Hybrid brayton multi-stage concentrated solar power plant energy and exergy performance study

Moreno Gamboa, Faustino; Nieto-Londoño, César

doi:https://doi.org/10.1115/1.4050486

dc.contributor.author	Moreno Gamboa, Faustino
dc.contributor.author	Nieto-Londoño, César
dc.date.accessioned	2021-10-14T00:24:25Z
dc.date.available	2021-10-14T00:24:25Z
dc.date.issued	2021-04-09
dc.identifier.uri	http://repositorio.ufps.edu.co/handle/ufps/304
dc.description.abstract	Hybrid Brayton concentrated solar power (CSP) plants have been gaining attention in the last decade upon many advantages regarding the use of traditional generation technologies combined with renewable energy sources. However, some technical and economic issues must be solved to allow its widespread use. Research and development efforts are deemed essential to the study of factors that constrain cycle performance looking to increase its efficiency, reducing fuel consumption, and decreasing emissions. This study presents the performance evaluation of a hybrid multi-stage CSP plant considering specific environmental conditions to attain the factor that constrains its optimal performance. Overall energy and exergy plant efficiencies are analyzed, considering an arbitrary number of stages. For instance, a double compression expansion hybrid CSP plant shows the overall energy efficiency of 32% larger, a 30% higher exergy efficiency, and a fuel conversion rate around 18% larger when compared with a single-stage CSP plant.	eng
dc.format.extent	08 páginas	spa
dc.format.mimetype	application/pdf	spa
dc.language.iso	eng	spa
dc.relation.ispartof	Journal of Energy Resources Technology. Vol.143 No.6.(2021)
dc.rights	© 2021 by ASME	eng
dc.rights.uri	https://creativecommons.org/licenses/by/4.0/	spa
dc.source	https://asmedigitalcollection.asme.org/energyresources/article-abstract/143/6/062108/1103608/Hybrid-Brayton-Multi-Stage-Concentrated-Solar?redirectedFrom=fulltext	spa
dc.title	Hybrid brayton multi-stage concentrated solar power plant energy and exergy performance study	eng
dc.type	Artículo de revista	spa
dcterms.references	IEA, 2019, “World Energy Outlook 2019,” International Energy Agency, Paris, France, Technical Report No. WEO-2019.	spa
dcterms.references	Ding, L., Akbarzadeh, A., Singh, B., and Remeli, M., 2017, “Feasibility of Electrical Power Generation Using Thermoelectric Modules Via Solar Pond Heat Extraction,” Energy. Convers. Manage., 135, pp. 74–83.	spa
dcterms.references	Elsayed, I., and Nishi, Y., 2018, “A Feasibility Study on Power Generation From Solar Thermal Wind Tower: Inclusive Impact Assessment Concerning Environmental and Economic Costs,” Energies, 11(11), p. 3181.	spa
dcterms.references	Kirmani, S., Jamil, M., and Akhtar, I., 2018, “Economic Feasibility of Hybrid Energy Generation With Reduced Carbon Emission,” IET Ren. Power Gen., 12(8), pp. 934–942.	spa
dcterms.references	Taylor, N., 2019, “Solar Thermal Electricity: Technology Development Report,” Technical Report, EUR 29913 EN, Publications Office of the European Union, Luxembourg.	spa
dcterms.references	Bouhal, T., Agrouaz, Y., Kousksou, T., Allouhi, A., and Bakkas, M., 2018, “Technical Feasibility of a Sustainable Concentrated Solar Power in Morocco Through an Energy Analysis,” Renewable. Sustainable. Energy. Rev., 81, pp. 1087–1095.	spa
dcterms.references	Rafique, M. M., and Bahaidarah, H. M. S., 2019, “Thermo-Economic and Environmental Feasibility of a Solar Power Plant as a Renewable and Green Source of Electrification,” Int. J. Green Energy, 16(15), pp. 1577–1590.	spa
