Abstract
This paper presents the thermo-hydraulic performance of small conical ribs on the absorber plate of a solar energy air heater (SAH) using exergy analysis. Application of conical protrusion ribs on the absorber is an attractive solution for enhancing the thermal performance of a SAH. However, these ribs are also responsible for high friction losses and increased fan power consumption caused by the turbulent air flow. To optimize the rib design, it is vital to consider both thermal and hydraulic performance at the same time. The SAH was assessed using an analytic method which predicts the exergy efficiency under operating parameters (e.g., Reynolds number, solar insolation and temperature increase parameter). The following geometric quantities of ribs were evaluated for optimum exergy efficiency: the relative rib height (e/D), which was in the range between 0.200 and 0.044, and the relative rib pitch (p/e), which was in the range between 6 and 12. The combination of a relative rib height of 0.044 and relative rib pitch of 10 exhibits the highest exergy efficiency of 0.0202. The optimization of the rib geometric quantities parameters was performed by considering the temperature increase parameter, aiming to achieve maximum exergy efficiency. The combination of rib parameters e/D = 0.044 and p/e = 10 are noted to yield best performance when operating at a temperature increase parameter above 0.0141 K∙m2/W.
Highlights
Renewable energy resources are gaining importance due to their eco-friendly nature, zero emissions, elimination of toxic gases, energy supply availability and security
The results revealed that dimple ribs lead to significant heat transfer enhancement without an excessive pressure drop penalty
Sharp corners on the conical ribs created flow turbulence which has a favorable effect in terms of heat transfer enhancement; at the expense of a reduced hydraulic performance
Summary
Renewable energy resources are gaining importance due to their eco-friendly nature, zero emissions, elimination of toxic gases, energy supply availability and security. The literature [2,3,4] reports that the performance of SAHs is not expected to develop enough to achieve economic viability in real applications The reason for this disadvantage is the low heat extraction ability of air, especially when flowing over smooth absorber plates. Sharp corners on the conical ribs created flow turbulence which has a favorable effect in terms of heat transfer enhancement; at the expense of a reduced hydraulic performance. They pointed out that dimple/protrusion rib roughness was more advantageous compared to other artificial roughness designs These types of rib roughness offer several advantages: (i) heat transfer enhancement without excessive pressure drop increase, (ii) no additional mass on the absorber plate and (iii) manufactured by pressing down on the indenting device. Sci. 2022, 12, 1696 investigate the effects of surface roughness on the exergy efficiency and (ii) optimize the protrusion ribs for best exergy efficiency in different temperature increase parameter rantghees.effects of surface roughness on the exergy efficiency and (ii) optimize the protrusion ribs for best exergy efficiency in different temperature increase parameter ranges
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