Dynamic response and disturbance optimization of high temperature heat pump steam systems

doi:10.16085/j.issn.1000-6613.2022-1167

Abstract

Abstract:

In order to improve the stability of the system operation of the high temperature heat pump steam system with R1233zd(E) as the refrigerant under off-design conditions, a simulation model of the system was established based on Modelica to investigate the effect of the factors, such as with or without internal heat-exchanger (IHX), and heat source temperature, mass flow rate, and refrigerant mass flow rate on the system performance. The results showed that the coefficient of performance (COP) of the system improved by 16.1% after adding the IHX, the performance parameters tended to be more stable along the flow direction of the refrigerant, the farther away from the fluctuating source, and the sensitivity of the state parameters was ranked as: refrigerant flow perturbation>heat source temperature perturbation>heat source mass flow perturbation. In addition, the stability of all performance parameters under disturbances was improved by adjusting the throttle valve opening through a PI controller to improve the system's immunity to disturbances, especially the steam output under the refrigerant mass flow disturbance of the process was changed from unstable to more stable 140°C steam output, and the steam production under the three disturbance factors increased by 20.8%, 3.0% and 1.9%, respectively.

Key words: high temperature heat pump, flash steam, dynamic simulation, internal and external disturbances, optimization, Modelica

摘要：

为提升以R1233zd(E)为工质的高温热泵蒸汽系统在非设计工况下系统运行的稳定性，基于Modelica语言建立了系统的仿真模型，考察了是否带有回热器及热源温度、质量流量、工质质量流量这些内外扰动对系统性能的影响。结果表明，在添加回热器后系统的性能系数提升了16.1%，沿着工质的流动方向，越远离波动源工质性能参数越趋于稳定，且状态参数的灵敏性排序为：工质质量流量扰动>热源温度扰动>热源质量流量扰动。另外，为提高系统抗干扰性，通过PI控制器对节流阀开度进行调节，优化后内外部扰动下所有性能参数的稳定性都得以提升，尤其是工质质量流量扰动下从无法稳定输出蒸汽到以较稳定方式输出140℃蒸汽，且三扰动因素下其产汽量分别提升了20.8%、3.0%和1.9%。

关键词: 高温热泵, 闪蒸, 动态仿真, 内外部扰动, 优化, Modelica语言

CLC Number:

TK123

LIU Guangping, LU Zhenneng, GONG Yulie. Dynamic response and disturbance optimization of high temperature heat pump steam systems[J]. Chemical Industry and Engineering Progress, 2023, 42(4): 1719-1727.

刘广平, 陆振能, 龚宇烈. 高温热泵蒸汽系统的动态响应及扰动优化[J]. 化工进展, 2023, 42(4): 1719-1727.