dcterms.references	Jacobson, M. Z., and Delucchi, M. A., 2011, “Providing All Global Energy With Wind, Water, and Solar Power, Part I: Technologies, Energy Resources, Quantities and Areas of Infrastructure, and Materials,” Energy Policy, 39(3), pp. 1154–1169.	spa
dcterms.references	Santos, M., Miguel-Barbero, C., Merchán, R., Medina, A., and Hernández, A. C., 2018, “Roads to Improve the Performance of Hybrid Thermosolar Gas Turbine Power Plants: Working Fluids and Multi-Stage Configurations,” Energy Convers Manage, 165, pp. 578–592.	spa
dcterms.references	Suresh, N., Thirumalai, N., and Dasappa, S., 2019, “Modeling and Analysis of Solar Thermal and Biomass Hybrid Power Plants,” Appl. Therm. Eng., 160, p. 114121.	spa
dcterms.references	Costa, S.-C., Mahkamov, K., Kenisarin, M., Ismail, M., Lynn, K., Halimic, E., and Mullen, D., 2019, “Solar Salt Latent Heat Thermal Storage for a Small Solar Organic Rankine Cycle Plant,” ASME J. Energy. Res. Technol., 142(3), p. 031203.	spa
dcterms.references	Korzynietz, R., Brioso, J., Gallas, M., Uhlig, R., Ebert, M., Buck, R., and Teraji, D., 2016, “Solugas—Comprehensive Analysis of the Solar Hybrid Brayton Plant,” Sol. Energy, 135, pp. 578–589.	spa
dcterms.references	Elmohlawy, A. E., Ochkov, V. F., and Kazandzhan, B. I., 2019, “Thermal Performance Analysis of a Concentrated Solar Power System (CSP) Integrated With Natural Gas Combined Cycle (NGCC) Power Plant,” Case Studies Thermal Eng., 14, p. 100458.	spa
dcterms.references	Jouhara, H., Ż abnień ska Gra, A., Khordehgah, N., Ahmad, D., and Lipinski, T., 2020, “Latent Thermal Energy Storage Technologies and Applications: A Review,” Int. J. Thermofluids, 4–5, p. 100039.	spa
dcterms.references	Bernardos, E., López, I., Rodríguez, J., and Abánades, A., 2013, “Assessing the Potential of Hybrid Fossil–Solar Thermal Plants for Energy Policy Making: Brayton Cycles,” Energy Policy, 62, pp. 99–106.	spa
dcterms.references	Fang, L., Li, Y., Yang, X., and Yang, Z., 2019, “Analyses of Thermal Performance of Solar Power Tower Station Based on a Supercritical CO2 Brayton Cycle,” ASME J. Energy. Res. Technol., 142(3), p. 031301.	spa
dcterms.references	Ferraro, V., Imineo, F., and Marinelli, V., 2013, “An Improved Model to Evaluate Thermodynamic Solar Plants With Cylindrical Parabolic Collectors and Air Turbine Engines in Open Joule–brayton Cycle,” Energy, 53, pp. 323–331.	spa
dcterms.references	Moreno-Gamboa, F., Escudero-Atehortua, A., and Nieto-Londoño, C., 2020, “Performance Evaluation of External Fired Hybrid Solar Gas-Turbine Power Plant in Colombia Using Energy and Exergy Methods,” Ther. Sci. Eng. Prog., 20, p. 100679.	spa
dcterms.references	Olivenza-León, D., Medina, A., and Calvo Hernández, A., 2015, “Thermodynamic Modeling of a Hybrid Solar Gas-Turbine Power Plant,” Energy Convers. Manage., 93, pp. 435–447.	spa
dcterms.references	Behar, O., 2018, “Solar Thermal Power Plants—A Review of Configurations and Performance Comparison,” Renewable. Sustainable. Energy. Rev., 92, pp. 608–627.	spa
dcterms.references	Merchán, R., Santos, M., Heras, I., Gonzalez-Ayala, J., Medina, A., and Hernández, A. C., 2020, “On-Design Pre-optimization and Off-Design Analysis of Hybrid Brayton Thermosolar Tower Power Plants for Different Fluids and Plant Configurations,” Renewable Sustainable Energy Rev., 119, p. 109590.	spa
dcterms.references	Gueymard, C., 2000, “Prediction and Performance Assessment of Mean Hourly Global Radiation,” Sol. Energy, 68(3), pp. 285–303.	spa
