Utilización de la energía solar para aplicaciones de enfriamiento

una revisión

Autores/as

DOI:

https://doi.org/10.36561/ING.24.6

Palabras clave:

Comodidad humana, Energía solar, Calefacción, Enfriamiento, Solar térmica, Humidificación

Resumen

La mayor parte de la energía en el sector residencial se consume para proporcionar el confort humano. El uso de recursos energéticos convencionales crea el problema del calentamiento global. Debido al severo impacto de los gases liberados en el medio ambiente, es necesario utilizar recursos energéticos alternativos para mantener la zona de confort humano. El uso de diferentes técnicas de conversión de energía solar está haciendo una contribución prometedora para proporcionar energía limpia. El propósito de este estudio es proporcionar una visión general de los avances recientes en el uso de la energía solar para proporcionar el confort climático interior. Se investiga en detalle el uso de técnicas de conversión no concentradoras y concentradoras. El estudio también analiza los incentivos de la energía solar para atraer inversiones en la fusión de las industrias de energía solar y comodidad humana.

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Shawn K.olson-hazboun. Why are we being punished, and they are being rewarded. views on

renewable energy in fossil fuels-based communities of the U.S. west. The Extractive Industries and

Society. https://doi.org/10.1016/j.exis.2018.05.001

A.Razmjoo, L.Gakenia Kaigutha, M.A.Vaziri Rad, M.Marzband, M.Denai . A Technical

analysis investigating energy sustainability utilizing reliable renewable energy sources to reduce

CO2 emissions in a high potential area. Renewable Energy.

https://doi.org/10.1016/j.renene.2020.09.042

E. Muh, F. Tabet, Comparative analysis of hybrid renewable energy systems for off-grid

applications in southern Cameroons, Renew. Energy 135 (2019) 41e54.

S.E. Hosseini, A.M. Andwari, M.A. Wahid, G. Bagheri, A review on green energy potentials

in Iran, Renew. Sustain. Energy Rev. 27 (2013) 533e545.

O. Ellabban, H. Abu-Rub, F. Blaabjerg, Renewable energy resources: current status, future

prospects and their enabling technology, Renew. Sustain. Energy Rev. 39 (2014) 748e764.

H. Karunathilake, P. Perera, R. Ruparathna, K. Hewage, R. Sadiq, Renewable energy

integration into community energy systems: a case study of new urban residential development, J.

Clean. Prod. 173 (2018) 292e307(sustainable urban transformations towards smarter, healthier

cities: theories, agendas and pathways)

A. Razmjoo, R. Shirmohammadi, A. Davarpanah, F. Pourfayaz, A. Aslani, Standalone hybrid

energy systems for remote area power generation, Energy Rep. 5 (2019) 231e241.

A.A. Razmjoo, A. Sumper, A. Davarpanah, Energy sustainability analysis based on SDGs for

developing countries, Energy Sources, Part A Recovery, Util. Environ. Eff. 42 (9) (2020)

e1056.

J. Koornneef, A. Ramírez, W. Turkenburg, A. Faaij, The environmental impact and risk

assessment of co2 capture, transport and storage- an evaluation of the knowledge base, Prog.

Energy Combust. Sci. 38 (1) (2012) 62e86

Ruben Laleman, Johan Albrecht. Nuclear and old fossil phase out scenarios: Assessment of

shortages, surpluses and the load factor of flexible assets with high renewable generation targets –

A Belgian case study. International Journal of Electrical Power & Energy Systems.

UN Environment Program Report. Global trends in Renewable Energy Investment 2015.

http://fs-unep-centre.org/sites/default/files/attachments/key_findings.pdf〉 [accessed 20.07.15

2015].

World Energy consumption Monitoring of world populated countries. US debt Clock.org.

http://www.usdebtclock.org/energy.html〉 [accessed 20.07.15]

Carlos Gaete-Morales, Alejandro Gallego-Schmid, Laurence Stamford, Adisa Azapagic. Life

cycle environmental impacts of electricity from fossil fuels in Chile over a ten-year period. Journal

of Cleaner Production ( IF 7.246 ) doi: 10.1016/j.jclepro.2019.05.374

Gioietta Kuo . When Fossil Fuels Run Out, What Then. Collapse economy and Energy

environment. https://mahb.stanford.edu/library-item/fossil-fuels-run/.

