Performance analysis of a direct-absorption parabolic trough solar collector

TL;DR

This study enhances direct-absorption parabolic trough solar collectors by applying a reflective coating to double optical path length, improving efficiency at lower absorption coefficients and comparing performance with conventional collectors under various conditions.

Contribution

The paper introduces a reflective coating modification to DAPTSCs that doubles optical path length, enabling lower nanofluid absorption coefficients and improved thermal efficiency compared to transparent designs.

Findings

Reflective coating doubles optical path length in DAPTSCs.

Coated DAPTSC outperforms transparent DAPTSC at absorption coefficients below 0.5 cm$^{-1}$.

Performance varies with inner tube diameter, flow rate, and inlet temperature.

Abstract

A parabolic trough solar collector is a dominant technology for high-temperature industrial applications, but efficient use of a conventional surface-based parabolic trough solar collector (SBPTSC) is limited by its high radiation loss due to the high surface temperature. Recently, direct-absorption parabolic trough solar collector (DAPTSC) using nanofluids has been proposed, and its thermal efficiency has been reported to be 5-10$\%$ higher than the conventional SBPTSC for inlet temperature up to 250$^\circ$C. However, the inner tubes of the receivers of the existing DAPTSCs are all transparent, so the sun rays entering the inner tube can only travel once through the nanofluids. As a result, the optical path length for the sun rays is limited by the inner tube size, which in turn requires high value of the absorption coefficient of nanofluids. Due to the approximately linear relation between the absorption coefficient and the particle concentration, higher absorption coefficient is likely to cause particle agglomeration, leading to detrimental effects on maintaining stable collector performance. In the current study, the transparent DAPTSC is improved by applying a reflective coating on the upper half of the inner tube outer surface, such that the optical path length is doubled compared to the transparent DAPTSC; thus, the absorption coefficient of the nanofluids can be reduced accordingly. The coated DAPTSC is found to have obvious advantage compared to the transparent DAPTSC at absorption coefficient below 0.5 cm$^{-1}$ for a receiver with inner tube diameter of 7 cm. In addition, performance of the transparent DAPTSC, the coated DAPTSC and the SBPTSC with black chrome coating have been compared to explore their advantageous operation conditions, such as inner tube diameter, flow rate, and inlet temperature, with or without a glass envelope for vacuum evacuation.