Multiphysics Analysis of Contact Pressure Profile of Airless tires as compared to Conventional Tires
Journal article, Peer reviewed
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Date
2020-11-15Metadata
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Ludvigsen S, Andleeb Z, Khawaja HA, Moatamedi M, Alzahabi B. The harsh climate of the Arctic has always posed significant challenges to car drivers. The severe loss in traction due to snow and icing on the roads has led to an increased risk of collisions. The purpose of this work is to replace the conventional air-filled tire with a non-pneumatic tire to improve the grip in the Arctic conditions. The grip obtained for tires is determined by the weight of the car and the friction between the tire and the road. The friction coefficient, used to determine fr. The International Journal of Multiphysics. 2020;14(4):399-425 https://doi.org/10.21152/1750-9548.14.4.399Abstract
The harsh climate of the Arctic has always posed significant challenges to
car drivers. The severe loss in traction due to snow and icing on the roads
has led to an increased risk of collisions. The chapter compares the
conventional air-filled tire with a non-pneumatic tire to improve the grip in the
Arctic conditions. The grip obtained for tires is determined by the weight of
the car and the friction between the tire and the road. The friction coefficient,
used to determine friction, is a function of the contact pressure. This chapter
discuss research work to obtain a concentrated pressure profile for the
airless tire, compared to a conventional tire. A finite element analysis using
ANSYS® Workbench is performed on two distinct models. The different
pressure profiles of the models are analyzed, and the results proved the
non-pneumatic tires have a more concentrated pressure profile with higher
pressure values.