Advantages of Titanium Alloy Anodizing Treatment

1. Film Layer Performance:After anodizing, a "super protective film" will form on the surface of the titanium alloy. Its chemical stability is at its peak! In "harsh environments" such as strong acids and strong bases, it is like a sturdy armor, firmly protecting the titanium alloy substrate and significantly extending the material's lifespan.

By precisely controlling the process, the membrane can be made into various brilliant colors such as golden yellow, blue, and purple. Its appearance is outstanding, enabling titanium alloy to effortlessly take the leading role in the fields of decoration and jewelry.

The surface hardness after processing can reach 300-800HV, with excellent wear resistance. After this treatment, mechanical parts, tools and other components will no longer be afraid of frequent friction and impact. The replacement frequency will be reduced, saving money and being convenient.

2. Process Adaptability: Flexible and versatile, capable of operating in multiple fields
The titanium alloy anodized surface has an excellent "temperament" and is highly versatile. There are a wide range of electrolyte options available, including acidic substances such as sulfuric acid and oxalic acid, as well as basic substances like sodium hydroxide. These can all be used as needed to create different types of oxide films with specific properties.

3. Function Expansion: Unlock 30+ skills, cross-over with no stress
(1) In the medical field: After the process has been improved, the membrane layer becomes biocompatible and can "get along well" with human tissues, reducing rejection reactions. With this technology, medical implants such as artificial joints and dental implants are safer and more reliable.

(2) Marine Engineering: This technology endows the coating with anti-fouling properties. In marine environments with high salt content and abundant microorganisms, it can effectively prevent marine organisms from attaching and pollutants from eroding, allowing the equipment to operate "cleanly" for an extended period.

(3) Electronic field: Making the oxide film conductive to meet the performance requirements of electronic components, contributing to the miniaturization and high performance of electronic devices.