The Future of Oil. Institute for the Analysis of Global Security. Journal of Energy security.

http://www.iags.org/futureofoil.html

Jackson Howarth. When Will The Earth Actually Run Out Of Fossil Fuel? Octopus Energy.

https://octopus.energy/blog/when-will-fossil-fuels-runout

Luis Pe´rez-Lombard , Jose´ Ortiz , Christine Pout “ A review on buildings energy consumption information” US department of Energy. Journal Energy and Buildings

https://dx.doi.org/10.1016/J.ENBUILD.2007.03.007.

Intentional Energy Agency (IEA), The Future of Cooling. 2018

Stratview Research, strategic Insight delivered, HVAC Insulation Market Size to experience

an impressive growth of 10.2%. https://www.stratviewresearch.com/776/hvac-insulationmarket.html.

Ibrahim Dincer. Renewable energy and sustainable development: a crucial review, Renewable

and sustainable energy Reviews. https://doi.org/10.1016/S1364-0321(99)00011-8.

Xiangyang Zhao Huabo Duan, inhui Li. An evaluation on the environmental consequences of

residual CFCs from obsolete household refrigerators in China. Waste management.

https://doi.org/10.1016/j.wasman.2010.10.018.

Iwan Sukarno, Hiroshi Matsumoto, Lusi Susanti. Household lifestyle effect on residential

electrical energy consumption in Indonesia: On-site measurement methods. Urban climate,

https://doi.org/10.1016/j.uclim.2017.02.008.

Nathan S. Lewis and Daniel G. Nocera Powering the planet: Chemical challenges in solar

energy utilization. https://doi.org/10.1073/pnas.0603395103.

Steve Hanley, 7 Charts — Solar Leads the Way as Renewables Grow Faster than Expected.

Clean technica. https://cleantechnica.com/2017/10/05/solar-leads-way-renewables-grow-fasterexpected.

N. Sönnichsen, Solar power net generation in the United States from 2000 to 2019,

https://www.statista.com/statistics/183447/us-energy-generation-from-solar-sources-from-2000.

The Freedonia, Group, Inc. World equipment demand, Celeveland, OH, USA; 2015

https://www.freedoniagroup.com.

Alka Solanki, Yash pal, Applications of flat plate collector in dairy industries: A review,

International Journal of Ambient Energy. https://doi.org/10.1080/01430750.2020.1721326.

Francis Agyenim, Ian Knight, Michael Rhodes, Design and experimental testing of the

performance of an outdoor LiBr/H2O solar therermal absorption cooling system with a cold store.

https://doi.org/10.1016/j.solener.2010.01.013.

Sheikhani H, Barzegarian R, Heydari A, Kianifar A, Kasaeian A, Grof ´ G, et al. A review of

solar absorption cooling systems combined with various auxiliary energy devices. J Therm Anal

Calorim 2018;134:2197–212. https://doi.org/10.1007/s10973-018-7423-4.

Ghafoor A, Munir A. Worldwide overview of solar thermal cooling technologies. Renew

Sustain Energy Rev 2015;43:763–74. https://doi.org/10.1016/j.rser.2014.11.073.

Kasaeian A, Bellos E, Shamaeizadeh A, Tzivanidis C. Solar-driven polygeneration systems:

recent progress and outlook. Appl Energy 2020;264.

https://doi.org/10.1016/j.apenergy.2020.114764.

Asdrubali, F., Grignaffini, S., 2005. Experimental evaluation of the performances of a

LiBr/H2O absorption refrigerator under different service conditions. International Journal of

Refrigeration 28, 489–497.

Auh, P.C., 1978. An overview of absorption cooling technology in solar applications. In:

Proceedings of the 3rd Workshop on the Use of Solar Energy for Cooling of Buildings, San

Francisco, California, pp. 14–18.

Sumathy, K., Huang, Z.C., Li, Z.F., 2002. Solar absorption cooling with low grade heat source

– a strategy of development in south china. Solar Energy 72 (2), 155–165.

