Abstract
Heat transfer under flow boiling is better in a rectangular channel filled with open-cell metal foam than in an empty channel, but the high pressure drop is a drawback of the empty channel method. In this study, various types of metal foam insert configurations were tested to reduce the pressure drop while maintaining high heat transfer. Specifically, we measured the boiling heat transfer and pressure drop of a two-phase vertical upward flow of R245fa inside a channel. To measure the pressure and temperature differences of the metal foam, differential pressure transducers and T-type thermocouples were used at both ends of the test section. While the saturation pressure was kept constant at 5.9 bar, the steam quality at the inlet of the test section was changed from 0.05 to 0.99. The channel height, moreover, was 3 mm, and the mass flux ranged from 133 to 300 kg/m2s. The two-phase flow characteristics were observed through a high-speed visualization experiment. Heat transfer tended to increase with the mean vapor quality, and, as expected, the fully filled metal foam channel offered the highest thermal performance. The streamwise insert pattern model had the lowest heat transfer at a low mass flux. However, at a higher mass flux, the three different insert models presented almost the same heat transfer coefficients. We found that the streamwise pattern model had a very low pressure drop compared to that of the spanwise pattern models. The goodness factors of the flow area and the core volume of the streamwise patterned model were higher than those of the full-filled metal foam channel.
Highlights
Open metal foam has a typical porous structure, with many randomly connected internal pathways and high porosity
The thermal performance of the heat exchanger can be improved by using metal foam inserts with a high surface area to volume ratio (790–2740 m2/m3) and high porosity (>90%)
Several groups have published experimental research on metal foam heat exchangers [1,2,3,4,5,6], and, to date, many studies have been conducted on the convective heat transfer of single-phase liquids or gases using small heat exchangers and metal foams [7,8,9,10,11,12,13,14,15,16,17,18,19]
Summary
Open metal foam has a typical porous structure, with many randomly connected internal pathways and high porosity. Zhao et al [25] studied the flow boiling heat transfer of R134a refrigerant flowing through a horizontal tube containing copper metal foam. Their experiments were performed at mass flow rates of 26–106 kg/m2s and saturation pressures of 3.5 and 6 bar, controlled by an electric heater. Kim et al [29] presented the experimental results for the boiling heat transfer of R245fa in a channel filled with 18 PPI copper metal foam. In this study, an experimental investigation was conducted on the heat and fluid flow characteristics of different types of patterned configuration models with porous media. Mass flux (R245fa) (kg/m2s) Inlet temperature (preheat) (◦C) Inlet temperature (hot water) (◦C)
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