Course Outcome
| CO1 | Illustrate the importance of the energy storage technology in power system |
| CO2 | Analyze the function of each storage technology and its characteristics |
| CO3 | Evaluate energy storage applications in Renewable energy systems, Electric vehicles and in Smart grid. |
| CO4 | Design energy storage devices for energy management and analyze its cost effectiveness |
Course Articulation Matrix: Correlation level [ 1: low, 2: medium, 3: High]
| PO | PO1 | PO2 | PO3 | PSO1 | PSO2 |
| CO | |||||
| CO1 | – | – | 1 | – | – |
| CO2 | 1 | – | – | – | |
| CO3 | 2 | – | 2 | – | – |
| CO4 | – | – | 1 | 3 | – |
Introduction to energy storage for power systems: Need and role of energy storage systems in power systems, applications, general considerations, Energy and power balance in a storage unit, Mathematical model of storage
Overview on Energy storage technologies: Potential energy (Pumped hydro, Compressed Air,) – Kinetic energy (Mechanical- Flywheel) Electrochemical energy (Batteries, Fuel cells) – Electrostatic energy (Super Capacitors), Electromagnetic energy (Superconducting Magnetic Energy Storage) – Different Types of Energy Storage Systems comparative analysis, Comparison of environmental impacts for different technologies.
Smart Grid and Electric Vehicle Storage Technology: Micro-grid/Smart Grid with SPV, Wind Energy, Fuel cell, Hydrogen, Battery Energy Storage with BMS, Balancing methods for battery pack: Active balancing and passive balancing, Battery Module & Pack Design, Battery management algorithms, Battery SCADA,
Hybrid Energy storage systems: configurations and applications, Improved Battery Technologies for Electric Vehicle- commercialized battery technologies, Second-life batteries Advanced batteries for EV Protection,cost analysis of EV batteries.