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Specialized in PE, PVC, TPE, TPU and Low Smoke Zero Halogen (LSZH) wire and cable compound and materials.
In high-rise buildings, subway tunnels, new energy power stations and industrial complex scenarios, the fire safety of wires and cables is directly related to life and property and system reliability.
YINSU Flame Retardant Company provides customized flame retardant solutions for global customers, covering PE (polyethylene), PVC (polyvinyl chloride), TPE (thermoplastic elastomer), TPU (thermoplastic polyurethane) and LSZH (low smoke and halogen free) wire and cable systems to meet all safety requirements, ranging from UL94 V-0 flame retardant certification to EN 45545 fire protection for rail transportation and IEC 60754 low smoke and halogen free toxicity. All-round safety requirements.
Material Common Use Typical FR Type YINSU Flame Retardant Item No.
PE HDPE, LDPE, LLDPE, Red phosphorus, halogen free FR, PRP-950X, PE-XT-20, YS-F22B, MCA-B
Cross-linked PE cables, Bromine antimony masterbatch MDH, ATH
Plastic insulated cables.
PVC PVC &Plastic insulated power cables, T3 / ATO alternatives T3, T30
Aluminum stranded wires,
Prefabricated branch cables.
TPE Insulated wires, flexible cables Organic phosphorus YS-F22B, YS-9003
Shielded insulated cables
TPU Special purpose cables Organic phosphorus YS-F22B, YS-9003
Power cables for frequency converters.
Others Welcome to consult more details.
Market SentimentThe main theme this week remains "more declines than increases." The off-season for downstream sectors and inventory pressure have led to sluggish spot market transactions. Although futures markets have been boosted by macro sentiments, they have failed to drive spot prices up. This
This article explores the incorporation of flame retardants as additives in plastic technology, focusing on the mechanisms of polymer combustion, the main modes of action of flame retardant materials, and commonly used flammability tests. It highlights the importance of cooling, char formation, dilution of flammable gases, and interruption of free radical chain reactions in enhancing polymer fire resistance. With challenges in optimizing flame retardant performance while maintaining material properties and environmental safety, innovations in flame retardant technology are pivotal. Keywords: flame retardants, polymer combustion, cooling, protective char, dilution, free radical chain reaction, flammability tests, plastic technology, fire safety.
As technology continues to advance and new materials are developed, we expect that these materials will continue to drive innovation and growth in a variety of industries in an even more environmentally friendly and efficient manner. Ultimately, through continuous research and improvement, we will be able to create engineering plastics products that are safer, more reliable and in line with our sustainability goals to meet the challenges of the future.
Explore the cutting-edge world of high-temperature engineering plastics that are revolutionizing industries from aerospace to electronics with "Inventory of 8 Common High-temperature Resistant Engineering Plasticss" – a comprehensive guide to the materials that stand the test of heat and perform under pressure.
In the process of formulating modified plastics, various factors need to be taken into consideration to ensure high performance and quality of the final product. YINSU Flame Retardant Company, based on its expertise in the field of flame retardant, provides a series of specialized flame retardant solutions for different materials.
This article explores the flame-retardant mechanisms of polymer composites, focusing on the roles of nitrogen, sulfur, silicon, and fluorine in improving fire resistance. It highlights how these elements contribute to flame retardancy through the formation of protective barriers, inert gas production, and inhibition of combustion processes. Despite advancements, challenges such as balancing performance with safety, minimizing environmental impact, regulatory compliance, and cost-effectiveness persist in achieving optimal flame retardancy in building materials. The ongoing research aims to address these challenges, promising safer, more sustainable flame-retardant solutions for the future. Keywords: polymer composites, flame retardant, nitrogen, sulfur, silicon, fluorine, building safety, environmental impact.
