Wind loads on a low-rise gable roof with and without solar panels and comparison to design standards

IF 2.7 Q2 ENGINEERING, CIVIL Sustainable and Resilient Infrastructure Pub Date : 2023-09-18 DOI:10.1080/23789689.2023.2257506
Aly Mousaad Aly, Emily Rone
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The addition of solar panels yields wind load reductions of 45–63%, depending on the configuration and details of the solar panel system, implying that buildings may not require additional reinforcement for PV panels. The findings have significant implications for enhancing the design and installation of residential solar energy systems, promising a more sustainable and secure future amid climate change and extreme weather challenges.KEYWORDS: Solar energy systemsroof damagehurricanesresiliencesustainability AcknowledgmentsThis research was funded by Solar Alternatives, PosiGen, and the Gulf States Renewable Energy Industry Association (GSREIA). Thanks to Mr. Jeff Cantin, Mr. Tom Neyhart, and Mr. Stephen Wright for their sup- port. Additional support was received from the NSF I-Corps program at Louisiana State University, and the Louisiana Board of Regents (ITRS, LEQSF(2022-25)-RD-B-02; RCS, LEQSF(2021-22)-RD-A-30). The findings are those of the authors and do not reflect the opinion of the sponsors.Disclosure statementNo potential conflict of interest was reported by the author(s).Additional informationFundingThe work was supported by the Louisiana Board of Regents [LEQSF(2022-25)-RD-B-02]; Louisiana State University [NSF I-Corps Lift2]; Solar Alternatives Inc. [Project #: AM211536].Notes on contributorsAly Mousaad AlyAly Mousaad Aly is an associate professor at Louisiana State University. Aly's research aims to advance knowledge in Wind Engineering and Structural Control to build more resilient and sustainable infrastructure, enhance safety, and reduce the tremendous cost of rebuilding after windstorms and earthquakes. He is the director of the LSU WISE research and education program (wise.lsu.edu). He was instrumental in bringing to life a state-of-the-art Open-Jet wind testing facility, which has proved capable of reproducing realistic wind effects on structures to resolve challenging scale issues. Aly has served as a wind engineering research fellow focusing on green energy infrastructure at Western University. His work included conducting an experimental study on vegetated building envelopes for the Bosco Verticale (Vertical Forest) building in Milan. He contributed to projects at the wind tunnel of the Polytechnic University of Milan, addressing wind effects on tall buildings, large roofs, bridges, and sensitive structural elements. Aly played a crucial role in aerodynamic/aeroelastic studies for the CityLife-Milano project, encompassing the Isozaki, Hadid, and Libeskind towers. 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In December 2020, Emily received her Bachelor of Science in Civil Engineering with a minor in Structural Engineering and graduated Summa Cum Laude with College Honors; she was also named the McLaughlin Medalist and a University Medalist, the highest honors of the College of Engineering and the university. Emily continued directly into the graduate program at LSU where she enjoyed the rigorous coursework and research, her extracurricular activities such as the Student Steel Bridge Competition Team and the LSU Women’s Rugby Football Club, and working part-time as a Civil Engineer Intern at Stantec, Inc in Baton Rouge. 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引用次数: 1

