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跨临界CO₂热泵在低影响翻新项目中用于替代锅炉的应用。

Application of transcritical CO heat pumps to boiler replacement in low impact refurbishment projects.

作者信息

Lambert William, Dehouche Zahir

机构信息

Department of Mechanical and Aerospace Engineering, College of Engineering, Design and Physical Sciences, Brunel University London, UB8 3PH, United Kingdom.

出版信息

Heliyon. 2024 Mar 6;10(6):e26929. doi: 10.1016/j.heliyon.2024.e26929. eCollection 2024 Mar 30.

DOI:10.1016/j.heliyon.2024.e26929
PMID:38501014
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10945128/
Abstract

80% of current UK housing stock is expected to still be in use in 2050. Difficult, intrusive and expensive, refurbishment measures are required to achieve the level of insulation required for current low temperature heat pumps. Transcritical CO heat pumps can achieve higher efficiencies, with higher output temperatures, than current, Carnot limited, synthetic gas heat pumps, with less environmental impact. Widely deployed in water heating and supermarket chilling systems, CO heat pumps need heating return temperatures of 30 °C or less to function effectively. This has impeded their adoption with hydronic heating systems which have high return temperatures. This study identified system modifications external to the refrigeration cycle that address return temperatures. It modelled a transcritical CO air source heat pump with a hydronic heating system in a solid wall semi-detached house. Full year system coefficients of performance over 3 were achieved in four UK locations by using space heating return fluids to defrost the air source heat exchanger and to pre-heat inlet water, recovering any remaining excess return fluid heat as a source for the heat pump. Solar panels boosted this to 5.1. The levelized cost of energy for the system was calculated (with heat pump grant) at 22p/kWh, lower than a gas boiler, with 9.45 tonnes CO emission savings over a fifteen-year life.

摘要

预计到2050年,英国目前80%的住房仍将在使用。翻新措施困难、繁琐且成本高昂,需要采取这些措施才能达到目前低温热泵所需的保温水平。与目前受卡诺循环限制的合成气热泵相比,跨临界CO₂热泵能够实现更高的效率和更高的输出温度,且对环境的影响更小。CO₂热泵广泛应用于水加热和超市制冷系统,其有效运行需要30°C或更低的供热回水温度。这阻碍了它们在回水温度较高的循环加热系统中的应用。本研究确定了制冷循环外部的系统改造措施,以解决回水温度问题。该研究对一栋实心墙半独立式房屋中配备循环加热系统的跨临界CO₂空气源热泵进行了建模。通过利用空间供热回水来除霜空气源热交换器和预热进水,并将剩余的多余回水热量作为热泵的热源回收,在英国的四个地点实现了全年系统性能系数超过3。太阳能板将这一系数提高到了5.1。计算得出该系统的平准化能源成本(含热泵补贴)为22便士/千瓦时,低于燃气锅炉,在15年的使用寿命内可减少9.45吨的CO₂排放。

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