史杰;郭恒超;常晟;董正峰;邵双全;郑竺凌;
Shi Jie;Guo Hengchao;Chang Cheng;Dong Zhengfeng;Shao Shuangquan;Zheng Zhuling;Shanghai International Airport Co.,Ltd.;Tongfang Technovator Int.(Shanghai) Co.,LTD.;Tsinghua Tongfang Co.,Ltd.;Huazhong University of Science and Technology;Shanghai Architectural Science Research Institute;

• 1:上海国际机场股份有限公司
• 2:同方泰德智能科技(上海)有限公司
• 3:同方股份有限公司
• 4:华中科技大学

摘要(Abstract)：

基于上海浦东机场1号能源中心的冷负荷及当地的分时电价政策,对比分析了冰蓄冷、冰浆蓄冷和水蓄冷系统并优选了水蓄冷系统作为蓄能方案。优化了水蓄冷系统和运行控制方案,分析了最大负荷日、部分负荷日和小负荷日的水蓄冷系统运行情况,验证了水蓄冷方案的可行性。并进一步开展了经济性分析,全年供冷运行费用从1 039.8万降为506.4万,降低了51.3%。以上结果表明水蓄冷系统具有良好的"削峰填谷"作用和降低供冷电费的效果。
The ice storage system,ice slurry cold storage system and water cold storage system were compared based on the cooling load and time-of-use tariff policy of 1^# Energy Center of Pudong International Airport,and the water cold storage system was selected and optimized as energy storage plan.The water cold storage system and operation control plan were optimized,the operation of the water cold storage system in the largest load day,the partial load day and the low load day was analyzed,and the feasibility of the water cold storage plan was validated.Further,its economic analysis was made,the annual operating cost for cooling was reduced from 10.398 Million RMB to 5.063 Million RMB,i.e.,a reduction of 51.3%.Above results show that the water cold storage system can realize peak-load shifting effect and save the operating cost for cooling.

关键词(KeyWords)： 能源中心;制冷系统;机场;蓄冷
energy center;refrigeration system;airport;cold storage

Abstract:

Keywords:

基金项目(Foundation): 国家重点研发计划项目(2016YFB0601600);; 国家自然科学基金项目(51676199)

作者(Authors): 史杰;郭恒超;常晟;董正峰;邵双全;郑竺凌;
Shi Jie;Guo Hengchao;Chang Cheng;Dong Zhengfeng;Shao Shuangquan;Zheng Zhuling;Shanghai International Airport Co.,Ltd.;Tongfang Technovator Int.(Shanghai) Co.,LTD.;Tsinghua Tongfang Co.,Ltd.;Huazhong University of Science and Technology;Shanghai Architectural Science Research Institute;

参考文献(References)：

• [1]清华大学建筑节能研究中心.中国建筑节能年度发展研究报告2018[M].北京:中国建筑工业出版社,2018.
• [2]高晓辉,魏庆芃,何材,等.公共建筑践行运行能耗总量控制的探索:《民用机场航站楼能效评价指南》[J].建筑节能,2019,47(10):16-22.
• [3]Liu X C,Li L S,Liu X H,et al.Analysis of passenger flow and its influences on HVAC systems:An agent based simulation in a Chinese hub airport terminal[J].Building and Environment,2019,154:55-67.
• [4]司鹏飞,戎向阳,石利军,等.机场航站楼能耗构成特征案例分析[J].暖通空调,2019,49(6):63-67.
• [5]韩星,张振.夏热冬冷地区机场类建筑能耗特点及节能措施分析[J].建筑科学,2013,29(12):87-92.
• [6]徐佩荣,虹桥机场空调负荷模型研究[J].低温建筑技术,2012(11):117-119.
• [7]肖伟,李晋秋,白洋,等.大兴国际机场能源规划与航站楼节能设计研究介绍[J].建筑节能,2019,47(10):9-14.
• [8]徐伟.北京大兴国际机场制冷站系统设计[J].暖通空调,2019,49(12):49.
• [9]沈列丞,陆燕,马伟骏.南京禄口国际机场2号航站楼空调与节能设计[J].暖通空调,2017,47(8):66-72.
• [10]徐伟,邹瑜,孙宗宇,等.《蓄冷空调工程技术规程》修订要点[J].暖通空调,2018,48(7):1-4.
• [11]Pu J,Liu G,Feng Z.Cumulative exergy analysis of ice thermal storage air conditioning system[J].Applied Energy,2012,93:564-569.
• [12]Ezan M A,Erek A,Dincer I.Energy and exergy analyses of an ice-on-coil thermal energy storage system[J].Energy,2011,36:6375-6386.
• [13]Bott C,Dressel I,Bayer P.State-of-technology review of water-based closed seasonal thermal energy storage systems[J].Renewable and Sustainable Energy Reviews,2019,113:109241.
• [14]Song X,Liu L,Zhu T,et al.Study of economic feasibility of a compound cool thermal storage system combining chilled water storage and ice storage[J].Applied Thermal Engineering,2018,133:613-621.
• [15]Sepehri A,Nelson B.Energy and emissions analysis of ice thermal energy storage in the western US[J].Energy & Buildings,2019,202:109393
• [16]Wu C T,Tsai Y H.Design of an ice thermal energy storage system for a building of hospitality operation[J].International Journal of Hospitality Management,2015,46:46-54.
• [17]Rahdar M H,Emamzadeh A,Ataei A.A comparative study on PCM and ice thermal energy storage tank for air-conditioning systems in office buildings[J].Applied Thermal Engineering,2016,96:391-399.
• [18]张敏,王晨晓.浦东机场能源中心水蓄冷运行方式改进方案[J].电力与能源,2014,35(6):772-775.
• [19]Wang J,Battaglia F,Wang S,et al.Flow and heat transfer characteristics of ice slurry in typical components of cooling systems:A review[J].International Journal of Heat and Mass Transfer,2019,141:922-939.
• [20]Kumar A,Yadav S K,Mahato A,et al.On-demand intermittent ice slurry generation for subzero cold thermal energy storage:Numerical simulation and performance analysis[J].Applied Thermal Engineering,2019,161:114081.
• [21]Tiwari V K,Kumar A,Kumar A.Enhancing ice slurry generation by using inclined cavity for subzero cold thermal energy storage:Simulation,experiment and performance analysis[J].Energy,2019,183:398-414.
• [22]Bouzaher M T,Bouchahm N,Guerira B,et al.On the thermal stratification inside a spherical water storage tank during dynamic mode[J].Applied Thermal Engineering,2019,159:113821.
• [23]Sait H H.Experimental study of water solidification phenomenon for ice-on-coil thermal energy storage application utilizing falling film[J].Applied Thermal Engineering,2019,146:135-145.