A detailed working fluid investigation for solar parabolic trough collectors

Abstract Solar energy is a promising energy source for covering a great variety of applications from low up to high temperature levels. In this study, the most mature concentrating technology, a commercial parabolic trough collector (Eurotrough ET-150), is investigated energetically and exergetically for a great temperature range from 300 K to 1300 K. Pressurized water, Therminol VP-1, nitrate molten salt, sodium liquid, air, carbon dioxide and helium are the examined working fluids; each one to be studied in the proper temperature range. In the first part of this study, the optimum mass flow rate is determined to every working fluid separately. After this point, the exergetic and the energetic performance of the collector operating with all these working fluids is examined. The final results prove that the liquid sodium leads to the global exergetic maximum efficiency (47.48%) for inlet temperature equal to 800 K, while the maximum exergetic performance of helium, carbon dioxide and air to be 42.21%, 42.06% and 40.12% respectively. Moreover, pressurized water is the best working medium for temperature levels up to 550 K, while carbon dioxide and helium are the only solutions for temperatures greater than 1100 K. The thermal analysis is performed with the EES tool.

[1]  Sanford Gordon,et al.  NASA Glenn Coefficients for Calculating Thermodynamic Properties of Individual Species , 2002 .

[2]  J. Coventry,et al.  A review of sodium receiver technologies for central receiver solar power plants , 2015 .

[3]  Yongping Yang,et al.  Comparison in net solar efficiency between the use of concentrating and non-concentrating solar collectors in solar aided power generation systems , 2015 .

[4]  K. A. Antonopoulos,et al.  Energetic and financial investigation of a stand-alone solar-thermal Organic Rankine Cycle power plant , 2016 .

[5]  Carmelina Abagnale,et al.  Energy, economic and environmental performance appraisal of a trigeneration power plant for a new district: Advantages of using a renewable fuel , 2016 .

[6]  S. Kalogirou A detailed thermal model of a parabolic trough collector receiver , 2012 .

[7]  Hongguang Jin,et al.  A three-dimensional simulation of a parabolic trough solar collector system using molten salt as heat transfer fluid , 2014 .

[8]  T. E. Boukelia,et al.  Investigation of solar parabolic trough power plants with and without integrated TES (thermal energy storage) and FBS (fuel backup system) using thermic oil and solar salt , 2015 .

[9]  Larbi Loukarfi,et al.  Estimation of the temperature, heat gain and heat loss by solar parabolic trough collector under Algerian climate using different thermal oils , 2013 .

[10]  Eduardo Zarza,et al.  Performance model and annual yield comparison of parabolic-trough solar thermal power plants with either nitrogen or synthetic oil as heat transfer fluid , 2014 .

[11]  Dimitrios M. Korres,et al.  Thermal and optical efficiency investigation of a parabolic trough collector , 2015 .

[12]  Kimon A. Antonopoulos,et al.  Energetic and financial evaluation of a solar assisted heat pump heating system with other usual heating systems in Athens , 2016 .

[13]  Soteris A. Kalogirou,et al.  Solar thermal collectors and applications , 2004 .

[14]  S. G. Penoncello,et al.  Thermodynamic Properties of Air and Mixtures of Nitrogen, Argon, and Oxygen From 60 to 2000 K at Pressures to 2000 MPa , 2000 .

[15]  Varun,et al.  Heat transfer augmentation using twisted tape inserts: A review , 2016 .

[16]  Luca Marocco,et al.  Assessment of thermal energy storage options in a sodium-based CSP plant , 2016 .

[17]  Eduardo Zarza,et al.  Theoretical basis and experimental facility for parabolic trough collectors at high temperature using gas as heat transfer fluid , 2014 .

[18]  Roberto Cipollone,et al.  Gases as Working Fluid in Parabolic Trough CSP Plants , 2013, ANT/SEIT.

[19]  Jan Fabian Feldhoff,et al.  Comparative system analysis of direct steam generation and synthetic oil parabolic trough power plants with integrated thermal storage , 2012 .

