Further Development of a Techno-Economic Optimization for High-Temperature-Electrolysis Plant at Pressurized Operation

Institut

Lehrstuhl für Energiesysteme (TUM-ED)

Typ

Masterarbeit /

Inhalt

theoretisch /  

Beschreibung

Reversible solid oxide cells (rSOC) have the capacity to produce hydrogen using the electricity generated from the intermittent renewable sources, and to reverse the process within the same system for generating electricity as well. Namely, the technology has the potential to play a central role in green energy systems due to the highest efficiency, broad feedstock options and operational flexibility compared to PEM and alkaline technologies. Green hydrogen is especially interesting for chemical and energy conversion technologies to either manufacture platform chemicals, energy intermediates or support the flexibility of the energy sector. Therefore, the integration of rSOC systems in commercial Power-to-X (PtX) technologies like methanol synthesis, Fischer-Tropsch-synthesis or chemical-storage shows a significant potential for increases in performance and economic viability. A multitude of commercial PtX technologies is operated at higher pressures to either increase efficiencies, volumetric energy densities or shift reaction equilibria towards certain products. However, pressurized rSOC systems are not state-of-the-art and require further research and development.

Therefore, this work focuses on determining the economic and efficiency sweet spot of pressurized rSOC operation for various commercial process integration options. In this thesis, a techno-economic optimization model is to be further developed from a preexisting 0-D electrolysis plant model. The goal is to extend the model for pressurized Co-Electrolysis operation and determine the optimal system configuration for evaluating efficiency and economic viability via a sensitivity study. Different cases regarding the energy landscape and end-use of the produced syngas (H2 & CO) are to be examined.

• Study of existing python model for rSOC
• Implementation of Co-Electrolysis operation in model
• Further development of periphery to display full plant
• Check and extend economic factors and cost functions
• Evaluating different setups on economic and efficiency level via sensitivity study

Voraussetzungen

• Interest in system studies and their economics
• Basic knowledge in python programming and optimization
• Basic knowledge about energy conversion technologies

Möglicher Beginn

sofort

Kontakt

Sören Ohmstedt, M.Sc.
Raum: R3737
Tel.: 089 289 16342
soeren.ohmstedttum.de

Ausschreibung