Copper Materials - When Every Ohm Matters
Copper alloys combine high electrical conductivity with mechanical strength and thermal stability. This makes them suitable for components that conduct current and are simultaneously exposed to mechanical loads. They are commonly used in welding technology, electrical engineering, mechanical engineering, and automotive manufacturing.
Copper-Aluminum Oxide
Dispersion-strengthened copper alloy with high thermal resistance and electrical conductivity
Copper-Chromium-Zirconium
Hardenable copper alloy with high conductivity and wear resistance
Copper-Cobalt-(Nickel)-Beryllium
Precipitation-hardened copper alloy with high hardness and thermal stability
Copper-Nickel-Silicon-Chromium
Hardenable copper alloy with high conductivity and wear resistance
Refractory Metals - When Heat Becomes a Challenge
These materials are defined by extremely high melting points and are used wherever maximum thermal and mechanical resistance is required. They are commonly used in manufacturing, electrical engineering, medical engineering, and aerospace.
Molybdenum
Material with good formability and high creep resistance
Tantalum
Material with high corrosion resistance and ductility
Titanium-Zirconium-Molybdenum
Alloy with increased high-temperature strength and high creep resistance.
Tungsten
Material with a very high melting point and high dimensional stability.
Tungsten Heavy Metals
Alloy with high density and strong shielding capability
Tungsten-Copper
Alloy with high electrical conductivity and resistance to thermal cycling.