Introduction of HT4G50HSL
This innovative PPA composite material is based on high-performance PPA, with the precise addition of 50% glass fiber and upgraded thermal stabilizers, creating a high-end engineering material with outstanding comprehensive performance. It not only boasts excellent modulus strength and superior dimensional stability but also features reliable thermal stability, capable of seamlessly meeting the multiple demands of harsh application scenarios.
| Parameter | Value |
| Polymer Base | PPA |
| Polymer Base Content | 40% to 50% |
| Reinforcement Content | 50% |
| Mechanical Strength | High modulus |
| Typical Uses | Alternative to aluminum-zinc die-casting alloys |
| Environmental Benefit | Automotive, consumer electronics, industrial equipment |
Widely suitable for the manufacturing of key automotive components, the product can perfectly replace traditional materials such as aluminum-zinc die-cast alloys. With core advantages including customizable performance, prominent cost-effectiveness, and wide applicability, it has become the preferred material solution in the high-end industrial field. As a trusted engineering plastic supplier, we can provide exclusive customized formula services tailored to your specific application needs, accurately matching your production and performance requirements.
Key Features
This 50% glass fiber-reinforced PPA material features top-tier thermal stability. Even when continuously used under long-term high-temperature operating conditions, it can effectively resist brittleness and avoid performance degradation, consistently maintaining stable and reliable performance to seamlessly tackle harsh high-temperature challenges.
With 50% high-proportion glass fiber filling technology, the material achieves a qualitative leap in mechanical strength and modulus, significantly improving component load-bearing capacity and easily meeting the strict mechanical performance requirements of high-end industrial scenarios.
Strictly compliant with international environmental standards such as RoHS and REACH, it supports recyclable design to help enterprises achieve green production. Meanwhile, it boasts high cost-effectiveness, optimizing the cost structure while ensuring performance, realizing a win-win situation for environmental protection and economy.
Widely applicable to the manufacturing of various core components requiring high strength and high temperature resistance, it is an ideal choice for replacing traditional materials such as aluminum-zinc die-cast alloys, providing more competitive material solutions for the automotive, high-end industrial and other fields.
