An experimental study on sub-cooled flow boiling CHF of R134a at low pressure condition with atmospheric pressure (AP) plasma assisted surface modification

In this study, sub-cooled flow boiling critical heat flux tests at low pressure were conducted in a rectangular flow channel with one uniformly heated surface, using simulant fluid R-134a as coolant. The experiments were conducted under the following conditions: (1) inlet pressure (P) of 400–800kPa,...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2015-02, Vol.81 (C), p.362-372
Main Authors: Kim, Seung Jun, Zou, Ling, Jones, Barclay G.
Format: Article
Language:English
Subjects:
Atmospheric pressure
Boiling
CHF
Computational fluid dynamics
Contact angle
CRITICAL HEAT FLUX
ENGINEERING
ENTHALPY
Fluid flow
Fluids
HEATING
Inlets
Low pressure
MASS TRANSFER
MODIFICATIONS
PRESSURE RANGE KILO PA
REFRIGERANTS
SCALING LAWS
SUB-COOLED FLOW BOILING
SUBCOOLED BOILING
SURFACE MODIFICATION
Surface properties
SURFACE TREATMENTS
Surface wettability
SURFACE WETTABILLITY
SURFACES
WATER
WETTABILITY
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Summary:In this study, sub-cooled flow boiling critical heat flux tests at low pressure were conducted in a rectangular flow channel with one uniformly heated surface, using simulant fluid R-134a as coolant. The experiments were conducted under the following conditions: (1) inlet pressure (P) of 400–800kPa, (2) mass flux (G) of 124–248kg/m2s, (3) inlet sub-cooling enthalpy (ΔHi) of 12–26kJ/kg. Parametric trends of macroscopic system parameters (G,P,ΔHi) were examined by changing inlet conditions. Those trends were found to be generally consistent with previous understandings of CHF behavior at low pressure condition (i.e. reduced pressure less than 0.2). A fluid-to-fluid scaling model was utilized to convert the test data obtained with the simulant fluid (R-134a) into the prototypical fluid (water). The comparison between the converted CHF of equivalent water and CHF look-up table with same operation conditions were conducted, which showed good agreement. Furthermore, the effect of surface wettability on CHF was also investigated by applying atmospheric pressure plasma (AP-plasma) treatment to modify the surface characteristic. With AP-plasma treatment, the change of microscopic surface characteristic was measured in terms of static contact angle. The static contact angle was reduced from 80° on original non-treated surface to 15° on treated surface. An enhancement of 18% on CHF values under flow boiling conditions were observed on AP-plasma treated surfaces compared to those on non-treated heating surfaces.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2014.10.032