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contributor authorJia, Xiu
contributor authorGrejtak, Tomas
contributor authorKrick, Brandon
contributor authorVermaak, Natasha
date accessioned2019-02-28T10:56:51Z
date available2019-02-28T10:56:51Z
date copyright10/1/2018 12:00:00 AM
date issued2018
identifier issn0021-8936
identifier otherjam_085_12_121011.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4251065
description abstractConsiderable effort has been made to model, predict, and mitigate wear as it has significant global impact on the environment, economy, and energy consumption. This work proposes generalized foundation-based wear models and a simulation procedure for single material and multimaterial composites subject to rotary or linear abrasive sliding wear. For the first time, experimental calibration of foundation parameters and asymmetry effects are included. An iterative wear simulation procedure is outlined that considers implicit boundary conditions to better reflect the response of the whole sample and counter-body system compared to existing models. Key features such as surface profile, corresponding contact pressure evolution, and material loss can be predicted. For calibration and validation, both rotary and linear wear tests are conducted on purpose-built tribometers. In particular, an experimental calibration procedure for foundation parameters is developed based on a Levenberg–Marquardt optimization algorithm. This procedure is valid for specific counter-body and wear systems using experimentally measured steady-state worn surface profiles. The calibrated foundation model is validated by a set of rotary wear tests on different bimaterial composite samples. The established efficient and accurate wear simulation framework is well suited for future design and optimization purposes.
publisherThe American Society of Mechanical Engineers (ASME)
titleExperimentally Calibrated Abrasive Sliding Wear Model: Demonstrations for Rotary and Linear Wear Systems
typeJournal Paper
journal volume85
journal issue12
journal titleJournal of Applied Mechanics
identifier doi10.1115/1.4041470
journal fristpage121011
journal lastpage121011-9
treeJournal of Applied Mechanics:;2018:;volume( 085 ):;issue: 012
contenttypeFulltext


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