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Thermal, hydraulic and exergetic evaluation of a parabolic trough collector operating with thermal oil and molten salt based nanofluids

•The use of nanofluids is examined in parabolic trough collectors.•CuO nanoparticles are dispersed in thermal oil and in nitrate molten salt.•The analysis is conducted with SolidWorks Flow Simulation for various cases.•The use of oil-based nanofluid leads up to 0.76% thermal enhancement.•The use of...

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Published in:	Energy conversion and management 2018-01, Vol.156, p.388-402
Main Authors:	Bellos, Evangelos, Tzivanidis, Christos, Tsimpoukis, Dimitrios
Format:	Article
Language:	English
Subjects:	Computational fluid dynamics Computer applications Computer simulation Copper Exergy Flow simulation Fluid dynamics Fluid flow Hydraulics Hydrodynamics Model accuracy Molten salt Molten salts Nanofluids Nanoparticles Oil Oxides Parabolic trough collector Salts Solar collectors Thermal energy Thermal enhancement Thermal oil Thermodynamic efficiency Working fluids
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creator	Bellos, Evangelos Tzivanidis, Christos Tsimpoukis, Dimitrios
description	•The use of nanofluids is examined in parabolic trough collectors.•CuO nanoparticles are dispersed in thermal oil and in nitrate molten salt.•The analysis is conducted with SolidWorks Flow Simulation for various cases.•The use of oil-based nanofluid leads up to 0.76% thermal enhancement.•The use of molten salt-based nanofluid leads up to 0.26% thermal enhancement. The use of nanofluids in parabolic trough collectors is a promising technique for enhancing their performance. This study investigates the dispersion of CuO nanoparticles in Syltherm 800 (thermal oil) and in nitrate molten salt (60% NaNO3 – 40% KNO3). The objective of this work is to examine the thermal efficiency enhancement margin of the utilization of nanofluids for two usual working fluids (thermal oil and molten salt) as base fluids. Moreover, this work includes hydraulic analysis about the pressure losses and exergetic analysis in order to evaluate the total performance of the collector. The module of LS-2 parabolic trough collector is examined with a computational fluid dynamics program developed in SolidWorks Flow Simulation. The model accuracy is checked with thermal efficiency and flow criteria using literature results. The simulations are conducted for temperatures up to 650 K for oil cases and up to 850 K for molten salt cases. According to the final results, the use of oil-based nanofluids leads to thermal efficiency enhancement up to 0.76%, while the use of molten salt-based nanofluid up to 0.26% thermal efficiency enhancement. The Nusselt number enhancement is found up to 40% for Syltherm 800-CuO and up to 13% for molten salt-CuO.
doi_str_mv	10.1016/j.enconman.2017.11.051
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The use of nanofluids in parabolic trough collectors is a promising technique for enhancing their performance. This study investigates the dispersion of CuO nanoparticles in Syltherm 800 (thermal oil) and in nitrate molten salt (60% NaNO3 – 40% KNO3). The objective of this work is to examine the thermal efficiency enhancement margin of the utilization of nanofluids for two usual working fluids (thermal oil and molten salt) as base fluids. Moreover, this work includes hydraulic analysis about the pressure losses and exergetic analysis in order to evaluate the total performance of the collector. The module of LS-2 parabolic trough collector is examined with a computational fluid dynamics program developed in SolidWorks Flow Simulation. The model accuracy is checked with thermal efficiency and flow criteria using literature results. The simulations are conducted for temperatures up to 650 K for oil cases and up to 850 K for molten salt cases. According to the final results, the use of oil-based nanofluids leads to thermal efficiency enhancement up to 0.76%, while the use of molten salt-based nanofluid up to 0.26% thermal efficiency enhancement. 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The use of nanofluids in parabolic trough collectors is a promising technique for enhancing their performance. This study investigates the dispersion of CuO nanoparticles in Syltherm 800 (thermal oil) and in nitrate molten salt (60% NaNO3 – 40% KNO3). The objective of this work is to examine the thermal efficiency enhancement margin of the utilization of nanofluids for two usual working fluids (thermal oil and molten salt) as base fluids. Moreover, this work includes hydraulic analysis about the pressure losses and exergetic analysis in order to evaluate the total performance of the collector. The module of LS-2 parabolic trough collector is examined with a computational fluid dynamics program developed in SolidWorks Flow Simulation. The model accuracy is checked with thermal efficiency and flow criteria using literature results. The simulations are conducted for temperatures up to 650 K for oil cases and up to 850 K for molten salt cases. According to the final results, the use of oil-based nanofluids leads to thermal efficiency enhancement up to 0.76%, while the use of molten salt-based nanofluid up to 0.26% thermal efficiency enhancement. 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The use of nanofluids in parabolic trough collectors is a promising technique for enhancing their performance. This study investigates the dispersion of CuO nanoparticles in Syltherm 800 (thermal oil) and in nitrate molten salt (60% NaNO3 – 40% KNO3). The objective of this work is to examine the thermal efficiency enhancement margin of the utilization of nanofluids for two usual working fluids (thermal oil and molten salt) as base fluids. Moreover, this work includes hydraulic analysis about the pressure losses and exergetic analysis in order to evaluate the total performance of the collector. The module of LS-2 parabolic trough collector is examined with a computational fluid dynamics program developed in SolidWorks Flow Simulation. The model accuracy is checked with thermal efficiency and flow criteria using literature results. The simulations are conducted for temperatures up to 650 K for oil cases and up to 850 K for molten salt cases. According to the final results, the use of oil-based nanofluids leads to thermal efficiency enhancement up to 0.76%, while the use of molten salt-based nanofluid up to 0.26% thermal efficiency enhancement. The Nusselt number enhancement is found up to 40% for Syltherm 800-CuO and up to 13% for molten salt-CuO.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.enconman.2017.11.051</doi><tpages>15</tpages><orcidid>https://orcid.org/0000-0002-5876-6549</orcidid></addata></record>
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source	ScienceDirect Journals
subjects	Computational fluid dynamics Computer applications Computer simulation Copper Exergy Flow simulation Fluid dynamics Fluid flow Hydraulics Hydrodynamics Model accuracy Molten salt Molten salts Nanofluids Nanoparticles Oil Oxides Parabolic trough collector Salts Solar collectors Thermal energy Thermal enhancement Thermal oil Thermodynamic efficiency Working fluids
title	Thermal, hydraulic and exergetic evaluation of a parabolic trough collector operating with thermal oil and molten salt based nanofluids
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