Spontaneous downward heat transport comparison tests of an improved system

“…2(i); their experimental results were obtained using methanol as working fluid. In [16] and [44] De Beni et al strengthened their original system by making other improvements, while in [45] an example of their system was used to produce warm water by solar heating in a mountain refuge.…”

“…In the past several names have been put forward to identify devices of this kind: "down-pumping heat pipes" [13], "reverse thermosyphon" [14], "passive vapour transport systems" [15], "spontaneous downward heat transport systems" [16] and so on . In my opinion, the best name for identifying these particular devices is periodic two-phase thermosyphons (PTPT), because they can operate with the evaporator located either above or below the condenser, they can be seen as a special version of a heat pipe or, more precisely, a two-phase thermosyphon and, lastly, they all operate in a periodic heat transfer regime.…”

“…(14) and (15), while Eq. (16) represents the rate of change of the mass inside all control volumes within the loop [57]: (15) where S A is the external surface of the accumulator, U A is the heat transfer coefficient (natural convection in this case with U A = 5 W·m −2 ·K −1 ) and T m represents the temperature of the heat sink, which is in contact with the external surface of the accumulator (T m = 293 K).…”

On periodic two-phase thermosyphons operating against gravity

“…2(i); their experimental results were obtained using methanol as working fluid. In [16] and [44] De Beni et al strengthened their original system by making other improvements, while in [45] an example of their system was used to produce warm water by solar heating in a mountain refuge.…”

“…In the past several names have been put forward to identify devices of this kind: "down-pumping heat pipes" [13], "reverse thermosyphon" [14], "passive vapour transport systems" [15], "spontaneous downward heat transport systems" [16] and so on . In my opinion, the best name for identifying these particular devices is periodic two-phase thermosyphons (PTPT), because they can operate with the evaporator located either above or below the condenser, they can be seen as a special version of a heat pipe or, more precisely, a two-phase thermosyphon and, lastly, they all operate in a periodic heat transfer regime.…”

“…(14) and (15), while Eq. (16) represents the rate of change of the mass inside all control volumes within the loop [57]: (15) where S A is the external surface of the accumulator, U A is the heat transfer coefficient (natural convection in this case with U A = 5 W·m −2 ·K −1 ) and T m represents the temperature of the heat sink, which is in contact with the external surface of the accumulator (T m = 293 K).…”

On periodic two-phase thermosyphons operating against gravity

“…Chociaż w przypadku tych dwóch ostatnich wpływ siły grawitacji na pracę urządzenia jest niewielki [15], to wykonanie kapilarnej struktury jest procesem technologicznie złożo-nym i kosztownym. Inną grupę urządzeń do transportu ciepła, pracujących przeciwko sile grawitacji stanowią dwufazowe termosyfony znane z literatury jako: pompująca w dół rura ciepła [3], termosyfon odwrócony [12], pasywny parowy system transportu [8], czy też spontaniczny system transportu ciepła w dół [2]. Chociaż nazwy tych urządzeń się różnią, to ich działanie oparte jest na okresowym, naprzemiennym transporcie ciepła za pośrednictwem pary od parownika do skraplacza i powrocie kondensatu ze skraplacza do parownika, przez co mogą być określone jako okresowy dwufazowy termosyfon [7].…”

Cykliczny termosyfon odwrócony o dwóch czynnikach roboczych

Utilization of solar thermal energy in mountain refuges through an innovative system