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浙江大学学报(工学版)
JOURNAL OF ZHEJIANG UNIVERSITY (ENGINEERING SCIENCE)
Traffic and Civil Engineering     
Anti-insulation behavior for exterior wall external insulation on residential buildings in hot summer and cold winter zone
RUAN Fang, QIAN Xiao qian, QIAN Kuang liang,YU Ya chao,SHI Shui hua
1.College of Civil Engineering and Architecture, Hangzhou 310058, China; 
2. Zhejiang Construction Industry Research Institute,Baoye Group,Shaoxing 312030,China
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Abstract  

The EnergyPlus simulation software was employed to analyze the energy saving effect of exterior wall external insulation in residential building of the hot summer and cold winter zone. Hangzhou was taken for an example to address the problem of the discrepancy between the actual air conditioning (AC) working conditions and design conditions in standards for residential building energy efficiency in this region. Results show that under the standard way of continuous AC operation method, exterior insulation has good energy saving effect; however, under intermittent AC operation method, external insulation can increase the annual cooling load. Based on daily meteorological data from 1971 to 2000, the five days moving average method was adopted to obtain the recommended value of heating and cooling period, which is more accordant with the actual situation of Hangzhou. After using the new heating and cooling period, the influence of anti-insulation behavior for exterior insulation on annual energy consumption is more significant; the annual energy saving rate significantly reduced. Further research shows that for the window to wall ratio (WWR) and cooling set temperature, there are a series of critical value for anti-insulation behavior in summer cooling (0.3 for WWR and 26 ℃ for cooling set temperature). When WWR and cooling set temperature are lower than the critical value, external insulation saves energy; when WWR and cooling set temperature are higher than the critical value, total energy consumption increases.

Published: 08 December 2016
CLC:  TU 111  
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Cite this article:

RUAN Fang, QIAN Xiao qian, QIAN Kuang liang,YU Ya chao,SHI Shui hua. Anti-insulation behavior for exterior wall external insulation on residential buildings in hot summer and cold winter zone. JOURNAL OF ZHEJIANG UNIVERSITY (ENGINEERING SCIENCE), 2016, 50(12): 2343-2349.

URL:

http://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2016.12.014     OR     http://www.zjujournals.com/eng/Y2016/V50/I12/2343


夏热冬冷地区居住建筑外墙外保温的反节能现象

针对夏热冬冷地区居住建筑现行节能设计标准中空调系统部分设计工况与该地区实际情况存在一定出入的问题,以杭州市为例,采用EnergyPlus能耗模拟软件模拟分析该地区居住建筑不同用能工况下外墙外保温的节能效果.结果显示,在标准规定的连续用能方式下,外墙外保温节能效果良好|而在间歇用能方式下,外墙外保温会增加全年冷负荷.以1971—2000年的日值气象数据为基础,采用五日滑动平均法,得出实际杭州市的采暖及空调期推荐值.在采用新的采暖、空调期后,外墙外保温夏季反节能现象对全年能耗的影响更加显著,全年节能率明显减小.进一步研究表明,对于窗墙比及制冷设定温度而言,均存在一系列的外保温反节能临界值(窗墙比为0.3,制冷设定温度为26 ℃),低于此临界值时外保温节能,高于此临界值时反节能.

