The coefficient of friction (μ) measures the resistance to sliding between two surfaces in contact. It is a key parameter in mechanical design because it affects wear, energy efficiency, accuracy, noise and component lifetime, both in industrial 3D printing and in CNC machining.
Understanding and controlling friction means reducing costs, increasing reliability and improving performance.
The coefficient of friction is a dimensionless value defined by the formula:
μ = Fₐ / Fₙ
Fₐ = friction force
Fₙ = normal force
μ high = more grip
μ low = smoother surfaces
Static friction (μₛ): prevents the start of motion
Kinetic (dynamic) friction (μₖ): acts during sliding
Rolling friction: typical of wheels and bearings, much lower
Values vary depending on surface roughness, load, lubrication and temperature.
In industrial 3D printing, friction also depends on the technology used:
MJF / SLS: uniform and isotropic friction
FDM: higher and directional friction
SLA: smooth surfaces but more brittle materials
For moving components, PA12 and PA11 produced with MJF offer the best balance between low friction and wear resistance.
Selection of low-μ materials (PA12, PA11, POM)
Improved surface finish
Lubrication or PTFE coating
Design that reduces contact pressure
Knurled or sandblasted surfaces
TPU and elastomers
Anti-slip patterns and functional geometries
The coefficient of friction directly affects:
Energy efficiency
Wear and service life
Mechanical accuracy
Safety and grip
Operating costs
Correct material and manufacturing process selection prevents over-engineering and long-term issues.
The coefficient of friction is a key parameter in the design of CNC components and 3D-printed parts. Materials such as PA12, PA11 and TPU allow controlled friction, high wear resistance and geometric freedom, making them ideal for modern industrial applications.
Do you need components with optimised friction?