Please wait a minute...
浙江大学学报(工学版)
浙江大学学报(工学版)  2026, Vol. 60 Issue (5): 1006-1015    DOI: 10.3785/j.issn.1008-973X.2026.05.010
能源与动力工程     
考虑客流时空分布的航站楼空调系统热湿-新风双层运行优化
廖文碧1(),郑梦莲2,*(),俞自涛2
1. 浙江大学 工程师学院,浙江 杭州 310015
2. 浙江大学 能源工程学院,浙江 杭州 310027
Thermal-humidity and fresh air dual-layer operation optimization for airport terminal air conditioning systems considering spatiotemporal passenger flow distribution
Wenbi LIAO1(),Menglian ZHENG2,*(),Zitao YU2
1. Polytechnic Institute, Zhejiang University, Hangzhou 310015, China
2. College of Energy Engineering, Zhejiang University, Hangzhou 310027, China
 全文: PDF(1594 KB)   HTML
摘要:

针对机场航站楼多功能区域负荷差异及客流时空分布不均导致的空调系统能耗浪费与乘客舒适性较低问题,构建融合乘客停留模型和移动模型的客流时空分布模型,提出兼顾热湿舒适性与空气质量的空调系统双层运行优化策略. 采用模型预测控制算法,通过上层热湿优化层动态调节送风参数,下层新风优化层动态调节新风比,实现滚动时域优化. 仿真结果表明,相较于传统温度调控的基线策略,所提策略协同考虑热湿调控、新风优化、客流响应等因素,在保证区域热湿舒适性和空气质量的前提下,空调系统能耗降低了14.6%.
关键词: 航站楼暖通空调系统客流时空分布热湿环境空气质量运行优化    
Abstract:

To address the issues of energy waste in air conditioning systems and reduced passenger comfort caused by load variations and uneven spatiotemporal distribution of passenger flow in multifunctional zones of airport terminals, a spatiotemporal distribution model of passenger flow that integrates dwell and movement behaviors was constructed. Furthermore, a dual-layer operation optimization strategy for air conditioning systems was proposed, jointly considering thermal-humidity comfort and indoor air quality. A model predictive control algorithm was employed in the strategy, where the upper thermal-humidity optimization layer dynamically adjusts air supply parameters, while the lower fresh air optimization layer dynamically regulates the fresh air ratio, achieving rolling-horizon optimization. Simulation results indicate that, compared to the baseline strategy relying solely on temperature control, the proposed strategy synergistically incorporates thermal-humidity regulation, fresh air optimization and passenger flow responsiveness. Under the premise of ensuring zonal thermal-humidity comfort and air quality, this strategy achieves a 14.6% reduction in air conditioning energy consumption.
Key words: airport terminal HVAC system    spatiotemporal passenger flow distribution    thermal-humidity environment    air quality    operation optimization
收稿日期: 2025-06-16 出版日期: 2026-05-06
CLC:  TP 393  
基金资助: 中央高校基本科研业务费专项资金资助项目(2022ZFJH04).
通讯作者: 郑梦莲     E-mail: 22360185@zju.edu.cn;menglian_zheng@zju.edu.cn
作者简介: 廖文碧(2000—),女,硕士生,从事能源系统优化研究. orcid.org/0009-0004-2201-905X. E-mail:22360185@zju.edu.cn
服务  
把本文推荐给朋友
加入引用管理器
E-mail Alert
作者相关文章  
廖文碧
郑梦莲
俞自涛

引用本文:

廖文碧,郑梦莲,俞自涛. 考虑客流时空分布的航站楼空调系统热湿-新风双层运行优化[J]. 浙江大学学报(工学版), 2026, 60(5): 1006-1015.