[1] 中华人民共和国建设部.民用建筑热工设计规范:G8 5017693[S].北京:中华人民共和国住房和城乡建设部.1993.
[2] GHRABMORCOS N. CHEOPS: a simplied tool for thermal assessment of Mediterranean residential buildings in hot and cold seasons [J]. Energy and Buildings. 2005, 37(6): 651-662.
[3] MOHSEN M S, AKASH B A. Some prospects of energy savings in buildings [J]. Energy Conversion and Management. 2001, 42(11): 1307-1315.
[4] MOHAMMAD S A. Performance characteristics and practical applications of common building thermal insulation materials [J]. Building and Environment. 2005, 40(3): 353-366.
[5] 钱晓倩,朱耀台.夏热冬冷地区建筑节能存在的问题与研究方向[J].施工技术,2012, 358(41): 27-29.
QIAN Xiaoqian, ZHU Yaotai. Basic research direction and problems existed in building energy saving in hot summer and cold winter climate zones [J]. Construction Technology. 2012, 358(41): 27-29.
[6] KOSSECKA E, KOSNY J. Influence of insulation configuration on heating and cooling loads in a continuously used building [J]. Energy and Buildings. 2002, 34(4): 321-331.
[7] BALOCCO C, GRAZZINI G, CAVALERA A. Transient analysis of an external building cladding [J]. Energy and Buildings. 2008, 40(7): 1273-1277.
[8] BOJIC M, YIK F. Influence of thermal insulation position in building envelope on the space cooling of highrise residential buildings in Hong Kong [J]. Energy and Buildings. 2001, 33(6): 569-581.
[9] BOJIC M, YIK F. Cooling energy evaluation for highrise residential buildings in Hong Kong [J]. Energy and Buildings. 2005, 37(4): 345-351.
[10] BOJIC M, YIK F, LEUNG W. Thermal insulation of cooled spaces in high rise residential buildings in Hong Kong [J]. Energy Conversion and Management. 2002, 43 (2): 165-183.
[11] PAN D, CHAN M, DENG S, et al. The effects of external wall insulation thickness on annual cooling and heating energy uses under different climates [J]. Applied Energy. 2012, 97(9): 313-318.
[12] MASOSO O T, GROBLER L J. A new and innovative look at anti-insulation behaviour in building energy [J]. Energy and Buildings. 2008, 40(10): 1889-1894.
[13] TUMMU P, CHIRARATTANANON S, HIEN V D, et al. Thermal performance of insulated walls enclosing residential spaces in Thailand [J]. Energy and Buildings. 2013, 61(6): 323-332.
[14] CHIRARATTANANON S, HIEN V D, TUMMU P. Thermal performance and cost effectiveness of wall insulation under Thai climate [J]. Energy and Buildings. 2012, 45(2): 82-90.
[15] 钱晓倩,吴敏莉,朱耀台,等.夏热冬冷地区居住建筑用电特性研究[J].建筑节能,2013,12(41): 77-81.
QIAN Xiaoqian, WU Minli, ZHU Yaotai, et al.Elect ricity consumpt ion of resident ial buildings in hot summer and cold winter zone [J]. Building Energy Efficiency, 2013,12(41): 77-81.
[16] CRAWLEY D B, LAWRIE L K, WINKELMANN F C, et al. EnergyPlus: creating a new-generation building energy simulation program [J]. Energy and Buildings, 2001, 33(4): 319-331.
[17] 宋芳婷,诸群飞,吴如宏,等.中国建筑热环境分析专用气象数据集[M].北京:中国建筑工业出版社,2005:12.
[18] 钱晓倩.夏热冬冷地区居住建筑电耗调查与分析报告[R].杭州: 浙江大学, 2013.
QIAN Xiaoqian. A survey and analysis report of residential building energy consumption in hot summer and cold winter zone [R]. Hangzhou: Zhejiang University. 2013.
[19] 中华人民共和住房和城乡建设部.夏热冬冷地区居住建筑节能设计标准:JGJ 1342010[S].北京:中华人民共和国住房和城乡建设部, 2010.
[20] 陈莉,方修睦,方修琦,等.过去20年气候变暖对我国冬季采暖气候条件与能源需求的影响[J].自然资源学报,2006,21(4): 590-597.
CHEN Li, FANG Xiu mu, FANG Xiu qi, et al. Influence of climate warming over the past 20 years on the climatic conditions of the winter heating and energy requirement [J]. Journal of Natural Resources, 2006,21(4): 590-597.
[21] 史珺,郭军,孙卫国.1961—2010年气候变化对天津市采暖期和夏季空调期的影响[J].气象与环境学报,2013,29(2): 61-67.
SHI Jun, GUO Jun, SUN Weiguo. Effect of climate change on winter heating period and summer aircondition period from 1961 to 2010 in Tianjin [J]. Journal of Meteorology and Environment, 2013, 29(2): 61-67.
[22] 中国气象数据网.中国地面累年值日值数据集[EB/OL].http:∥data.cma.gov.cn/.
[23] 中华人民共和住房和城乡建设部.民用建筑供暖通风与空气调节设计规范:GB 50736-2012[S].北京:中华人民共和国住房和城乡建设部,2012.
[24] 中华人民共和住房和城乡建设部.建筑气候区划标准:GB 5017893[S].北京:中华人民共和国住房和城乡建设部,1993.
[25] 沈昭华,谭洪卫,吕思强,等.上海地区建筑能耗计算用典型年气象数据的研究[J].暖通空调,2010, 40(1): 89-94.
SHEN Zhaohua, TAN Hongwei, LV Siqiang, et al. Research on the typical meteorological year data of Shanghai for the building energy consumption calculation [J]. HV&AC, 2010, 40(1): 89-94.
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