Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques

Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques

Electric vehicles are spreading in automotive industry pushed by the need of reducing greenhouse gas. However, the use of multiple electric motors, i.e., one per wheel, allows to redefine the vehicle powertrain layout with great benefits on vehicle dynamics. Electric motors braking torque is in gene...

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Main Authors: Michele Vignati, Mattia Belloni, Davide Tarsitano, Edoardo Sabbioni
Format: Article
Language:English
Published: Hindawi Limited 2021-01-01
Series:Mathematical Problems in Engineering
Online Access:http://dx.doi.org/10.1155/2021/1088805
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spelling doaj-2604e83b0197464dbfbf6f4c7bbfb6192021-07-19T01:04:30ZengHindawi LimitedMathematical Problems in Engineering1563-51472021-01-01202110.1155/2021/1088805Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking TorquesMichele Vignati0Mattia Belloni1Davide Tarsitano2Edoardo Sabbioni3Department of Mechanical EngineeringDepartment of Mechanical EngineeringDepartment of Mechanical EngineeringDepartment of Mechanical EngineeringElectric vehicles are spreading in automotive industry pushed by the need of reducing greenhouse gas. However, the use of multiple electric motors, i.e., one per wheel, allows to redefine the vehicle powertrain layout with great benefits on vehicle dynamics. Electric motors braking torque is in general not enough to produce high decelerations. Hydraulic friction brakes are still necessary for safety reasons and to avoid oversized motors. This paper presents a control strategy for distributed electric motors (EM), one per wheel, to maximize the regenerative braking. The controller handles cooperative braking among EMs and hydraulic brakes, which are still necessary to guarantee top braking performance of the car. The proposed algorithm considers the driver requested braking torque as well as the required yaw moment by stability control system. Motor efficiency map and wheel normal load are considered to optimally distribute the torques. With respect to conventional distribution strategies, the presented algorithm improves performance, maximizing the regenerative braking power.http://dx.doi.org/10.1155/2021/1088805
collection DOAJ
language English
format Article
sources DOAJ
author Michele Vignati
Mattia Belloni
Davide Tarsitano
Edoardo Sabbioni
spellingShingle Michele Vignati
Mattia Belloni
Davide Tarsitano
Edoardo Sabbioni
Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
Mathematical Problems in Engineering
author_facet Michele Vignati
Mattia Belloni
Davide Tarsitano
Edoardo Sabbioni
author_sort Michele Vignati
title Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
title_short Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
title_full Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
title_fullStr Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
title_full_unstemmed Optimal Cooperative Brake Distribution Strategy for IWM Vehicle Accounting for Electric and Friction Braking Torques
title_sort optimal cooperative brake distribution strategy for iwm vehicle accounting for electric and friction braking torques
publisher Hindawi Limited
series Mathematical Problems in Engineering
issn 1563-5147
publishDate 2021-01-01
description Electric vehicles are spreading in automotive industry pushed by the need of reducing greenhouse gas. However, the use of multiple electric motors, i.e., one per wheel, allows to redefine the vehicle powertrain layout with great benefits on vehicle dynamics. Electric motors braking torque is in general not enough to produce high decelerations. Hydraulic friction brakes are still necessary for safety reasons and to avoid oversized motors. This paper presents a control strategy for distributed electric motors (EM), one per wheel, to maximize the regenerative braking. The controller handles cooperative braking among EMs and hydraulic brakes, which are still necessary to guarantee top braking performance of the car. The proposed algorithm considers the driver requested braking torque as well as the required yaw moment by stability control system. Motor efficiency map and wheel normal load are considered to optimally distribute the torques. With respect to conventional distribution strategies, the presented algorithm improves performance, maximizing the regenerative braking power.
url http://dx.doi.org/10.1155/2021/1088805
work_keys_str_mv AT michelevignati optimalcooperativebrakedistributionstrategyforiwmvehicleaccountingforelectricandfrictionbrakingtorques
AT mattiabelloni optimalcooperativebrakedistributionstrategyforiwmvehicleaccountingforelectricandfrictionbrakingtorques
AT davidetarsitano optimalcooperativebrakedistributionstrategyforiwmvehicleaccountingforelectricandfrictionbrakingtorques
AT edoardosabbioni optimalcooperativebrakedistributionstrategyforiwmvehicleaccountingforelectricandfrictionbrakingtorques
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