Modern manufacturing uses ever-increasing amounts of plastic parts.  Their self-tapping screw joints, however, must be handled very differently from metal joints.  Because of the unique properties of plastic, torque-only control is unreliable.  Below we explain why a combined torque-and-angle strategy is essential.

1  Particularities of plastic tightening

1.1  Material differences

• Plastics have a low elastic modulus and high ductility, so parts deform easily.

• Low hardness means the thread can strip or the boss can crack if over-tightened.

1.2  Torque reaches target too early

As the screw cuts its thread, the soft plastic generates a high “tapping torque.”  If the driver stops at a preset torque, the screw may still be floating above the seating surface, creating an unacceptable “float” defect.

1.3  Risk of over-tightening

Once the head contacts the plastic, further rotation can strip the thread or crack the part before torque rises enough to trigger a conventional shut-off.

2  The necessity of angle monitoring

2.1  Define a torque-angle window

Laboratory tests determine a safe torque range and a corresponding angular window.  This window is based on plastic grade, boss geometry, screw size, and target clamp load.

2.2  Real-time monitoring

During production, the controller logs both torque and angle.  A joint is accepted only if:
• Torque ≥ lower torque limit, and
• Angle lies within the pre-defined range.

This dual-criterion method prevents both float (torque OK, angle too low) and over-tightening (torque OK, angle too high), ensuring reliable plastic joints and higher yield.

In practice, companies should establish the torque-angle envelope for every plastic/screw combination and enforce it on the line.  This simple extra step avoids costly defects and guarantees consistent, high-quality assemblies.