Thermodynamic analytical model of a loop heat pipe

“…Although previous studies on LHP modeling contributed significantly to the understanding of the physical phenomena involved in the operation of such systems, the literature survey evidences a lack in the modeling of the evaporation phenomenon within the capillary wick (Table 4). Indeed, many of the published models did not present details about how the evaporation thermal conductance is determined or modeled [29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47]49]. Besides, according to the literature review, to date, no models have been established for the prediction of the evaporation heat transfer coefficient in the capillary structures.…”

Modeling of Loop Heat Pipe Thermal Performance

“…Although previous studies on LHP modeling contributed significantly to the understanding of the physical phenomena involved in the operation of such systems, the literature survey evidences a lack in the modeling of the evaporation phenomenon within the capillary wick (Table 4). Indeed, many of the published models did not present details about how the evaporation thermal conductance is determined or modeled [29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47]49]. Besides, according to the literature review, to date, no models have been established for the prediction of the evaporation heat transfer coefficient in the capillary structures.…”

Modeling of Loop Heat Pipe Thermal Performance

“…This is because of the layers of glass wool that are made to cover the adiabatic section. Thus, the vapor moves faster through the ports without losing its temperature 17 . The condenser inlet or the outlet of the adiabatic section is indicated as point 4.…”

“…Thus, the vapor moves faster through the ports without losing its temperature. 17 The condenser inlet or the outlet of the adiabatic section is indicated as point 4. This particular point is stated to be the superheated region for the working fluid due to low pressure in the condenser area.…”

Feasibility of using multiport minichannel as thermosyphon for cooling of miniaturized electronic devices

“…Enhancing the internal cooling of the channels is achieved by different augmentation techniques such as jet impingement [1], porous inserts [2], roughness elements [3], ribs, baffles [4], porous fins [5], or two-phase cooling [6]. Enhancing the internal cooling of the channels is achieved by different augmentation techniques such as jet impingement [1], porous inserts [2], roughness elements [3], ribs, baffles [4], porous fins [5], or two-phase cooling [6].…”

An empirical correlation for isothermal parallel plate channel completely filled with porous media