Applications of Energy Storage Systems On Electric Vehicles

Mode of Delivery

Face to Face

Prerequisites and Co-Requisites

None

Recommended Optional Programme Components

Not Required

Course Contents

This course equips candidates with in-depth knowledge on the history of modern transportation and environmental impact, electric, hybrid electric and fuel cell vehicles and electric vehicle development and applications in energy storage systems, the structure of electric vehicles, vehicle performance, energy consumption, the structure of hybrid electric vehicles, series hybrid, parallel hybrid connections, the structure of fuel cell vehicles, electrochemical batteries, energy efficiency, battery technology, lead acid batteries, nickel-based batteries, lithium-based batteries, ultracapacitors, features of ultracapacitors, basic operating principles, performance, ultracapacite technologies, high-speed flywheels, flywheel of the working principles, the power capacity of the flywheel system, flywheel technology, energy storage system for fuel cell vehicles, fuel cells operating principle, characteristics of fuel cell systems, fuel cell technologies and varieties, hybrid electric vehicles and hydrogen storage, varieties, production of hydrogen, classification of the propulsion system in hybrid vehicles, and evaluation, comparison of energy storage systems in vehicles, energy storage systems in electric vehicles in terms of evaluating the energy economy, effects of electrical vehicle technology on automotive industry and new formations.

Weekly Schedule

1) History of Modern Transportation and Enviromental Impact, Electric, Hybrid Electric, Fuel Cell Vehicles and Electric Vehicle, Development and Applications in Energy Storage Systems.
2) The Structure of Electrical Vehicles, Vehicle Performance, energy Consumption.
3) Hybrid Electrical Vehicle Structure, Series Hybrid, Parallel Hybrid Connections.
4) Fuel Cell Vehicle Structure.
5) Electrochemical Batteries, Energy Efficiency, Battery Technology, Lead Acid Batteries, Nickel-based Batteries, Lithium-based Batteries.
6) Ultracapacitors and Features, Basic Operating Principles, Performance, Ultracapacite Technologies.
7) High Speed Flywheels, Flywheel of the Working Principles, Power Capacity of the Flywheel System, Flywheel technology.
8) Energy Systems in Fuel Cell Vehicle, Working Principles of Fuel Cells, Fuel Cell System Characteristics, and Types of Fuel Cell Technology.
9) Energy Systems in Fuel Cell Vehicle, Fuel Cell System Characteristics, and Types of Fuel Cell Technology.
10) Hydrogen Storage in Electric Vehicles and Hybrid Electric Vehicles, Production of Hydrogen, Varieties.
11) Hydrogen Storage in Electric and Hybrid Vehicles, Hydrogen Production.
12) Comparison of Energy Storage Systems Investigation in Vehicles.
13) Evaluation of Energy Storage Systems in Electrical Vehicles, in Terms of Energy Economy.
14) Evaluation of the Technological Developments in Energy Storage Systems.
15) The Effects of Electrical Vehicle Technology on Automotive Industry and New Formations.

Recommended or Required Reading

1- M. Ehsani, Y. Gao, S. E. Gay, A. Emadi, “Modern Electric, Hybrid Electric and Fuel Cell Vehicles; Fundamentals, Theory and Design”, 2005.
2- Papazov G., “Energy Storage Systems for Electric Vehicles”, 1995.
3- M. Ehsani, Y. Gao, S. E. Gay, A. Emadi, “Modern Electric, Hybrid Electric and Fuel Cell Vehicles; Fundamentals, Theory and Design”, 2005.
4- Papazov G., “Energy Storage Systems for Electric Vehicles”, 1995.
5- Energy Storage for Power System, A.Ter-Gazarian, IEE Energy Series, 1994.
6- Energy Storage, Pavlov D., G. Papazov, 1995.
7- Automotive Electronics Handbook, Ronald K. Jurgen.
8- S. M. Schoenung, “Characteristics and Technologies for Long-vs. Short-Term Energy Storage.”, Sandıa National Lab. Sandia Report, 2001.
9- Energy Storage for Power System, A.Ter-Gazarian, IEE Energy Series, 1994.
10- Energy Storage, Pavlov D., G. Papazov, 1995.
11- Automotive Electronics Handbook, Ronald K. Jurgen.
12- S. M. Schoenung, “Characteristics and Technologies for Long-vs. Short-Term Energy Storage.”, Sandıa National Lab. Sandia Report, 2001.
13- - M. Ehsani, Y. Gao, S. E. Gay, A. Emadi, “Modern Electric, Hybrid Electric and Fuel Cell Vehicles; Fundamentals, Theory and Design”, 2005. - Papazov G., “Energy Storage Systems for Electric Vehicles”, 1995. - Energy Storage for Power System, A.Ter-Gazarian, IEE Energy Series, 1994. - Energy Storage, Pavlov D., G. Papazov, 1995. - Automotive Electronics Handbook, Ronald K. Jurgen. - S. M. Schoenung, “Characteristics and Technologies for Long-vs. Short-Term Energy Storage.”, Sandıa National Lab. Sandia Report, 2001. - Dergilerde yayınlanan son on yıl içindeki makaleler
14- - M. Ehsani, Y. Gao, S. E. Gay, A. Emad, "Modern Electric, Hybrid Electric Vehicles and Fuel Cell, Fundamentals, Theory and Design", 2005. - Papazov G., "Energy Storage Systems for Electric Vehicles", 1995. - Power for Energy Storage System, A.Ter-Gazarian, IEE Energy Series, 1994. - Energy Storage, D. Pavlov, G. Papazov, 1995. - Automotive Electronics Handbook Ronald K. Jurgen. - S. M. Schoenung, "Characteristics and Technologies for Long-vs. Short-Term Energy Storage. "Sandia National Lab. Sandia Report, 2001.

Planned Learning Activities and Teaching Methods

1) Lecture
2) Discussion
3) Demonstration
4) Group Study
5) Problem Solving

Assessment Methods and Criteria

Contribution of Semester Studies to Course Grade	60%
Number Percentage Semester Studies Quiz 1 40% Presentation/Seminar 4 60%
Contribution of Final Examination to Course Grade	40%
Total	100%

Language of Instruction

Turkish

Work Placement(s)

Not Required