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Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa

Supercritical carbon dioxide (sCO2) power cycles have been identified as an attractive technology to reduce the cost, complexity and footprint, and to increase the thermal efficiency of thermal power plants. In this work, two promising sCO2 power cycles are investigated for use in a proposed dry-coo...

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Main Author: Du Sart, Colin F
Other Authors: Rousseau, Pieter
Format: Thesis
Language:English
English
Published: Department of Mechanical Engineering 2026
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access_status_str Open Access
author Du Sart, Colin F
author2 Rousseau, Pieter
author_browse Du Sart, Colin F
Rousseau, Pieter
author_facet Rousseau, Pieter
Du Sart, Colin F
author_sort Du Sart, Colin F
collection Thesis
description Supercritical carbon dioxide (sCO2) power cycles have been identified as an attractive technology to reduce the cost, complexity and footprint, and to increase the thermal efficiency of thermal power plants. In this work, two promising sCO2 power cycles are investigated for use in a proposed dry-cooled 50 MWe concentrated solar power (CSP) plant in Southern Africa. These include the partial cooling with reheating (PCRH) cycle and the recompression with intercooling and reheating (RCICRH) cycle. Initially, a techno-economic design point study is performed to determine near optimal operating conditions and component requirements in which the recuperators are optimally sized, by volume, as printed circuit heat exchangers (PCHEs). This contrasts with other comparative studies where simplified models are used that do not consider the effect of actual recuperator geometry on heat transfer and pressure drop. The results suggest that the RCICRH cycle requires larger recuperators and turbomachinery, resulting in a marginally higher capital outlay for the power cycle, but offers superior thermal efficiencies, which suggests that a smaller solar field is required. However, the PCRH cycle requires a smaller solar receiver system and a smaller thermal energy storage (TES) system. Thereafter, conceptual designs for the cycle components (compressors, turbines, heaters and coolers) are developed. Additionally, auxiliary equipment (piping, valves, fans, TES tank and inventory tank) is sized and selected. Given the limited data available on sCO2 component modelling, unique sizing methodologies that employ fundamental one-dimensional (1D) thermofluid network modelling approaches are developed and verified. Compared to models used by others, which often contain significant simplifying assumptions, the models used in this work are more suited for off-design and transient power cycle studies, and for costing. Furthermore, by developing component designs for both cycles, the similarities and differences of the PCRH and RCICRH cycles are further clarified. A dynamic model of the RCICRH cycle is then developed. Using the model, a bypass and fan on-off control strategy for a multi-cell mechanical forced draft air-cooled heat exchanger (ACHE) system is proposed and demonstrated for the first time during changing ambient conditions. The model is also used to characterise the off-design performance of the cycle and the changing component boundary conditions for various methods of load control. Finally, the transient performance and operating requirements for the cycle are investigated. Accurate and stable load-following can be achieved using a combination of inventory and upper cycle bypass control. Furthermore, by using both upper cycle bypass control and compressor outlet throttling, the cycle can continue to operate during a load-rejection event. This is the first sCO2 study where all major cycle components are designed, fully integrated, and used to perform a comprehensive off-design and dynamic study for a cycle of this output capacity for a CSP application. While the selected boundary conditions and technological limitations considered in this study are unique to Southern Africa, many of the methods presented in this work may be used to develop conceptual designs for sCO2 power cycles of a similar scale.
