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被动式太阳能建筑整合设计研究进展及展望

舒波 张阳 王家倩 杨尽 丁玎

舒波, 张阳, 王家倩, 杨尽, 丁玎. 被动式太阳能建筑整合设计研究进展及展望[J]. 工业建筑, 2021, 51(7): 177-184. doi: 10.13204/j.gyjzG20052805
引用本文: 舒波, 张阳, 王家倩, 杨尽, 丁玎. 被动式太阳能建筑整合设计研究进展及展望[J]. 工业建筑, 2021, 51(7): 177-184. doi: 10.13204/j.gyjzG20052805
SHU Bo, ZHANG Yang, WANG Jiaqian, YANG Jin, DING Ding. RESEARCH PROGRESS AND PROSPECT OF INTEGRATED DESIGN OF PASSIVE SOLAR BUILDINGS[J]. INDUSTRIAL CONSTRUCTION, 2021, 51(7): 177-184. doi: 10.13204/j.gyjzG20052805
Citation: SHU Bo, ZHANG Yang, WANG Jiaqian, YANG Jin, DING Ding. RESEARCH PROGRESS AND PROSPECT OF INTEGRATED DESIGN OF PASSIVE SOLAR BUILDINGS[J]. INDUSTRIAL CONSTRUCTION, 2021, 51(7): 177-184. doi: 10.13204/j.gyjzG20052805

被动式太阳能建筑整合设计研究进展及展望

doi: 10.13204/j.gyjzG20052805
基金项目: 

国家自然科学基金面上项目(51278421);住房和城乡建设部研究开发项目(2018-K2-009);四川省科技厅重点项目(2020YFS0309)。

详细信息
    作者简介:

    舒波,男,1971年出生,博士,教授。

    通讯作者:

