地铁设备管理用房风冷多联系统运行方案研究
摘要:地铁车站设备管理用房通风空调系统能耗是地铁车站能耗的重要组成部分。近年采用风冷多联系统作为主要空调系统,并设置机械通风系统的项目逐渐增多。针对该类型空调方案的全年运行方案尚缺乏相关研究。本文选取某地铁标准车站,建立了全年逐时能耗分析模型,分析对比了不同气候区多种运行方案下的全年运行能耗。研究表明,对于大部分地区的典型车站(单位体积发热量≤0.023 kW/m3),能效优先运行方案与风冷多联系统优先运行方案的全年运行能耗差别小于10%,综合考虑运行能耗和运行方案的实施复杂性,大部分地区地铁车站设备管理用房可以采用全年风冷多联系统优先运行方案。
关键词:地铁车站设备管理用房风冷多联系统机械通风系统运行方案
尊敬的用户,本篇文章需要2元,点击支付交费后阅读
限时优惠福利:领取VIP会员
全年期刊、VIP视频免费!
全年期刊、VIP视频免费!
参考文献[1] 刘传乾.地铁车站中变频多联空调系统应用分析与设计[J].建筑热能通风空调,2013,32(2):58-60.
[2] 黄建辉.地铁车站设备房变冷媒流量(VRV)系统使用分析[J].现代城市轨道交通,2006(3):33-34.
[3] 赖雪龙,王宪,王晓冬.深圳地铁空调变频式多联机系统的节能分析[J].城市轨道交通研究,2011,14(2):62-67.
[4] 周群,罗佳,高吉祥.分布式空调系统在地铁车站设备房的应用[J].轨道交通暖通空调,2017,47(5):19-22.
[5] 李小坤.多联机空调与机械通风集成系统在地铁车站设备管理用房中的应用[J].城市轨道交通研究,2019,22(7):126-132.
[6] 中国建筑科学研究院.建筑照明设计标准:GB 50034—2013[S].北京:中国建筑工业出版社,2014:43.
[7] 付战莹,林菁,李亮,等.厦门某地铁车站设备管理用房空调负荷实测及设计优化[J].暖通空调,2022,52(12):66-71.
[8] 余珏,李亮,李晓锋.基于现场实测的地铁站设备管用房设备发热量计算方法研究[J].建筑科学,2017,33(8):168-172.
[9] 北京城建设计研究总院有限责任公司,中国地铁工程咨询有限责任公司.地铁设计规范:GB 50157—2013[S].北京:中国计划出版社,2014:124.
[10] ZHOU Y P,WU J Y,WANG R Z,et al.Energy simulation in the variable refrigerant flow air-conditioning system under cooling conditions[J].Energy and buildings,2007,39(2):212-220.
[11] ZHOU Y P,WU J Y,WANG R Z,et al.Simulation and experimental validation of the variable-refrigerant-volume (VRV) air-conditioning system in EnergyPlus[J].Energy and buildings,2008,40(6):1041-1047.
[12] 王磊,苏醒.地铁车站设备管理用房设备发热量计算[J].建筑科学,2021,37(2):97-102.
[2] 黄建辉.地铁车站设备房变冷媒流量(VRV)系统使用分析[J].现代城市轨道交通,2006(3):33-34.
[3] 赖雪龙,王宪,王晓冬.深圳地铁空调变频式多联机系统的节能分析[J].城市轨道交通研究,2011,14(2):62-67.
[4] 周群,罗佳,高吉祥.分布式空调系统在地铁车站设备房的应用[J].轨道交通暖通空调,2017,47(5):19-22.
[5] 李小坤.多联机空调与机械通风集成系统在地铁车站设备管理用房中的应用[J].城市轨道交通研究,2019,22(7):126-132.
[6] 中国建筑科学研究院.建筑照明设计标准:GB 50034—2013[S].北京:中国建筑工业出版社,2014:43.
[7] 付战莹,林菁,李亮,等.厦门某地铁车站设备管理用房空调负荷实测及设计优化[J].暖通空调,2022,52(12):66-71.
[8] 余珏,李亮,李晓锋.基于现场实测的地铁站设备管用房设备发热量计算方法研究[J].建筑科学,2017,33(8):168-172.
[9] 北京城建设计研究总院有限责任公司,中国地铁工程咨询有限责任公司.地铁设计规范:GB 50157—2013[S].北京:中国计划出版社,2014:124.
[10] ZHOU Y P,WU J Y,WANG R Z,et al.Energy simulation in the variable refrigerant flow air-conditioning system under cooling conditions[J].Energy and buildings,2007,39(2):212-220.
[11] ZHOU Y P,WU J Y,WANG R Z,et al.Simulation and experimental validation of the variable-refrigerant-volume (VRV) air-conditioning system in EnergyPlus[J].Energy and buildings,2008,40(6):1041-1047.
[12] 王磊,苏醒.地铁车站设备管理用房设备发热量计算[J].建筑科学,2021,37(2):97-102.
Research on operation schemes of air-cooled multi-connection systems for subway equipment management rooms
Abstract: The energy consumption of ventilation and air conditioning system in the equipment management room of subway station is an important part of energy consumption of subway station. In recent years, the number of projects using air-cooled multi-connection systems as the main air conditioning systems and setting up mechanical ventilation systems has gradually increased. There is still a lack of relevant research on the annual operation scheme of this type of air conditioning scheme. This paper selects a standard subway station, and establishes an analysis model of hourly energy consumption throughout the year to analyse and compare the annual operating energy consumption under various operation schemes in different climate zones. The results show that for typical stations with calorific values per unit volume less than or equal to 0.023 kW/m3 in most areas, the annual operating energy consumption difference between the energy efficiency priority operation scheme and the air-cooled multi-connection system priority operation scheme is less than 10%. Taking into consideration of the operational energy consumption and the complexity of the implementation of the operation schemes, the air-cooled multi-connection system priority operation scheme can be adopted throughout the year for the equipment management rooms of subway stations in most areas.
Keywords: subway station; equipment management room; air-cooled multi-connection system; mechanical ventilation system; operation scheme;
612
0
0