直膨式太阳能热泵蒸发器结构优化研究

周北雁; 黄兴华; 侯晓涵

doi:10.12299/jsues.24-0158

直膨式太阳能热泵蒸发器结构优化研究

doi: 10.12299/jsues.24-0158

上海工程技术大学机械与汽车工程学院, 上海 201620

详细信息

作者简介:
周北雁（1999 − ），男，硕士生，研究方向为太阳能热泵。E-mail：1744990535@qq.com

通讯作者:
黄兴华（1971 − ），男，副教授，博士，研究方向为两相流动与强化换热、太阳能光热高效利用。E-mail：xhhuang@sues.edu.cn

中图分类号: TK519
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- 文章访问数: 13
- HTML全文浏览量: 9
- PDF下载量: 0
- 被引次数: 0
出版历程
- 收稿日期: 2024-06-02
- 网络出版日期: 2025-12-22
- 刊出日期: 2025-09-30

Optimization of evaporator structure in a direct expansion solar heat pump

School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201620, China

摘要

摘要: 对直膨式太阳能热泵系统中集热/蒸发器结构进行研究，建立吹胀板集热/蒸发器分布参数的数值模型，利用试验数据对模型进行可靠性验证，模拟分析管道流程管数排布、管间距对集热/蒸发器板的集热效率以及热泵系统性能系数(coefficient of performance, COP)的影响。结果表明，在总管数一定的条件下，第一、二流程管数比增大，制冷剂总压降越低，蒸发温度越高；管数比为1∶1时集热效率与COP最佳。随管间距的增大，集热效率与COP先增大后减小，管间距在0.04 m时达到最佳值。
- 太阳能 /
- 集热/蒸发器 /
- 管间距 /
- 流程排布 /
- 数值模拟
Abstract: The optimization of the collector/evaporator structure in a direct-expansion solar heat pump system was investigated. A distributed parameter numerical model for a roll-bond collector/evaporator was developed and validated against experimental data. The effects of the path tube number arrangement and tube spacing on the collector/evaporator collector efficiency and the coefficient of performance (COP) of the heat pump system were simulated and analyzed. The results indicate that, for a given total number of tubes, a larger tube number ratio between the first and second paths can lead to a lower total refrigerant pressure drop and a higher evaporation temperature. The optimal heat collection efficiency and COP are achieved when the tube number ratio is 1∶1. Furthermore, as the tube spacing increases, both the heat collection efficiency and COP first increase and then decrease, reaching their maximum values at a tube spacing of 0.04 m.
- solar energy /
- collector/evaporator /
- tube spacing /
- path arrangement /
- numerical simulation

HTML全文

图 1 直膨式太阳能热泵热水器原理图

Figure 1. Schematic diagram of direct expansion solar heat pump water heater

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图 2 制冷剂循环过程压焓图

Figure 2. Pressure-enthalpy diagram of refrigerant circulation process

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图 3 两流程太阳能集热/蒸发器的单元划分

Figure 3. Unit division of two paths solar collector/evaporator

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图 4 太阳能集热/蒸发器区域划分

Figure 4. Zone division of solar collector/evaporator

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图 5 系统仿真流程图

Figure 5. Flow chart of system simulation

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图 6 试验装置图

Figure 6. Experimental setup diagram

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图 7 试验与模拟COP对比

Figure 7. Comparison of COP between experimental and simulation results

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图 8 试验集热/蒸发器表面温度分布

Figure 8. Experimental collector/evaporator surface temperature distribution

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图 9 模拟集热/蒸发器表面温度分布

Figure 9. Simulation of surface temperature distribution on collector/evaporator

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图 10 管道内制冷剂压力变化

Figure 10. Variation of refrigerant pressure in tube

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图 11 管道内制冷剂温度变化

Figure 11. Variation of refrigerant temperature in tube

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图 12 制冷剂平均温度与过热区面积的变化

Figure 12. Variation of average refrigerant temperature and area of superheated zone

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图 13 集热效率与COP的变化

Figure 13. Variation of heat collection efficiency and COP

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图 14 不同管间距时COP随管数比的变化

Figure 14. Variation of COP with ratio of tube numbers at different tube spacings

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图 15 不同管间距时集热效率与COP

Figure 15. Heat collection efficiency and COP at different tube spacings

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