The basis of a novel method for passive solar water heating homologous to the traditional thermosyphon but driven by salinity gradient induced by changes of salinity gradient induced by evaporation at the collector is outlined. Its purpose, likewise than a thermosyphon, is to simplify the transfer of liquid while avoiding the cost and complexity of a conventional pump. However, in this concept, the fluid motion is not obtained from the tendency of a less dense fluid to rise above a denser fluid (natural convection) but rather by taking advantage of the energy released during the spontaneous mixing of the low-concentration (evaporated fraction) solution and the high-concentration (no-evaporated fraction) solution, which have been previously separated into two streams in the evaporator module. Finally, the possibility of driving the thermal osmosis by the strong thermal dependence of the solubility featured by many solutions rather than evaporation is envisaged. One important point in favor of the proposed thermosyphon driven by thermo-osmosis is that makes possible downward heat and mass transfer, i.e., heat and mass transport from the top roofs (where solar collectors are generally placed) to the bottom (inside the homes), and then the use of expensive and voluminous tanks so characteristic of current thermosyphons driven by natural convection is no longer needed.
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October 2018
Research-Article
Pressure-Retarded Osmosis Thermosyphon
Francisco J. Arias,
Francisco J. Arias
Department of Fluid Mechanics,
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
e-mail: francisco.javier.arias@upc.edu
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
e-mail: francisco.javier.arias@upc.edu
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Salvador de las Heras
Salvador de las Heras
Department of Fluid Mechanics,
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
Search for other works by this author on:
Francisco J. Arias
Department of Fluid Mechanics,
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
e-mail: francisco.javier.arias@upc.edu
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
e-mail: francisco.javier.arias@upc.edu
Salvador de las Heras
Department of Fluid Mechanics,
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
University of Catalonia,
ESEIAAT C/Colom 11,
Barcelona 08222, Spain
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 March 29, 2017; final manuscript received April 1, 2018; published online May 29, 2018. Assoc. Editor: Wojciech Lipinski.
J. Sol. Energy Eng. Oct 2018, 140(5): 051006 (4 pages)
Published Online: May 29, 2018
Article history
Received:
March 29, 2017
Revised:
April 1, 2018
Citation
Arias, F. J., and de las Heras, S. (May 29, 2018). "Pressure-Retarded Osmosis Thermosyphon." ASME. J. Sol. Energy Eng. October 2018; 140(5): 051006. https://doi.org/10.1115/1.4039893
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