Gear Fatigue Strength: Design, Verification, And Engineering Applications
Publish Time: 2025-12-04 Origin: Site
Introduction
1. Mechanism of Gear Fatigue Failure
1.1 Basic Characteristics of Gear Fatigue Failure
Cyclic load action: Caused by alternating contact stress and bending stress.
Crack initiation and propagation: Typically undergoes three stages—crack initiation, stable propagation, and rapid fracture.
Stress concentration effect: Fatigue is prone to occur at the tooth root transition curve and surface defects.
1.2 Main Fatigue Failure Modes
(1) Tooth Surface Contact Fatigue (Pitting)
Microscopic mechanism: Cracks initiated by the maximum shear stress in the subsurface → propagate to the surface → material spalling.
Manifestations:
Initial pitting: Isolated pits with diameter < 1mm.
Extended pitting: Connected pits forming spalling areas.
Macroscopic pitting: Large-area spalling with depth > 0.2mm.
(2) Tooth Root Bending Fatigue
Fracture process: Cracks initiate on the tensile stress side of the tooth root → propagate to the compressive stress side → tooth breakage.
Typical characteristics:
Shell-like fracture morphology.
Visible fatigue striations.
Coarse-grained final fracture zone.
(3) Surface Crushing (Plastic Deformation)
Occurrence conditions: Extremely high contact stress exceeding the material yield limit.
Common scenarios:
Soft tooth surface gears.
Impact load working conditions.
Improper heat treatment.
2. Gear Fatigue Strength Design Theories
2.1 Basic Theoretical Framework
Stress-Life Method (S-N curve): Suitable for high-cycle fatigue (> 10⁴ cycles).
Strain-Life Method (ε-N curve): Suitable for low-cycle fatigue (< 10⁴ cycles).
Fracture Mechanics Method: Prediction based on crack growth rate da/dN.