Ultra-low temperature heating system based on dual-source solar assisted heat pump using compound parabolic concentrator-capillary tube solar collector
Article
Yang, L.W., Pu, J.H., Xu, R.J., Yang, T. and Wang, H.S. 2024. Ultra-low temperature heating system based on dual-source solar assisted heat pump using compound parabolic concentrator-capillary tube solar collector. Energy and Buildings. 324. https://doi.org/10.1016/j.enbuild.2024.114903
Type | Article |
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Title | Ultra-low temperature heating system based on dual-source solar assisted heat pump using compound parabolic concentrator-capillary tube solar collector |
Authors | Yang, L.W., Pu, J.H., Xu, R.J., Yang, T. and Wang, H.S. |
Abstract | The fifth-generation heating – ultra-low temperature heating benefits to reduce electricity consumption and achieve the net zero goal. The dual-source solar assisted heat pump based heating system has been demonstrated to be an attractive green heating technology for the domestic sector. However, the slower response speed of the low temperature heating to the variation of heating load in responding to the variations of weather conditions limits its thermal comfort performance. The enhancement in solar collector performance brings valuable improvements in response speed of the heating system. In the present work, a heating system based on solar assisted air source heat pump using a compound parabolic concentrator-capillary tube solar collector (CPC-CSC) is investigated with the set heating temperatures of 40, 45, 50, and 55 °C. This heating system works for both space heating and hot water under the weather conditions in London. The results suggest that using a concentrated solar collector improves the response speed of the heating system at low set heating temperatures. For such a heating system, the ultra-low heating temperature increases the application of renewable energy and passive heating (by 6.4%). Compared with the dual-source indirect expansion solar assisted heat pump using flat plate collector, the heating system using CPC-CSC can reduce TEWI by 4.6% with a slightly longer (1.9%) payback period. As the set heating temperature decreases from 55 to 40 °C, the seasonal and yearly system seasonal performance factors significantly increase by 17.1% and 20.5%, respectively. |
Keywords | Low temperature heating; Compound parabolic concentrator-capillary tube solar collector; Solar assisted air source heat pump; Domestic heating; Seasonal performance factor |
Sustainable Development Goals | 11 Sustainable cities and communities |
Middlesex University Theme | Sustainability |
Publisher | Elsevier |
Journal | Energy and Buildings |
ISSN | 0378-7788 |
Electronic | 1872-6178 |
Publication dates | |
Online | 10 Oct 2024 |
01 Dec 2024 | |
Publication process dates | |
Submitted | 24 Jun 2024 |
Accepted | 08 Oct 2024 |
Deposited | 16 Oct 2024 |
Output status | Published |
Accepted author manuscript | File Access Level Open |
Digital Object Identifier (DOI) | https://doi.org/10.1016/j.enbuild.2024.114903 |
https://repository.mdx.ac.uk/item/1v353q
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