Thermal and Thermo-hydraulic Performance of Finned Double-Pass Solar Air Collector Utilizing Cylindrical Capsules Nano-Enhanced PCM

solar air collector with a finned absorber and nano-enhanced PCM in the lower channel is one of the significant and attractive designs proposed to improve the performance. This research paper presents a novel mathematical model of steady-state equilibrium equations created and developed for two air streams: the glass cover, absorber plate, fins, nano -enhanced PCM capsules, and back plate. The influence of various operating parameters on thermal and thermo-hydraulic performance was presented and discussed. The simulations were conducted at air mass flow rates from 0.02 kg/s through 0.06 kg/s and solar irradiance levels ranging from 475 W/m2 to 1000 W/m2. The proposed collector has an optimal energy efficiency of 80%, an exergy efficiency of 18.2% at solar irradiance of 1000 W/m2, and a mass flow rate of 0.06 kg/s. The minimum and maximum improvement potentials for solar irradiance levels of 475-1000 W/m2 at an ambient temperature of 298 K are 163- 237 W. The proposed collector's best findings in the current study are 1.0 m in length and a width of roughly 0.3 m for air mass flow rates of 0.02-0.06 kg/s.

Automated summary

This research paper presents a mathematical model of a solar air collector with a finned absorber and nano-enhanced PCM. The model simulates the thermal and thermo-hydraulic performance of the collector considering various operating parameters. The optimal energy and exergy efficiencies were achieved at a solar irradiance of 1000 W/m2 and a mass flow rate of 0.06 kg/s. The collector showed significant improvement potentials in terms of power output at different irradiance levels.