Solar-to-thermal energy conversion technologies are an important and increasingly promising segment of our renewable energy technology future. Today, concentrated solar power (CSP) plants provide a method to efficiently store and distribute solar energy. Current industrial solar-to-thermal energy technologies employ selective solar absorber coatings to collect solar radiation, which suffer from low solar-to-thermal efficiencies at high temperatures due to increased thermal emission from selective absorbers. Solar absorbing nanofluids (a heat transfer fluid (HTF) seeded with nanoparticles), which can be volumetrically heated, are one method to improve solar-to-thermal energy conversion at high temperatures. To date, radiative analyses of nanofluids via the radiative transfer equation (RTE) have been conducted for low temperature applications and for flow conditions and geometries that are not representative of the technologies used in the field. In this work, we present the first comprehensive analysis of nanofluids for CSP plants in a parabolic trough configuration. This geometry was chosen because parabolic troughs are the most prevalent CSP technologies. We demonstrate that the solar-to-thermal energy conversion efficiency can be optimized by tuning the nanoparticle volume fraction, the temperature of the nanofluid, and the incident solar concentration. Moreover, we demonstrate that direct solar absorption receivers have a unique advantage over current surface-based solar coatings at large tube diameters. This is because of a nanofluid's tunability, which allows for high solar-to-thermal efficiencies across all tube diameters enabling small pressure drops to pump the HTF at large tube diameters.
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October 2018
Research-Article
Analysis of Nanofluid-Based Parabolic Trough Collectors for Solar Thermal Applications
Justin P. Freedman,
Justin P. Freedman
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Search for other works by this author on:
Hao Wang,
Hao Wang
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Search for other works by this author on:
Ravi S. Prasher
Ravi S. Prasher
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720;
Department of Mechanical Engineering,
University of California,
Berkeley, CA 94720
e-mail: rsprasher@lbl.gov
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720;
Department of Mechanical Engineering,
University of California,
Berkeley, CA 94720
e-mail: rsprasher@lbl.gov
Search for other works by this author on:
Justin P. Freedman
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Hao Wang
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720
Ravi S. Prasher
Energy Storage and Distributed Resources
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720;
Department of Mechanical Engineering,
University of California,
Berkeley, CA 94720
e-mail: rsprasher@lbl.gov
Division,
Lawrence Berkeley National Laboratory,
1 Cyclotron Road,
Berkeley, CA 94720;
Department of Mechanical Engineering,
University of California,
Berkeley, CA 94720
e-mail: rsprasher@lbl.gov
1Corresponding author.
Contributed by the Solar Energy Division of ASME for publication in the JOURNAL OF SOLAR ENERGY ENGINEERING: INCLUDING WIND ENERGY AND BUILDING ENERGY CONSERVATION. Manuscript received November 26, 2017; final manuscript received March 31, 2018; published online May 29, 2018. Assoc. Editor: Marc Röger.
J. Sol. Energy Eng. Oct 2018, 140(5): 051008 (8 pages)
Published Online: May 29, 2018
Article history
Received:
November 26, 2017
Revised:
March 31, 2018
Citation
Freedman, J. P., Wang, H., and Prasher, R. S. (May 29, 2018). "Analysis of Nanofluid-Based Parabolic Trough Collectors for Solar Thermal Applications." ASME. J. Sol. Energy Eng. October 2018; 140(5): 051008. https://doi.org/10.1115/1.4039988
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