TY - GEN
T1 - Thermo-economic comparison of CO2 and water as a heat carrier for long-distance heat transport from geothermal sources
AU - Ungar, Pietro
AU - Schifflechner, Christopher
AU - Wieland, Christoph
AU - Spliethoff, Hartmut
AU - Manfrida, Giampaolo
N1 - Publisher Copyright:
© (2023) by ECOS 2023 All rights reserved.
PY - 2023
Y1 - 2023
N2 - Deep geothermal energy has tremendous potential for decarbonizing the heating sector. However, one common obstacle can be the mismatch between geologically attractive regions in the countryside and urban areas with a high heat demand density, which are therefore attractive for district heating systems. In the last years, an increasing number of regions consider the transport of geothermal heat into urban clusters. One example of such a region is the South German Molasse Basin in Upper Bavaria. However, such heat transport pipelines come along with massive upfront investment costs due to the required large pipe diameter and insulation thickness. While the classic concept foresees the use of water as a heat carrier in such long-distance heat transportation pipelines, CO2 can be an attractive alternative. This study investigates the thermo-economic performance of CO2 as a heat transport carrier for a potential long-distance heat transmission pipeline with a length of 20 km, which could connect a planned geothermal project in the South of Munich with the existing district heating network of Munich. The results of the base case scenario demonstrate that for both heat carrier options water and CO2 rather low LCOH for the transport of the heat can be achieved. The resulting additional LCOH by the long-distance heat transport of around 0.6 cC/kWh are rather small compared to the typical overall LCOH of geothermal district heating systems. Comparing the thermo-economic performance of water and CO2 reveals rather similar achievable LCOH, with a slight advantage for the classical concept of using water. However, this changes if the installation of a high temperature heat pump (HTHP) is considered in order to increase the thermal capacity of the heat transport system. In the case of using CO2, the additional temperature increase takes place directly within the CO2 stream by just installing a compressor, while in the case of the water system, a complete HTHP system needs to be installed. In combination with a higher achievable COP, the CO2 HTHP configurations results in lower overall LCOH compared to the water system.
AB - Deep geothermal energy has tremendous potential for decarbonizing the heating sector. However, one common obstacle can be the mismatch between geologically attractive regions in the countryside and urban areas with a high heat demand density, which are therefore attractive for district heating systems. In the last years, an increasing number of regions consider the transport of geothermal heat into urban clusters. One example of such a region is the South German Molasse Basin in Upper Bavaria. However, such heat transport pipelines come along with massive upfront investment costs due to the required large pipe diameter and insulation thickness. While the classic concept foresees the use of water as a heat carrier in such long-distance heat transportation pipelines, CO2 can be an attractive alternative. This study investigates the thermo-economic performance of CO2 as a heat transport carrier for a potential long-distance heat transmission pipeline with a length of 20 km, which could connect a planned geothermal project in the South of Munich with the existing district heating network of Munich. The results of the base case scenario demonstrate that for both heat carrier options water and CO2 rather low LCOH for the transport of the heat can be achieved. The resulting additional LCOH by the long-distance heat transport of around 0.6 cC/kWh are rather small compared to the typical overall LCOH of geothermal district heating systems. Comparing the thermo-economic performance of water and CO2 reveals rather similar achievable LCOH, with a slight advantage for the classical concept of using water. However, this changes if the installation of a high temperature heat pump (HTHP) is considered in order to increase the thermal capacity of the heat transport system. In the case of using CO2, the additional temperature increase takes place directly within the CO2 stream by just installing a compressor, while in the case of the water system, a complete HTHP system needs to be installed. In combination with a higher achievable COP, the CO2 HTHP configurations results in lower overall LCOH compared to the water system.
KW - Carbon Dioxide
KW - District Heating Networks
KW - Economic Analysis
KW - Geothermal Energy
KW - Heat Transfer
UR - http://www.scopus.com/inward/record.url?scp=85174518055&partnerID=8YFLogxK
U2 - 10.52202/069564-0233
DO - 10.52202/069564-0233
M3 - Conference contribution
AN - SCOPUS:85174518055
T3 - 36th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2023
SP - 2593
EP - 2602
BT - 36th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2023
PB - International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems
T2 - 36th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2023
Y2 - 25 June 2023 through 30 June 2023
ER -