Wenbi LIAO,Menglian ZHENG,Zitao YU. Thermal-humidity and fresh air dual-layer operation optimization for airport terminal air conditioning systems considering spatiotemporal passenger flow distribution. Journal of ZheJiang University (Engineering Science), 2026, 60(5): 1006-1015.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.05.010        https://www.zjujournals.com/eng/CN/Y2026/V60/I5/1006

图 1  航站楼空调送风区域划分示意图
图 2  空调送风区域暖通空调系统结构
图 3  单个航班乘客离港流程
图 4  考虑客流时空分布的双层运行优化策略
功能区域人员密度/
(m2·人?1)		照明功率密度/
(W·m?2)		设备功率密度/
(W·m?2)		渗透次数/
(h?1)
值机区59150.2
安检区39150.2
候机区410150.2
表 1  热湿负荷设计参数
围护结构类型传热系数/(W·m?2·K?1)
外墙1.04
屋面0.32
天窗及幕墙1.63
表 2  围护结构参数
约束边界θin/℃θsa/℃RHin/%dsa/(g·kg?1)
下限2412.8408
上限2820.07012
表 3  暖通空调系统运行参数
图 5  值机区空调送风区域分布
优化策略优化变量新风比客流量
S1$ {\theta}_{\text{sa}}、{q_V} $固定0.25日均值
S2$ {\theta}_{\text{sa}}、{d}_{\text{sa}}、{q_V} $固定0.25日均值
S3$ {\theta}_{\text{sa}}、{d}_{\text{sa}}、{q_V}、\beta $动态优化日均值
S4$ {\theta}_{\text{sa}}、{d}_{\text{sa}}、{q_V}、\beta $动态优化仿真结果
表 4  不同优化策略的实施方案
图 6  典型日航班时刻表
航班类别$ \sigma $$ \mu $
国内4.383 90.414 55
国际4.519 90.402 97
表 5  乘客停留模型参数
图 7  航站楼功能区域客流量模拟结果
图 8  值机区不同空调送风区域客流时空分布
图 9  不同策略在热湿优化层的运行结果对比
优化策略ATD/℃AHD/%
S10.286.10
S20.350.84
S40.913.32
表 6  温湿度违规情况
图 10  不同策略的典型日总能耗对比(热湿优化层)
图 11  不同策略的送风湿度优化结果对比
图 12  不同策略在新风优化层的运行结果对比
图 13  不同策略的典型日总能耗对比(新风优化层)
图 14  不同策略的暖通空调系统总能耗对比
优化策略制冷能耗风机能耗总能耗
S113 3288 54821 876
S212 7618 42021 181
S311 6532 10520 073
S410 2618 43118 692
表 7  不同策略的暖通空调系统总能耗组成
1 余娟, 林波荣, 黄彦祥, 等 我国航站楼用能和室内环境质量调研与实测分析[J]. 清华大学学报: 自然科学版, 2020, 60 (12): 977- 984
YU Juan, LIN Borong, HUANG Yenhsiang, et al Investigation and analysis of the energy use and indoor air quality of Chinese airport terminals[J]. Journal of Tsinghua University: Science and Technology, 2020, 60 (12): 977- 984
2 LIN L, LIU X, ZHANG T, et al Energy consumption index and evaluation method of public traffic buildings in China[J]. Sustainable Cities and Society, 2020, 57: 102132
doi: 10.1016/j.scs.2020.102132
3 ORTEGA ALBA S, MANANA M Energy research in airports: a review[J]. Energies, 2016, 9 (5): 349
doi: 10.3390/en9050349
4 王佳丽. 某航站楼冷负荷分区预测及中央空调系统末端优化控制研究 [D]. 西安: 西安建筑科技大学, 2021.
WANG Jiali. Research on cooling load zoning prediction and air conditioning system terminal optimization control of a terminal building [D]. Xi’an: Xi’an University of Architecture and Technology, 2021.
