GPPre:A Python⁃Based Tool in Grasshopper for Office Building Performance Optimization

下载PDF

导出

摘要 With the development of the economic and low⁃carbon society,high⁃performance building(HPB)design plays an increasingly important role in the architectural area.The performance of buildings usually includes the building energy consumption,building interior natural daylighting,building surface solar radiation,and so on.Building performance simulation(BPS)and multiple objective optimizations(MOO)are becoming the main methods for obtaining a high performance building in the design process.Correspondingly,the BPS and MOO are based on the parametric tools,like Grasshopper and Dynamo.However,these tools are lacking the data analysis module for designers to select the high⁃performance building more conveniently.This paper proposes a toolkit“GPPre”developed based on the Grasshopper platform and Python language.At the end of this paper,a case study was conducted to verify the function of GPPre,which shows that the combination of the sensitivity analysis(SA)and MOO module in the GPPre could aid architects to design the buildings with better performance.

作者 Hui Ren Shoulong Wang

机构地区 Heilongjiang Cold Region Architectural Science Key Laboratory Department of Chemical Engineering and Safety

出处《Journal of Harbin Institute of Technology(New Series)》 CAS 2021年第5期47-60,共14页 哈尔滨工业大学学报（英文版）

关键词 GPPre building performance simulation multiple objective optimizations high⁃performance building Python language

分类号 TU243 [建筑科学—建筑设计及理论]

引文网络
相关文献

参考文献2

1孙澄,韩昀松.光热性能考虑下的严寒地区办公建筑形态节能设计研究[J].建筑学报,2016(2):38-42. 被引量：39
2孙澄,韩昀松,张斌.严寒地区办公建筑环境信息模型建构[J].新建筑,2015(5):4-9. 被引量：6

二级参考文献21

1清华大学建筑节能研究中心.中国建筑节能年度发展研究报告2011[M].北京:中国建筑工业出版社,2011:1-2.
2Ramesh T, Prakash R, Shukla K. Life Cycle Energy Analysis of Buildings: An Overview[J]. Energy and Buildings, 2010, 42(10): 1592-1600.
3Bosche F, Haas C T. Automated Retrieval of 3D CAD Model Objects in Construction Range Images[J]. Automation in Construction, 2008, 17(4): 499-512.
4Milne M, Kohut T. Eliminating Air Conditioners in New Southern California Housing[C]//Proceedings of the American Solar Energy Society. Phoenix AZ, 2010: 3528-3536.
5Kalay Y E. Performance-Based Design[J]. Automation in Construction, 1999, 8(4): 395-409.
6Leinartas H A. Optimization of Whole House Retrofit Packages for Targeting 50% Annual Energy Use Reductions in Pre-1978 Chicagoland Homes[D]. Chicago: Illinois Institute of Technology, 2014.
7Lin S H, Gerber D J. Evolutionary Energy Performance Feedback for Design: Multidisciplinary Design Optimization and Performance Boundaries for Design Decision Support[J]. Energy and Buildings, 2014, 84(12): 426-441.
8Gursel I. CLIP: Computational Support for Lifecycle Integral Building Performance Assessment[D]. Delft: Delft University of Technology, 2010.
9Znouda Essia, Ghrab-Morcos Nadia, Hadj- Alouane Atidei. Optimization of mediterranean building design using genetic algorithms[J].Energy and Buildings, 2007, 39(2): 148-153.
10Manzan Marco, Pinto Francesco, Genetic optimization of external shading devices[C]// Proceedings: Building Simulation. Glasgow, 2009: 180-187.

