[1]赵娟,周波涛,白艺飞,等.高原寒冷地区既有建筑节能改造适宜性及经济性分析[J].西安建筑科技大学学报(自然科学版),2023,55(05):774-782.[doi:10.15986/j.1006-7930.2023.05.017]
 ZHAO Juan,ZHOU Botao,BAI Yifei,et al.Suitability and economic analysis of existing building energy saving reconstruction in cold plateau region[J].J. Xi’an Univ. of Arch. & Tech.(Natural Science Edition),2023,55(05):774-782.[doi:10.15986/j.1006-7930.2023.05.017]
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高原寒冷地区既有建筑节能改造适宜性及经济性分析()
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西安建筑科技大学学报(自然科学版)[ISSN:1006-7930/CN:61-1295/TU]

卷:
55
期数:
2023年05期
页码:
774-782
栏目:
出版日期:
2023-10-28

文章信息/Info

Title:
Suitability and economic analysis of existing building energy saving reconstruction in cold plateau region
文章编号:
1006-7930(2023)05-0774-09
作者:
赵娟周波涛白艺飞高俊梅强天伟
(西安工程大学 城市规划与市政工程学院,陕西 西安 710048)
Author(s):
ZHAO Juan ZHOU Botao BAI Yifei GAO Junmei QIANG Tianwei
(School of Urban Planning and Municipal Engineering, Xi′an Polytechnic University, Xi′an 710048, China)
关键词:
既有建筑节能改造围护结构朝向差异空气源热泵经济性分析
Keywords:
Energy saving transformation of existing buildings Differences in the orientation of the envelope Air source heat pump Economic analysis
分类号:
TU243;TU111.4
DOI:
10.15986/j.1006-7930.2023.05.017
文献标志码:
A
摘要:
通过对拉萨某办公建筑室内外温度实测,发现该建筑北向房间室内温度不满足供暖要求.为寻找供暖系统问题,探究北向房间不满足要求的原因,充分考虑高海拔、强辐射等气候因素的影响,首先基于既有建筑的围护结构朝向差异化研究,提出三种节能改造方案并分别进行DeST能耗模拟.模拟结果显示,方案2改造后供暖季的总供热量比方案1减少了50-79%,方案3比方案1减少了52-50%,围护结构改造效果显著;其次进行节能性分析,对空气源热泵运行参数进行高原修正,并提出热源设计改造方案A(改造围护结构并加装电热膜)和方案B(直接更换空气源热泵),对这两种方案分别进行经济性分析.结果显示,保留原有设备的方案A比方案B初投资费用节省101.02万元,年运行费用节省0.533万元,生命周期费用节省105.38万元,是可以优先推广的既有建筑改造方式.
Abstract:
Through the actual measurement of indoor and outdoor temperatures of an office building in Lhasa, it was found that the indoor temperature of the northfacing rooms of the building did not meet the heating requirements. To find the heating system problems and explore the reasons why the north-facing rooms do not meet the requirements, the influence of climatic factors such as high altitude and strong radiation is considered. Firstly, based on the study of the differentiation of the envelope orientation of the existing building, three energy-saving retrofitting schemes are proposed and DeST energy consumption simulations are conducted separately. The simulation results show that the total heat supply in the heating season after the renovation of scheme 2 is reduced by 50-79% compared with scheme 1, and scheme 3 is reduced by 52-50% compared with scheme 1, so the effect of envelope renovation is remarkable; secondly, energy-saving analysis is conducted, the operating parameters of air source heat pump are modified in plateau, and heat source design renovation scheme A (renovation of envelope structure and addition of electric heat film) and scheme B (direct replacement of air source heat pump), and economic analysis was conducted for these two options respectively. The results show that Option A, which retains the original equipment, saves 1,010,200 CNY in initial investment costs, 5330 CNY in annual operating costs and 1,053,800 CNY in life-cycle costs compared to Option B. It is the preferred method of retrofitting existing buildings that can be promoted.

参考文献/References:

[1]肖榆川. 基于热环境优化的拉萨居住建筑空间模式研究[D].西安:西安建筑科技大学,2020.

