Your search keyword '"Zeyu Chen"' showing total 6 results

1. A Model-Based Sensor Fault Diagnosis Scheme for Batteries in Electric Vehicles

Author

Quanqing Yu, Changjiang Wan, Junfu Li, Rui Xiong, and Zeyu Chen

Subjects

battery management system, sensor fault diagnosis, fault-tolerant control, state of charge, open-circuit voltage, multiple residuals, Technology

Abstract

The implementation of each function of a battery management system (BMS) depends on sensor data. Efficient sensor fault diagnosis is essential to the durability and safety of battery systems. In this paper, a model-based sensor fault diagnosis scheme and fault-tolerant control strategy for a voltage sensor and a current sensor are proposed with recursive least-square (RLS) and unscented Kalman filter (UKF) algorithms. The fault diagnosis scheme uses an open-circuit voltage residual generator and a capacity residual generator to generate multiple residuals. In view of the different applicable state of charge (SOC) intervals of each residual, different residuals need to be selected according to the different SOC intervals to evaluate whether a sensor fault occurs during residual evaluation. The fault values of the voltage and current sensors are derived in detail based on the open-circuit voltage residual and the capacity residual, respectively, and applied to the fault-tolerant control of battery parameters and state estimations. The performance of the proposed approaches is demonstrated and evaluated by simulations with MATLAB and experimental studies with a commercial lithium-ion battery cell.

Published

2021

2. Optimal Energy Management of Plug-In Hybrid Electric Vehicles Concerning the Entire Lifespan of Lithium-Ion Batteries

Author

Zeyu Chen, Jiahuan Lu, Bo Liu, Nan Zhou, and Shijie Li

Subjects

battery aging, plug-in electric vehicles, energy management, global optimization, state of health, particle swarm algorithm, Technology

Abstract

The performance of lithium-ion batteries will inevitably degrade during the high frequently charging/discharging load applied in electric vehicles. For hybrid electric vehicles, battery aging not only declines the performance and reliability of the battery itself, but it also affects the whole energy efficiency of the vehicle since the engine has to participate more. Therefore, the energy management strategy is required to be adjusted during the entire lifespan of lithium-ion batteries to maintain the optimality of energy economy. In this study, tests of the battery performances under thirteen different aging stages are involved and a parameters-varying battery model that represents the battery degradation is established. The influences of battery aging on energy consumption of a given plug-in hybrid electric vehicle (PHEV) are analyzed quantitatively. The results indicate that the variations of capacity and internal resistance are the main factors while the polarization and open circuit voltage (OCV) have a minor effect on the energy consumption. Based on the above efforts, the optimal energy management strategy is proposed for optimizing the energy efficiency concerning both the fresh and aging batteries in PHEV. The presented strategy is evaluated by a simulation study with different driving cycles, illustrating that it can balance out some of the harmful effects that battery aging can have on energy efficiency. The energy consumption is reduced by up to 2.24% compared with that under the optimal strategy without considering the battery aging.

Published

2020

3. Optimal Energy Management Strategy of a Plug-in Hybrid Electric Vehicle Based on a Particle Swarm Optimization Algorithm

Author

Zeyu Chen, Rui Xiong, Kunyu Wang, and Bin Jiao

Subjects

plug-in hybrid electric vehicle, energy management strategy, particle swarm optimization, global optimal control, Technology

Abstract

Plug-in hybrid electric vehicles (PHEVs) have been recognized as one of the most promising vehicle categories nowadays due to their low fuel consumption and reduced emissions. Energy management is critical for improving the performance of PHEVs. This paper proposes an energy management approach based on a particle swarm optimization (PSO) algorithm. The optimization objective is to minimize total energy cost (summation of oil and electricity) from vehicle utilization. A main drawback of optimal strategies is that they can hardly be used in real-time control. In order to solve this problem, a rule-based strategy containing three operation modes is proposed first, and then the PSO algorithm is implemented on four threshold values in the presented rule-based strategy. The proposed strategy has been verified by the US06 driving cycle under the MATLAB/Simulink software environment. Two different driving cycles are adopted to evaluate the generalization ability of the proposed strategy. Simulation results indicate that the proposed PSO-based energy management method can achieve better energy efficiency compared with traditional blended strategies. Online control performance of the proposed approach has been demonstrated through a driver-in-the-loop real-time experiment.

