Thermodynamic Optimization of a Geothermal- Based Organic Rankine Cycle System Using an Artificial Bee Colony Algorithm

Geothermal energy is a renewable form of energy, however due to misuse, processing and management issues, it is necessary to use the resource more efficiently. To increase energy efficiency, energy systems engineers carry out careful energy control studies and offer alternative solutions. With this...

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Published inEnergies (Basel) Vol. 10; no. 11; p. 1691
Main Authors Özkaraca, Osman, Keçebaş, Pınar, Demircan, Cihan, Keçebaş, Ali
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.11.2017
Subjects
Artificial Bee Colony (ABC)
Computer simulation
Destruction
Efficiency
Electric power plants
Energy
Energy efficiency
Energy management
Energy resources
Energy sources
Exergy
exergy analysis
Geothermal energy
Geothermal power
geothermal power plant
Information processing
Optimization
Organic Rankine Cycle (ORC)
Performance enhancement
performance improvement
Power plants
Rankine cycle
Search algorithms
thermodynamic modeling
Thermodynamics
Vaporizers
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Summary:Geothermal energy is a renewable form of energy, however due to misuse, processing and management issues, it is necessary to use the resource more efficiently. To increase energy efficiency, energy systems engineers carry out careful energy control studies and offer alternative solutions. With this aim, this study was conducted to improve the performance of a real operating air-cooled organic Rankine cycle binary geothermal power plant (GPP) and its components in the aspects of thermodynamic modeling, exergy analysis and optimization processes. In-depth information is obtained about the exergy (maximum work a system can make), exergy losses and destruction at the power plant and its components. Thus the performance of the power plant may be predicted with reasonable accuracy and better understanding is gained for the physical process to be used in improving the performance of the power plant. The results of the exergy analysis show that total exergy production rate and exergy efficiency of the GPP are 21 MW and 14.52%, respectively, after removing parasitic loads. The highest amount of exergy destruction occurs, respectively, in condenser 2, vaporizer HH2, condenser 1, pumps 1 and 2 as components requiring priority performance improvement. To maximize the system exergy efficiency, the artificial bee colony (ABC) is applied to the model that simulates the actual GPP. Under all the optimization conditions, the maximum exergy efficiency for the GPP and its components is obtained. Two of these conditions such as Case 4 related to the turbine and Case 12 related to the condenser have the best performance. As a result, the ABC optimization method provides better quality information than exergy analysis. Based on the guidance of this study, the performance of power plants based on geothermal energy and other energy resources may be improved.
ISSN:1996-1073
1996-1073
DOI:10.3390/en10111691