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language English
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last_indexed 2026-07-01T04:02:11.918Z
license_str Not specified — see source repository
provenance_str_mv Harvested via OAI-PMH from UCTD — University of Cape Town Open Access Repository
publishDate 2026
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spelling oai:open.uct.ac.za:11427/43315 Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa Du Sart, Colin F Rousseau, Pieter supercritical carbon dioxide recompression cycle partial cooling cycle concentrated solar power centrifugal compressor radial inflow turbine air-cooled heat exchanger printed circuit heat exchanger process design control system off-design dynamic simulation transient analysis Supercritical carbon dioxide (sCO2) power cycles have been identified as an attractive technology to reduce the cost, complexity and footprint, and to increase the thermal efficiency of thermal power plants. In this work, two promising sCO2 power cycles are investigated for use in a proposed dry-cooled 50 MWe concentrated solar power (CSP) plant in Southern Africa. These include the partial cooling with reheating (PCRH) cycle and the recompression with intercooling and reheating (RCICRH) cycle. Initially, a techno-economic design point study is performed to determine near optimal operating conditions and component requirements in which the recuperators are optimally sized, by volume, as printed circuit heat exchangers (PCHEs). This contrasts with other comparative studies where simplified models are used that do not consider the effect of actual recuperator geometry on heat transfer and pressure drop. The results suggest that the RCICRH cycle requires larger recuperators and turbomachinery, resulting in a marginally higher capital outlay for the power cycle, but offers superior thermal efficiencies, which suggests that a smaller solar field is required. However, the PCRH cycle requires a smaller solar receiver system and a smaller thermal energy storage (TES) system. Thereafter, conceptual designs for the cycle components (compressors, turbines, heaters and coolers) are developed. Additionally, auxiliary equipment (piping, valves, fans, TES tank and inventory tank) is sized and selected. Given the limited data available on sCO2 component modelling, unique sizing methodologies that employ fundamental one-dimensional (1D) thermofluid network modelling approaches are developed and verified. Compared to models used by others, which often contain significant simplifying assumptions, the models used in this work are more suited for off-design and transient power cycle studies, and for costing. Furthermore, by developing component designs for both cycles, the similarities and differences of the PCRH and RCICRH cycles are further clarified. A dynamic model of the RCICRH cycle is then developed. Using the model, a bypass and fan on-off control strategy for a multi-cell mechanical forced draft air-cooled heat exchanger (ACHE) system is proposed and demonstrated for the first time during changing ambient conditions. The model is also used to characterise the off-design performance of the cycle and the changing component boundary conditions for various methods of load control. Finally, the transient performance and operating requirements for the cycle are investigated. Accurate and stable load-following can be achieved using a combination of inventory and upper cycle bypass control. Furthermore, by using both upper cycle bypass control and compressor outlet throttling, the cycle can continue to operate during a load-rejection event. This is the first sCO2 study where all major cycle components are designed, fully integrated, and used to perform a comprehensive off-design and dynamic study for a cycle of this output capacity for a CSP application. While the selected boundary conditions and technological limitations considered in this study are unique to Southern Africa, many of the methods presented in this work may be used to develop conceptual designs for sCO2 power cycles of a similar scale. 2026-06-12T10:02:44Z 2026-06-12T10:02:44Z 2026 2026-06-12T10:00:33Z Thesis / Dissertation Doctoral PhD http://hdl.handle.net/11427/43315 en eng application/pdf Department of Mechanical Engineering Faculty of Engineering and the Built Environment University of Cape Town
spellingShingle supercritical carbon dioxide
recompression cycle
partial cooling cycle
concentrated solar power
centrifugal compressor
radial inflow turbine
air-cooled heat exchanger
printed circuit heat exchanger
process design
control system
off-design
dynamic simulation
transient analysis
Du Sart, Colin F
Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
thesis_degree_str Doctoral
title Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
title_full Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
title_fullStr Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
title_full_unstemmed Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
title_short Thermofluid design and dynamic simulation of an sCO2 power cycle for a 50 MWe concentrated solar thermal tower plant in Southern Africa
title_sort thermofluid design and dynamic simulation of an sco2 power cycle for a 50 mwe concentrated solar thermal tower plant in southern africa
topic supercritical carbon dioxide
recompression cycle
partial cooling cycle
concentrated solar power
centrifugal compressor
radial inflow turbine
air-cooled heat exchanger
printed circuit heat exchanger
process design
control system
off-design
dynamic simulation
transient analysis
url http://hdl.handle.net/11427/43315
work_keys_str_mv AT dusartcolinf thermofluiddesignanddynamicsimulationofansco2powercyclefora50mweconcentratedsolarthermaltowerplantinsouthernafrica