. Applications of Propylene: Plastic Manufacturing: Propylene is crucial in the production of polypropylene, which is used in making containers, automotive components, carpets, and other everyday products. Chemical Synthesis: It is used as a base material to produce chemicals like acrylonitrile, used in acrylic fibers and resins, and propylene oxide, a precursor for polyurethane. Textile Industry: Polypropylene fibers, derived from propylene, are used in producing durable textiles, upholstery, and industrial fabrics. Packaging Industry: Propylene-based plastics are widely used in food packaging, storage containers, and flexible films due to their lightweight and moisture-resistant properties. Automotive Parts: Propylene is used in creating plastic components that help reduce vehicle weight and enhance fuel efficiency. #Propylene #PlasticManufacturing #IndustrialApplications #SperluxEnergy

🌱 Exploring the World of PLA and PHA 🌿 Dive into the fascinating realm of bioplastics with us! Discover the unique characteristics of Polyhydroxyalkanoate (PHA) and Polylactic Acid (PLA) materials, setting them apart from traditional plastics. 🍃 Uncover the secrets behind achieving optimal results through experimentation with extrusion and blowing parameters. From feed temperature to blend composition, we'll guide you through the intricacies of this eco-friendly journey. PHA, a biopolymer born from bacteria, stands tall with its strength, while PLA, a biodegradable gem sourced from corn or sugarcane, flaunts flexibility and transparency. Join us as we delve into the melting temperatures, extrusion speeds, and pressure considerations crucial for crafting quality PHA/PLA blends. Embark on a journey through extrusion, where heating transforms mixtures into continuous forms. Learn about the vital temperature controls, extrusion speeds, and extruder configurations that shape the path to excellence. Then, step into the world of mold blowing, where objects come to life with compressed air. Discover the art of cooling and solidification, ensuring that these blends maintain their shape and ecological virtues. We'll unravel the mysteries of additives, exploring how they enhance thermal stability, tensile strength, and flexibility in PHA/PLA blends. 🌐 Join us in embracing the environmental benefits of these bioplastics, reducing our footprint in the world of conventional plastics. Let's unlock sustainable solutions together! ♻️✨ #PLA #PHA #Bioplastics #SustainableLiving https://lnkd.in/dVf4K45e

3 is the magic number. ✨ We work with three distinct types of plastic polymers, each with unique characteristics that enable us to meet the diverse needs of our customers. Importantly, all of these materials are recyclable, reflecting our commitment to sustainability and positive environmental practices. 𝗢𝘂𝗿 𝘁𝘆𝗽𝗲𝘀 𝗼𝗳 𝗣𝗹𝗮𝘀𝘁𝗶𝗰 𝗣𝗼𝗹𝘆𝗺𝗲𝗿: 🟩 Commodity Polymers — Ideal for high-volume applications across various industries, where cost efficiency is essential without affecting performance. 🟪 Engineering Polymers — Designed for applications requiring exceptional strength and durability, with flame retardant properties, making them perfect for high demand performance circumstances. 🟩 Advanced Polymers — Tailored for specialised applications where specific characteristics are needed, allowing us to provide customised solutions that meet unique project requirements. Get in touch for help on selecting the right polymer for your project - https://bit.ly/3ZqOcfz #PlasticPolymers #UKmfg #PlasticInjectionMoulding #Manufacturing #CommodityPolymers #EngineeringPolymers #AdvancedPolymers

In the world of plastics, polymers, and coatings, optimizing efficiency and maintaining consistent quality are crucial. BriskHeat understands these challenges, and we’re here to help you achieve them with our surface heating and temperature control solutions. #industrialheating #plastics