Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization

The recent reviews that have been conducted serve to highlight the remarkable effectiveness that can be achieved by combining various technologies to extract energy efficiently from underground reservoirs. In this particular study, our focus is on a geothermal-driven poly-generation plant that ingen...

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Published in:DESALINATION
Main Authors: Hai, Tao; Chaturvedi, Rishabh; Almujibah, Hamad; Marjan, Riyam K.; Thuong, T. Van; Soliman, N.; El-Shafai, W.; Fouad, H.
Format: Article
Language:English
Published: ELSEVIER 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001346779200001
author Hai
Tao; Chaturvedi
Rishabh; Almujibah
Hamad; Marjan
Riyam K.; Thuong
T. Van; Soliman
N.; El-Shafai
W.; Fouad, H.
spellingShingle Hai
Tao; Chaturvedi
Rishabh; Almujibah
Hamad; Marjan
Riyam K.; Thuong
T. Van; Soliman
N.; El-Shafai
W.; Fouad, H.
Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
Engineering; Water Resources
author_facet Hai
Tao; Chaturvedi
Rishabh; Almujibah
Hamad; Marjan
Riyam K.; Thuong
T. Van; Soliman
N.; El-Shafai
W.; Fouad, H.
author_sort Hai
spelling Hai, Tao; Chaturvedi, Rishabh; Almujibah, Hamad; Marjan, Riyam K.; Thuong, T. Van; Soliman, N.; El-Shafai, W.; Fouad, H.
Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
DESALINATION
English
Article
The recent reviews that have been conducted serve to highlight the remarkable effectiveness that can be achieved by combining various technologies to extract energy efficiently from underground reservoirs. In this particular study, our focus is on a geothermal-driven poly-generation plant that ingeniously integrates a single flash binary geothermal power unit with multiple sub-systems. In order to comprehensively evaluate environmental impacts, we have conducted extended-environmental and exergo-environmental assessments, which have allowed us to calculate CO2 emissions levels as well as the sustainability index. Through bi-objective optimization, the optimal operational conditions can be determined in this system. The investigation of dead temperature reveals the most significant changes in energy and exergy efficiencies, as well as in the CO2 emission rate. A notable conflict arises between exergy efficiency and the system product cost, making it essential to consider both as objectives in optimization efforts. Under optimal conditions, the total input exergy is 1043 kW. However, the system still experiences an exergy destruction rate of 484.1 kW. The highest rate of exergy destruction is observed in the vapor generator of the organic flash cycle, which accounts for 130.7 kW.
ELSEVIER
0011-9164
1873-4464
2024
586

10.1016/j.desal.2024.117873
Engineering; Water Resources

WOS:001346779200001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001346779200001
title Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
title_short Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
title_full Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
title_fullStr Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
title_full_unstemmed Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
title_sort Integrating geothermal energy and desalination unit into a poly-generation configuration: Comprehensive study and optimization
container_title DESALINATION
language English
format Article
description The recent reviews that have been conducted serve to highlight the remarkable effectiveness that can be achieved by combining various technologies to extract energy efficiently from underground reservoirs. In this particular study, our focus is on a geothermal-driven poly-generation plant that ingeniously integrates a single flash binary geothermal power unit with multiple sub-systems. In order to comprehensively evaluate environmental impacts, we have conducted extended-environmental and exergo-environmental assessments, which have allowed us to calculate CO2 emissions levels as well as the sustainability index. Through bi-objective optimization, the optimal operational conditions can be determined in this system. The investigation of dead temperature reveals the most significant changes in energy and exergy efficiencies, as well as in the CO2 emission rate. A notable conflict arises between exergy efficiency and the system product cost, making it essential to consider both as objectives in optimization efforts. Under optimal conditions, the total input exergy is 1043 kW. However, the system still experiences an exergy destruction rate of 484.1 kW. The highest rate of exergy destruction is observed in the vapor generator of the organic flash cycle, which accounts for 130.7 kW.
publisher ELSEVIER
issn 0011-9164
1873-4464
publishDate 2024
container_volume 586
container_issue
doi_str_mv 10.1016/j.desal.2024.117873
topic Engineering; Water Resources
topic_facet Engineering; Water Resources
accesstype
id WOS:001346779200001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001346779200001
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