A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations

A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations

In this paper an integrated refrigeration system is designed, in which the waste heat from an ejector-expansion trans-critical CO2 (EETRCC) cooling scheme is used for the generation of cooling not only above but also below the temperature of zero degrees Celsius. Waste heat usage was accomplished vi...

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Published in:Sustainable Energy Technologies and Assessments
Main Author: Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
Format: Article
Language:English
Published: Elsevier Ltd 2023
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85150034435&doi=10.1016%2fj.seta.2023.103118&partnerID=40&md5=b4c649712b7c14a3ad2718196ea888df
id 2-s2.0-85150034435
spelling 2-s2.0-85150034435
Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
2023
Sustainable Energy Technologies and Assessments
57

10.1016/j.seta.2023.103118
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85150034435&doi=10.1016%2fj.seta.2023.103118&partnerID=40&md5=b4c649712b7c14a3ad2718196ea888df
In this paper an integrated refrigeration system is designed, in which the waste heat from an ejector-expansion trans-critical CO2 (EETRCC) cooling scheme is used for the generation of cooling not only above but also below the temperature of zero degrees Celsius. Waste heat usage was accomplished via employment of an absorption refrigeration system in conjunction with a CO2 trans-critical refrigeration cycle. The absorption refrigeration cycle generates excess cooling above zero temperature utilizing the waste heat from ejector expansion system. Appropriate thermodynamic models are employed for feasibility assessment of integrated refrigeneration system, along with economic considerations to estimate produced cooling price. The results revealed significant better performance of novel integrated framework compared to standalone EETRCC cycle. In the best-case scenario, the levelized cost of cooling for the former is obtained as 105.3 $/GJ and, while the latter produces cooling with a levelized cost of 120.9 $/GJ. Also, it has been concluded that, when the temperature of the second evaporator is raised, the exergy efficiency of the system drops by 3 %, which results in increment of unit cost of the cooling by 6.34 %. In addition, highest exergy destructions are found to be 27.53 kW in the gas cooler and 15.57 kW in the generator. © 2023 Elsevier Ltd
Elsevier Ltd
22131388
English
Article
author Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
spellingShingle Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
author_facet Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
author_sort Hai T.; Ashraf Ali M.; Dhahad H.A.; Alizadeh A.; Sharma K.; Fahad Almojil S.; Ibrahim Almohana A.; Fahmi Alali A.; Attia E.-A.
title A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
title_short A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
title_full A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
title_fullStr A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
title_full_unstemmed A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
title_sort A novel bi-evaporator cooling system via integration of absorption refrigeration cycle for waste energy recovery from an ejector-expansion trans-critical CO2 (EETRCC) cycle: Proposal and optimization with environmental considerations
publishDate 2023
container_title Sustainable Energy Technologies and Assessments
container_volume 57
container_issue
doi_str_mv 10.1016/j.seta.2023.103118
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85150034435&doi=10.1016%2fj.seta.2023.103118&partnerID=40&md5=b4c649712b7c14a3ad2718196ea888df
description In this paper an integrated refrigeration system is designed, in which the waste heat from an ejector-expansion trans-critical CO2 (EETRCC) cooling scheme is used for the generation of cooling not only above but also below the temperature of zero degrees Celsius. Waste heat usage was accomplished via employment of an absorption refrigeration system in conjunction with a CO2 trans-critical refrigeration cycle. The absorption refrigeration cycle generates excess cooling above zero temperature utilizing the waste heat from ejector expansion system. Appropriate thermodynamic models are employed for feasibility assessment of integrated refrigeneration system, along with economic considerations to estimate produced cooling price. The results revealed significant better performance of novel integrated framework compared to standalone EETRCC cycle. In the best-case scenario, the levelized cost of cooling for the former is obtained as 105.3 $/GJ and, while the latter produces cooling with a levelized cost of 120.9 $/GJ. Also, it has been concluded that, when the temperature of the second evaporator is raised, the exergy efficiency of the system drops by 3 %, which results in increment of unit cost of the cooling by 6.34 %. In addition, highest exergy destructions are found to be 27.53 kW in the gas cooler and 15.57 kW in the generator. © 2023 Elsevier Ltd
publisher Elsevier Ltd
issn 22131388
language English
format Article
accesstype
record_format scopus
collection Scopus
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