- All
- Product Name
- Product Keyword
- Product Model
- Product Summary
- Product Description
- Multi Field Search
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.
Yellow phosphorus rose nearly 6% again this week, approaching 29,000 yuan/ton. Transactions at high price levels have already encountered resistance—how much longer can the costs of phosphorus-based flame retardants hold up?
When modifying high-temperature nylon and PBT for flame retardancy—where processing temperatures frequently reach 300°C—conventional halogen-free phosphorus-based flame retardants tend to decompose, cause mold fouling, and lead to yellowing as soon as they are introduced. However, after modifying the molecular structure and applying a coating, thermal stability has improved, mold fouling has decreased, and light-colored parts no longer risk discoloration.
Blooming issues often lie in the mismatch between formulation and processing. This article explains in depth — from mechanism to practical operation — how to match suitable red phosphorus flame retardants with processing conditions, so that anti-blooming performance no longer depends on luck.
Just because a formulation works in the lab doesn’t mean it can be stably mass-produced on the line. The real threshold in flame retardant preparation lies in the transition from craftsmanship to engineering—and modified coating technology is precisely the bridge across that gap.
Struggling with recycled material flame retardancy? You might be underestimating the power of red phosphorus masterbatch! Here’s why high-content red phosphorus flame retardants can deliver stability where ADP falls short in recycled plastics—lower cost, greater tolerance, and a hidden ace in the circular economy
Flame retardant migration is not simply a matter of physical migration, but a complex process determined by chemical structure, interaction forces with the substrate, and environmental factors. For red phosphorus flame retardants, the density of the coating process and compatibility with the substrate are key factors determining whether migration occurs during long-term use. This article is suitable for materials engineers and formulation R&D personnel seeking a deeper understanding of the core principles behind flame retardant stability.