  XIAO Yuchuan. Research on Spatial Model of Residential Buildings in Lhasa Based on Thermal Environment Optimization[D]. Xi′an: Xi′an Univ. of Arch. & Tech., 2020.
[2]桑国臣,方倩,王文康,等.太阳能建筑外墙传热系数朝向差异设计研究[J].太阳能学报,2018,39(12):3440-3450.
  SANG Guochen, FANG Qian, WANG Wenkang, et al. Study on difference of heat transfer coefficient in difference facing orientation exterior wall of solar building[J]. Acta Energiae Solaris Sinica, 2018,39(12):3440-3450.
[3]李榕榕,程晓喜,黄献明,等.基于日照影响下冷热负荷计算的公共建筑“最佳朝向”反思[J].建筑学报,2020(11):99-104.
  LI Rongrong, CHENG Xiaoxi, HUANG Xianming, et al. Reflections on the optimal building orientation based on the analysis of oolingheating loads affected by solar parameters[J]. Architectural Journal, 2020(11):99-104.
[4]胡达明,陈定艺,单平平,等.夏热冬暖地区居住建筑朝向对能耗的影响分析[J].建筑节能,2017,45(5):57-60.
  HU Daming, CHENG Yiding, SHAN Pingping, et al. Influence of residential building orientations to energy consumption in hot summer and warm winter zone[J]. Journal of Building Energy Efficiency, 2017,45(5):57-60.
[5]FURTADO A, RODRIGUES H, AREDE A, et al. A experimental characterization of seismic plus thermal energy retrofitting techniques for masonry infill walls[J].Journal of Building Engineering 2023,75.
[6]梁秒梦.太阳能建筑非均匀节能构造及热环境分析[D].西安:西安理工大学,2017.
  LIANG Miaomeng. Nonuniform energysaving structure and thermal environment analysis of solar building[D]. Xi′an:Xi′an University of Technology, 2017.
[7]MOGHADDAM F B, MIR J M, YANGUAS A B, et al. Building orientation in Green facade performance and its positive effects on urban landscape case study: An urban block in barcelona[J]. Sustainability 2020, 12, 9273.
[8]崔俊奎,陈杰,包文增.寒冷地区公共建筑围护结构改造与节能分析[J].建筑技术,2020,51(3):4.
  CUI Junkui, CHEN Jie, BAO Wenzeng. Reconstruction and energy saving analysis of public building envelope structure in cold area[J]. Architectural Technology, 2020,51(3):4.
[9]黄帅帅,李炎,崔景东,等.寒冷地区某既有办公建筑围护结构优化改造研究[J].制冷与空调(四川),2020,34(2):9.
  HUANG Shuaishuai, LI Yan, CUI Jingdong, et al. Research on optimization and transformation of envelope structure of an existing office building in cold area[J]. Refrigeration & Air Conditioning(SI CHUAN), 2020, 34(2):9.
[10]CONSUEGRA F M, FRUTOS F D , OTEIZA I. Minimal monitoring of improvements in energy performance after envelope renovation in subsidized single family housing in madrid[J]. Sustainability, 2020, 13.
[11]OCHOA L L, CASAS L H, GONZALEZ L L, et al. Energy renovation of residential buildings in cold mediterranean zones using optimized thermal envelope insulation thicknesses: The case of Spain[J]. Sustainability, 2020, 12(6):2287.
[12]ZHANG L L, LIU Z A , HOU C P, et al. Optimization analysis of thermal insulation layer attributes of building envelope exterior wall based on DeST and life cycle economic evaluation[J]. Case Studies in Thermal Engineering, 2019: 100410.
[13]FAR C, FAR H. Improving energy efficiency of existing residential buildings using effective thermal retrofit of building envelope[J]. Indoor and Built Environment ,2019,28(6):744-760.
[14]FLEUR L L , ROHDIN P, MOSHFEGH B. Investigating costoptimal energy renovation of a multifamily building in Sweden[J]. Energy and Buildings, 2019:109438.
