In the fields of industrial manufacturing, high-end equipment and infrastructure engineering, the environmental adaptability and stable performance of materials are essential to ensure the long-term and safe operation of equipment. Conventional elastic materials tend to harden, crack and degrade when exposed to extreme low temperatures, outdoor aging and harsh working conditions, failing to meet the requirements of high-end scenarios. Featuring excellent comprehensive properties, phenyl silicone rubber elastic putty has become a preferred new material for various buffering and protection devices.



Outstanding low-temperature resistance stands out as its core advantage. Ordinary elastic materials will gradually lose flexibility and resilience below zero degrees Celsius. By contrast, this modified putty maintains excellent elasticity and flexibility even at an ultra-low temperature of -120°C, without hardening, embrittlement or weakened resilience. It perfectly meets the buffering and shock absorption demands of equipment operating in frigid environments.

Beyond superb cold resistance, the product also boasts remarkable weather resistance, ozone resistance, radiation resistance and ablation resistance, along with good self-extinguishing performance. It resists aging and deterioration when exposed to long-term outdoor sunlight, moisture and oxidation. Under harsh conditions such as high temperature and radiation, it effectively enhances equipment safety and service life.

With reliable and versatile performance, it is widely matched with various buffers and applied across numerous industries. It serves the shock absorption systems of aerospace equipment, rail transit and marine vessels, and reinforces the stability of bridge protection structures. It is also well-suited for metallurgy, mining and offshore platforms, delivering steady performance in tough working environments.

Compared with traditional elastic materials, this product integrates low-temperature toughness, environmental durability and safety performance. It solves the common problems of short service life and poor stability of traditional buffering materials under extreme conditions. As a reliable functional material, it has become an indispensable choice for shock absorption and protection in modern industry and infrastructure construction.