Your search keyword '"electro-hydraulic braking"' showing total 3 results

1. Energy Storage Systems for Electric Vehicles.

Subjects

History of engineering & technology, AC-AC converters, CFD, CVT speed ratio control, EV batteries, Electric Truck Simulator, Electric Vehicle (EV), Kalman filter, Lithium-ion battery, MATLAB, MeshWorks, SEI forming additives, SLI battery, Simscape, Traveling Salesman Problem (TSP), Vehicle Routing Problem (VRP), adaptive EKF SOC estimation, adaptive equivalent consumption minimization strategy (A-ECMS), adaptive model-based algorithm, artificial intelligence, artificial neural networks, automated guided vehicle, autoregressive models of nonstationary signals, available capacity, battery, battery capacity, battery chargers, battery life, battery mechanical aging, battery modelling and simulation, battery recycling, battery reusing, battery sizing, battery testing cycler, battery thermal management, battery thermal model, braking force distribution, braking intention, butyronitrile, cabin heating, cell expansion, coulomb counting, diffusion induced stress, driving conditions identification, dual-motor energy recovery, echelon utilization, electric bus, electric buses, electric vehicle, electric vehicles, electrified propulsion, electro-hydraulic braking, electrochemical-thermal model, electrode particle model, energy consumption and efficiency characteristics, energy efficiency, energy management, energy storage applications, environmental conditions, equalization algorithm, estimation, fast charging, force, fuel cell, fuel cell hybrid electric vehicle, fuzzy unscented Kalman filtering algorithm, global optimization, heat and mass transfer, hybrid electric vehicles (HEVs), hybrid energy storage system, hybrid vehicles, hydrostatic stress influence on diffusion, improved second-order RC equivalent circuit, iron phosphate, joint estimation, latent heat storage, layered bidirectional equalization, least squares support vector machines (LSSVM), least-energy routing algorithm, li-ion battery, linear observer SOC estimation, linear quadratic estimator, lithium ion battery, lithium-ion batteries, lithium-ion battery, lithium-ion cobalt battery, lithium-ion polymer battery, lowest instantaneous energy costs, metallic phase change material, metric evaluation, micro-channel cooling plate, mode switching, model-based design, motor minimum loss, multi-objective energy management, new energy vehicle, nitrile-based solvents, non-aqueous electrolyte, oil-electric-hydraulic hybrid system, open circuit voltage, open-circuit voltage, optimal energy management, particle swarm optimization (PSO), performance degradation modelling, pontryagin's minimum principle (PMP), power batteries, power battery, power conversion harmonics, power distribution, powertrain optimization, recurrent-neural-network (RNN), regenerative braking system, resistance, retired batteries, square root cubature Kalman filter, state of charge, state of energy, state of health, state-of-charge, state-of-charge estimation (SOC), state-of-health, temperature, thermal analysis, thermal energy storage, torque coordinated control, waveforms modeling, wireless power transmission

Abstract

Summary: The global electric car fleet exceeded 7 million battery electric vehicles and plug-in hybrid electric vehicles in 2019, and will continue to increase in the future, as electrification is an important means of decreasing the greenhouse gas emissions of the transportation sector. The energy storage system is a very central component of the electric vehicle. The storage system needs to be cost-competitive, light, efficient, safe, and reliable, and to occupy little space and last for a long time. It should also be produced and disposed of in an environmentally friendly manner. This leaves many research challenges, and the purpose of this book is therefore to provide a platform for sharing the latest findings on energy storage systems for electric vehicles (electric cars, buses, aircraft, ships, etc.) Research in energy storage systems requires several sciences working together, and this book therefore include contributions from many different disciplines; this covers a wide range of topics, e.g. battery-management systems, state-of-charge and state-of-health estimation, thermal-battery-management systems, power electronics for energy storage devices, battery aging modelling, battery reuse and recycling, etc.

