Wall thickness

Wall Thickness

In 3D printing, wall thickness refers to the distance between one surface of your model and the opposite sheer surface. For the Standard Grade, the minimum wall thickness you can use is 1 mm. The minimum wall thickness you can use for the Performance Grade is 0.5 mm. However, the applicable minimum wall thickness might vary as it depends, amongst other factors, on the part’s geometry and size. Therefore, we recommend a thickness of 2 mm to create structural walls or features. 

There is no maximum wall thickness as such but keep in mind that thicker areas may increase stresses in your part, which could cause deformations and might lead to unstable build processes. 

Detail size

Detail Size

Very fine details (as small as 0.5 mm) are possible when you print in Titanium, using Metal 3D Printing (M3DP). Detail sizes refer to the distance between the surface of your model and the surface of your detail.

Embossed and engraved texts are also considered as details, but as the printability and readability depend highly on the print orientation, we can only give a general guideline for embossed and engraved text; use Arial 20 pt with 0.4 mm height and depth. 

As it is difficult to predict results for all possible fonts, Arial 20 pt corresponds to characters with a line thickness of 0.7 mm and a minimum overall text height of 5 mm. To illustrate what you can expect, please refer to the examples below of engraved and embossed text in the most favorable orientation for both Standard and Performance Grade.  

Standard Grade Embossed

Standard Grade Engraved

Surface quality

Surface Quality and Orientation

The buildup direction of a part has a large impact on the surface quality as it defines the orientation of the part’s surfaces with respect to the horizontal plane or build plate. Angles (β) measuring less than 45° with reference to the build plate tend to lead to poorer surface quality, while steep angles of more than 45° are likely to have better, smoother surfaces. An overhanging structure (e.g. the underside of a table) is likely to have poor surface quality.


If your design requires threads or other post-machining, please get in touch with our project management team to discuss how we can achieve the right result.

Get in touch

Thermal-induced stresses

Thermally Induced Stresses

Your model in Titanium is 3D-printed using M3DP which is basically a layer-wise welding process. The layer-wise powder melting and its solidification leads to thermally induced stresses upon the cooling down of the melted powder. A design that is not suitable for M3DP can lead to build failures and/or part deformations due to large thermally induced stresses. It is therefore essential to consider the process-specific restriction while designing the part. We advise you to round off or fillet the edges in your design with a minimum radius of 3 mm. Also, avoid sharp edges for the same reason. Try to avoid large material accumulations and, in general, favor organic shapes over edged designs.

Dimensional accuracy

Dimensional Accuracy

Dimensional accuracy doesn’t relate to the detail of your model but to its deviation from the nominal measurement. The general accuracy for 3D-printed metal is 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.   

If you are not familiar with these norms, have a look at the table below to get an idea of the tolerance per dimensions you can expect as well as the IT grade according to ISO 286. 

Note that form deviations might also occur due to designs that do not conform to M3DP and high thermally induced stresses. 

Dimensions in mm

Casting standard DIN EN ISO 8062-3: 2008-09

Tolerance in mm

ISO286 IT grade

3 DCTG 6 ±0.2 IT14
3-30  DCTG 6 ±0.2 IT12
30-60  DCTG 8 ±0.5 IT13
60-120  DCTG 8 ±0.7 IT13
120-250  DCTG 8 ±0.9 IT13
250-400  DCTG 8 ±1.1 IT13



M3DP is a layer-wise manufacturing process. The part is built up layer by layer according to a digital file. Depending on the part surface’s orientation, support structures might become necessary which also have to be printed in the manufacturing process. The support structures keep your model rigidly connected to the build platform during the printing process and absorb internal stress, while also preventing part deformations. Walls or overhangs with angles measuring below 45° with reference to the build platform typically need to be supported as they would otherwise lead to building errors. After the part is successfully built, the support is removed and the part is sandblasted. Some evidence of the removed support structures may still be visible.

Powder removal

Powder Removal

When making a hollow model, it is important to include at least one hole in your design so that the unused powder trapped inside the cavity can be removed. Try to use a minimum wall thickness of 1 mm and keep at least one opening with a minimum diameter of 3 mm. This opening will serve as an exit for the unused powder trapped inside the printed part. Larger and complex cavities need multiple holes with larger diameters, preferably 7 mm. Holes in the center of your model are usually the best as they allow most of the powder to be removed. Powder traps in hollow part sections must be avoided in order to allow for complete removal of the powder inside the hollow section.

Although the printing process itself allows us to produce air- or water-tight items, we do not guarantee the air- or water-tightness of the printed parts, as air- and water-tightness depends on more factors than the wall thickness and the pressure which will be applied. In general, we would recommend printing in performance degrees as it has the lowest porosity. 

Holes and threads


The minimum recommended diameter for a hole is 2 mm. This is the minimum diameter needed to remove internal powder; if the hole is smaller the powder will get stuck inside the geometry. Complex and irregularly shaped holes or interior spaces are impossible for us to inspect or remove the powder completely.

The longer and more complex you make the internal channels, the larger the minimum diameter you have to maintain. A print result according to the CAD geometries, therefore, cannot always be guaranteed in such cases. We strongly recommend that you avoid designing long internal channels in M3DP unless you are in contact with a Materialise project manager who can review your files.

For bores with high demands on tolerances, we recommend providing offsets or closing the holes completely for printing. The part can later be post-machined to ensure bores according to the part-specific requirements.

Contact us for more guidance

File re.jpg

File requirements

We accept file formats STL, 3DS, 3DM, OBJ, WRL, MATPART, STP, SKP, SLDPRT, STEP, CATPART, IGES, MODEL, MXP, and MGX on Materialise OnSite.

Next to file formats we also have constraints related to the content of those files. To deliver the best possible quality and ensure traceability, we only allow 1 model per part to be ordered via our online platform OnSite. This means per file, there can only be one shell. If there are multiple shells in one file, we will only process it as it is recognized as one model or part meaning that the shells are intersecting or interlocking each other (if applicable see the technical specifications below). Otherwise your part will not be processed correctly.

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.
Layer thickness 0.03 – 0.6 mm
Minimum wall thickness

1.0 mm (Standard Grade) 

0.5 mm (Performance Grade) 

Structural wall thickness

2 mm

Minimum detail 0.5 mm
Maximum part dimensions

245 x 245 x 270 mm (offline orders)
220 x 220 x 250 mm (online orders)

Interlocking or enclosed parts? No
Surface structure Unfinished parts typically have a rough surface but various finishing degrees can achieve smooth surfaces.