Course Overview
If the good features of the gasoline engine could be combined with those of the electric motor to produce a superior car. The gasoline engine contributes to the favorable range capability. The electric car provides quiet comfort and ease of control. A combination of the two yields the hybrid automobile.This course provides an excellent in depth understanding of different components of Hybrid electric vehicles(HEV’s).How the architecture is different from gasoline cars? Which energy storage method best suits the hybrid architecture as well as how the electronics change from conventional vehicles? The course also highlights various control strategies used in HEVsHEVs and case studies of HEV’s to apply theoretical knowledge in practical applications.
Who is this program for?
The program is designed for students or professionals who are:
- Having a Diploma, BE / B.Tech or equivalent in domains such as Automotive, Mechanical, EEE, ECE, Instrumentation, Mechatronics.
- Designing enthusiasts (No academic qualification mandatory)
- Working in industries such as Automotive, Auto components, Design, Manufacturing, etc.
- Working in Functional areas such as R&D, Analysis, Maintenance, Projects, component design, etc.
- Interested in pursuing further studies on a part-time or full-time basis in the Design and Engineering Sector.
- Candidates looking to enter Electric Vehicle domain specializations.
Course Syllabus
- Introduction to Sustainable Transportation
- Architecture of Hybrid Electric Drive trains
- Electronics in HEV
- Energy Storage systems for Hybrids
- Electric propulsion systems
- Hybrid drive train design
- Case Study
Detailed Curriculum
EV-HEV-PHEV-FCV
Brief History on Hybrid Electric Vehicles(HEV)
What are Micro,Mild and Smart Hybrids
Layouts of HEV
Series
Parallel
Series Parallel
Complex
Diesel and Other hybrids
Other approaches to Hybridization
Hybridization ratio
Concept of Hybrid Electric Drive trains
System level diagram of HEV
Series Hybrid Drivetrain(Electrical Coupling)
Power flow Control in Series Drivetrain
Parallel Hybrid Drivetrain
Parallel Hybrid Drivetrain with Torque Coupling
Parallel Hybrid Drivetrain with Speed Coupling
Hybrid Drive train with both Speed and Torque Coupling
Power flow Control in Parallel Hybrid Drivetrain
Power flow Control in Series-Parallel Hybrid Drivetrain(ICE and EM dominated)
Power flow control in Complex Hybrids(Front Hybrid Rear Electric and Front Electric Rear Hybrids)
DC-DC converters for EV and HEV Applications
DC-AC Inverters for EV and HEV applications
Electrochemical batteries
Specific Energy
Specific Power
Energy Density
Energy efficiency
Battery Technologies
Lead acid
Nickel-based batteries
Lithium-based batteries
Ultracapacitors
Ultra high-speed flywheels
Hybridization of energy storage
DC Motor drives-Operating principle and performance
Induction motor drives-Operating principle and performance
Permanent magnet Brushless DC motor drives
Switched reluctance motor drives
Control strategies
Design of Engine power capacity
Design of electric motor power capacity
Transmission design
Energy storage design
Toyota Prius and Toyota Power Split device
Honda Civic
MATLAB
E-Vehicle Design Engineer/Hybrid design engineer/EV Engineer/simulation engineer for companies in E mobility.
Who Should Enroll:
This course is designed for automotive engineers, design technicians, EV enthusiasts, and students in related fields who are interested in advancing their careers by gaining a detailed understanding of hybrid electric vehicles.
Learning Outcomes:
- Gain a comprehensive understanding of hybrid electric vehicle technologies and their components.
- Develop the skills to design and optimize hybrid drivetrains.
- Understand the environmental impact and sustainability practices associated with HEVs.
- Be equipped to contribute to advancements in hybrid vehicle technologies.
Certification:
Upon successful completion, participants will receive a Certification in Hybrid Electric Vehicle Technology, certifying their expertise in this crucial area of automotive innovation.
