Ti6Al4V, one of the widest-known alloys in Metal 3D Printing, combines excellent mechanical properties with very low specific weight. This material is corrosion- resistant and used in a variety of demanding engineering environments such as aeronautics. Applications include functional prototypes, solid end-use parts, medical devices and spare parts.
Technical Specifications
| Standard lead time | Minimum of 10 working days, depending on part size, number of components and finishing degrees (online & offline orders) |
| Standard accuracy | In accordance with DCTG 8 of DIN EN ISO 8062-3: 2008-09 for dimensions between 30 and 400 mm, DTTG 6 for dimensions below 30 mm and DIN ISO 2768 -1 g (rough) for dimensions between 3 mm and 400mm. (for more details and IT grades have a look at the design guidelines.) |
| Layer thickness | 0.03 – 0.6 mm |
| Minimum wall thickness | 1 mm (standard grade) / 0.5 mm (performance grade) |
| Minimum detail | 0.5 mm |
| Maximum part dimensions |
245 x 245 x 270 mm (offline orders) |
| Interlocking or enclosed parts? | No |
| Surface structure | Unfinished parts typically have a rough surface but various finishing degrees can achieve smooth surfaces. |
NEW: Standard and Performance Grades
You can now choose between our two grades for Metal 3D Printing, to achieve the right balance of performance and efficiency for each project.
Standard
- Industry-standard quality requirements
- Ideal for prototypes and simple end-parts
- Form-, fit- and function-testing
- Strength and density similar to cast parts
- Available on online and offline orders
Performance
- Ideal for complex metal parts designed for AM
- Applications in demanding environments
- Suited for series production
- Strength and density more performant than casting
- Specialized quality test reports available to your specification
- Available on online and offline orders
To compare the material properties of the two grades, take a look at the datasheet below.
Want to know which grade is right for you? Tell us about your project >
Datasheet
| MEASUREMENT | STANDARD GRADE | PERFORMANCE GRADE | ASTM/PROCEDURE |
|---|---|---|---|
| Density | >4.36 g/cm³ | >4.39 g/cm³ | WGE-Prod-067EN |
| Relative Density | >99% | >99.5% | WGE-Prod-067EN |
| Tensile Strength | >900 MPa* | >980 MPa | DIN EN2002-1 |
| Yield Strength | >830 MPa* | >900 MPa | DIN EN2002-1 |
| E-Modulus | 110 GPa | 110 GPa | DIN EN2002-1 |
| Elongation at Break | >10%* | >14% | DIN EN2002-1 |
| Roughness Ra | <20 µm | <20 µm | ISO 4287 / AITM 1-00070 |
| Roughness Rz | <80 µm | <80 µm | ISO 4287 / AITM 1-00070 |
| Hardness | >310 HV | >340 HV | ISO 6597-1:03-2006 |
Actual values may vary with build condition
Strong tensions, due to part geometry, may cause distortion in the part which may lead to greater deviation. Values for surface roughness depending on orientation or surface. Downward-facing surfaces and surfaces with support will be rougher.
Values represent stress relief heat treated status.
*Values for tensile specimens according to DIN EN ISO 6892 status as built
How Does Metal 3D Printing Work?
Metal 3D Printing is a laser-based technology that uses powdered metals. Similar to Laser Sintering, a high-powered laser selectively binds together particles on the powder bed while the machine distributes even layers of metallic powder. Support structures are automatically generated and built simultaneously in the same material, and are later manually removed. Once complete, the part undergoes heat treatment.