Hammad M, Zurigat Y. Performance of a second generation solar cooling unit. Solar Energy

;62(2): 79–84

IEA Solar Heating and Cooling Programme. Task 38 (Solar Air conditioning and

Refrigeration, 2006–2011). <http://www.ieashc.org/task38/index.html>.

Henning H-M. Solar assisted air-conditioning in buildings – a handbook for planners. Wien:

Springer; 2004. ISBN3-211-00647.

Fong KF, Chow TT, Lee CK, Lin Z, Chan LS. Comparative study of different solar cooling

systems for buildings in subtropical city. Solar Energy 2010;84: 227–44.

Praene JP, Marc O, Lucas F, Miranville F. Simulation and experimental investigation of solar

absorption cooling system in Reunion Island. Appl Energy 2011;88:831–9.

Agyenim F, Knight I, Rhodes M. Design and experimental testing of the performance of an

outdoor LiBr/H2O solar thermal absorption system with a cold store. Sol Energy 2010;84:735–44.

. A. Buonomano, F. Calise, A. Palombo, Solar heating and cooling systems by CPVT and ET

solar collectors: A novel transient simulation model.

https://doi.org/10.1016/j.apenergy.2012.10.023.

Lattieff, F.A., Atiya, M.A., Al-Hemiri, A.A., 2019. Test of solar adsorption air-conditioning

powered by evacuated tube collectors under the climatic conditions of Iraq. Renewable Energy

, 20–29

Sami M. Alelyani A, Weston K. Bertrand A, Zhaoli Zhang B, Patrick E. Phelan, Experimental

study of an evacuated tube solar adsorption cooling moduleand its optimal adsorbent bed design.

https://doi.org/10.1016/j.solener.2020.09.044.

Ghaddar NK, Shihab M, Bdeir F. Modeling and simulation of solar absorption system

performance in Beirut. Renewable Energy 1997;10(4):539–58.

. F. Assilzadeha,, S.A. Kalogiroub, Y. Alia, K. Sopiana, Simulation and optimization of a LiBr

solar absorption cooling system with evacuated tube collectors.

https://doi.org/10.1016/j.renene.2004.09.017.

Jebasingh VK, Herbert GMJ. A review of solar parabolic trough collector. Renew Sustain

Energy Rev 2016;54:1085–91. https://doi.org/10.1016/j.rser.2015.10.043.

Cabrera FJ, Fernandez-García ´ A, Silva RMP, P´ erez-García M. Use of parabolic trough

solar collectors for solar refrigeration and air-conditioning applications. Renew Sustain Energy

Rev 2013;20:103–18. https://doi.org/10.1016/j.rser.2012.11.081.

Lokurlu A, Richarts F, Krüger D. High efficient utilisation of solar energy with newly

developed parabolic trough collectors (SOLITEM PTC) for chilling and steam production in a

hotel at the Mediterranean coast of Turkey. Int J Energy Technol Policy 2005;3:137–46.

https://doi.org/10.1504/IJETP.2005.006745.

Qu M, Yin H, Archer DH. A solar thermal cooling and heating system for a building:

experimental and model based performance analysis and design. Sol Energy 2010;84:166–82.

https://doi.org/10.1016/j.solener.2009.10.010.

Buonomano A, Calise F, D’Accadia MD, Ferruzzi G, Frascogna S, Palombo A, et al.

Experimental analysis and dynamic simulation of a novel high-temperature solar cooling system.

Energy Convers Manag 2016;109:19–39. https://doi.org/10.1016/j.enconman.2015.11.047.

Li M, Xu C, Hassanien RHE, Xu Y, Zhuang B. Experimental investigation on the performance

of a solar powered lithium bromide–water absorption cooling system. Int J Refrig 2016;71:46–59.

https://doi.org/10.1016/j.ijrefrig.2016.07.023.

Soussi M, Balghouthi M, Guizani AA, Bouden C. Model performance assessment and

experimental analysis of a solar assisted cooling system. Sol Energy 2017;143:43–62.

https://doi.org/10.1016/j.solener.2016.12.046.