[20]  K. A. Antonopoulos,et al.  Exergetic and energetic comparison of LiCl-H2O and LiBr-H2O working pairs in a solar absorption cooling system , 2016 .

[21]  Mengna Hong,et al.  Compound Heat Transfer Enhancement of a Converging-Diverging Tube with Evenly Spaced Twisted-tapes * , 2007 .

[22]  Ahmed F. Ghoniem,et al.  A review of solar methane reforming systems , 2015 .

[23]  Rong Zeng,et al.  Exergy and environmental assessments of a novel trigeneration system taking biomass and solar energy as co-feeds , 2016 .

[24]  Xavier Py,et al.  A thermocline thermal energy storage system with filler materials for concentrated solar power plants: Experimental data and numerical model sensitivity to different experimental tank scales , 2016 .

[25]  María José Montes,et al.  Thermofluidynamic Model and Comparative Analysis of Parabolic Trough Collectors Using Oil, Water/Steam, or Molten Salt as Heat Transfer Fluids , 2010 .

[26]  Amenallah Guizani,et al.  Experimental investigation of parabolic trough collector system under Tunisian climate: Design, manufacturing and performance assessment , 2016 .

[27]  K. V. Sharma,et al.  Numerical validation of experimental heat transfer coefficient with SiO2 nanofluid flowing in a tube with twisted tape inserts , 2014 .

[28]  K. A. Antonopoulos,et al.  Exergetic, energetic and financial evaluation of a solar driven absorption cooling system with various collector types , 2016 .

[29]  K. A. Antonopoulos,et al.  The use of gas working fluids in parabolic trough collectors – An energetic and exergetic analysis , 2016 .

[30]  D. Yogi Goswami,et al.  Thermal energy storage using chloride salts and their eutectics , 2016 .

[31]  Vishwas V. Wadekar,et al.  Ionic liquids as heat transfer fluids – An assessment using industrial exchanger geometries , 2017 .

[32]  Ralf Uhlig,et al.  Thermodynamic evaluation of liquid metals as heat transfer fluids in concentrated solar power plants Original Research Article , 2013 .

[33]  C. Yaws Chemical properties handbook , 1999 .

[34]  Jinliang Xu,et al.  Performance analysis of a parabolic trough solar collector using Al2O3/synthetic oil nanofluid , 2016 .

[35]  Ilker Tari,et al.  Energy–exergy and economic analyses of a hybrid solar–hydrogen renewable energy system in Ankara, Turkey , 2016 .

[36]  A. Abánades,et al.  A review on the application of liquid metals as heat transfer fluid in Concentrated Solar Power technologies , 2016 .

[37]  Yongping Yang,et al.  A novel hybrid storage system integrating a packed-bed thermocline tank and a two-tank storage system for concentrating solar power (CSP) plants. , 2016 .

[38]  A. Fouda,et al.  An integrated A/C and HDH water desalination system assisted by solar energy: Transient analysis and economical study , 2016 .

[39]  Josua P. Meyer,et al.  Heat transfer and entropy generation in a parabolic trough receiver with wall-detached twisted tape inserts , 2016 .

[40]  V. Zare,et al.  Proposal, exergy analysis and optimization of a new biomass-based cogeneration system , 2016 .

[41]  Mario Amelio,et al.  An evaluation of the performance of an integrated solar combined cycle plant provided with air-linear parabolic collectors , 2014 .

[42]  Dimitrios M. Korres,et al.  Design, simulation and optimization of a compound parabolic collector , 2016 .

[43]  Judith Gurney BP Statistical Review of World Energy , 1985 .

[44]  K. A. Antonopoulos,et al.  Thermal enhancement of solar parabolic trough collectors by using nanofluids and converging-diverging absorber tube , 2016 .

[45]  Faramarz Sarhaddi,et al.  Experimental investigation of exergy efficiency of a solar photovoltaic thermal (PVT) water collector based on exergy losses , 2015 .

[46]  James E. Pacheco,et al.  Results of molten salt panel and component experiments for solar central receivers: Cold fill, freeze/thaw, thermal cycling and shock, and instrumentation tests , 1995 .