LEARNING OUTCOMES
-Understands a system level approach to thermal energy storage between Power plants, Industry, Community and building level
-Can prepare fundamental heat and mass balances of thermal energy storages
-Connects the need for thermal energy storage created by both RES-Electricity and RES-Heat
-Compares the functioning of different energy storage technologies & materials
-Is able to characterize energy storage by technology, temperature, and timescale
-Applies thermal energy storages to a case study
Credits: 5
Schedule: 28.04.2025 - 28.05.2025
Teacher in charge (valid for whole curriculum period):
Teacher in charge (applies in this implementation): Andrea Ferrantelli
Contact information for the course (applies in this implementation):
CEFR level (valid for whole curriculum period):
Language of instruction and studies (applies in this implementation):
Teaching language: English. Languages of study attainment: English
CONTENT, ASSESSMENT AND WORKLOAD
Content
valid for whole curriculum period:
This course introduces a system level approach to thermal energy storage (TES), considering the fundamentals of TES, and how it can improve the sustainability of energy systems. TES is introduced by assessing the need for its application, including excess heat from industrial and energy sector installations, production and demand mismatch (especially with RES production) and the role of consumer side incentive such as dynamic electricity and heat tariffs. A common approach is taken to all TES technologies emphasizing the importance of temperatures and timescale (seasonal vs short term). The use of TES at different levels is
then assessed as follows:
A. Power plants, Industrial level, including use of DH network for storage
B. Community level e.g. ATES, BTES, CTES, PTES
C. Buildings e.g. Thermal mass, phase change materials, Chemical storage, DSM with HP ground heat storage (rock/soil)
Assessment Methods and Criteria
valid for whole curriculum period:
Case studies, Personal Assignments, Project
Workload
valid for whole curriculum period:
Contact hours (12 x 2 h) = 24 h
Excursion = 6 h
Individual assignments and reading = 60 h
Project work = 44 h
Assessment session = 3 h
DETAILS
Study Material
valid for whole curriculum period:
Reading material provided during the course
Substitutes for Courses
valid for whole curriculum period:
Prerequisites
valid for whole curriculum period:
SDG: Sustainable Development Goals
7 Affordable and Clean Energy
9 Industry, Innovation and Infrastructure
11 Sustainable Cities and Communities
13 Climate Action
FURTHER INFORMATION
Further Information
valid for whole curriculum period:
Teaching Language: English
Teaching Period: 2024-2025 Spring V - V
2025-2026 Spring V - VRegistration:
The course has a total amount of 60 participants. First priority with students from the Advanced Energy Solutions Masters program (all majors). Registration for the course via Sisu (sisu.aalto.fi)