Numerical Study of Effect of Thermocapillary Convection on Melting Process of Phase Change Material subjected to Local Heating

Kim, Yangkyun; Hossain, Akter; Nakamura, Yuji

doi:10.1299/jtst.8.136

Cited by 8 publications

(2 citation statements)

References 31 publications

(35 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although this approach was excellent to reveal the dripping/deformation behavior of the polymers, internal heat transfer inside the molten matter cannot be handled because of the limitation of the adopted model. At nearly the same time, Kim et al [17] [18] [19] [20] studied dripping dynamics by using the Enthalpy-Porosity and Volume of Fluid S. Singh method under the Finite Volume Method (FVM) to explain the complex thermal fluid process inside the molten matter. These works, have been successfully demonstrated the impact of deformation and dripping on the heat transfer rate of phase change process [17].…”

Section: Introductionmentioning

confidence: 99%

“…At nearly the same time, Kim et al [17] [18] [19] [20] studied dripping dynamics by using the Enthalpy-Porosity and Volume of Fluid S. Singh method under the Finite Volume Method (FVM) to explain the complex thermal fluid process inside the molten matter. These works, have been successfully demonstrated the impact of deformation and dripping on the heat transfer rate of phase change process [17]. It is found that molten matter dynamics can accelerate dripping [18] and that the internal fluid motion by the thermocapillary effect is insignificant when the deformation is substantial [19].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Numerical Study of the Irradiated Ignition of Obliquely Oriented Thermally-Deformable Polymer

Singh¹

2022

OJFD

View full text Add to dashboard Cite

This study numerically investigates the influence of molten matter dynamics on the gasification and subsequent ignitability of an inclined thermoplastic specimen subjected to localized irradiation heat flux normal to the surface. A thermoplastic material is modeled as a phase change material with predefined solidification and melting temperatures, respectively, and the gasification process is modeled by the Arrhenius law of molten matter. Gas phase kinetics is not considered for simplicity purposes; instead, the onset of ignition of polymer is estimated on the basis of the critical mass flux concept. According to the numerical results, as the inclination angle becomes steeper (toward the vertical angle), the estimated ignition delay becomes shorter, showing ignition is promoted, whereas it is turned to be difficult to occur when inclination angles are above the vertical angle (>90˚) having a longer delay time for the onset of gasification. With careful observation, the thermal interaction between the hot molten matter and unmelted (cold) solid is found to play an important role in gasification. The formation of a bulge due to resolidification to suppress the dripping downstream could be the source to promote ignition. By contrast, the hot molten matter is enforced to detach from the unmelted solid and "freely fall-off" to prohibit ignition for inclination angles beyond 90˚. This supports the notion that high-enthalpy caused by the external heating is simply lost because of dripping, and there is less chance of catching fire there.

show abstract