机构地区:[1]Building Energy Research Center,School of Architecture,Tsinghua University,Beijing 100084,China [2]School of Architecture,Southeast University,Nanjing,Jiangsu 210096,China [3]School of Environment and Energy Engineering,Beijing University of Civil Engineering and Architecture,Beijing 100044,China [4]College of Civil Engineering,Hunan University,Changsha,Hunan 410082,China [5]School of Mechanical Engineering,Tongji University,Shanghai200092,China [6]Beijing Key Lab of Heating,Gas Supply,Ventilating and Air Conditioning Engineering,Beijing University of Civil Engineering and Architecture,Beijing 100044,China [7]China State Construction Technology Center,Beijing 101320,China [8]School of Architecture,Harbin Institute of Technology,Harbin,Heilongjiang 150090,China [9]School of Architecture,Xi'an University of Architecture and Technology,Xi'an,Shaanxi 710055,China [10]School of Architecture,South China University of Technology,Guangzhou,Guangdong 510641,China [11]Institute of Building Environment and Energy,China Academy of Building Research,Beijing 100013,China [12]Beijing Key Laboratory of Green Built Environment and Energy Efficient Technology,Beijing University of Technology,Beijing 100124,China [13]Key Lab of Built Environment and Energy of Tianjin,School of Environmental Science and Engineering,Tianjin University,Tianjin 300350,China [14]School of Energy and Power Engineering,Nanjing University of Science and Technology,Nanjing 210094,China [15]School of Civil Engineering,Guangzhou University,Guangzhou 510006,China [16]Faculty of Computing,Harbin Institute of Technology,Harbin,Heilongjiang 150001,China [17]Beijing Glory PKPM Technology Co.,Ltd.Beijing 100013,China [18]Beijing Tangent Software Co.,Ltd,Beijing 100081,China [19]Shanghai Huadianyuan Information Technology Co.,Ltd,Shanghai200092,China [20]Luoyang Hongye Information Technology Co.,Ltd.Luoyang,Henan 471822,China
出 处:《Building Simulation》2022年第11期1849-1868,共20页建筑模拟(英文)
基 金:supported by the“13th Five-Year”National Key R&D Program of China(No.2017YFC0702200)。
摘 要:Buildings contribute to almost 30%of total energy consumption worldwide.Developing building energy modeling programs is of great significance for lifecycle building performance assessment and optimization.Advances in novel building technologies,the requirements of high-performance computation,and the demands for multi-objective models have brought new challenges for building energy modeling software and platforms.To meet the increasing simulation demands,DeST 3.0,a new-generation building performance simulation platform,was developed and released.The structure of DeST 3.0 incorporates four simulation engines,including building analysis and simulation(BAS)engine,HVAC system engine,combined plant simulation(CPS)engine,and energy system(ES)engine,connected by air loop and water loop balancing iterations.DeST 3.0 offers numerous new simulation features,such as advanced simulation modules for building envelopes,occupant behavior and energy systems,cross-platform and compatible simulation kernel,FMI/FMU-based co-simulation functionalities,and high-performance parallel simulation architecture.DeST 3.0 has been thoroughly evaluated and validated using code verification,inter-program comparison,and case-study calibration.DeST 3.0 has been applied in various aspects throughout the building lifecycle,supporting building design,operation,retrofit analysis,code appliance,technology adaptability evaluation as well as research and education.The new generation building simulation platform DeST 3.0 provides an efficient tool and comprehensive simulation platform for lifecycle building performance analysis and optimization.
关 键 词:DeST building performance SIMULATION building energy modeling
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