NH3/CO2 cascade systems have become one of the most widely used kinds of industrial and commercial refrigeration systems, in which the middle temperature and condensing temperature are the most important parameters affecting the system performance, and hence chosen as control variables in optimization control. However, the existing optimization control based on data-driven models still encounters the problem of how to obtain complete data covering a large number and wide range of operating conditions as soon and low cost as possible. To solve this problem, a novel energy-saving control method of NH3/CO2 cascade refrigeration systems by data-driven models with varying searching boundaries was proposed innovatively. The potential of the proposed methods was evaluated from the precision and power perspectives. Results showed that the proposed energy-saving control method had the lowest RMSEs of control variables and system power, which indicated its very high optimization precision. Besides, it provided a reduction in energy consumption by 10.62% compared to the conventional constant-variable control approach and by 1.2% compared to the data-driven model with fixed search boundaries, which proved the huge potential of the proposed control method.
MessineoA. R744-R717 Cascade refrigeration system: performance evaluation compared with a HFC two-stage system. Energy Proc2012; 14: 56–65.
2.
JankovichDOsmanK. A feasibility analysis of replacing the standard ammonia refrigeration device with the Cascade NH3/CO2 refrigeration device in the food industry. Therm Sci2015; 19: 1821–1833.
3.
AminyavariMNajafiBShiraziA, et al.Exergetic, economic and environmental (3E) analyses, and multi-objective optimization of a CO2/NH3 cascade refrigeration system. Appl Therm Eng2014; 65: 42–50.
4.
RezayanOBehbahaniniaA. Thermoeconomic optimization and exergy analysis of CO2/NH3 cascade refrigeration systems. Energy2011; 36: 888–895.
5.
MosaffaAHFarshiLGInfante FerreiraCA, et al.Exergoeconomic and environmental analyses of CO2/NH3 cascade refrigeration systems equipped with different types of flash tank intercoolers. Energy Convers Manag2016; 117: 442–453.
6.
MaMYuJWangX. Performance evaluation and optimal configuration analysis of a CO2/NH3 cascade refrigeration system with falling film evaporator–condenser. Energy Convers Manag2014; 79: 224–231.
7.
ManskeKReindlDKleinS. Evaporative condenser control in industrial refrigeration systems. Int J Refrig2001; 24: 676–691.
8.
YangQLiuLLiuG, et al.Thermodynamic analysis of volume flow rate ratio on the performance of a NH3/CO2 cascade refrigeration system. IOP Conf Ser Mater Sci Eng2021; 1180: 012051, IOP Publishing2021.
9.
LeeT-SLiuC-HChenT-W. Thermodynamic analysis of optimal condensing temperature of cascade-condenser in CO2/NH3 cascade refrigeration systems. Int J Refrig2006; 29: 1100–1108.
10.
Alberto DopazoJFernández-SearaJSieresJ, et al.Theoretical analysis of a CO2–NH3 cascade refrigeration system for cooling applications at low temperatures. Appl Therm Eng2009; 29: 1577–1583.
11.
TripathySJenaJPadhiaryDK, et al.Thermodynamic analysis of a cascade refrigeration system based on carbon dioxide and ammonia. Int J Eng Res Afr2014; 4: 24–29.
12.
GetuHMBansalPK. Thermodynamic analysis of an R744–R717 cascade refrigeration system. Int J Refrig2008; 31: 45–54.
13.
BingmingWHuagenWJianfengL, et al.Experimental investigation on the performance of NH3/CO2 cascade refrigeration system with twin-screw compressor. Int J Refrig2009; 32: 1358–1365.
14.
DopazoJAFernández-SearaJ. Experimental evaluation of a cascade refrigeration system prototype with CO2 and NH3 for freezing process applications. Int J Refrig2011; 34: 257–267.
15.
GiovanniniMLorenziniM. Numerical model of an industrial refrigeration system for condensation temperature optimisation. Therm Sci Eng Prog2023; 42: 101846.
16.
LuWMengZSunY, et al.Improved energy performance of ammonia recycling system using floating condensing temperature control. Appl Therm Eng2016; 102: 1011–1018.
17.
ChenWXingZTangH, et al.Theoretical and experimental investigation on the performance of screw refrigeration compressor under part-load conditions. Int J Refrig2011; 34: 1141–1150.
18.
WangZLiuZLiuF, et al.Research on operating characteristics of single slide valve capacity control mechanism of the single screw refrigeration compressor. Proc Inst Mech Eng A J Power Energy2014; 228: 965–977.
19.
WuYZhiRLeiB, et al.Slide valves for single-screw expanders working under varied operating conditions. Energies2016; 9: 478.
20.
WangZWangZWangJ, et al.Research of thermal dynamic characteristics for variable load single screw refrigeration compressor with different capacity control mechanism. Appl Therm Eng2017; 110: 1172–1182.
21.
SunSXingZLiY, et al.Experimental investigation on twin screw refrigeration compressor with different capacity control methods. Int J Refrig2021; 130: 370–381.
22.
LiuXHuangBZhengY. Control strategy for dynamic operation of multiple chillers under random load constraints. Energy2023; 270: 126932.
23.
AdelekanDSOhunakinOSPaulBS. Artificial intelligence models for refrigeration, air conditioning and heat pump systems. Energy Rep2022; 8: 8451–8466.
24.
HosozMErtuncHM. Modelling of a cascade refrigeration system using artificial neural network. Int J Energy Res2006; 30: 1200–1215.
25.
RashidiMMAmooieH. Performance analysis of CO2/NH3 cascade refrigeration system using ANNs. J Adv Comput Sci Technol2012; 1: 1–17.
26.
LiYPanXLiaoX, et al.A data-driven energy management strategy based on performance prediction for cascade refrigeration systems. Int J Refrig2022; 136: 114–123.
27.
FengYShuJWangC, et al.Energy-saving control method for NH3-CO2 cascade refrigeration system by directly regulating slide valve position in twin-screw compressor. Appl Therm Eng2024; 239: 122116.
28.
MortadiMEl FadarA. Performance, economic and environmental assessment of solar cooling systems under various climates. Energy Convers Manag2022; 252: 114993.
29.
Prado de NicolásAMolina-GarcíaAVera-GarcíaF. Performance evaluation and feasibility study of a cooling tower model for zero liquid discharge-desalination processes. Energy Convers Manag2023; 297: 117673.
30.
ZhaoRZhangHSongS, et al.Global optimization of the diesel engine–organic Rankine cycle (ORC) combined system based on particle swarm optimizer (PSO). Energy Convers Manag2018; 174: 248–259.
31.
LemmonEHuberMMcLindenM. NIST standard reference database 23: reference fluid thermodynamic and transport properties (REFPROP). National Institute of Standards and Technology, 2013. Standard Reference Data Program.Version 9.1.
32.
ManskeKA. Performance optimization of industrial refrigeration systems. University of Wisconsin-Madison2000.
33.
StullR. Wet-Bulb temperature from relative humidity and air temperature. J Appl Meteorol Climatol2011; 50: 2267–2269.
34.
AsadHSYuenRKKLiuJ, et al.Adaptive modeling for reliability in optimal control of complex HVAC systems. Build Simul2019; 12: 1095–1106.
