Master Thesis Online
Travail de fin d'études et stage[BR]- Travail de fin d'études : Optimization of E-fuels Production and Water Utilisation in Remote Renewable Energy Hub with Carbon Capture and Storage[BR]- Stage
Swerdtfegers, Hugo 
Promotor(s) :
Ernst, Damien
Date of defense : 24-Jun-2024/25-Jun-2024 • Permalink : http://hdl.handle.net/2268.2/19896
TFE_SWERDTFEGERS_HUGO.pdfDetails
| Title : | Travail de fin d'études et stage[BR]- Travail de fin d'études : Optimization of E-fuels Production and Water Utilisation in Remote Renewable Energy Hub with Carbon Capture and Storage[BR]- Stage |
| Translated title : | [fr] Optimisation de la production de biocarburant et de l'utilisation de l'eau dans un centre d'énergie renouvelable éloigné avec capture et stockage du carbone |
| Author : | Swerdtfegers, Hugo
|
| Date of defense : | 24-Jun-2024/25-Jun-2024 |
| Advisor(s) : | Ernst, Damien
|
| Committee's member(s) : | Léonard, Grégoire
Louveaux, Quentin
Dachet, Victor
|
| Language : | English |
| Number of pages : | 80 |
| Keywords : | [en] RREH [en] Energy [en] CCS [en] Renewable [en] E-Fuel |
| Discipline(s) : | Engineering, computing & technology > Energy |
| Research unit : | Smart Grids Lab |
| Target public : | Researchers Professionals of domain Student General public Other |
| Complementary URL : | https://github.com/HugoSwerdtfegers/TFE_FT-Products |
| Institution(s) : | Université de Liège, Liège, Belgique |
| Degree: | Master en ingénieur civil électromécanicien, à finalité spécialisée en énergétique |
| Faculty: | Master thesis of the Faculté des Sciences appliquées |
Abstract
[en] This report explores the techno-economics of producing carbon-neutral synthetic fuel using Remote Renewable Energy Hubs (RREH). A RREH is a Power-to-X concept that aims to integrate and optimize renewable resources, designed in a remote area where high-quality renewable resources are abundant and harvested. The entire energy supply chain is modeled to characterize connectivity between technologies and processes.
The reference scenario considers the production of carbon-neutral synthetic methane, powered by solar and wind energy in Algeria, for delivery to North-western European market by 2030 for a system supplying 10 TWh annually.
The model has been developed to integrate Direct Ocean Capture (DOC), capturing carbon dioxide in the water rather than in the air. Results indicate a cost reduced by 2.94\% for the DOC scenario. Sensitivity analysis considers various parameters, including investment costs and operational flexibility, revealing configurations lowering the price by 8.28\%.
The study was then extended to account for the system’s water output, by considering it as a by-product with potential utility for local communities. Findings illustrate a scenario in which water is priced at 3.09 €/t, equivalent to the one in Europe, facilitating the provision of fresh water to thousands of residents. Other more favorable configurations offer prices reduction of 9.1\%.
A multi-hub configuration is then created to compare different hub locations economically and then see the possible interactions between them. The results show that a hub at Cap Horn, in southern Chile, can deliver synthetic methane at a cost reduced by 13.36\% compared to the reference scenario.
Finally, the Fischer-Tropsch reaction is modeled to obtain synthetic fuels for decarbonizing the transport and aviation sectors (kerosene, diesel and gasoline). The implementation of several configurations suggests costs ranging from 2.41 €/kg to 2.13 €/kg, similar to those in the scientific literature. A techno-economic study shows optimistic prices reduces by 20.7\% and the impact of a change in electrolyzer efficiency.
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