    张阳,2754547412@qq.com。

RESEARCH PROGRESS AND PROSPECT OF INTEGRATED DESIGN OF PASSIVE SOLAR BUILDINGS

  • 摘要: 面对全球能源危机和环境问题,被动式太阳能建筑因具有低能耗、低成本、无污染等特点而备受关注,全球学者对"被动式太阳能建筑"的部件、性能等开展了广泛的研究。通过对近20年来被动式太阳能建筑整合设计的研究进展及态势的分析,发现目前被动式太阳能建筑设计研究的框架体系已初步形成,被动式太阳能建筑地域分布与太阳能辐射具有显著的地理空间契合性特征;在研究技术上,发展中国家与发达国家还存在一定差距;我国的被动式太阳能建筑研究主要集中在严寒、寒冷及夏热冬冷地区等。最后,对加强被动式太阳能建筑整合设计的研究、地区的拓展、建筑部件组合运用等方面提出了建议。
  • [1] LOTFABADI P. Analyzing Passive Solar Strategies in the Case of High-Rise Building[J]. Renewable and Sustainable Energy Reviews, 2015, 52:1340-1353.
    [2] HARKOUSS F, FARDOUN F, BIWOLE P H. Passive Design Optimization of Low Energy Buildings in Different Climates[J]. Energy, 2018, 165:591-613.
    [3] KIRANKUMAR G, SABOOR S, ASHOK BABU T P. Investigation of Different Window and Wall Materials for Solar Passive Building Design[J]. Procedia Technology, 2016, 24:523-530.
    [4] DIAKAKI C, GRIGOROUDIS E, KOLOKOSTA D. Towards a Multi-Objective Optimization Approach for Improving Energy Efficiency in Buildings[J]. Energy & Buildings, 2008, 40(9):1747-1754.
    [5] CHANDEL S S, SARKAR A. Performance Assessment of a Passive Solar Building for Thermal Comfort and Energy Saving in a Hilly Terrain of India[J]. Energy & Buildings, 2015, 86:873-885.
    [6] PETERKIN N. Rewards for Passive Solar Design in the Building Code of Australia[J]. Renewable Energy, 2008, 34(2):440-443.
    [7] 路宾, 郑瑞澄, 李忠, 等.太阳能建筑应用技术研究现状及展望[J]. 建筑科学, 2013, 29(10):20-25.
    [8] ALBAYYAA H, HAGARE D, SAHA S. Energy Conservation in Residential Buildings by Incorporating Passive Solar and Energy Efficiency Design Strategies and Higher Thermal Mass[J]. Energy & Buildings, 2018, 182:205-213.
    [9] HASTINGS S R. Myths in Passive Solar Design[J]. Solar Energy, 1995, 55(6):445-451.
    [10] 陈洪.被动式太阳能建筑的原理及其在室内设计中的应用[J]. 室内设计, 2000(4):40-44.
    [11] 鲁永飞, 夏海山.被动式太阳能建筑一体化设计策略[J]. 建设科技, 2009(24):97-99.
    [12] 刘加平.建筑物理[M].北京:中国建筑工业出版社, 2009.
    [13] RABAH K. Development of Energy-Efficient Passive Solar Building Design in Nicosia Cyprus[J]. Renewable Energy, 2005, 30(6):937-956.
    [14] 张磊, 鞠晓磊, 曾雁.《被动式太阳能建筑技术规范》解读[J]. 建设科技, 2012(5):50-54, 57.
    [15] 王崇杰, 薛一冰.太阳能建筑设计[M].北京:中国建筑工业出版社, 2007.
    [16] GULDENTOPS G, VAN DESSEL S. A Numerical and Experimental Study of a Cellular Passive Solar façade System for Building Thermal Control[J]. Solar Energy, 2017, 149:102-113.
    [17] ULAVI T, HEBRINK T, DAVIDSON J H. Analysis of a Hybrid Solar Window for Building Integration[J]. Energy Procedia, 2014, 57:1941-1950.
    [18] MORRISSEY J, MOORE T, HORNE R E. Affordable Passive Solar Design in a Temperate Climate:An Experiment in Residential Building Orientation[J]. Renewable Energy, 2011, 36(2):568-577.
    [19] MILLER W, BUYS L, BELL J. Performance Evaluation of Eight Contemporary Passive Solar homes in Subtropical Australia[J]. Building and Environment, 2012, 56:57-68.
    [20] SHAVIV E. Design Tools for Bio-Climatic and Passive Solar Buildings[J]. Solar Energy, 1999, 67(4/5/6):189-204.
    [21] KRVGER E, GIVONI B. Thermal Monitoring and Indoor Temperature Predictions in a Passive Solar Building in an Arid Environment[J]. Building and Environment, 2008, 43(11):1792-1804.
    [22] KONIS K, GAMAS A, KENSEK K. Passive Performance and Building form:An Optimization Framework for Early-Stage Design Support[J]. Solar Energy, 2016, 125:161-179.
    [23] FERNÁNDEZ-GONZÁLEZ A. Analysis of the Thermal Performance and Comfort Conditions Produced by Five Different Passive Solar Heating Strategies in the United States Midwest[J]. Solar Energy, 2006, 81(5):581-593.
    [24] XU X, ZHANG Y P, LIN K P, et al. Modeling and Simulation on the Thermal Performance of Shape-Stabilized Phase Change Material Floor Used in Passive Solar Buildings[J]. Energy & Buildings, 2005, 37(10):1084-1091.
    [25] CHEN C, LI Y, LI N, et al. A Computational Model to Determine the Optimal Orientation for Solar Greenhouses Located at Different Latitudes in China[J]. Solar Energy, 2018, 16:19-26.
