Your search keyword '"EV applications"' showing total 4 results

1. Inductor‐based auxiliary circuit‐assisted ZVS in full‐bridge dc–dc converter for EV applications.

Author

Srivastava, Manaswi, Tomar, Pavan Singh, Verma, Arun Kumar, Kanamarlapudi, Venkata Ravi Kishore, and Sandeep, N.

Abstract

This study proposes an efficient soft‐switched full‐bridge DC/DC converter (FBDC) topology operated with modified pulse width modulation (MPWM) for electric vehicle (EV) battery chargers, as the role of DC/DC converter is more prominent in on‐board charging. The proposed auxiliary circuit offers zero voltage switching (ZVS) turn‐on to all the active switches of the converter during full battery charging range. In consequence, the losses associated with the proposed FBDC are minimal and offer maximum efficiency as compared to available benchmark topologies operated with different gating schemes. The size of magnetic elements used in the proposed topology also reduced as to conventional FBDC operating with trailing edge pulse width modulation and phase shifted modulation gating techniques. A detailed designing and analysis of the MPWM operated ZVS FBDC is presented. Besides, the rationale behind the selection of switching frequency in order to ensure wide‐range ZVS is detailed. Further the proposed topology is compared with the other competent topologies for proving its significant merits. Simulation of the proposed configuration is performed at 3.3 kW. Following which, the experimental results obtained from a laboratory prototype of 500 W, 80 kHz validating the operability and feasibility of the proposed converter are presented. [ABSTRACT FROM AUTHOR]

Published

2020

2. Optimisation of HF signal injection parameters for EV applications based on sensorless IPMSM drives.

Author

Zine, Wided, Idkhajine, Lahoucine, Monmasson, Eric, Makni, Zaatar, Chauvenet, Pierre‐Alexandre, Condamin, Bruno, and Bruyere, Antoine

Abstract

The study proposes a parameter optimisation of the high‐frequency (HF) signal injection sensorless algorithm applied to an interior permanent magnet synchronous machine (IPMSM). The latter is intended for electric vehicle (EV) traction applications with dedicated mission profile under specific constraints. This optimisation aims to minimise two conflicting objectives: (i) minimising the position estimation error which impacts the torque accuracy and (ii) minimising torque ripples responsible for additional stress on the motor shaft, causing unwanted noise in the vehicle powertrain. The main contribution of this study is to provide guidelines for the selection of the HF signal injection tuning parameters so as to satisfy these objectives. To do so, a genetic algorithm has been implemented and the optimisation process is based on a reliable simulation model. Using a simulation model is deliberately chosen in order to reflect the behaviour of a motor series. Besides, in order to integrate the specificities of the target application, the optimisation process is based on a typical EV mission profile. A set of non‐dominated solutions satisfying the tradeoff between the position error and the torque ripples is obtained, discussed and finally tested with success on an experimental setup. [ABSTRACT FROM AUTHOR]

Published

2018

3. Electric vehicles energy management using lithium-batteries and ultracapacitors

Author

Ismail Oukkacha, Brayima Dakyo, Mamadou Bailo Camara, Groupe de Recherche en Electrotechnique et Automatique du Havre (GREAH), Université Le Havre Normandie (ULH), and Normandie Université (NU)-Normandie Université (NU)

Subjects

Engineering, business.product_category, traction mode, energy storage system, voltage-source convertors, 02 engineering and technology, invertors, Electric vehicle, 7. Clean energy, DC motor, Traction motor, [SPI]Engineering Sciences [physics], 0203 mechanical engineering, Ultracapacitors, 0202 electrical engineering, electronic engineering, information engineering, Supercapacitors, PMSM, EV applications, DC-bus, Supercapacitor, traction motors, battery powered vehicles, Electrical engineering, VSI, Energy management, DC-DC power convertors, 020302 automobile design & engineering, antiwindup PI controller, synchronous motors, machine control, PI control, Anti-windup PI controller, Matalb-Simulink software, Synchronous motor, PMSM control, ultracapacitor pack, DC-DC converter, primary cells, Vehicle dynamics, electric vehicle applications, permanent magnet synchronous machine control, voltage source inverter, UC pack, Energy storage, EV power sharing, Bidirectional DC/DC converter, Synchronous machines, energy management systems, ESS, lithium-batteries, business.industry, 020208 electrical & electronic engineering, [SPI.NRJ]Engineering Sciences [physics]/Electric power, electric vehicle energy management, Lithium battery, DC-BUS, traction motor, business, permanent magnet motors

Abstract

International audience; This paper presents energy management strategy for electric vehicle (EV) applications. The proposed method is used to share the requested energy of the EV between the ultracapacitors (UCs) and lithium-batteries. The traction motor is a Permanent Magnet Synchronous Machine (PMSM) controlled by a Voltage-Source-Inverter (VSI) and fed by the UCs and the batteries. The energy storage system (ESS) is connected to DC-bus through two DC-DC converters. The aim of this paper is focused on requested EV power sharing between UCs pack and the batteries pack according to the dynamic response of these sources using anti-windup PI controller. This study is based on a real example of EV, in addition only the traction mode is considered. The performances of the proposed method are evaluated through some simulations using MATALB/Simulink software.

Published

2017

4. Energy management based on two-phase interleaved buck-boost and boost converters for Electric Vehicles applications - using lithium-battery and fuel cell

Author

Brayima Dakyo, Mamadou Bailo Camara, Hamid Gualous, Groupe de Recherche en Electrotechnique et Automatique du Havre (GREAH), Université Le Havre Normandie (ULH), Normandie Université (NU)-Normandie Université (NU), Laboratoire Universitaire des Sciences Appliquées de Cherbourg (LUSAC), and Université de Caen Normandie (UNICAEN)

Subjects

Engineering, Energy management, Context (language use), Lithium-battery, Polynomials, fuel cell vehicles, 7. Clean energy, Interleaved buck-boost converter, energy management method, converter efficiency, Dynamic control, [SPI.MAT]Engineering Sciences [physics]/Materials, Batteries, [SPI]Engineering Sciences [physics], currents control methods, PIC18F4431 microcontrollers, Electronic engineering, energy management systems, EV applications, Fuel cells, [PHYS]Physics [physics], Li, Buck converter, business.industry, Boost converter, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, [SPI.NRJ]Engineering Sciences [physics]/Electric power, Buck–boost converter, Voltage measurement, polynomial correctors, Converters, Current measurement, Polynomial control, energetic autonomy problems, power convertors, Microcontroller, lithium, Fuel Cell, Voltage control, dc-bus voltage, [SDE]Environmental Sciences, business, electric vehicles applications, electric current control, microcontrollers, two-phase interleaved buck-boost converters, Voltage

Abstract

International audience; This paper deals the energy management method between the lithium-battery and the fuel cell for the Electric Vehicles (EV) applications. This idea is due to the present trend in the EV applications, knowing that the major drawback in these last one is the energetic autonomy problems. In this context, using the lithium-battery and the fuel cell with a good strategy for energy management is a promising solution to improve the system's performances. This paper is focused on the DC-bus voltage and the currents control methods based on the two-phase interleaved buck-boost and boost converters using the polynomial's correctors. The two-phase interleaved buck-boost converter is proposed to do a good compromise between the cost and the converter's efficiency. The efficiency of the two-phase interleaved converter is compared to that of the conventional buck-boost converter. The proposed control methods are implemented in the two PIC18F4431 microcontrollers to control the experimental tests bench. Through some experimental results obtained in the reduced scale, the authors present an improved energy management method for the EV applications.

Published

2012