• Title of article

    On the quenching of steel and zircaloy spheres in water-based nanofluids with alumina, silica and diamond nanoparticles

  • Author/Authors

    Kim، نويسنده , , Hyungdae and DeWitt، نويسنده , , Gregory and McKrell، نويسنده , , Thomas and Buongiorno، نويسنده , , Jacopo and Hu، نويسنده , , Lin-wen، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2009
  • Pages
    12
  • From page
    427
  • To page
    438
  • Abstract
    The quenching curves (temperature vs time) for small (∼1 cm) metallic spheres exposed to pure water and water-based nanofluids with alumina, silica and diamond nanoparticles at low concentrations (⩽0.1 vol%) were acquired experimentally. Both saturated (ΔTsub = 0 °C) and highly subcooled (ΔTsub = 70 °C) conditions were explored. The spheres were made of stainless steel and zircaloy, and were quenched from an initial temperature of ∼1000 °C. The results show that the quenching behavior in nanofluids is nearly identical to that in pure water. However, it was found that some nanoparticles accumulate on the sphere surface, which results in destabilization of the vapor film in subsequent tests with the same sphere, thus greatly accelerating the quenching process. The entire boiling curves were obtained from the quenching curves using the inverse heat transfer method, and revealed that alumina and silica nanoparticle deposition on the surface increases the critical heat flux and minimum heat flux temperature, while diamond nanoparticle deposition has a minimal effect on the boiling curve. The possible mechanisms by which the nanoparticles affect the quenching process were analyzed. It appears that surface roughness increase and wettability enhancement due to nanoparticle deposition may be responsible for the premature disruption of film boiling and the acceleration of quenching. The basic results were also confirmed by quench tests with rodlets.
  • Keywords
    film boiling , Minimum heat flux , wettability , rodlets
  • Journal title
    International Journal of Multiphase Flow
  • Serial Year
    2009
  • Journal title
    International Journal of Multiphase Flow
  • Record number

    1410296