Energy Engineering

Learning outcomes / Skills:

Identifying, analyzing and solving complex problems within energy engineering, based on conventional, renewable and clean energy sources, including through the use of methods and techniques specific to applied and industrial research. Planning and coordinating the vertical development of energy systems based on conventional, renewable and clean energy sources in order to achieve the objectives from an energy point of view (maximum energy efficiency, resilience, economic profitability, minimized impact on the environment and society, adaptation to climate change).

The achievement of holistic horizontal integration between energy systems based on conventional, renewable and clean energy sources so that the technical-economic optimum is reached on their whole

Implementation of solutions based on IT/digital means within energy systems;

Approaching energy projects based on various energy sources in the context of sustainable development and energy resilience

The development of projects in the field of energy systems based on conventional, renewable and clean energy sources, including by addressing elements aimed at financing them

Research topics (selection)

Intelligent energy systems (smart grid, super grid, smart buildings); Application of energy technologies in buildings to increase energy efficiency (passive houses, zero-energy houses); Strategies for implementing renewable energy solutions; Optimization of hybrid energy systems; Energy storage; Solutions based on IT/digital means in energy systems; Study of new generations of nuclear reactors, including SMR; Study of energy recovery and utilization technologies; Environmental and human health impact assessment of different energy technologies; Analysis of energy systems and processes using mathematical modeling and simulation techniques.

Enjoy international experience in EELISA alliance partners, https://eelisa.eu/. All subject of the program are open to receiving Erasmus incoming students.