About Me

header ads

ELECTRIC VEHICLE TECHNOLOGIES (18EE823)

ELECTRIC VEHICLE TECHNOLOGIES

Subject Code 18EE823 
CIE Marks 40
Number of Lecture Hours/Week (L:T:P)3:0:0 
SEE Marks 60
Credits 03 
Exam Hours 03



Course Learning Objectives:
· To understand working of Electric Vehicles and recent trends.
· Ability to analyze different power converter topology used for electric vehicle application.
· Ability to develop the electric propulsion unit and its control for application of electric vehicles.
· Ability to design converters for battery charging and explain transformer less topology.

Module-1

Electric and Hybrid Electric Vehicles
Configuration of Electric Vehicles, Performance of Electric Vehicles, Traction motor characteristics,
Tractive effort and Transmission requirement, Vehicle performance, Tractive effort in normal
driving, Energy consumption Concept of Hybrid Electric Drive Trains, Architecture of Hybrid
Electric Drive Trains, Series Hybrid Electric Drive Trains, Parallel hybrid electric drive trains.


Module-2

Energy storage for EV and HEV Energy storage requirements, Battery parameters, Types of Batteries, Modelling of Battery, Fuel Cell basic principle and operation, Types of Fuel Cells, PEMFC and its operation, Modelling of PEMFC, Supercapacitors.

Module-3

Electric Propulsion EV consideration, DC motor drives and speed control, Induction motor drives, Permanent Magnet Motor Drives, Switch Reluctance Motor Drive for Electric Vehicles, Configuration and control of Drives.

Module – 4

Design of Electric and Hybrid Electric Vehicles Series Hybrid Electric Drive Train Design: Operating patterns, control strategies, Sizing of major components, power rating of traction motor, power rating of engine/generator, design of PPS Parallel Hybrid Electric Drive Train Design: Control strategies of parallel hybrid drive train, design of engine power capacity, design of electric motor drive capacity, transmission design, energy storage design.

Module – 5

Power Electronic Converter for Battery Charging Charging methods for battery, Termination methods, charging from grid, The Z-converter, Isolated bidirectional DC-DC converter, Design of Z- converter for battery charging, High-frequency transformer based isolated charger topology, Transformer less topology.

Course Outcomes: At the end of the course the student will be able to:

· Explain the working of electric vehicles and recent trends.
· Analyze different power converter topology used for electric vehicle application.
· Develop the electric propulsion unit and its control for application of electric vehicles.
· Design converters for battery charging and explain transformer less topology.

Question paper pattern:

· The question paper will have ten questions.
· Each full question is for 20 marks.
· There will be 2 full questions (with a maximum of three sub questions in one full question) from each
module.
· Each full question with sub questions will cover the contents under a module.
· Students will have to answer 5 full questions, selecting one full question from each module.

Text Books

1 Modern Electric, Hybrid Electric, and Fuel Cell Vehicles: Fundamentals, Theory, and Design M. Ehsani, Y. Gao, S. Gay and Ali Emadi C RC Press 2005
2 Electric and Hybrid Vehicles: Design Fundamentals Iqbal Husain CRC Press 2003

Reference Books

1 Energy Management Strategies for Electric and Plug-in Hybrid Electric Vehicles Sheldon S. Williamson Springer 2013
2 Modern Electric Vehicle Technology C.C. Chan and K.T. Chau OXFORD University Press 2001
3 Hybrid Electric Vehicles Principles And Applications With Practical Perspectives Chris Mi, M. Abul Masrur, David Wenzhong Gao Wiley Publication 2011

Post a Comment

0 Comments