    [26] ZHU J Y, CHEN B. A Mathematic Model of a Color-changed Passive Solar House[J]. Energy Procedia, 2017, 105:1009-1014.
    [27] LEBIED M, SICK F, CHOULLI Z, et al. Improving the Passive Building Energy Efficiency Through Numerical Simulation:A Case Study for Tetouan Climate in Northern of Morocco[J]. Case Studies in Thermal Engineering, 2018, 11:125-134.
    [28] FILIPPIÍN C, BEASCOCHEA A, ESTEVES A, et al. A Passive Solar Building for Ecological Research in Argentina:The First Two Years Experience[J]. Solar Energy, 1998, 63(2):105-115.
    [29] TONG G H, CHRISTOPHER D M, LI T, et al. Passive Solar Energy Utilization:A Review of Cross-Section Building Parameter Selection for Chinese Solar Greenhouses[J]. Renewable and Sustainable Energy Reviews, 2013, 26:540-548.
    [30] ZHOU G B, ZHANG Y P, WANG X, et al. An Assessment of Mixed Type PCM-Gypsum and Shape-Stabilized PCM Plates in a Building for Passive Solar Heating[J]. Solar Energy, 2007, 81(11):1351-1360.
    [31] CHANDEL S S, AGGARWAL R K. Performance Evaluation of a Passive Solar Building in Western Himalayas[J]. Renewable Energy, 2008, 33(10):2166-2173.
    [32] LAU C C S, LAM J C, LIU Y. Climate Classification and Passive Solar Design Implications in China[J]. Energy Conversion and Management, 2007, 48(7):2006-2015.
    [33] RAMAN P, MANDE S, KISHORE V V N. A Passive Solar System for Thermal Comfort Conditioning of Buildings in Composite Climates[J]. Solar Energy, 2001, 70(4):319-329.
    [34] YOUSEF M S, HASSAN H, AHMED M, et al. Energy and Exergy Analysis of Single Slope Passive Solar Still Under Egyptian Climate Conditions[J]. Energy Procedia, 2017, 141:18-23.
    [35] ZAIN-AHMED A, SOPIAN K, OTHMAN MYH, et al. Daylighting as a Passive Solar Design Strategy in Tropical Buildings:A Case Study of Malaysia[J]. Energy Conversion and Management, 2002, 43(13):1725-1736.
    [36] JAFARI A, POSHTIRI A H. Passive Solar Cooling of Single-Storey Buildings by an Adsorption Chiller System Combined with a Solar Chimney[J]. Journal of Cleaner Production, 2017, 141:662-682.
    [37] PRIYA R S, SUNDARRAJA M C, RADHAKRISHNAN S, et al. Solar Passive Techniques in the Vernacular Buildings of Coastal Regions in Nagapattinam, TamilNadu-India:A Qualitative and Quantitative Analysis[J]. Energy & Buildings, 2012, 49:50-61.
    [38] ZHU J Y, CHEN B. Experimental Study on Thermal Response of Passive Solar House with Color Changed[J]. Renewable Energy, 2015, 73:55-61.
    [39] CHEN B, ZHUANG Z, CHEN X, et al. Field Survey on Indoor Thermal Environment of Rural Residences with Coupled Chinese Kang and Passive Solar Collecting Wall Heating in Northeast China[J]. Solar Energy, 2006, 81(6):781-790.
    [40] ATHIENITIS A K, AKHNIOTIS E. Methodology for Computer-aided Design and Analysis of Passive Solar Buildings[J]. Computer-Aided Design, 1993, 25(4):203-214.
    [41] HERAS M R, JIMÉNEZ M J, SAN ISIDRO M J, et al. Energetic Analysis of a Passive Solar Design, Incorporated in a Courtyard After Refurbishment, Using an Innovative Cover Component Based in a Sawtooth Roof Concept[J]. Solar Energy, 2004, 78(1):85-96.
    [42] TOMBAZIS A N, PREUSS S A. Design of Passive Solar Buildings in Urban Areas[J]. Solar Energy, 2001, 70(3):311-318.
    [43] VASSILIADES C, MICHAEL A, SAVVIDES A, et al. Improvement of Passive Behaviour of Existing Buildings Through the Integration of Active Solar Energy Systems[J]. Energy, 2018, 163:1178-1192.
    [44] MOLS T, DZENE K P, VANAGA R, et al. Experimental Study of Small-Scale Passive Solar Wall Module with Phase Change Material and Fresnel Lens[J]. Energy Procedia, 2018, 147:467-473.
    [45] STEVANOVI S. Optimization of Passive Solar Design Strategies:A Review[J]. Renewable and Sustainable Energy Reviews, 2013, 25:177-196.
    [46] KIMURA K. Solar Architecture for the Happiness of Mankind[J]. Solar Energy, 1999, 67(4):169-179.
    [47] MAURER C, CAPPEL C, KUHN T E. Progress in Building-Integrated Solar Thermal Systems[J]. Solar Energy, 2015, 103:118-123.
