Halogen-free + Nano = The Next-Generation Flame Retardant Power Combo! How can modified plastics be both eco-friendly and fire-resistant? Get your ticket to the future of flame retardant technology with this 3-minute quick read.

This report reveals how adhesives and flame retardants work together in new energy vehicle battery packs to block thermal runaway within 5 minutes, truly elevating the fire safety of electric vehicles.

Lightweight Battery Pack Flame Retardant Solution: High-toughness PA6 base compounded with halogen-free flame retardant, achieving UL 94 V-0@1.5 mm, passing 150°C hot box and nail penetration tests, one-stop solution meeting all requirements of new energy vehicles for low smoke, non-toxicity, and high GWIT.

This article provides an in-depth analysis of the balance between flame retardant decomposition temperature and efficiency. It reveals how halogen-free flame retardants can achieve both low-smoke/low-toxicity and UL 94 V-0 performance during high-temperature processing, offering replicable practical parameters for material selection and process optimization.

New Focus in Battery Pack Flame Retardancy: Comparing aerogel, mica, and foamed ceramic insulation solutions, revealing how to synergize with halogen-free flame retardants to meet new energy vehicle flame retardancy standards – achieving no propagation ≥5 minutes after single-cell thermal runaway, easily complying with GB 38031 and EU ECE R100 battery pack flame retardancy regulations

A one-stop review of common faults in processing PA66 flame retardant: From barrel temperature and back pressure settings to the thermal stability of the flame retardant, a step-by-step guide to troubleshooting pain points like fiber floating, bubbles, and burning. Selecting the right PA66 flame retardant and locking in the process window can immediately increase yield by 50%.

PA66 flame-retardant parts always returned for having "bubbles"? Two sentences teach you to eliminate bubbles from material, machine, mold, and process at once, instantly boosting yield!

The yellow phosphorus market remains locked in a stalemate, with prices range-bound amid tense supply-demand negotiations. In the short term, without a major catalyst, this standoff is likely to persist, keeping fluctuations within a narrow band.

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.

Nylon gets brittle and flow rate plummets after adding flame retardants? Don't rush to cut costs! 5 sets of data reveal exactly how much flame retardants impact mechanical strength, MFI, and heat deflection—easy to understand at a glance

Flame retardants causing discoloration? This article pinpoints five key culprits: additive impurities, thermal decomposition, metal ions, processing shear stress, and moisture absorption during storage. It provides practical solutions for flame-retardant nylon and PBT, helping you maintain flame-retardant ratings while keeping color difference ΔE < 0.5.

3.This article provides an in-depth analysis of three major technical routes: nanophosphorus systems, reactive DOPO derivatives, and high-transparency halogen-free intumescent systems. It also presents actionable nylon flame retardant modification solutions that allow flame retardants to maintain V-0 rating while achieving haze <5% and light transmittance >85%.

The use of high-performance polymer is extremely common within the automotive industry for illumination systems, bumpers and fenders. Polymer is also widely used for the improvement of automotive fuel efficiency, safety, and durability. Taking into considerations the challenges faced in reducing aut

Flame retardant ≠ non-combustible. What kind of "black technology" is hidden inside modified plastics? This article deconstructs the "true nature" of flame retardants and the extreme application scenarios of flame-retardant materials. Read it and become an insider instantly.

Choosing the wrong flame retardant burns not just your material, but also your profits and compliance certificates! Understand the 5 key selection principles at once. Don't let the next fire turn your orders to ash.

Halogen-free flame retardant "top performer" MCA teams up with phosphorus-nitrogen flame retardants, turning nylon into a "non-burnable" black tech material—read this article to unlock new insights into eco-friendly flame retardancy!

How do halogen-free flame retardants conquer the "tough nut" of elastomer flame retardancy? This article breaks down the selection, application, and challenges of flame retardants for thermoplastic elastomers, showing that flame retardants are not just an additive, but a catalyst for performance leapfrogging.

Serving as a mainstay in halogen-free flame retardancy, phosphate ester products like IPPP and TCEP rely on precisely controlled synthesis—including key alkylation processes—to ensure the high purity required for advanced applications.