Zhang HL, Baeyens J, Degrève J, Cacères G. Concentrated solar power plants: review and

design methodology. Renewable Sustainable Energy Rev 2013;22:466–81.

Lazzarin RM. Solar cooling: PV or thermal? A thermodynamic and economical analysis. Int

J Refrig 2014;39:38–47.

Mittal V, Kasana KS, Thakur NS. The study of solar absorption air-conditioning systems. J.

Energy S Afr 2005;16..

Kaushik SC, Arora A. Energy and exergy analysis of single effect and series flow double

effect water–lithium bromide absorption refrigeration systems. Int J Refrig 2009;32(6):1247–58.

Aliane A, Abboudi S, Seladji C, Guendouz B. An illustrated review on solar absorption

cooling experimental studies. Renewable Sustainable Energy Rev 2016;65:443–58.

Fadi A. Ghaith, Haseeb-ul-Hassan Razzaq. Performance of solar powered cooling system

using Parabolic Trough Collector in UAE” Sustainable Energy Technologies and Assessments.

https://doi.org/10.1016/j.seta.2017.08.005.

Rossetti A, Paci E, Alimonti G. Experimental analysis of the performance of a medium

temperature solar cooling plant. Int J Refrig 2017;80:264–73.

https://doi.org/10.1016/j.ijrefrig.2017.05.002

Galindo-Luna YR, Gomez-Arias ´ E, Romero RJ, Venegas-Reyes E, MontielGonzalez ´ M,

Unland-Weiss HEK, et al. Hybrid solar-geothermal energy absorption air-conditioning system

operating with NaOH-H2O-Las tres vírgenes (Baja California Sur), “La Reforma” case. Energies

;11.. https://doi.org/10.3390/en11051268.

Luna YRG, Franco WRG, Carrasco UD, Domínguez RJR, García JCJ. Integration of the

experimental results of a parabolic trough collector (PTC) solar plant to an absorption airconditioning system. Appl Sci 2018;8. https://doi.org/10.3390/app8112163.

Kalogirou SA. Solar thermal collectors and applications. vol. 30. 2004.

https://doi.org/10.1016/j.pecs.2004.02.001.

Jiaqiang E, Liu G, Liu T, Zhang Z, Zuo H, Hu W, et al. Harmonic response analysis of a large

dish solar thermal power generation system with wind-induced vibration. Sol Energy

;181:116–29. https://doi.org/10.1016/j.solener.2019.01.089.

Zuo H, Liu G, Jiaqiang E, Zuo W, Wei K, Hu W, et al. Catastrophic analysis on the stability

of a large dish solar thermal power generation system with wind-induced vibration. Sol Energy

;183:40–9. https://doi.org/10.1016/j.solener.2019.03.003.

Design of Solar Dish collector for vapor absorption refrigeration system. International Journal

of Civil Engeering and technology.

Rafał Figaj, Mateusz Szubel, Estera Przenzak, Mariusz Filipowicz “Feasibility of a smallscale hybrid dish/flat-plate solar collector system as a heat source for an absorption cooling unit”.

Mehrdad Moradi A, Mehdi Mehrpooya, Optimal design and economic analysis of a hybrid

solid oxide fuel cell and parabolic solar dish collector, combined cooling, heating and power

(CCHP) system used for a large commercial tower. https://doi.org/10.1016/j.energy.2017.05.001.

Su B, Han W, Zhang X, Chen Y, Wang Z, Jin H. Assessment of a combined cooling, heating

and power system by synthetic use of biogas and solar energy. Appl Energy 2018;229:922–35.

https://doi.org/10.1016/j.apenergy.2018.08.037.

Figaj R, Szubel M, Przenzak E, Filipowicz M. Feasibility of a small-scale hybrid dish/flatplate solar collector system as a heat source for an absorption cooling unit. Appl Therm Eng

;163:114399. https://doi.org/10.1016/j.applthermaleng.2019.114399.

Begum SN, Kiran CR, Vasundara K. Design analysis and fabrication of solar vapour

absorption. Int J Innov Technol Explor Eng 2019;8:371–6.

https://doi.org/10.35940/ijitee.I3068.0789S319.