    [48] GARDE F, MARA T, LAURET A P, et al. Bringing Simulation to Implementation:Presentation of a Global Approach in the Design of Passive Solar Buildings Under Humid Tropical Climates[J]. Solar Energy, 2001, 71(2):109-120.
    [49] KUMMERT M, ANDRÉ P, NICOLAS J. Optimal Heating Control in a Passive Solar Commercial Building[J]. Solar Energy, 2001, 69:103.
    [50] STRØMANN-ANDERSEN J, SATTRUP P A. The Urban Canyon and Building Energy Use:Urban Density Versus Daylight and Passive Solar Gains[J]. Energy & Buildings, 2011, 43(8):2011-2020.
    [51] HUGHES B R, OATES M. Performance Investigation of a Passive Solar-Assisted Kiln in the United Kingdom[J]. Solar Energy, 2011, 85(7):1488-1498.
    [52] DARKWA K, O'CALLAGHAN P W, TETLOW D. Phase-Change Drywalls in a Passive-Solar Building[J]. Applied Energy, 2006, 83(5):425-435.
    [53] SAVVIDES A, VASSILIADES C, MICHAEL A, et al. Siting and Building-Massing Considerations for the Urban Integration of Active Solar Energy Systems[J]. Renewable Energy, 2019, 135:963-974.
    [54] HENG C K, CHOO M L L, ZHANG J. Relationship Between Density, Urban Form and Environmental Performance[G]//Growing Compact:Urban Form, Density and Sustainability. London:Routledge, 2017.
    [55] ZHANG J, LE X, SHABUNKO V, et al. Impact of Urban Block Typology on Building Solar Potential and Energy Use Efficiency in Tropical High-Density City[J]. Applied Energy, 2019, 240:513-533.
    [56] AMADO M, POGGI F. Solar Energy Integration in Urban Planning:GUUD Model[J]. Energy Procedia, 2014, 50:277-284.
    [57] 孙丹. 新型被动式太阳能相变集热蓄热墙系统研究[D]. 大连:大连理工大学, 2016.
    [58] DUFFIE J A, BECKMAN W A. Solar Engineering of Thermal Processes Second Edition[J]. American Journal of Physics, 1980, 81(4):16591.
    [59] 王垚. 太阳能技术在建筑上的应用研究[D]. 西安:西安科技大学, 2010.
    [60] CHEN C, GUO H F, LIU Y N, et al. A New Kind of Phase Change Material (PCM) for Energy-Storing Wallboard[J]. Energy & Buildings, 2007, 40(5):882-890.
    [61] KOSNY J, FALLAHI A, SHUKLA N, et al. Thermal Load Mitigation and Passive Cooling in Residential Attics Containing PCM-Enhanced Insulations[J]. Solar Energy, 2014, 108:164-177.
    [62] JUANICÓ L E. A New Design of Configurable Solar Awning for Managing Cooling and Heating Loads[J]. Energy & Buildings, 2009, 41(12):1381-1385.
    [63] TRONCHIN L, MANFREN M, JAMES P A B. Linking Design and Operation Performance Analysis Through Model Calibration:Parametric Assessment on a Passive House Building[J]. Energy, 2018, 165:26-40.
    [64] GOU S Q, NIK V M, SCARTEZZINI J L, et al. Passive Design Optimization of Newly-Built Residential Buildings in Shanghai for Improving Indoor Thermal Comfort While Reducing Building Energy Demand[J]. Energy & Buildings, 2018, 169:484-506.
    [65] 钟珂, 杨柳, 汪妇欢, 等.被动式太阳能建筑室内热环境评价指标的分析[J]. 西安建筑科技大学学报(自然科学版), 2003(1):14-16.
    [66] ZIRNHELT H E, RICHMAN R C. The Potential Energy Savings from Residential Passive Solar Design in Canada[J]. Energy & Buildings, 2015, 103:224-237.
    [67] NGUYEN A T, REITER S, RIGO P. A Review on Simulation-Based Optimization Methods Applied to Building Performance Analysis[J]. Applied Energy, 2014, 113(1):1043-1058.
    [68] TIAN Z C, ZHANG X K, JIN X, et al. Towards Adoption of Building Energy Simulation and Optimization for Passive Building Design:A Survey and a Review[J]. Energy & Buildings, 2018, 158:1306-1316.
    [69] YI Y K, MALKAWI A M. Optimizing Building form for Energy Performance Based on Hierarchical Geometry Relation[J]. Automation in Construction, 2009, 18(6):825-833.
    [70] TUHUS-DUBROW D, KRARTI M. Genetic-Algorithm Based Approach to Optimize Building Envelope Design for Residential Buildings[J]. Building and Environment, 2010, 45(7):1574-1581.
    [71] SHI X, YANG W J. Performance-Driven Architectural Design and Optimization Technique from a Perspective of Architects[J]. Automation in Construction, 2013, 32:125-135.
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  • 收稿日期:  2020-05-28
  • 网络出版日期:  2021-11-11

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