3D printing

Aluminum alloy wire, as a feedstock for 3D printing, is reshaping the pathways to high-end manufacturing. By optimizing alloy composition and processing parameters, it effectively addresses longstanding industry challenges—such as cracking, porosity, and uneven mechanical properties—that typically arise during the 3D printing of conventional aluminum alloys. The resulting parts achieve a density exceeding 99%, with high dimensional accuracy and rapid printing speeds.

Welding applications

Argon arc welding (TIG/MIG) processes for automotive aluminum alloy bodies, rail transit vehicles, and marine aluminum structures. The welding wire exhibits excellent fluidity, produces aesthetically pleasing welds, and ensures high strength compatibility. Magnesium alloy welding wire helps minimize weld cracking and porosity, thereby enhancing the mechanical properties of the joint.

Vacuum coating

In vacuum coating systems, materials are heated and evaporated to deposit aluminum reflective films, which are used in optical lenses, automotive headlight reflectors, decorative coatings, and more. After evaporation, hard coatings such as titanium nitride (TiN) and titanium oxide are formed, enhancing the surface hardness and wear resistance of cutting tools and molds; they can also be employed for surface modification of biomedical materials.

Aerospace

It is used to manufacture load-bearing components such as aircraft engine blades, fuselage fasteners, and landing‑gear springs. Titanium alloys boast high specific strength, excellent high‑temperature resistance, and superior corrosion resistance, enabling significant weight reduction and improved fuel efficiency. High‑purity aluminum alloy wire exhibits excellent electrical conductivity, corrosion resistance, and machinability, ensuring the reliable operation of aircraft systems.