Article
Fatigue Damage Investigation of Ultra-Large Tire Components
International Journal of Fatigue
Abstract
Off-road ultra-large tires experience different modes of heat-related fatigue failure in operation due to inherent material defects that grow into visible cracks under service loads. This study implements the cracking energy density theory to predict nucleation life of selected components of a 56/80R63 tire. The method uses an assumed intrinsic flaw, a fatigue crack growth law, and a rubber constitutive law to compute local crack driving forces from strain history loads obtained via FEA. The results show that the lower sidewall, belt endings, and inner tread lug corners are the critical regions for crack initiation with lives 5.03 x 105, 1.207 x 105, and 2.01 x 104 cycles, respectively.
Department(s)
Mining Engineering
Keywords and Phrases
- Cracking energy density,
- Fatigue crack growth,
- Finite element analysis,
- Strain-induced crystallization,
- Tire
Document Type
Article - Journal
Document Version
Citation
File Type
text
Language(s)
English
Rights
© 2019 Elsevier Ltd, All rights reserved.
Publication Date
2-1-2019
Publication Date
01 Feb 2019
Disciplines
Citation Information
Wedam Nyaaba, Samuel Frimpong and Angelina Anani. "Fatigue Damage Investigation of Ultra-Large Tire Components" International Journal of Fatigue Vol. 119 (2019) p. 247 - 260 ISSN: 0142-1123 Available at: http://works.bepress.com/samuel-frimpong/32/
The authors acknowledge the financial support from the Department of Mining and Nuclear Engineering at Missouri University of Science and Technology through the SMP project.