Considering the significance of the appropriate selection of boundary conditions
(BCs) in modelling step for practical engineering applications, this study
presents a numerical work focusing on the impacts of BCs on the natural convection
of molten phase change material (PCM) used for cooling of photovoltaics
(PV). A rectangular enclosure loaded with liquid PCM (Pr = 41.22) is
considered at an inclination angle of θ = 30 to simulate a PV-PCM system.
Heat flux is applied to the top wall, and impacts of two different BCs at the
bottom wall, namely isothermal and convective BCs, on the flow and heat
transfer characteristics are compared by taking six different Biot numbers
(0.1 ≤ Bi ≤ 100) into account, while the reference case is considered as isothermal
BC. Furthermore, the effects of various aspect ratios (AR = 1, 2 and 4) and
Rayleigh numbers (Ra = 104, 105 and 106) are also included. The results revealed
that Biot number has a significant effect on mean Nusselt number. Compared
to the isothermal case, low Biot numbers (Bi < 10) significantly restrict
convection motions inside the enclosure and result in remarkably different
mean Nusselt numbers, while high Biot numbers give significantly similar
results due to low thermal resistance outside the bottom wall. Moreover, the
heat transfer enhancement by increasing AR and Ra is considerably high at
high Biot numbers, while it is remarkably constricted at low Biot numbers. As
a result of comprehensive analyses, it is deduced that utilization of isothermal
BCs instead of convective BC for easiness of modelling can be a reasonable
approach providing that Biot number is sufficiently large (Bi > 10). Although
the inspiration of the present study is PV/PCM systems, the results can be generalized
for any kind of fluids used in similar natural convection applications.