Published

2015

4. Optimal Energy Management of Plug-In Hybrid Electric Vehicles Concerning the Entire Lifespan of Lithium-Ion Batteries

Author

Bo Liu, Nan Zhou, Jiahuan Lu, Zeyu Chen, and Shijie Li

Subjects

Battery (electricity), Control and Optimization, business.product_category, energy management, Energy management, State of health, Computer science, 020209 energy, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Internal resistance, lcsh:Technology, Automotive engineering, plug-in electric vehicles, 0203 mechanical engineering, Electric vehicle, genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, battery aging, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy economics, state of health, particle swarm algorithm, lcsh:T, Renewable Energy, Sustainability and the Environment, Open-circuit voltage, global optimization, 020302 automobile design & engineering, Energy consumption, chemistry, Lithium, business, Energy (miscellaneous), Efficient energy use

Abstract

The performance of lithium-ion batteries will inevitably degrade during the high frequently charging/discharging load applied in electric vehicles. For hybrid electric vehicles, battery aging not only declines the performance and reliability of the battery itself, but it also affects the whole energy efficiency of the vehicle since the engine has to participate more. Therefore, the energy management strategy is required to be adjusted during the entire lifespan of lithium-ion batteries to maintain the optimality of energy economy. In this study, tests of the battery performances under thirteen different aging stages are involved and a parameters-varying battery model that represents the battery degradation is established. The influences of battery aging on energy consumption of a given plug-in hybrid electric vehicle (PHEV) are analyzed quantitatively. The results indicate that the variations of capacity and internal resistance are the main factors while the polarization and open circuit voltage (OCV) have a minor effect on the energy consumption. Based on the above efforts, the optimal energy management strategy is proposed for optimizing the energy efficiency concerning both the fresh and aging batteries in PHEV. The presented strategy is evaluated by a simulation study with different driving cycles, illustrating that it can balance out some of the harmful effects that battery aging can have on energy efficiency. The energy consumption is reduced by up to 2.24% compared with that under the optimal strategy without considering the battery aging.

Published

2020

5. Optimal Energy Management Strategy of a Plug-in Hybrid Electric Vehicle Based on a Particle Swarm Optimization Algorithm

Author

Kunyu Wang, Bin Jiao, Zeyu Chen, and Rui Xiong

Subjects

Engineering, Control and Optimization, Energy management, Energy Engineering and Power Technology, lcsh:Technology, jel:Q40, energy management strategy, jel:Q, jel:Q43, jel:Q42, jel:Q41, jel:Q48, global optimal control, jel:Q47, Electrical and Electronic Engineering, Multi-swarm optimization, MATLAB, Engineering (miscellaneous), computer.programming_language, jel:Q49, plug-in hybrid electric vehicle, particle swarm optimization, Renewable Energy, Sustainability and the Environment, business.industry, lcsh:T, Particle swarm optimization, jel:Q0, jel:Q4, Fuel efficiency, Electricity, business, computer, Algorithm, Driving cycle, Energy (miscellaneous), Efficient energy use

Abstract

Plug-in hybrid electric vehicles (PHEVs) have been recognized as one of the most promising vehicle categories nowadays due to their low fuel consumption and reduced emissions. Energy management is critical for improving the performance of PHEVs. This paper proposes an energy management approach based on a particle swarm optimization (PSO) algorithm. The optimization objective is to minimize total energy cost (summation of oil and electricity) from vehicle utilization. A main drawback of optimal strategies is that they can hardly be used in real-time control. In order to solve this problem, a rule-based strategy containing three operation modes is proposed first, and then the PSO algorithm is implemented on four threshold values in the presented rule-based strategy. The proposed strategy has been verified by the US06 driving cycle under the MATLAB/Simulink software environment. Two different driving cycles are adopted to evaluate the generalization ability of the proposed strategy. Simulation results indicate that the proposed PSO-based energy management method can achieve better energy efficiency compared with traditional blended strategies. Online control performance of the proposed approach has been demonstrated through a driver-in-the-loop real-time experiment.

Published

2015

6. A Novel Single-Turn Permanent Magnet Synchronous Machine for Electric Aircraft

Author

Zeyu Cheng, Zhi Cao, John T. Hwang, and Chris Mi

Subjects

coil configuration, more electric aircraft, multiphase permanent magnet synchronous motor (PMSM), power density, Technology

Abstract

This paper proposes a novel multi-phase single-turn permanent magnet synchronous motor (MSPMSM) to meet the stringent requirements of electric aircraft, such as high power density, high torque, and low mass and volume. The MSPMSM features a unique single-turn winding configuration, which can reduce the coil overhang, increase the power density and torque, and reduce the weight of the motor in conventional multi-turn motors. The proposed MSPMSM is studied by the finite element method (FEM) and compared to a conventional PMSM with the same geometry and PM usage. The performance comparison results under different load conditions show that the proposed MSPMSM has higher torque and power density than the conventional motor.

Published

2023