Water depth effect on energy, exergy losses, and exergy efficiency of solar still with wick materials: an experimental research.

This study analyzes the energy and exergy destruction of a solar still with black painted wick materials (SS with BPWM) at different salt water depths (Wd) of 1, 2, and 3 cm. The coefficients of heat transfer for evaporative, convective, and radiant heat transfer have been calculated for a basin, water, and glass. The thermal efficiency and exergy losses caused by basin material, basin water, and glass material were also determined.

Energy and exergy analysis of conventional acrylic solar still with and without copper fins.

A detailed exergy analysis of a conventional and copper finned acrylic solar still has been presented in this manuscript. The evaporative, convective, and radiative heat transfer coefficient of water-glass has been calculated. Also energy efficiency, exergy destruction of basin, water, and glass has been determined.

Inferences on the effects of geometries and heat transfer fluids in multi-cavity solar receivers by using CFD.

This paper discusses about the design and analysis of a novel multi-cavity tubular receiver developed for small- and medium-scale concentrated solar power applications from the existing basic baffle-plated volumetric receiver model which is used in large-scale applications. The design and analysis work has been completed to enhance the thermal performance of cavity receivers for the average solar power input of 12 kW with a dish concentrator of 15 m aperture area. This was carried out by replacing the baffle plates from the conventional basic volumetric receiver with multi-cavity tubes, keeping the heat transfer area as constant.