Titanium

  • T35
  • Titane Grade 1

  • T35, Grade 1

Norms ASTM B-265, ASTM B-337, ASTM B-338, ASTM B-348, ASTM B-381, ASTM F-67, ASTM F-468, ASTM F-467

Production technique Drawn,
Rolled

Chemical composition Mechanical characteristics
Fe Ti Other Rm Rp A% HB Density W/m.k
≤ 0,2 Reste ≤ 0,305 ≥ 241 ≥ 172 ≥ 25 120 4,51 21,6
Description

Excellent corrosion resistance. Good cold formability and ductility. Excellent weldability. Good tenacity.

Application

Capacitors, Heat exchangers, Water treatment, Shielding, Nuclear reactors, Geothermal, Stainless Steel Valves, Springs, Connectors, Cryogenics, Manufacture of paper, Watches and jewelry, Architecture

 


 

  • T40
  • Titane Grade 2

  • T40, Grade 2

Norms ASTM B-265, ASTM B-337, ASTM B-338, ASTM B-348, ASTM B-381, ASTM F-67, ASTM F-468, ASTM F-468, AMS 4902

Production technique Drawn, Rolled

Chemical composition Mechanical characteristics
Fe Ti Other Rm Rp A% HB Density W/m.k
≤ 0,3 Reste ≤ 0,375 ≥ 345 ≥ 275 ≥ 20 160 4,51 21,6
Description

The most common for industrial use. Good balance between ductility-cold formability and resistance Mechanics. Excellent weldability. Exellent resistance to corrosion.

Application

Capacitors, Heat exchangers, Water treatment, Shielding, Nuclear reactors, Geothermal, Stainless Steel Valves, Springs, Connectors, Cryogenics, Manufacture of paper, Watches and jewelry, Architecture

 


 

  • T50
  • Titane Grade 3

  • T50, Grade 3

Norms ASTM B-265, ASTM B-337, ASTM B-338, ASTM B-348, ASTM B-381, ASTM F-67, ASTM F-468, AMS 4900

Production technique Drawn, Rolled

Chemical composition Mechanical characteristics
Fe Ti Other Rm Rp A% HB Density W/m.k
≤ 0,3 Reste ≤ 0,495 ≥ 448 ≥ 379 ≥ 18 200 4,51 21,6
Description

Good Mechanics resistance. Ductility limited. Excellent weldability. Excellent corrosion resistance.

Application

Capacitors, Heat exchangers, Water treatment, Shielding, Nuclear reactors, Geothermal, Stainless Steel Valves, Springs, Connectors, Cryogenics, Manufacture of paper, Watches and jewelry, Architecture

 


 

  • T60
  • Titane Grade 4

  • T60, Grade 4

Norms ASTM B-348, ASTM B-367, ASTM B-381, ASTM F-67, ASTM F-468, AMS 4901

Production technique Etiré, Laminé

Chemical composition Mechanical characteristics
Fe Ti Other Rm Rp A% HB Density W/m.k
IACS
≤ 0,5 Reste ≤ 0,545 ≥ 551 ≥ 482 ≥ 15 250 4,51 21,6
Description

Good Mechanics resistance. Good weldability. Good resistance to corrosion.

Application

Capacitors, Heat exchangers, Water treatment, Shielding, Nuclear reactors, Geothermal, Stainless Steel Valves, Springs, Connectors, Cryogenics, Manufacture of paper, Watches and jewelry, Architecture

 


 

  • TA6V
  • Titane Grade 5

  • TA6V, Grade 5

Norms ASTM B-265, ASTM B-348, ASTM B-381, ASTM F-467, ASTM F-468, AMS 4928, AMS 4965, AMS 4967, RECUIT (AMS 4911, AMS 4906, AMS 4935)

Production technique Drawn, Rolled

Chemical composition Mechanical characteristics
Al Fe Ti V Other Rm Rp A% HB Density W/m.k
5,5-6,75 ≤ 0,4 Reste 3,5-4,5 ≤ 0,365 ≥ 1000 ≥ 910 ≥ 18 350 4,43 7,3
Description

The most widespread alloy titanium. Suitable for heat treatment. Usable up to 400 ° C. Suitable for foundry. Fairly good weldability. Forging ability (Roughing + finishing at 980/970 ° C).

Application

Capacitors, Heat exchangers, Water treatment, Shielding, Nuclear reactors, Geothermal,Stainless Steel Valves, Springs, Connectors, Cryogenics, Manufacture of paper, Watches and jewelry, Architecture

 


 

  • TA6V ELI
  • Titane TA6V ELI

  • Grade 23

Norms AMS 4907, AMS 4930, AMS 4956, ASTM B-337, ASTM F 136-92, ISO 5832

Production technique Drawn, Rolled

Chemical composition Mechanical characteristics
Al Fe Ti V Other Rm Rp A% HB Density W/m.k
IACS
5,5-6,5 ≤ 0,25 Reste 3,5-4,5 ≤ 0,273 ≥ 980 ≥ 900 ≥ 17 315 4,43 7,3
Description

The ELA (Extra Low Intersticials) grade of TA6V was developed to improve toughness and ductility at very low temperatures. Biocompatible. Recommended in seawater under stress. Fairly good weldability. Forging ability.

Application

Engine and structural parts with strong toughness. Surgical Implants.

 


 

  • TZM
  • TZM

Production technique Sintered

Chemical composition Mechanical characteristics
Zr Mo Ti Other Rm Rp A% HB Density Recristallisation
temperature
0,06-0,12 Reste 0,4-0,55 0,01-0,04 690 – 1130 620 – 1000 2,0-8,0 300-450 10,16 1250
Description

Compared to molybdenum, TZM has a higher recrystallization temperature and higher heat resistance. It is therefore a material which is perfectly suitable for producing tools which must have a particularly high heat resistance. The use of TZM is preferable to molybdenum for the assembled parts because it is better suited for welding.

Application

Under pressure moulding, Vacuum furnaces, Boats for firing and sintering techniques at temperatures above 1500 ° C