CONTACT FATIGUE LIFE STUDY OF WIND TURBINE GEARBOX BASED ON MULTIAXIAL FATIGUE CRITERION

Gu Huiyun, Zhou Jianxing, Cui Quanwei, Fei Xiang, Wen Jianmin, Fang Zhong

Acta Energiae Solaris Sinica ›› 2026, Vol. 47 ›› Issue (6) : 372-383.

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Acta Energiae Solaris Sinica ›› 2026, Vol. 47 ›› Issue (6) : 372-383. DOI: 10.19912/j.0254-0096.tynxb.2025-0165

CONTACT FATIGUE LIFE STUDY OF WIND TURBINE GEARBOX BASED ON MULTIAXIAL FATIGUE CRITERION

  • Gu Huiyun1, Zhou Jianxing1, Cui Quanwei1, Fei Xiang1, Wen Jianmin1,2, Fang Zhong2
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Abstract

Wind turbine gearboxes are subjected to contact loads during operation, resulting in contact fatigue damage in the gears, which significantly affects their service life. To accurately predict the contact fatigue life of gears, this study takes a 6 MW wind turbine gearbox operating at Dabancheng Wind Farm, Xinjiang, as the research object. A gearbox dynamic model considering both internal and external excitations is established to calculate the dynamic meshing forces of each helical gear pair. The analysis incorporates local material properties and residual stresses in the gears. By applying the Dang Van multiaxial fatigue criterion combined with S-N curves, the fatigue damage distribution in the helical gears under contact loading is analyzed. Fatigue hotspots are identified, and critical operating conditions are extracted to develop a surrogate model, which quantifies the contact fatigue damage and estimates the contact fatigue life of each gear over a 20-year design period. The results indicate that the engage-in and recess points of external meshing pairs in helical gears are the primary fatigue hotspots, making them more susceptible to fatigue failure. Among all gears, the sun gears exhibit the most severe contact fatigue damage, with estimated contact fatigue life of 8 years for the high-speed sun gear and 21 years for the low-speed sun gear. Conversely, the planetary gears in both stages show relatively lower fatigue damage, with their contact fatigue life exceeding 30 years. The ring gear experiences the least fatigue damage, resulting in an exceptionally long service life.

Key words

gears / wind turbines / fatigue damage / multiaxial fatigue criterion / contact loads / key operating conditions

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Gu Huiyun, Zhou Jianxing, Cui Quanwei, Fei Xiang, Wen Jianmin, Fang Zhong. CONTACT FATIGUE LIFE STUDY OF WIND TURBINE GEARBOX BASED ON MULTIAXIAL FATIGUE CRITERION[J]. Acta Energiae Solaris Sinica. 2026, 47(6): 372-383 https://doi.org/10.19912/j.0254-0096.tynxb.2025-0165

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