[15]BRUCK A, DIAZ RUANO S, AUER H. Values and implications of building envelope retrofitting for residential Positive Energy Districts [J]. Energy and Buildings, 2022: 275.
[16]刘晓君,王瑾.基于西安市既有住宅性能的节能改造项目优选研究[J].西安建筑科技大学学报(自然科学版),2013,45(5):732-737.
  LIU Xiaojun, WANG Jing. Research on the optimization of energy-saving renovation projects based on the performance of existing residential buildings in Xi′an[J]. Journal of Xi′an University of Architecture and Technology (Natural Science Edition), 2013,45(5):732-737.
[17]LI Y, CHEN L. A study on database of modular fa-ade retrofitting building envelope [J]. Energy and Buildings, 2020, 214: 1098-1133.
[18]何梅,石颜博.严寒地区既有居住建筑节能改造窗户节能效果研究——以内蒙古地区为例[J].西安建筑科技大学学报(自然科学版),2013,45(4):554-558.
  HE Mei, SHI Yanbo. Study on the energy saving effect of window energy saving reconstruction of existing residential buildings in severe cold areaTaking Inner Mongolia as an example[J]. J. of Xi′an Univ. of Arch. & Tech.(Natural Science Edition), 2013,45(4):554-558.
[19]HABIBI S, OBONYO E A, MEMARI A M. Design and development of energy efficient reroofing solutions [J]. Renewable Energy, 2020, 151: 1209-1219.
[20]李峥嵘,曾诗琴,赵群,等.贵州地扪侗寨传统民居围护结构改造对室内热湿环境影响[J].西安建筑科技大学学报(自然科学版),2016,48(6):908-911.
  LI Zhengrong, ZENG Shiqing, ZHAO Qun, et al. The influence of enclosure structure transformation of traditional dwellings in Dimen Dong Village of Guizhou on indoor thermal and humid environment[J]. J. of Xi′an Univ. of Arch. & Tech.(Natural Science Edition), 2016,48(6):908-911.
[21]高鹏程,王昭俊,刘畅等.严寒地区被动房热泵空调机组冬季性能测试与分析[J].暖通空调,2023,53(6):120-123,69.
  GAO Pengcheng, WANG Zhaojun, LIU Chang, et al. Performance test and analysis of heat pump air conditioning units of a passive house in severe cold zone in winter[J]. Journal of HV&AC, 2023,53(6):120-123,69.
[22]李欣林.拉萨地区空气源热泵供暖应用研究[D].重庆:重庆大学,2014.
  LI Xinlin. Application Research on Air Source Heat Pump Heating in Lhasa[D]. Chongqing:Chongqing University,2014.
[23]CHESSER M , LYONS P , REILLY P, et al. Air source heat pump insitu performance[J]. Energy and Buildings, 2021: 1113-1124.
[24]PU Jihong, SHEN Chao, YANG Haotian, et al. Investigating heat transfer and frosting performance of air source heat pumps with the impact of particulate fouling[J]. Energy for Sustainable Development , 2021: 194-203.
[25]王洋涛,赵润俐,田琦.空气源热泵及辅助电加热地板辐射采暖系统耦合优化[J].华侨大学学报:自然科学版,2019,40(5): 661-667.
  WANG Yangtao, ZHAO Runli, TIAN Qi. Coupling optimization of air source heat pump and auxiliary electric heating floor radiant heating system[J]. Journal of Huaqiao University (Natural Science), 2019,40(5): 661-667.
[26]西藏自治区住房和城乡建设厅. 西藏自治区民用建筑节能设计标准DBJ540001—2016[M]. 西藏自治区住房和城乡建设厅, 2016
  Department of Housing and Urban-Rural Development of Tibet Autonomous Region of the People′s Republic of China. Design Standard for Energy Efficiency of Civil Buildings DBJ540001—2016[M]. Department of Housing and Urban-Rural Development of Tibet Autonomous Region, 2016.

备注/Memo

备注/Memo:
收稿日期:2022-04-28修回日期:2023-08-30
基金项目:国家自然科学基金青年资金资助项目(52208125)
第一作者:赵娟(1984—),女,博士,副教授,主要研究可再生能源利用、太阳能供暖技术及相变蓄热技术等. E-mail: juanzhao1220@163.com
更新日期/Last Update: 2023-11-03