Why tolerances fail in 3D printing

Why tolerances fail in 3D printing

Many parts achieve acceptable dimensional accuracy but still fail to fit, assemble or function correctly.

This happens because tolerances depend on interaction between parts, not on isolated measurements.

Accuracy is not the same as fit

A part can be dimensionally correct and still fail in assembly. Tolerances are defined by real interaction under load.

What tolerance failure looks like

Typical symptoms

parts that do not fit despite correct dimensions
holes too tight or shafts too loose
snap-fits that break or do not engage
assemblies requiring force or failing after use
inconsistent fit between batches

Key technical insight

Tolerances are not defined by a single dimension. They are defined by how multiple features interact in real conditions.

Why tolerances fail

Main causes

overcuring reduces internal clearances
geometry-dependent cure variation
post-curing shrinkage
surface roughness affecting interfaces
anisotropic behaviour between directions

Why internal features are critical

Typical effects

holes print smaller than designed
clearances partially close
threads lose definition
tight fits become interference fits

Why material behaviour matters

Material impact

brittle resins crack during assembly
shrinkage alters final fit
low toughness reduces reliability
unstable systems create variability

Important consequence

Two parts with identical dimensions can behave completely differently depending on the material system.

Why calibration cubes are not enough

Limitations

do not represent internal geometries
do not test mating parts
do not simulate real assembly
do not capture material deformation

What controlled tolerances require

Control principles

functional calibration geometries
material selection based on use
controlled curing conditions
designed clearance compensation
real assembly validation

From dimensional accuracy to functional fit

Practical transition

design for clearance, not perfect contact
adjust tolerances to process capability
use tougher materials for assemblies
validate using real parts

Where to go next

Structured calibration

Engineering selection guide

Thermoplastic-like materials

Dimensional accuracy page

Dimensional accuracy defines size. Tolerances define functionality.

Parts must work together, not just measure correctly.

Next step in your engineering workflow

Use the links below to move from diagnosis to validation and then to engineering material selection.

Next actions

Diagnose why your workflow or printed part may fail

Validate if your printed part will actually work

Compare materials using engineering selection criteria