Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant

Organic Rankine Cycle (ORC) applications include ocean thermal energy conversion (OTEC), in which mechanical work is generated from heat energy to rotate generators and generate electricity. The OTEC system heated and cooled its refrigerant by taking advantage of the relatively small temperature dif...

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Main Authors: Suruji, Muhammad Aiman Wafi, Nik Mohd., Nik Ahmad Ridhwan, Nasir, Nazri, Wahinuddin, Muhammad Ajwad, Othman, Norazila, Mat, Shabudin
Format: Article
Language:English
Published: Penerbit UTM Press 2023
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Online Access:http://eprints.utm.my/108499/1/NikAhmadRidhwan2023_ThermodynamicsAnalysisofSolarEjectorPump.pdf
http://eprints.utm.my/108499/
http://dx.doi.org/10.11113/jm.v46.464
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Institution: Universiti Teknologi Malaysia
Language: English
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spelling my.utm.1084992024-11-12T06:17:01Z http://eprints.utm.my/108499/ Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant Suruji, Muhammad Aiman Wafi Nik Mohd., Nik Ahmad Ridhwan Nasir, Nazri Wahinuddin, Muhammad Ajwad Othman, Norazila Mat, Shabudin TJ Mechanical engineering and machinery Organic Rankine Cycle (ORC) applications include ocean thermal energy conversion (OTEC), in which mechanical work is generated from heat energy to rotate generators and generate electricity. The OTEC system heated and cooled its refrigerant by taking advantage of the relatively small temperature difference between the warmer surface seawater and the colder deep seawater. The low-temperature difference between seawater and the rest of the system meant that the thermal efficiency of the system was relatively low; to address this problem, the OTEC cycles needed to be revised. To increase the basic OTEC cycle's thermal efficiency by 3.3–4.0%, various modifications have been developed. Two such cycles are the Solar Boosted OTEC (SOTEC) cycle and the Ejector Pump cycle (EP-OTEC). While the two improvements alter the rotating turbine parameters in different ways, they can be combined to create an improved OTEC cycle through the use of thermodynamics. In this study, an algorithm for revised OTEC was developed using MATLAB, and the performance of the system after the modifications was further quantified. This SEP-OTEC cycle thermal efficiency gives a 1.2-fold improvement when compared to the previous OTEC cycle thermal efficiency, which was 3.1%. Penerbit UTM Press 2023-06 Article PeerReviewed application/pdf en http://eprints.utm.my/108499/1/NikAhmadRidhwan2023_ThermodynamicsAnalysisofSolarEjectorPump.pdf Suruji, Muhammad Aiman Wafi and Nik Mohd., Nik Ahmad Ridhwan and Nasir, Nazri and Wahinuddin, Muhammad Ajwad and Othman, Norazila and Mat, Shabudin (2023) Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant. Jurnal Mekanikal, 46 (NA). pp. 1-13. ISSN 2289-3873 http://dx.doi.org/10.11113/jm.v46.464 DOI:10.11113/jm.v46.464
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
language English
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Suruji, Muhammad Aiman Wafi
Nik Mohd., Nik Ahmad Ridhwan
Nasir, Nazri
Wahinuddin, Muhammad Ajwad
Othman, Norazila
Mat, Shabudin
Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
description Organic Rankine Cycle (ORC) applications include ocean thermal energy conversion (OTEC), in which mechanical work is generated from heat energy to rotate generators and generate electricity. The OTEC system heated and cooled its refrigerant by taking advantage of the relatively small temperature difference between the warmer surface seawater and the colder deep seawater. The low-temperature difference between seawater and the rest of the system meant that the thermal efficiency of the system was relatively low; to address this problem, the OTEC cycles needed to be revised. To increase the basic OTEC cycle's thermal efficiency by 3.3–4.0%, various modifications have been developed. Two such cycles are the Solar Boosted OTEC (SOTEC) cycle and the Ejector Pump cycle (EP-OTEC). While the two improvements alter the rotating turbine parameters in different ways, they can be combined to create an improved OTEC cycle through the use of thermodynamics. In this study, an algorithm for revised OTEC was developed using MATLAB, and the performance of the system after the modifications was further quantified. This SEP-OTEC cycle thermal efficiency gives a 1.2-fold improvement when compared to the previous OTEC cycle thermal efficiency, which was 3.1%.
format Article
author Suruji, Muhammad Aiman Wafi
Nik Mohd., Nik Ahmad Ridhwan
Nasir, Nazri
Wahinuddin, Muhammad Ajwad
Othman, Norazila
Mat, Shabudin
author_facet Suruji, Muhammad Aiman Wafi
Nik Mohd., Nik Ahmad Ridhwan
Nasir, Nazri
Wahinuddin, Muhammad Ajwad
Othman, Norazila
Mat, Shabudin
author_sort Suruji, Muhammad Aiman Wafi
title Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
title_short Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
title_full Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
title_fullStr Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
title_full_unstemmed Thermodynamics analysis of solar-ejector pump OTEC (SEP-OTEC) rankine cycle using ammonia as refrigerant
title_sort thermodynamics analysis of solar-ejector pump otec (sep-otec) rankine cycle using ammonia as refrigerant
publisher Penerbit UTM Press
publishDate 2023
url http://eprints.utm.my/108499/1/NikAhmadRidhwan2023_ThermodynamicsAnalysisofSolarEjectorPump.pdf
http://eprints.utm.my/108499/
http://dx.doi.org/10.11113/jm.v46.464
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