Figures/Tables 13

References 17

1	ZHANG Jing, ZHANG Honghu, HE Yaling, et al. A comprehensive review on advances and applications of industrial heat pumps based on the practices in China[J]. Applied Energy, 2016, 178: 800-825.
2	HUANG Feng, ZHENG Jie, BALEYNAUD J M, et al. Heat recovery potentials and technologies in industrial zones[J]. Journal of the Energy Institute, 2017, 90(6): 951-961.
3	胡宏海, 张泓, 张雪. 过热蒸汽在肉类调理食品加工中的应用研究[J]. 肉类研究, 2013, 27(7): 48-52.
	HU Honghai, ZHANG Hong, ZHANG Xue. Research and application of superheated steam in prepared meat food processing[J]. Meat Research, 2013, 27(7): 48-52.
4	MALAVIKA S, CHIRANJEEVI C, SEKHAR Y R, et al. Performance optimization of a heat pump for high temperature application[J]. Materials Today: Proceedings, 2021, 46: 5278-5285.
5	KONDOU Chieko, KOYAMA Shigeru. Thermodynamic assessment of high-temperature heat pumps using Low-GWP HFO refrigerants for heat recovery[J]. International Journal of Refrigeration, 2015, 53: 126-141.
6	FRATE Guido Francesco, FERRARI Lorenzo, DESIDERI Umberto. Analysis of suitability ranges of high temperature heat pump working fluids[J]. Applied Thermal Engineering, 2019, 150: 628-640.
7	BAI Tao, YAN Gang, YU Jianlin. Thermodynamic assessment of a condenser outlet split ejector-based high temperature heat pump cycle using various low GWP refrigerants[J]. Energy, 2019, 179: 850-862.
8	刘炳伸, 龚宇烈, 陆振能, 等. 用于高温热泵蒸汽系统的几种工质的循环性能[J]. 可再生能源, 2015, 33(12): 1755-1761.
	LIU Bingshen, GONG Yulie, LU Zhenneng, et al. Several working fluids for high temperature heat pump steam system[J]. Renewable Energy Resources, 2015, 33(12): 1755-1761..
9	史琳, 安青松. 基加利修正案生效后替代制冷剂的选择与对策思考[J]. 制冷与空调, 2019, 19(9): 50-58.
	SHI Lin, AN Qingsong. Low GWP refrigerants options and countermeasures discussion after the entry into force of Kigali Amendment[J]. Refrigeration and Air-Conditioning, 2019, 19(9): 50-58.
10	JIANG Jiatong, HU Bin, WANG R Z, et al. Theoretical performance assessment of low-GWP refrigerant R1233zd(E) applied in high temperature heat pump system[J]. International Journal of Refrigeration, 2021, 131: 897-908.
11	ZHANG Ying, DENG Shuai, ZHAO Li, et al. Dynamic test and verification of model-guided ORC system[J]. Energy Conversion and Management, 2019, 186: 349-367.
12	DONG Liujia, LI Yaoyu, MU Baojie, et al. Self-optimizing control of air-source heat pump with multivariable extremum seeking[J]. Applied Thermal Engineering, 2015, 84: 180-195.
13	GRACE I N, DATTA D, TASSOU S A. Sensitivity of refrigeration system performance to charge levels and parameters for on-line leak detection[J]. Applied Thermal Engineering, 2005, 25(4): 557-566.
14	NOEL D, TEUILLIÈRES C, RIVIÈRE P, et al. Experimental characterization of fault impacts on the functioning variables of an inverter driven heat pump[C]//10th International Conference on System Simulation in Buildings, Liège, Belgium, 2018: 1-20.
15	JENSEN J M. Dynamic modeling of thermofluid systems[D]. Copenhagen: Technical University of Denmark, 2003.
16	CHAMOUN Marwan, RULLIERE Romuald, HABERSCHILL Philippe, et al. Dynamic model of an industrial heat pump using water as refrigerant[J]. International Journal of Refrigeration, 2012, 35(4): 1080-1091.
17	ARPAGAUS Cordin, BERTSCH Stefan. Experimental comparison of HCFO and HFO R1224yd(Z), R1233zd(E), R1336mzz(Z), and HFC R245fa in a high-temperature heat pump up to 150℃ supply temperature[C]//18th International Refrigeration and Air Conditioning Conference, Purdue, 2021: 1-12.

部件	参数设定值
压缩机	容积式效率压缩机；排量1.31dm³；额定转速30Hz；容积效率0.8；绝热效率0.8；机械效率0.95
冷凝器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数180；壁厚0.5cm
蒸发器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数150；壁厚0.5cm
回热器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数30；壁厚0.5cm
膨胀阀	有效节流面积1.55×10^-5m²
水泵	变速泵
闪蒸罐	容积0.1m³
储液罐	容积0.01m³

部件	参数设定值
压缩机	容积式效率压缩机；排量1.31dm³；额定转速30Hz；容积效率0.8；绝热效率0.8；机械效率0.95
冷凝器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数180；壁厚0.5cm
蒸发器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数150；壁厚0.5cm
回热器	逆流板式；铜材质；板长0.3m；板宽0.1m；平板数30；壁厚0.5cm
膨胀阀	有效节流面积1.55×10^-5m²
水泵	变速泵
闪蒸罐	容积0.1m³
储液罐	容积0.01m³

设备及仪器	参数设置	型号选择
蒸发器出口过热度	5℃	—
压缩机	变频活塞式；30~60Hz	型号：Bitzer， 2DES-3Y New Ecoline
膨胀阀	电子式	型号：Siemens，MVL661.15-0.4
换热器	铜焊板式换热器	—
集液罐体积	5.6L	型号：Bitzer，FS56
温度计	精度：±0.1K	K型热电偶
流量计	精度：±0.05%	科里奥利流量计
功率测量仪	精度：±0.2%	型号：Infratek，ITL-101

设备及仪器	参数设置	型号选择
蒸发器出口过热度	5℃	—
压缩机	变频活塞式；30~60Hz	型号：Bitzer， 2DES-3Y New Ecoline
膨胀阀	电子式	型号：Siemens，MVL661.15-0.4
换热器	铜焊板式换热器	—
集液罐体积	5.6L	型号：Bitzer，FS56
温度计	精度：±0.1K	K型热电偶
流量计	精度：±0.05%	科里奥利流量计
功率测量仪	精度：±0.2%	型号：Infratek，ITL-101

参数	水泵PI控制器	节流阀PI控制器	压缩机PI控制器
K_p	0.7	-0.001	-1
t_i /s	2	0.5	0.5
b	1	1	1