5 MA K, WANG D, SUN Y, et al Model predictive control for thermal comfort and energy optimization of an air handling unit system in airport terminals using occupant feedback[J]. Sustainable Energy Technologies and Assessments, 2024, 65: 103790
doi: 10.1016/j.seta.2024.103790
6 TANG H, YU J, GENG Y, et al Unlocking ventilation flexibility of large airport terminals through an optimal CO2-based demand-controlled ventilation strategy[J]. Building and Environment, 2023, 244: 110808
doi: 10.1016/j.buildenv.2023.110808
7 TANG H, YU J, GENG Y, et al Enhancing occupant-centric ventilation control in airport terminals: a predictive optimization framework integrating agent-based simulation[J]. Building and Environment, 2025, 276: 112829
doi: 10.1016/j.buildenv.2025.112829
8 LIN L, LIU X, LIU X, et al A prediction model to forecast passenger flow based on flight arrangement in airport terminals[J]. Energy and Built Environment, 2023, 4 (6): 680- 688
doi: 10.1016/j.enbenv.2022.06.006
9 唐浩, 余娟, 张仲宸, 等 大型航站楼室内物理环境质量实测与时空特征分析研究[J]. 建筑科学, 2023, 39 (10): 9- 14
TANG Hao, YU Juan, ZHANG Zhongchen, et al Analysis of spatiotemporal characteristics of indoor physical environmental quality in large terminal buildings based on field measurement[J]. Building Science, 2023, 39 (10): 9- 14
10 谷现良, 谢静超, 刘加平 大型机场航站楼冷热负荷时空分布影响因素分析[J]. 建筑科学, 2022, 38 (12): 215- 224
GU Xianliang, XIE Jingchao, LIU Jiaping Analysis of influencing factors of the spatiotemporal distribution of cooling and heating load in large airport terminal[J]. Building Science, 2022, 38 (12): 215- 224
doi: 10.13614/j.cnki.11-1962/tu.2022.12.26
11 张仲宸, 洪家杰, 朱嘉俊, 等 基于需求导向的航站楼空调及新风控制策略探讨[J]. 建筑节能(中英文), 2021, 49 (6): 61- 66
ZHANG Zhongchen, HONG Jiajie, ZHU Jiajun, et al Demand-oriented terminal air conditioning and fresh air control strategies[J]. Building Energy Efficiency, 2021, 49 (6): 61- 66
doi: 10.3969/j.issn.2096-9422.2021.06.010
12 REN Z, KIM J I, KIM J Assessment methodology for dynamic occupancy adaptive HVAC control in subway stations integrating passenger flow simulation into building energy modeling[J]. Energy and Buildings, 2023, 300: 113667
doi: 10.1016/j.enbuild.2023.113667
13 YUAN J, XIAO Z, CHEN X, et al A temperature & humidity setback demand response strategy for HVAC systems[J]. Sustainable Cities and Society, 2021, 75: 103393
doi: 10.1016/j.scs.2021.103393
14 SINHA K, ALI N, RAJASEKAR E Evaluating the dynamics of occupancy heat gains in a mid-sized airport terminal through agent-based modelling[J]. Building and Environment, 2021, 204: 108147
doi: 10.1016/j.buildenv.2021.108147
15 KRAMER R P, VAN SCHIJNDEL A W M, SCHELLEN H L The importance of integrally simulating the building, HVAC and control systems, and occupants’ impact for energy predictions of buildings including temperature and humidity control: validated case study museum Hermitage Amsterdam[J]. Journal of Building Performance Simulation, 2017, 10 (3): 272- 293
doi: 10.1080/19401493.2016.1221996
16 LU X, PANG Z, FU Y, et al The nexus of the indoor CO2 concentration and ventilation demands underlying CO2-based demand-controlled ventilation in commercial buildings: a critical review[J]. Building and Environment, 2022, 218: 109116
doi: 10.1016/j.buildenv.2022.109116
17 朱颖心, 魏庆芃, 林波荣, 等. 航站楼高大空间节能设计和运行应用指南[M]. 北京: 中国建筑工业出版社, 2012.
