Experimental study of channel roughness effect in diffusion bonded pulsating heat pipes

Experimental study of channel roughness effect in diffusion bonded pulsating heat pipes

•This research reports the roughness effect in diffusion bonded pulsating heat pipes.•The device with higher roughness at evaporator zone increases thermal performance.•Stop-over instability appears on the device with increased thermal performance. This study investigates the influence of surface fi...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 166; p. 114734
Main Authors: Betancur-Arboleda, Luis Alonso, Flórez Mera, Juan Pablo, Mantelli, Marcia
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 05-02-2020
Elsevier BV
Subjects:
Copper
Diffusion
Diffusion bonding
Diffusion effects
Diffusion welding
Evaporators
Heat pipes
Hydraulics
Nucleation
Pipes
Roughness
Sanding
Sandpaper
Start-up
Stop-over
Surface finishing
Surface roughness
Thermal resistance
Thermal stability
Vertical orientation
Working fluids
Start-up
Thermal resistance
Diffusion bonding
Stop-over
Roughness
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Summary:•This research reports the roughness effect in diffusion bonded pulsating heat pipes.•The device with higher roughness at evaporator zone increases thermal performance.•Stop-over instability appears on the device with increased thermal performance. This study investigates the influence of surface finishing on thermal performance of copper flat pulsating heat pipes (PHP). Two copper flat PHPs with overall dimensions of 208 × 150 × 5 mm3 were fabricated using the diffusion bonding technique. In both devices, the internal surfaces were modified. In the first one, the channel inner surface was sanded with standard sandpaper Grit N1200. In the second PHP (called hybrid), the evaporator zone was sanded with standard sandpaper Grit N100 and the condenser section with Grit N1200. Both devices counted ten parallel channels with hydraulic diameter of 2.5 mm. Distillated water was used as working fluid. The transient thermal performance and thermal resistance were analyzed, for filling ratios of 10, 15, 25, 37.5, 50 and 75% and for tilt angles of 0° and 90° bottom heat mode. Start-up, thermal stability and hysteresis were experimentally tested. Three regimes were observed: conduction, unstable, stable. In general, the hybrid PHP showed lower thermal resistances, except for the filling ratio of 75% at vertical position. The hybrid device shows stop-over instabilities at power inputs between 140 and 180 W, at vertical position and low filling ratios. Higher surface roughness increases the number of vapor nucleation sites, which, in turn, improves the phase change at evaporator zone and facilitates the start-up conditions at low filling ratios. However, increasing roughness also rises pressure drops, mainly at high filling ratios.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2019.114734