Product Description:

Pure titanium is a silver-white metal, it has many excellent properties. Titanium has a density of 4.51g/cm3, which is slightly heavier than the prestigious light metal magnesium. The mechanical strength is similar to that of steel, two times larger than aluminum and five times larger than magnesium. Titanium high temperature, melting point 1942K, nearly 1000K higher than gold, nearly 500K higher than steel.

Classification of titanium wire:Titanium wire, titanium alloy wire, pure titanium glasses wire, titanium straight wire, titanium hanging wire, titanium coil wire, titanium bright wire, medical titanium wire, titanium nickel alloy wire.

Specification of titanium wire
• Titanium wire specification: φ0.8-φ6.0mm
Glasses titanium wire specification: φ1.0-φ6.0mm special titanium wire

Titanium wire specification: φ0.2-φ8.0mm special for hanging tools

The main standard of titanium wire

GB/T,GJB,AWS,ASTM,AMS,JIS

Grade of titanium wire

TA0,TA1,TA2,TA3,TA4,TA5,TA6,TA7,TA9,TA10,TC1,TC2,TC3,TC4，TC6,TC11,GR1，GR2，GR3，GR5 Ti6AL4V ELI,Ti6AL7Nb,Ti13Nb13Zr,Ti1533

State of titanium wire

Annealing state (M) Hot working state (R) Cold working state (Y)(annealing, ultrasonic wave inspection)

Surface of titanium wire

Pickling surface Bright surface

Titanium wire use

Military, medical, sporting goods, glasses, earrings, headwear, electroplating hanging, welding wire and other industries.

titanium wire carburizing surface treatment:

Titanium wire with carbon to form a high hardness of the stable carbide. The growth of the carbonized layer between titanium and carbon is determined by the diffusion rate of titanium in the carbonized layer.

The solubility of carbon in titanium is small, totaling 0.3 at 850X: and about 0.1 at 600C. B due to the small solubility of carbon in titanium, the surface hardening is basically achieved only through the titanium carbide layer and the deposited layer of the underlying surface. Carburizing must be carried out under the condition of removing oxygen, because the hardness of the surface layer formed by the powder suitable for carburizing commonly used in steel against the surface of carbon monoxide or oxygen-containing carbon monoxide reaches 2700MPa and 8500MPa, and the surface layer is combined. It is easy to peel off.

In contrast, under deoxidizing or decarburizing conditions, a thin titanium carbide layer may form during carburization in charcoal. The hardness of this layer is 32OUOMPa, which corresponds to the hardness of titanium carbide. The depth of the carburized layer is substantially greater than the depth of the nitrided layer when nitriding with nitrogen under the same conditions. Under oxygen-enriched conditions, it must be taken into account that the absorption of oxygen affects the hardening depth. Only under the condition of very thin layer thickness, in vacuum or argon-methane atmosphere, carbon powder can form sufficient adhesion strength. In contrast, the use of gas carburizing agent can form a particularly hard and good bonding titanium carbide hardened layer. At the same time, the hardening spread formed under the condition of temperature between 950 ° C. and 10201 ° C. is between 50 μm and 50 ° C. As the layer thickness increases, the titanium carbide layer becomes more brittle and tends to flake off. In order to avoid carbon inclusions from invading the titanium carbide layer due to the decomposition of rethane, gas carburization should be carried out in an inert gas with a specified dosage of about 2% rethane by volume. Lower surface hardness results when methane carburization is utilized with propane additives. When propane carburized by gas was used under the condition that the bonding force reached 90 kPa, although the thickness of the hardened layer was measured to be thin, it had the best wear resistance. Hydrogen is absorbed under the condition of using gas-type carburizing agent, but it has to be removed again during vacuum annealing.