Local heat transfer measurement and thermo-fluid characterization of a pulsating heat pipe

A compact Closed Loop Pulsating Heat Pipe (CLPHP), filled with ethanol (65% v/v), made of four transparent glass tubes forming the adiabatic section and connected with copper U-turns in the evaporator and condenser sections respectively, is designed in order to perform comprehensive thermal-hydrauli...

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Bibliographic Details
Published in:International journal of thermal sciences 2014-01, Vol.75 (75), p.140-152
Main Authors: Mameli, Mauro, Marengo, Marco, Khandekar, Sameer
Format: Article
Language:English
Subjects:
Applied sciences
Devices
Devices using thermal energy
Energy
Energy. Thermal use of fuels
Ethanol
Ethyl alcohol
Evaporation
Exact sciences and technology
Flow patterns
Fluid flow
Heat pipes
Heat transfer
Local heat transfer
Oscillations
Pressure variation
Pulsating Heat Pipes
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Summary:A compact Closed Loop Pulsating Heat Pipe (CLPHP), filled with ethanol (65% v/v), made of four transparent glass tubes forming the adiabatic section and connected with copper U-turns in the evaporator and condenser sections respectively, is designed in order to perform comprehensive thermal-hydraulic performance investigation. Local heat transfer coefficient is estimated by measurement of tube wall and internal fluid temperatures in the evaporator section. Simultaneously, fluid pressure oscillations are recorded together with the corresponding flow patterns. The thermal performances are measured for different heat input levels and global orientation of the device with respect to gravity. One exploratory test is also done with azeotropic mixture of ethanol and water. Results show that a stable device operation is achieved (i.e. evaporator wall temperatures can reach a pseudo-steady-state) only when a circulating flow mode is established superimposed on local pulsating flow. The heat transfer performance strongly depends on the heat input level and the inclination angle, which, in turn, also affect the ensuing flow pattern. The spectral analysis of the pressure signal reveals that even during the stable performance regimes, characteristic fluid oscillation frequencies are not uniquely recognizable. Equivalent thermal conductivities of the order of 10–15 times that of pure copper are achieved. Due to small number of turns horizontal mode operation is not feasible. Preliminary results indicate that filling azeotropic mixture of ethanol and water as working fluid does not alter the thermal performance as compared to pure ethanol case. •Local heat transfer measurement and flow visualization in the Pulsating Heat Pipe.•Thermal-hydraulic characterization at different operating conditions/orientations.•Different flow patterns observed, net circulating flow being the most efficient.•Equivalent thermal conductivity PHP is of the order of 10–15 times that of copper.•Time-averaged internal heat transfer coefficient approaches 4600 W/m2 K.
ISSN:1290-0729
1778-4166
DOI:10.1016/j.ijthermalsci.2013.07.025