TY - GEN
T1 - Prediction of extremely high minimum heat flux point during quenching in nanofluid
AU - Umehara, Yutaro
AU - Okawa, Tomio
N1 - Publisher Copyright:
© 2020 American Society of Mechanical Engineers (ASME). All rights reserved.
PY - 2020
Y1 - 2020
N2 - In nanofluid that is a liquid containing colloidal dispersion of nanometer-sized particles, it is known that the quenching heat transfer characteristics such as TMHF (minimum heat flux temperature) is improved mainly due to modification of the surface properties caused by nanoparticle deposition during boiling. In this study, the water-based silica (SiO2) nanofluid was used to clarify the mechanisms of the quenching characteristics variation in nanofluid. The Inconel 718 rodlet (φ16×30mm) and SUS304 rodlet (φ15×30mm) were used as the test pieces. The four properties of the nanoparticle layer were measured: Roughness, wettability, wickability, and thickness. Then, the temperature transient in the nanoparticle layer was calculated using the one-dimensional heat conduction equation. It was shown that the surface temperature of the nanoparticle layer should be maintained low enough for a sufficiently long time after immersing the high-temperature test piece in the nanofluid for remarkable increase in TMHF to occur.
AB - In nanofluid that is a liquid containing colloidal dispersion of nanometer-sized particles, it is known that the quenching heat transfer characteristics such as TMHF (minimum heat flux temperature) is improved mainly due to modification of the surface properties caused by nanoparticle deposition during boiling. In this study, the water-based silica (SiO2) nanofluid was used to clarify the mechanisms of the quenching characteristics variation in nanofluid. The Inconel 718 rodlet (φ16×30mm) and SUS304 rodlet (φ15×30mm) were used as the test pieces. The four properties of the nanoparticle layer were measured: Roughness, wettability, wickability, and thickness. Then, the temperature transient in the nanoparticle layer was calculated using the one-dimensional heat conduction equation. It was shown that the surface temperature of the nanoparticle layer should be maintained low enough for a sufficiently long time after immersing the high-temperature test piece in the nanofluid for remarkable increase in TMHF to occur.
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M3 - Conference contribution
AN - SCOPUS:85096037729
SN - 9784888982566
T3 - International Conference on Nuclear Engineering, Proceedings, ICONE
BT - Student Paper Competition; Thermal-Hydraulics; Verification and Validation
PB - American Society of Mechanical Engineers (ASME)
T2 - 2020 International Conference on Nuclear Engineering, ICONE 2020, collocated with the ASME 2020 Power Conference
Y2 - 4 April 2020 through 5 April 2020
ER -