dcterms.references	Liu, B. Y., and Jordan, R. C., 1960, “The Interrelationship and Characteristic Distribution of Direct, Diffuse and Total Solar Radiation,” Sol. Energy, 4(3), pp. 1–19.	spa
dcterms.references	National Aeronautics and Space Administration, 2018, “Power Data Access Viewer,” https://power.larc.nasa.gov/data-access-viewer/, Accessed April 1, 2019.	spa
dcterms.references	MeteoSevilla, 2017, “Estación Meteorológica de Santiponce,” Sevilla, Spain, http://www.meteosevilla.com/inicio.htm, Accessed June 25, 2017.	spa
dcterms.references	Ramírez-Cerpa, E., Acosta-Coll, M., and Vélez-Zapata, J., 2017, “Análisis De Condiciones Climatológicas De Precipitaciones De Corto Plazo En Zonas Urbanas: Caso De Estudio Barranquilla, Colombia,” Idesia (Arica), 35, pp. 87–94.	spa
dcterms.references	Sánchez-Orgaz, S., 2012, “Modelización, Análisis Y Optimización Termodinámica De Plantas De Potencia Multietapa Tipo Brayton. Aplicación a Centrales Termosolares,” Ph.D. thesis, Universidad de Salamanca, Spain.	spa
dcterms.references	Santos, M., Merchán, R., Medina, A., and Calvo Hernández, A., 2016, “Seasonal Thermodynamic Prediction of the Performance of a Hybrid Solar Gas-Turbine Power Plant,” Energy Convers. Manage., 115, pp. 89–102.	spa
dcterms.references	Aljundi, I. H., 2009, “Energy and Exergy Analysis of a Steam Power Plant in Jordan,” Appl. Therm. Eng., 29(2), pp. 324–328.	spa
dcterms.references	Yue, T., and Lior, N., 2018, “Thermal Hybrid Power Systems Using Multiple Heat Sources of Different Temperature: Thermodynamic Analysis for Brayton Cycles,” Energy, 165, pp. 639–665.	spa
dcterms.references	Petela, R., 2003, “Exergy of Undiluted Thermal Radiation,” Sol. Energy, 74(6), pp. 469–488.	spa
dcterms.references	Atif, M., and Al-Sulaiman, F. A., 2017, “Energy and Exergy Analyses of Solar Tower Power Plant Driven Supercritical Carbon Dioxide Recompression Cycles for Six Different Locations.”	spa
dcterms.references	Romier, A., 2004, “Small Gas Turbine Technology,” Appl. Therm. Eng., 24(11), pp. 1709–1723, Industrial Gas Turbine Technologies.	spa
dcterms.references	Santos, M., Merchán, R., Medina, A., and Hernández, A. C., 2016, “Seasonal Thermodynamic Prediction of the Performance of a Hybrid Solar Gas-Turbine Power Plant,” Energy Convers. Manage., 115, pp. 89–102.	spa
dc.contributor.corporatename	Journal of Energy Resources Technology	spa
dc.identifier.doi	https://doi.org/10.1115/1.4050486
dc.relation.citationedition	Vol.143 No.6.(2021)	spa
dc.relation.citationendpage	8	spa
dc.relation.citationissue	6(2021)	spa
dc.relation.citationstartpage	1	spa
dc.relation.citationvolume	143	spa
dc.relation.cites	Moreno-Gamboa, F., and Nieto-Londoño, C. (April 9, 2021). "Hybrid Brayton Multi-Stage Concentrated Solar Power Plant Energy and Exergy Performance Study." ASME. J. Energy Resour. Technol. June 2021; 143(6): 062108. https://doi.org/10.1115/1.4050486
dc.relation.ispartofjournal	Journal of Energy Resources Technology,	spa
dc.rights.accessrights	info:eu-repo/semantics/openAccess	spa
dc.subject.proposal	alternative energy sources	eng
dc.subject.proposal	energy systems analysis	eng
dc.subject.proposal	renewable energy	eng
dc.type.coar	http://purl.org/coar/resource_type/c_6501	spa
dc.type.content	Text	spa
dc.type.driver	info:eu-repo/semantics/article	spa
dc.type.redcol	http://purl.org/redcol/resource_type/ART	spa
oaire.accessrights	http://purl.org/coar/access_right/c_abf2	spa
oaire.version	http://purl.org/coar/version/c_970fb48d4fbd8a85	spa
dc.type.version	info:eu-repo/semantics/publishedVersion	spa