共引文献41

1陈鑫星,李珺杰.环境要素影响下的中庭原型空间多维性能互联优化推演[J].世界建筑,2021(11):112-117. 被引量：1
2王玉,孔祥洪,郭良玉.中空栓剂的临床应用前景展望[J].山东医药工业,2000,19(2):14-14.
3刘利刚,林波荣,彭渤.中国典型高层办公建筑平面布置与能耗关系模拟研究[J].新建筑,2016(6):104-108. 被引量：5
4郭强,邹广天.基于决策树分类的可拓建筑策划预测方法[J].智能系统学报,2017,12(1):117-123. 被引量：9
5邢凯,邵郁,孙惠萱.严寒地区过渡季办公建筑热舒适实测研究[J].建筑学报,2017(3):118-122. 被引量：4
6高政翔.建筑采光节能设计的整体思维及设计手段[J].低碳世界,2017,7(26):164-165. 被引量：2
7夏冰.办公建筑空间布局类型的低碳设计研究[J].新建筑,2017(4):92-95. 被引量：3
8孙澄,韩昀松,庄典.“性能驱动”思维下的动态建筑信息建模技术研究[J].建筑学报,2017(8):68-71. 被引量：16
9邢凯,张洪瑞,高亮.建筑传热系数和窗墙比对严寒地区办公建筑能耗影响研究[J].城市建筑,2017,0(19):118-121. 被引量：5
10周怡彤,刘莹.建筑形态设计参数对办公建筑能耗影响分析[J].山西建筑,2017,43(31):179-181. 被引量：3

1Deqin Xiao,Jianzhao Feng,Tanyu Lin,Chunhua Pang,Yaowen Ye.Classification and recognition scheme for vegetable pests based on the BOF-SVM model[J].International Journal of Agricultural and Biological Engineering,2018,11(3):190-196. 被引量：1
2Haitao WANG,Zhanhuai LI,Xiao ZHANG,Xiaonan ZHAO,Song JIANG.WOBTree:a write-optimized B+-tree for non-volatile memory[J].Frontiers of Computer Science,2021,15(5):37-51.
3国际文摘[J].建筑节能（中英文）,2021,49(9):178-178.
4Salman Sakib,Grant Besse,Peng Yin,Daniel Gang,Donald Hayes.Sediment transport simulation and design optimization of a novel marsh shoreline protection technology using computational fluid dynamics (CFD) modeling[J].International Journal of Sediment Research,2022,37(1):14-25.
5V.Piscopo,A.Scamardella.点蚀损耗对船体梁极限强度的影响[J].Journal of Marine Science and Application,2021,20(3):477-490.
6朱阅岸,简怀兵,龙永超,李彬,王树,吴喜亮,钟治初,张延松.构建新型高性能与高可用的键值数据库系统[J].软件学报,2021,32(10):3203-3218. 被引量：3
7Damla Keskin,Guangyue Zu,Abigail M.Forson,Lisa Tromp,Jelmer Sjollema,Patrick van Rijn.Nanogels:A novel approach in antimicrobial delivery systems and antimicrobial coatings[J].Bioactive Materials,2021,6(10):3634-3657. 被引量：4
8Zhanrong Li,Xingcai Zhang,Jiang Ouyang,Dandan Chu,Fengqi Han,Liuqi Shi,Ruixing Liu,Zhihua Guo,Grace X.Gu,Wei Tao,Lin Jin,Jingguo Li.Ca^(2+)-supplying black phosphorus-based scaffolds fabricated with microfluidic technology for osteogenesis[J].Bioactive Materials,2021,6(11):4053-4064. 被引量：4
9Mohammad Keshavarzi,Mohammad Rahmani-Asl.GenFloor:Interactive generative space layout system via encoded tree graphs[J].Frontiers of Architectural Research,2021,10(4):771-786.
10Na YANG,Chunliang XIA,Tao YU,Xiaomin ZUO,Yangyi SUN,Xiangxiang YAN,Jian ZHANG,Jin WANG,Huijun LE,Libo LIU,William Edmund WARD.Measurement of Martian atmospheric winds by the O_(2) 1.27 μm airglow observations using Doppler Michelson Interferometry: A concept study[J].Science China Earth Sciences,2021,64(11):2027-2042. 被引量：1

Journal of Harbin Institute of Technology(New Series)

2021年第5期

浏览历史

内容加载中请稍等...

GPPre:A Python⁃Based Tool in Grasshopper for Office Building Performance Optimization

参考文献2

二级参考文献21

共引文献41

相关作者

相关机构

相关主题

浏览历史