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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.
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Phosphorus has been designated as a strategic necessity by multiple countries, and its profound impact on the halogen-free phosphorus-nitrogen flame retardant industry can no longer be ignored. Let’s delve into the major industry transformation driven by cost pressures and supply-demand restructuring—and explore how companies can shift from "resource dependency" to "value-based competition" as a path to breakthrough.
From antimony oxide-chlorinated paraffin in 1930 to today's nanocomposites and macromolecular design, we systematically trace the evolution of flame retardant technologies, while providing an in-depth introduction to cutting-edge directions such as composite systems, synergistic mechanisms, and macromolecular flame retardants. For technical professionals focused on halogen-free, high-efficiency flame retardant solutions, this review offers valuable technical insights and trend analysis.
The article reviews the grades and application cases of automotive flame-retardant materials like ABS, PC, and PP, covering flame retardant selection and UL94 V-0 data, to help quickly match flame-retardant solutions for automotive components.
The white frost on flame-retardant PP originates from flame retardant migration and precipitation. The article offers three solutions: compatibilizer coating, low-temperature/low-shear processing, and post-treatment annealing, achieving Grade 0 precipitation in tests, helping flame-retardant PP maintain a lasting bright surface while achieving UL94 V-0.
Piperazine pyrophosphate flame retardant application dismantles the 4 major challenges behind the advantages of halogen-free flame retardants: water resistance/leaching, processing corrosion, a narrow synergy window, and difficulty achieving V-0 in thick sections. It provides practical test solutions for nylon and PE flame retardancy, helping you stably achieve UL94 V-0.
