期刊
RENEWABLE ENERGY
卷 178, 期 -, 页码 1174-1186出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.renene.2021.06.138
关键词
Solar thermal; Nanofluid; Efficiency; Pumping power; Optical loss
资金
- Australian Research Council [ARC DE160100131]
- UNSW
- Spectroscopy Laboratory within the Mark Wainwright Analytical Centre at the University of New SouthWales
This study investigates the impact of using nanofluids, super-hydrophobic walls, an anti-reflective coating, and a transparent selective surface on the thermal efficiency of a microchannel-based solar receiver. The study found that nanofluids have the biggest potential in reducing optical losses in direct absorption solar collectors.
Solar thermal receivers are designed to absorb as much sunlight as possible (e.g., to increase energy inputs) while minimising heat losses and parasitic pumping energy requirements (e.g., to reduce energy losses). The field of direct absorption solar collectors has devised numerous elegant solutions for increasing energy inputs. Mitigating the energy losses, however, represents the other-generally overlooked-factor. To address this research gap, this study investigates the impact of nanofluids, super-hydrophobic walls, an anti-reflective coating, and a transparent selective on the thermal efficiency of a microchannel-based solar receiver. The proposed modifications were ranked by their impact on the overall collector efficiency. It was found that compared to a pure water reference case, using a nanofluid working fluid provides the biggest reduction in optical losses (validating the literature's focus on this aspect). However, a micro-patterned surface achieved nearly the same improvement in optical efficiency. Adding a nanofluid, an anti-reflective cover, and a super-hydrophobic surface (in concert) can boost the efficiency by similar to 7% (compared to the reference case). Overall, this study provides a systematic approach to investigating features to mitigate energy loss mechanisms in direct absorption solar collectors via detailed component-level experimental testing and collector-level theoretical analysis. Crown Copyright (C) 2021 Published by Elsevier Ltd. All rights reserved.
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