The impact of hybrid and electric powertrains on vehicle dynamics, control systems and energy regeneration

Crolla, D.A.; Cao, Dongpu

doi:10.1080/00423114.2012.676651

Cited by 112 publications

(58 citation statements)

References 61 publications

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“…These safety functionalities can be enhanced by means of torque-vectoring through the electric motors, as analysed in detail in De Novellis et al (2015) through experiments: a yaw moment can be continuously generated without variation of the net traction force. However, "despite the significant volume of theoretical studies of torque-vectoring on vehicle handling control, there is no widely accepted design methodology of how to exploit it to improve vehicle handling and stability significantly" (Crolla and Cao, 2012). In this respect, within the vehicle controller implementation presented in this paper, the driver can select between different driving modes (e.g., Normal, Sport and Eco), each of these corresponding to a specific set of reference understeer characteristics, and hence to different reference yaw rates, which can enhance the driver's experience also in common driving conditions at moderate lateral accelerations.…”

Section: Introductionmentioning

confidence: 99%

Integral sliding mode for the yaw moment control of four-wheel-drive fully electric vehicles with in-wheel motors

Goggia

Sorniotti

Novellis

et al. 2015

IJPT

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Fully electric vehicles with individually controlled motor drives allow the continuous actuation of direct yaw moment control in order to enhance vehicle safety and the handling performance by achieving a set of reference understeer characteristics. For applications on real vehicles, the control structure must provide ease of implementation, robustness and tunability. This paper discusses an integral sliding mode formulation for torque-vectoring control, which fulfils these requirements. The control structure is presented with reference to the vehicle cornering performance objectives, the motivation for integral sliding mode control and the selection of the controller parameters for stability and chattering avoidance. Six different manoeuvres are simulated for an in-wheel electric motor drivetrain layout. The results show that integral sliding mode control has significant benefits over a more conventional control method based on a combined feedforward and proportional-integral-derivative controller. The integral sliding mode controller does not require fine tuning of a feedforward control action and is characterised by superior tracking performance and disturbance rejection properties. Integral sliding mode for the yaw moment control of four-wheel-drive 389

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Section: Introductionmentioning

confidence: 99%

Integral sliding mode for the yaw moment control of four-wheel-drive fully electric vehicles with in-wheel motors

Goggia

Sorniotti

Novellis

et al. 2015

IJPT

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“…As recently pointed out in [7], 'despite the significant volume of theoretical studies of torque-vectoring on vehicle handling control, there is no widely accepted design methodology of how to exploit it to improve vehicle handling and stability significantly'. To address this issue, novel analytical tools and metrics are required that provide data for the engineer to make an informed design choice.…”

Section: Introductionmentioning

confidence: 99%

Design and comparison of the handling performance of different electric vehicle layouts

Novellis

Sorniotti

Gruber

2013

Proceedings of the Institution of Mechanical Engineers, Part D:

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In contrast to conventional internal combustion engine driven vehicles, the number of motors in fully electric cars is not fixed. A variety of architectural solutions, including from one to four individually controlled electric drive units, With respect to linear handling characteristics, the simulations indicate that the influence of torque-vectoring is independent of the location of the controlled axles (front or rear) and considerably affected by the number of controlled axles.

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“…Low-emission pure electric vehicles are among the most effective technologies to alleviate such dependency and promote further developments of green transportation [2]. The design of the powertrain structure and the drive control strategy of pure electric vehicles (PEVs) are important for high economic, dynamic, and ride comfort performances [3].…”

Section: Introductionmentioning

confidence: 99%

Optimization and Model Validation of Operation Control Strategies for a Novel Dual-Motor Coupling-Propulsion Pure Electric Vehicle

Zheng

Jia

et al. 2018

Energies

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Abstract:The strict operational condition of driving motors for vehicles propels the development of more complicated configurations in pure electric vehicles (PEVs). Multi-power-source powertrain configurations are one of the efficient technologies to reduce the manufacturing difficulty of driving motors. However, most of the existing studies are predominantly focused on optimal designs of powertrains and power distribution between the engine and motor of hybrid electric vehicles, which are not appropriate for PEVs. This paper proposes a novel dual-motor coupling-propulsion powertrain system that improves the dynamic and economic performance of the powertrain system in PEVs. The proposed powertrain system can realize both the single-motor driving mode and dual-motor coupling driving mode. The driving modes are divided and a power distribution strategy for the different driving modes based on an optimal system efficiency rule is employed, which enhances the performance of the proposed system. Further, a mode-switching strategy that ensures driving comfort by preventing jerk during mode switching is incorporated into the system. The results of comparative evaluations that were conducted using a dual-motor electric vehicle model implemented in MATLAB/Simulink, indicate that the mileage and dynamic performance of the proposed powertrain system are significantly better than those of the traditional single-motor powertrain system.

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The impact of hybrid and electric powertrains on vehicle dynamics, control systems and energy regeneration

Cited by 112 publications

References 61 publications

Integral sliding mode for the yaw moment control of four-wheel-drive fully electric vehicles with in-wheel motors

Integral sliding mode for the yaw moment control of four-wheel-drive fully electric vehicles with in-wheel motors

Design and comparison of the handling performance of different electric vehicle layouts

Optimization and Model Validation of Operation Control Strategies for a Novel Dual-Motor Coupling-Propulsion Pure Electric Vehicle

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