2. A Pressure-Coordinated Control for Vehicle Electro-Hydraulic Braking Systems

Author

Yang Yang, Guangzheng Li, and Quanrang Zhang

Subjects

hybrid electric vehicle, electro-hydraulic braking, braking force distribution, braking system design, pressure coordinated control, Technology

Abstract

The characteristics of electro-hydraulic braking systems have a direct influence on the fuel consumption, emissions, brake safety, and ride comfort of hybrid electric vehicles. In order to realize efficient energy recovery for ensuring braking safety and considering that the existing electro-hydraulic braking pressure control systems have control complexity disadvantages and functional limitations, this study considers the front and rear dual-motor-driven hybrid electric vehicle as the prototype and based on antilock brake system (ABS) hardware, proposes a new braking pressure coordinated control system with electro-hydraulic braking function and developed a corresponding control strategy in order to realize efficient energy recovery and ensure braking safety, while considering the disadvantages of control complexity and functional limitations of existing electro-hydraulic system. The system satisfies the pressure coordinated control requirements of conventional braking, regenerative braking, and ABS braking. The vehicle dynamics model based on braking control strategy and pressure coordinated control system is established, and thereafter, the performance simulation of the vehicle-based pressure coordinated control system under typical braking conditions is carried out to validate the performance of the proposed system and control strategy. The simulation results show that the braking energy recovery rates under three different conditions—variable braking intensity, constant braking intensity and integrated braking model—are 66%, 55% and 47%. The battery state of charge (SOC) recovery rates are 0.37%, 0.31% and 0.36%. This proves that the motor can recover the reduced energy of the vehicle during braking and provide an appropriate braking force. It realizes the ABS control function and has good dynamic response and braking pressure control accuracy. The simulation results illustrate the effectiveness and feasibility of the program which lays the foundation for further design and optimization of the new regenerative braking system.

Published

2018

3. A Pressure-Coordinated Control for Vehicle Electro-Hydraulic Braking Systems

Author

Guangzheng Li, Yang Yang, and Quanrang Zhang

Subjects

Control and Optimization, business.product_category, Computer science, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, Automotive engineering, Vehicle dynamics, Electric vehicle, Brake, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), hybrid electric vehicle, braking force distribution, braking system design, Renewable Energy, Sustainability and the Environment, Pressure control, lcsh:T, 020208 electrical & electronic engineering, electro-hydraulic braking, Anti-lock braking system, Regenerative brake, Control system, business, Energy (miscellaneous), Efficient energy use, pressure coordinated control

Abstract

The characteristics of electro-hydraulic braking systems have a direct influence on the fuel consumption, emissions, brake safety, and ride comfort of hybrid electric vehicles. In order to realize efficient energy recovery for ensuring braking safety and considering that the existing electro-hydraulic braking pressure control systems have control complexity disadvantages and functional limitations, this study considers the front and rear dual-motor-driven hybrid electric vehicle as the prototype and based on antilock brake system (ABS) hardware, proposes a new braking pressure coordinated control system with electro-hydraulic braking function and developed a corresponding control strategy in order to realize efficient energy recovery and ensure braking safety, while considering the disadvantages of control complexity and functional limitations of existing electro-hydraulic system. The system satisfies the pressure coordinated control requirements of conventional braking, regenerative braking, and ABS braking. The vehicle dynamics model based on braking control strategy and pressure coordinated control system is established, and thereafter, the performance simulation of the vehicle-based pressure coordinated control system under typical braking conditions is carried out to validate the performance of the proposed system and control strategy. The simulation results show that the braking energy recovery rates under three different conditions&mdash, variable braking intensity, constant braking intensity and integrated braking model&mdash, are 66%, 55% and 47%. The battery state of charge (SOC) recovery rates are 0.37%, 0.31% and 0.36%. This proves that the motor can recover the reduced energy of the vehicle during braking and provide an appropriate braking force. It realizes the ABS control function and has good dynamic response and braking pressure control accuracy. The simulation results illustrate the effectiveness and feasibility of the program which lays the foundation for further design and optimization of the new regenerative braking system.

Published

2018