Bianchini A, Guzzini A, Pellegrini M, Saccani C. Performance assessment of a solar parabolic

dish for domestic use based on experimental measurements. Renew Energy 2019;133:382–92.

https://doi.org/10.1016/j.renene.2018.10.046.

Ghaith FA, Razzaq H ul H. Performance of solar powered cooling system using Parabolic

Trough Collector in UAE. Sustain Energy Technol Assessments 2017;23: 21–32.

https://doi.org/10.1016/j.seta.2017.08.005.

Franchini G, Brumana G, Perdichizzi A. Performance prediction of a solar district cooling

system in Riyadh, Saudi Arabia – a case study. Energy Convers Manag 2018;166:372–84.

https://doi.org/10.1016/j.enconman.2018.04.048.

H.H. El-Ghetany , M.A. Omara , R.G. Abdelhady , Gamal B. Abdelaziz. Design of silica

gel/water adsorption chiller powered by solar energy for air conditioning applications, Journal of

Energy Storage 63 (2023) 107055. https://doi.org/10.1016/j.est.2023.107055

A. Mostafa, M. Hassanain, E. Elgendy, Transient simulation and design parameters

optimization of a cold store utilizes solar assisted adsorption refrigeration system, Case Stud.

Therm. Eng. 37 (2022), 102273.

M. Hassan, I.I. El-Sharkawy, K. Harby, Study of an innovative combined absorptionadsorption cooling system employing the same evaporator and condenser, Case Stud. Therm. Eng.

(2023), 102690.

V. Cardoso-Fernandez a, A. Bassam b, O. May Tzuc c,, M.A. Barrera Ch. d, Jorge de Jesús

Chan-Gonz alez c, M.A. Escalante Soberanis b, N. Velazquez-Lim one, Luis J. Ricalde b. Global

sensitivity analysis of a generator-absorber heat exchange (GAX) system’s thermal performance

with a hybrid energy source: An approach using artificial intelligence models, Applied Thermal

Engineering 218 (2023) 119363. https://doi.org/10.1016/j.applthermaleng.2022.119363

O. May Tzuc, J.J. Chan-Gonzalez, I.E. Castaneda-Robles, F. Lezama-Z , M. MMohenoBarrueta, M. Jim´ Torres, R. Best, Multivariate inverse artificial neural network to analyze and

improve the mass transfer of ammonia in a Plate Heat Exchanger-Type Absorber with NH 3 /H 2

O for solar cooling applications, Energy Explor. Exploit. 40 (6) (2022) 1686–1711.

S.M.S. Mahmoudi, A.D. Akbari, M.A. Rosen, A novel combination of absorption heat

transformer and refrigeration for cogenerating cooling and distilled water: Thermoeconomic

optimization, Renew. Energy 194 (2022) 978–996

Ashwni, Ahmad Faizan Sherwani. Analysis of solar energy driven organic Rankine cyclevapor compression refrigeration system, Thermal Science and Engineering Progress 35 (2022).

https://doi.org/10.1016/j.tsep.2022.101477

Asad A. Naqvi, Ahsan Ahmed & Talha Bin Nadeem. Efficiency Improvement of Photovoltaic

Module by Air Cooling Applied Solar Energy volume 57, pages 517–522 (2021)

Ahsan Ahmed, Talha Bin Nadeem, Asad A. Naqvi , Mubashir Ali Siddiqui , Muhammad

Hamza Khan , Muhammad Saad Bin Zahid , Syed Muhammad Ammar. Investigation of PV

utilizability on university buildings: A case study of Karachi, Pakistan, Renewable Energy, August

https://doi.org/10.1016/j.renene.2022.06.006

Ahsan Ahmed, Asad A. Naqvi, Talha Bin Nadeem & Muhammad Uzair. Performance of the

Photovoltaic Modules: a Case Study of Karachi, Pakistan Applied Solar Energy volume 57,

pages370–376 (2021).

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Publicado

2023-06-29

Cómo citar

[1]
A. Shazad y M. Uzair, «Utilización de la energía solar para aplicaciones de enfriamiento: una revisión», Memoria investig. ing. (Facultad Ing., Univ. Montev.), n.º 24, pp. 69–91, jun. 2023.

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