Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles

Our society is heavily and intrinsically dependent on energy transformation and usage. In a world scenario where resources are being depleted while their demand is increasing, it is crucial to optimize every process. During the last decade the concept of energy efficiency has become a leitmotif in s...

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Main Author: Senatore, Carmine
Other Authors: Engineering Science and Mechanics
Format: Others
Published: Virginia Tech 2014
Subjects:
Online Access:http://hdl.handle.net/10919/37781
http://scholar.lib.vt.edu/theses/available/etd-05112010-000153/
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spelling ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-377812020-09-26T05:32:19Z Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles Senatore, Carmine Engineering Science and Mechanics Cramer, Mark S. Hendricks, Scott L. Dowling, Norman E. Sandu, Corina Ross, Shane D. tire dynamics tractive efficiency energy efficiency tire soil interaction off-road torque distribution fuel economy lateral force multi pass Our society is heavily and intrinsically dependent on energy transformation and usage. In a world scenario where resources are being depleted while their demand is increasing, it is crucial to optimize every process. During the last decade the concept of energy efficiency has become a leitmotif in several fields and has directly influenced our everyday life: from light bulbs to airplane turbines, there has been a general shift from pure performance to better efficiency. In this vein, we focus on the mobility and tractive efficiency of off-road vehicles. These vehicles are adopted in military, agriculture, construction, exploration, recreation, and mining applications and are intended to operate on soft, deformable terrain. The performance of off-road vehicles is deeply influenced by the tire-soil interaction mechanism. Soft soil can drastically reduce the traction performance of tires up to the point of making motion impossible. In this study, a tire model able to predict the performance of rigid wheels and flexible tires is developed. The model follows a semi-empirical approach for steady-state conditions and predicts basic features, such as the drawbar pull, the driving torque and the lateral force, as well as complex behaviors, such as the slip-sinkage phenomenon and the multi-pass effect. The tractive efficiency of different tire-soil configurations is simulated and discussed. To investigate the handling and the traction efficiency, the tire model is implemented into a four-wheel vehicle model. Several tire geometries, vehicle configurations (FWD, RWD, AWD), soil types, and terrain profiles are considered to evaluate the performance under different simulation scenarios. The simulation environment represents an effective tool to realistically analyze the impact of tire parameters (size, inflation pressure) and torque distribution on the energy efficiency. It is verified that larger tires and decreased inflation pressure generally provide better traction and energy efficiency (under steady-state working conditions). The torque distribution strategy between the axles deeply affects the traction and the efficiency: the two variables canâ t clearly be maximized at the same time and a trade-off has to be found. Ph. D. 2014-03-14T21:10:57Z 2014-03-14T21:10:57Z 2010-05-03 2010-05-11 2010-05-25 2010-05-25 Dissertation etd-05112010-000153 http://hdl.handle.net/10919/37781 http://scholar.lib.vt.edu/theses/available/etd-05112010-000153/ Senatore_C_D_2010.pdf In Copyright http://rightsstatements.org/vocab/InC/1.0/ application/pdf Virginia Tech
collection NDLTD
format Others
sources NDLTD
topic tire dynamics
tractive efficiency
energy efficiency
tire soil interaction
off-road
torque distribution
fuel economy
lateral force
multi pass
spellingShingle tire dynamics
tractive efficiency
energy efficiency
tire soil interaction
off-road
torque distribution
fuel economy
lateral force
multi pass
Senatore, Carmine
Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
description Our society is heavily and intrinsically dependent on energy transformation and usage. In a world scenario where resources are being depleted while their demand is increasing, it is crucial to optimize every process. During the last decade the concept of energy efficiency has become a leitmotif in several fields and has directly influenced our everyday life: from light bulbs to airplane turbines, there has been a general shift from pure performance to better efficiency. In this vein, we focus on the mobility and tractive efficiency of off-road vehicles. These vehicles are adopted in military, agriculture, construction, exploration, recreation, and mining applications and are intended to operate on soft, deformable terrain. The performance of off-road vehicles is deeply influenced by the tire-soil interaction mechanism. Soft soil can drastically reduce the traction performance of tires up to the point of making motion impossible. In this study, a tire model able to predict the performance of rigid wheels and flexible tires is developed. The model follows a semi-empirical approach for steady-state conditions and predicts basic features, such as the drawbar pull, the driving torque and the lateral force, as well as complex behaviors, such as the slip-sinkage phenomenon and the multi-pass effect. The tractive efficiency of different tire-soil configurations is simulated and discussed. To investigate the handling and the traction efficiency, the tire model is implemented into a four-wheel vehicle model. Several tire geometries, vehicle configurations (FWD, RWD, AWD), soil types, and terrain profiles are considered to evaluate the performance under different simulation scenarios. The simulation environment represents an effective tool to realistically analyze the impact of tire parameters (size, inflation pressure) and torque distribution on the energy efficiency. It is verified that larger tires and decreased inflation pressure generally provide better traction and energy efficiency (under steady-state working conditions). The torque distribution strategy between the axles deeply affects the traction and the efficiency: the two variables canâ t clearly be maximized at the same time and a trade-off has to be found. === Ph. D.
author2 Engineering Science and Mechanics
author_facet Engineering Science and Mechanics
Senatore, Carmine
author Senatore, Carmine
author_sort Senatore, Carmine
title Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
title_short Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
title_full Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
title_fullStr Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
title_full_unstemmed Prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
title_sort prediction of mobility, handling, and tractive efficiency of wheeled off-road vehicles
publisher Virginia Tech
publishDate 2014
url http://hdl.handle.net/10919/37781
http://scholar.lib.vt.edu/theses/available/etd-05112010-000153/
work_keys_str_mv AT senatorecarmine predictionofmobilityhandlingandtractiveefficiencyofwheeledoffroadvehicles
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