长江流域居住建筑气密性现状及其在供暖供冷期内的控制需求
摘要:建筑气密性是衡量建筑热工性能的重要指标之一,同时对室内人员的健康和热舒适性具有一定的影响。随着长江流域冬季供暖需求的提升,该地区建筑气密性得到了越来越多的关注。本文对该地区的5栋代表性建筑进行了气密性测试,建筑年代较老的建筑由于施工水平导致气密性较差,所选用的外窗开启方式会影响气密性水平,房间的孔洞也是影响整体气密性的重要因素。从建筑节能和人员健康与舒适的角度确认了长江流域适宜的渗透换气次数为0.5~0.7 h-1,该地区新建建筑在正常施工水平和合理运维的情况下基本能够满足此气密性要求。
关键词:气密性渗透风自然通风供暖供冷长江流域居住建筑
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[4] 贾洪愿,李百战,姚润明,等.探讨长江流域室内热环境营造:基于建筑热过程的分析[J].暖通空调,2019,49(4):1- 11,42.
[5] 曹馨匀,喻伟,熊杰,等.基于能耗限额的夏热冬冷地区居住建筑节能技术方案[J].暖通空调,2022,52(7):41- 52.
[6] 李信仪,王晗,喻伟,等.重庆地区既有居住建筑低能耗改造策略初探[J].暖通空调,2019,49(4):49- 55,132.
[7] YAO R M,COSTANZO V,LI X Y,et al.The effect of passive measures on thermal comfort and energy conservation.A case study of the hot summer and cold winter climate in the Yangtze River region[J].Journal of building engineering,2018,15:298- 310.
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[9] 中国建筑科学研究院.建筑外门窗气密、水密、抗风压性能分级及检测方法:GB/T 7106—2008[S].北京:中国标准出版社,2008:3.
[10] 中国建筑科学研究院.夏热冬冷地区居住建筑节能设计标准:JGJ 134—2010[S].北京:中国建筑工业出版社,2010:3- 8.
[11] 姚润明,喻伟,王晗,等.长江流域建筑供暖空调解决方案和相应系统重点项目研究[J].暖通空调,2018,48(2):1- 9.
[12] CAO X Y,YAO R M,DING C,et al.Energy-quota-based integrated solutions for heating and cooling of residential buildings in the hot summer and cold winter zone in China[J].Energy and buildings,2021,236:110767.
[13] LI X Y,YAO R M,YU W,et al.Low carbon heating and cooling of residential buildings in cities in the hot summer and cold winter zone:a bottom-up engineering stock modeling approach[J].Journal of cleaner production,2019,220:271- 288.
[14] 上海市建筑科学研究院(集团)有限公司,上海市建筑建材业市场管理总站.上海市工程建设规范——居住建筑节能设计标准:DGJ 08-205—2011[S].上海:上海市城乡建设和交通委员会,2011:5.
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Investigation on airtightness of residences in the Yangtze River Basin and its regulations during the heating and cooling period
Abstract: The airtightness of buildings is an important index to measure the thermal performance of buildings, and it also has impacts on occupants' health and thermal comfort. With the increase of heating demand in the Yangtze River Basin, the airtightness of buildings in this area has received more attention. This article presents a study of onsite measurements of airtightness on five representative buildings in the area. The older buildings have poor airtightness due to the unskilled construction and installation, the window and door leakages, and the hole for air-conditioner pipes. From the perspectives of building energy conservation, and occupants' health and comfort, it is confirmed that the appropriate range of infiltration air change rates in the Yangtze River Basin is 0.5 to 0.7 per hour. New buildings in this area can basically meet this air tightness requirement under improved construction and better operation and maintenance.
Keywords: airtightness; infiltration; natural ventilation; heating and cooling; the Yangtze River Basin; residence;
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