Abstract
Nanoparticle dispersed fluids, nanofluids, have been widely investigated. However, thermal conductivity of molten salt-based nanofluid had never been measured and investigated yet. Since molten salts are high Prandtl number fluids, it is necessary to enhance heat transfer of the molten salts when they are employed as coolants. Therefore, in the present study we produced a molten salt-based nanofluid, and measured its thermal conductivity to demonstrate the molten salt-based nanofluid was able to enhance its own thermal conductivity. We employed Heat Transfer Salt (HTS: 40 wt% NaNO2, 7 wt% NaNO3, and 53 wt% KNO3) as a base fluid since it was a typical example of molten salts. We mixed HTS with silicon carbide nanoparticles, which was a molten salt-based nanofluid, and investigated change in thermal conductivity by mixing nanoparticle by means of transient hot-wire method. We found that, at a particle volume fraction of 0.72%, the effective thermal conductivity increased by 13% at 200oC. Compared with Wiener equations, and Hashin-Shtrikman equations, we confirmed that the measured value was located in between the theoretical upper and lower limits of nanofluids thermal conductivity. Based on this, we concluded that mixing nanoparticle with a molten salt was able to enhance its thermal conductivity.
Highlights
Nanoparticles suspended fluids, nanofluids, have been widely investigated since it was reported that the nanofluids are able to change their own thermophysical properties from their base fluids.[1]
We investigated the molten salt-based nanofluid thermal conductivity by means of the transient hot-wire method
At the particle volume fraction of 0.72%, the silicon carbide (SiC) nanoparticles increased the Heat Transfer Salt (HTS) thermal conductivity by approximately 13%
Summary
Nanoparticles suspended fluids, nanofluids, have been widely investigated since it was reported that the nanofluids are able to change their own thermophysical properties from their base fluids.[1] Amounts of nanofluid thermal conductivity change,[2] and heat conduction mechanism in the nanofluids[3,4] have been investigated and discussed until now. Those nanofluids base fluids were water, ethylene glycol, and oils. It has been reported that an eutectic salt of lithium carbonate and potassium carbonate (62 mol% Li2CO3 -38 mol% K2CO3) mixed with SiO2 nanoparticles,[5] and an eutectic salt of sodium nitrate and potassium nitrate (60 wt% NaNO3 – 40 wt% KNO3) mixed with SiO2 nanoparticles[6] improved their own specific heat capacity
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