化工进展 ›› 2021, Vol. 40 ›› Issue (10): 5431-5440.DOI: 10.16085/j.issn.1000-6613.2020-2077

• 化工过程与装备 • 上一篇    下一篇

带引射器的跨临界CO2机械过冷热泵系统性能分析

董丽玮(), 李敏霞(), 姚良, 马一太, 詹浩淼   

  1. 中低温热能高效利用教育部重点实验室(天津大学),天津 300350
  • 收稿日期:2020-10-15 修回日期:2020-11-17 出版日期:2021-10-10 发布日期:2021-10-25
  • 通讯作者: 李敏霞
  • 作者简介:董丽玮(1997—),女,硕士研究生,研究方向为制冷与热泵节能技术。E-mail:liwei_dong@tju.edu.cn
  • 基金资助:
    国家自然科学基金(51876135);空调设备及系统运行节能国家重点实验室开放基金(ACSKL2018KT02)

Analysis of performance of CO2 transcritical heat pump system with mechanical subcooling and ejector

DONG Liwei(), LI Minxia(), YAO Liang, MA Yitai, ZHAN Haomiao   

  1. Low and Medium Grade Energy of Ministry of Education, Tianjin University, Tianjin 300350, China
  • Received:2020-10-15 Revised:2020-11-17 Online:2021-10-10 Published:2021-10-25
  • Contact: LI Minxia

摘要:

热泵循环中引射器的使用能减少能量损失,改善循环性能。在已有机械过冷循环的基础上加入引射器,本文提出主循环带引射器[MSHPS(MWE)]和辅循环带引射器[MSHPS(AWE)]的跨临界CO2机械过冷热泵系统。通过建立热力学模型,对系统使用散热片(TDR)、地盘管(FCR)和小温差风机盘管(STD-FCU)3类不同末端的性能进行分析。将该系统与CO2基本系统(BASE)、CO2机械过冷系统(MSHPS)进行了对比,并选取了我国4个典型气候城市,对其供暖期间的运行进行了季节供热性能系数(HSPF)分析。结果表明,在额定工况下,机械过冷系统均存在最优主、辅循环排气压力和最优过冷器出口温度,使系统性能系数(COP)最高;其中以STD-FCU为末端的系统具有最高COP。通过与已有系统的对比,表明在额定工况下,MSHPS(AWE)和MSHPS(MWE)较BASE系统的COP最高分别能提升约21.18%和26.66%,较MSHPS最高能分别提升约2.62%和9.53%,MSHPS(MWE)具有更好的性能提升效果。MSHPS(MWE)系统在严寒工况下仍能运行,带引射器的系统在不同温区均具有更高的HSPF。以哈尔滨为代表的严寒地区的HSPF改善效果最明显,以TDR为末端的系统更适用于高纬度的严寒地区,以STD-FCU为末端的系统更适用于低纬度的地区。此外,辅循环工质的种类会影响系统的整体性能,MSHPS(AWE)中使用CO2的提升效果最好, MSHPS(MWE)中使用R717的提升效果最好。使用混合工质R32/R1234yf的系统具有更高的COP,但提升效果并非最优。

关键词: CO2热泵, 引射器, 机械过冷, 散热末端, 性能系数, 季节供热性能系数

Abstract:

The use of ejector can reduce energy loss and improve the performance of cycle in heat pump. The ejector was integrated with the existing cycle,CO2 transcritical heat pump system with mechanical subcooling that major cycle with ejector and auxiliary cycle with ejector were proposed respectively. A thermodynamic model was developed to analyze the performance of system when using three different terminals, traditional designed radiator (TDR), floor-coil radiator (FCR) and small temperature difference fan-coil unit (STD-FCU). The new systems were compared with CO2 basic system (BASE) and CO2 mechanical subcooling heat pump system (MSHPS). Four typical climate cities were selected in China and heating seasonal performance factor (HSPF) were discussed during the heating season. The results indicated that a maximum coefficient of performance (COP) exists at optimum major discharge pressure, auxiliary discharge pressure and subcooler outlet temperature in mechanical subcooling system. The system with STD-FCU as the terminal has the highest COP. Compared with the COP of BASE system under rated condition, MSHPS (AWE) and MSHPS (MWE) can increase by up to 21.18% and 26.66% respectively. And compared with the COP of MSHPS, the new system can increase by about 2.62% and 9.53% respectively. MSHPS (MWE) has better performance improvement effect. MSHPS (MWE) can still operate under severely cold conditions. The system with ejector has higher HSPF in different temperature regions. The HSPF improvement effect of the cold regions represented by Harbin is most obvious. The system with TDR as the terminal is more suitable for the cold region of high latitude, and the system with STD-FCU as the terminal is more suitable for the area of low latitude. In addition, refrigerants used in auxiliary cycle affect the overall performance of the system. CO2 achieves the best effect in MSHPS (AWE) and R717 achieves the best effect in MSHPS (MWE).The system can reach higher COP when R32/R1234yf is employed in auxiliary cycle but can’t achieve the best effect.

Key words: CO2 heat pump, ejector, mechanical subcooling, terminal, coefficient of performance(COP), heating seasonal performance factor(HSPF)

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