Resistance High Temperature SIC Forks Core boost for semiconductor precision manufacturing

Description:

Resistance High Temperature SiC Fork, also known as Pressureless Sintered Silicon Carbide Robotic Arm, is a high-performance mechanical component manufactured using advanced pressureless sintering technology. This product is primarily made of silicon carbide (SiC) and is sintered under normal pressure, resulting in exceptional properties such as high hardness, high strength, high-temperature resistance, and corrosion resistance.

Application:

1. High-Temperature Resistance

2. High Strength and Hardness

3. Corrosion Resistance

4. Lightweight Design

Feature:

The Resistance High Temperature SiC Fork is widely used in semiconductor manufacturing, high-temperature furnaces, aerospace, nuclear energy, and other fields. It is particularly suitable for mechanical components that require high-temperature resistance, corrosion resistance, and high strength.

The physical properties of pressureless sintered silicon carbide ceramics products:

Founded in 2017, Kegu is a leading advanced materials developer based in China’s Xixian New District, Qinhan New City—strategically positioned near major transport links including the Xianyang East Expressway. With a registered capital of 35.5 million RMB (approx. 5 million USD), we operate from a modern 5-acre production facility where we combine materials science innovation with precision manufacturing.

We specialize in engineering high-performance ceramic components for mission-critical industries such as New Energy, Chemical Processing, Pharmaceuticals, and Aerospace. Our products are known for exceptional thermal stability, excellent chemical resistance, and outstanding mechanical properties.

Leveraging a strong R&D foundation, we deliver customized ceramic solutions that meet stringent international quality standards while enhancing operational performance and reducing lifecycle costs for OEMs and innovators worldwide. At Kegu, we’re solving tomorrow’s material challenges—today.