18 LIU X, LI L, LIU X, et al Field investigation on characteristics of passenger flow in a Chinese hub airport terminal[J]. Building and Environment, 2018, 133: 51- 61
19 GU X, XIE J, HUANG C, et al Prediction of the spatiotemporal passenger distribution of a large airport terminal and its impact on energy simulation[J]. Sustainable Cities and Society, 2022, 78: 103619
doi: 10.1016/j.scs.2021.103619
20 KIM W, PARK Y, KIM B J Estimating hourly variations in passenger volume at airports using dwelling time distributions[J]. Journal of Air Transport Management, 2004, 10 (6): 395- 400
doi: 10.1016/j.jairtraman.2004.06.009
21 中华人民共和国国家卫生健康委员会. 室内空气质量标准: GB/T 18883—2002 [S]. 北京: 中国标准出版社, 2003.
22 YANG Y, SRINIVASAN S, HU G, et al Distributed control of multizone HVAC systems considering indoor air quality[J]. IEEE Transactions on Control Systems Technology, 2021, 29 (6): 2586- 2597
doi: 10.1109/TCST.2020.3047407
23 YU L, XIE D, JIANG T, et al Distributed real-time HVAC control for cost-efficient commercial buildings under smart grid environment[J]. IEEE Internet of Things Journal, 2018, 5 (1): 44- 55
doi: 10.1109/JIOT.2017.2765359
24 董俐言, 杨彩青, 张杰, 等 航站楼建筑空调负荷特征及影响因素分析[J]. 暖通空调, 2021, 51 (6): 13- 20
DONG Liyan, YANG Caiqing, ZHANG Jie, et al Analysis of air conditioning load characteristics and influencing factors in terminal buildings[J]. Heating Ventilating and Air Conditioning, 2021, 51 (6): 13- 20
25 叶翠, 李哲青, 温嘉权, 等 机场航站楼空调系统负荷精算方法研究: 以我国夏热冬暖地区枢纽机场航站楼为例[J]. 暖通空调, 2023, 53 (4): 20- 26
YE Cui, LI Zheqing, WEN Jiaquan, et al Research on HVAC cooling load calculation method of airport terminals: a case study of hub airport terminal in hot summer and warm winter zone of China[J]. Heating Ventilating and Air Conditioning, 2023, 53 (4): 20- 26
doi: 10.19991/j.hvac1971.2023.04.03
26 LI Z, ZHANG J, GUAN H Passenger spatiotemporal distribution prediction in airport terminals based on physics-guided spatio-temporal graph convolutional network and its effect on indoor environment prediction[J]. Sustainable Cities and Society, 2024, 106: 105375
doi: 10.1016/j.scs.2024.105375
27 贾俊华. 大面积航班延误下机场应急疏散研究 [D]. 南京: 南京航空航天大学, 2018.
JIA Junhua. Research on the emergency evacuation of passengers in the large-area flight delay situation [D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2018.
[1] 周旭,杨子毓,张俊伟,吴燕玲,林小杰,钟崴,刘宝芹. 基于用户负荷量化的供热系统二级网运行优化[J]. 浙江大学学报(工学版), 2025, 59(8): 1624-1633.
[2] 范海东,陈竹,赵中阳,梁成思,郑成航,高翔. 1 000 MW燃煤机组湿法脱硫装置氧化系统运行优化[J]. 浙江大学学报(工学版), 2023, 57(4): 675-682.
[3] 寿春晖, 祁志福, 李敏, 邹正伟, 刘春红, 李晓东. 超低排放燃煤机组SO2减排的环境影响[J]. 浙江大学学报(工学版), 2017, 51(10): 1967-1973.
[4] 陈文聪, 侯艺文, 吴建, 王莉红. 化纤行业PM2.5和VOCs排放特性研究[J]. 浙江大学学报(工学版), 2017, 51(1): 145-152.