Energy Storage
| Structure Type: | Study unit |
|---|---|
| Code: | ET00BN43 |
| Curriculum: | ETE 2023 |
| Level: | Bachelor of Engineering |
| Year of Study: | 4 (2026) |
| Semester: | Spring |
| Credits: | 5 cr |
| Responsible Teacher: | Songok, Joel |
| Language of Instruction: | English |
Courses During the Academic Year 2025-2026
| Impl. | Group(s) | Study Time | Teacher(s) | Language |
|---|---|---|---|---|
| 3001 | ET2023, ET2023-A, ET2023-B, ETE2023, ETE2023-A, ETE2023-B, ETE2023-C | 2026-01-07 – 2026-04-30 | Joel Songok | English |
Learning Outcomes
By the end of the course, students will be able to:
1. Explain the thermodynamic, electro-chemical, and mechanical principles underlying major energy storage technologies.
2. Evaluate and compare storage systems based on key metrics (e.g., energy density, power density, cycle life, round-trip efficiency).
3. Design basic models for storage system performance using analytical and simulation tools.
4. Analyze the integration of storage technologies into renewable energy systems, considering economic, environmental, and safety factors.
5. Apply critical thinking to solve real-world problems through literature review, data analysis, and collaborative project work.
6. Communicate technical concepts effectively via reports and presentations.
Student's Workload
135 hours including contact teaching and self-studies
Contents
The course content consist of Introduction to Energy storage, different types of energy storage: thermal, mechanical, electrochemical, chemical and electrical storage as well as the economics, sustainability and policy aspects.
Mode of Delivery / Planned Learning Activities and Teaching Methods
Contact teaching