Abstract

ABSTRACTThis paper aims to understand how photovoltaic (PV) panels impact wind loads on low-rise buildings. The hypothesis posits that solar panels on a roof reduce wind-induced forces on components and cladding. To test this hypothesis, we experimentally investigated a 1:7.5 scale model in an open-jet wind facility, considering cases of bare roof and roofs with PV panels in three different configurations. The findings indicate that PV panels offer varying benefits based on the wind direction angle, generally reducing total wind forces on the primary structure. The addition of solar panels yields wind load reductions of 45–63%, depending on the configuration and details of the solar panel system, implying that buildings may not require additional reinforcement for PV panels. The findings have significant implications for enhancing the design and installation of residential solar energy systems, promising a more sustainable and secure future amid climate change and extreme weather challenges.KEYWORDS: Solar energy systemsroof damagehurricanesresiliencesustainability AcknowledgmentsThis research was funded by Solar Alternatives, PosiGen, and the Gulf States Renewable Energy Industry Association (GSREIA). Thanks to Mr. Jeff Cantin, Mr. Tom Neyhart, and Mr. Stephen Wright for their sup- port. Additional support was received from the NSF I-Corps program at Louisiana State University, and the Louisiana Board of Regents (ITRS, LEQSF(2022-25)-RD-B-02; RCS, LEQSF(2021-22)-RD-A-30). The findings are those of the authors and do not reflect the opinion of the sponsors.Disclosure statementNo potential conflict of interest was reported by the author(s).Additional informationFundingThe work was supported by the Louisiana Board of Regents [LEQSF(2022-25)-RD-B-02]; Louisiana State University [NSF I-Corps Lift2]; Solar Alternatives Inc. [Project #: AM211536].Notes on contributorsAly Mousaad AlyAly Mousaad Aly is an associate professor at Louisiana State University. Aly's research aims to advance knowledge in Wind Engineering and Structural Control to build more resilient and sustainable infrastructure, enhance safety, and reduce the tremendous cost of rebuilding after windstorms and earthquakes. He is the director of the LSU WISE research and education program (wise.lsu.edu). He was instrumental in bringing to life a state-of-the-art Open-Jet wind testing facility, which has proved capable of reproducing realistic wind effects on structures to resolve challenging scale issues. Aly has served as a wind engineering research fellow focusing on green energy infrastructure at Western University. His work included conducting an experimental study on vegetated building envelopes for the Bosco Verticale (Vertical Forest) building in Milan. He contributed to projects at the wind tunnel of the Polytechnic University of Milan, addressing wind effects on tall buildings, large roofs, bridges, and sensitive structural elements. Aly played a crucial role in aerodynamic/aeroelastic studies for the CityLife-Milano project, encompassing the Isozaki, Hadid, and Libeskind towers. He also innovated in the implementation of smart dampers in super-tall buildings and developed a novel energy-based probabilistic approach to assess the effectiveness of this damping technology for vibration control under multiple hazards. Aly has co-authored more than 60 peer-reviewed journal publications. He earned a Ph.D. in Mechanical Engineering from the Polytechnic University of Milan and is a licensed Professional Engineer (PE) in Louisiana.Emily RoneEmily Rone began her undergraduate studies at Louisiana State University (LSU) where she participated in the Accelerated Master’s Program, was an active member and elected president of the student chapter of the American Society of Civil Engineers, completed her senior bridge design project, and successfully defended her honors thesis for the Ogden Honors College. In December 2020, Emily received her Bachelor of Science in Civil Engineering with a minor in Structural Engineering and graduated Summa Cum Laude with College Honors; she was also named the McLaughlin Medalist and a University Medalist, the highest honors of the College of Engineering and the university. Emily continued directly into the graduate program at LSU where she enjoyed the rigorous coursework and research, her extracurricular activities such as the Student Steel Bridge Competition Team and the LSU Women’s Rugby Football Club, and working part-time as a Civil Engineer Intern at Stantec, Inc in Baton Rouge. Upon completion of her master’s degree, Emily advanced to a full-time position at Stantec.
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带和不带太阳能板的低矮山墙屋顶的风荷载及其与设计标准的比较
摘要本文旨在了解光伏板对低层建筑风荷载的影响。该假说认为,屋顶上的太阳能电池板可以减少风力对组件和包层的影响。为了验证这一假设,我们在一个开放式风力设施中实验研究了一个1:7.5比例的模型,考虑了三种不同配置的裸屋顶和安装光伏板的屋顶。研究结果表明,光伏板根据风向角度的不同提供了不同的效益,通常会降低主要结构的总风力。根据太阳能电池板系统的配置和细节,太阳能电池板的增加可以减少45-63%的风荷载,这意味着建筑物可能不需要额外加固光伏电池板。研究结果对加强住宅太阳能系统的设计和安装具有重要意义,有望在气候变化和极端天气挑战下实现更可持续、更安全的未来。本研究由Solar Alternatives、PosiGen和海湾国家可再生能源工业协会(GSREIA)资助。感谢杰夫·坎廷先生、汤姆·内哈特先生和斯蒂芬·赖特先生的支持。额外的支持来自路易斯安那州立大学的NSF I-Corps项目和路易斯安那大学校董会(ITRS, LEQSF(2022-25)-RD-B-02;RCS, LEQSF (2021 - 22) -RD-A-30)。这些发现是作者的发现,并不反映资助者的意见。披露声明作者未报告潜在的利益冲突。本研究得到了路易斯安那州校董会的支持[LEQSF(2022-25)-RD-B-02];路易斯安那州立大学[NSF I-Corps lif2];太阳能替代能源公司[项目号:AM211536]。作者简介:Aly Mousaad Aly是路易斯安那州立大学的副教授。Aly的研究旨在推进风力工程和结构控制方面的知识,以建设更具弹性和可持续性的基础设施,提高安全性,并减少风暴和地震后重建的巨大成本。他是路易斯安那州立大学WISE研究和教育项目(wise.lsu.edu)的主任。他在将最先进的Open-Jet风力测试设备带入生活方面发挥了重要作用,该设备已被证明能够在结构上重现真实的风力效果,以解决具有挑战性的规模问题。Aly曾在西部大学担任风能工程研究员,专注于绿色能源基础设施。他的工作包括为米兰的垂直森林(Bosco Verticale)建筑进行植被建筑围护结构的实验研究。他为米兰理工大学的风洞项目做出了贡献,研究了风对高层建筑、大型屋顶、桥梁和敏感结构元素的影响。Aly在米兰城市生活项目的空气动力学/空气弹性研究中发挥了至关重要的作用,该项目包括矶崎、哈迪德和里伯斯金塔楼。他还创新了智能阻尼器在超高层建筑中的应用,并开发了一种新的基于能量的概率方法来评估这种阻尼技术在多重危险下控制振动的有效性。Aly与人合著了60多篇同行评议的期刊出版物。他在米兰理工大学获得机械工程博士学位,是路易斯安那州的注册专业工程师。Emily Rone在路易斯安那州立大学(LSU)开始了她的本科学习,在那里她参加了加速硕士课程,是美国土木工程师协会学生分会的活跃成员并当选为主席,完成了她的高级桥梁设计项目,并成功地为奥格登荣誉学院的荣誉论文辩护。在2020年12月,艾米丽获得了土木工程学士学位,辅修结构工程,并以优异成绩毕业;她还被评为麦克劳克林奖章获得者和大学奖章获得者,这是工程学院和大学的最高荣誉。Emily直接进入了路易斯安那州立大学的研究生课程,在那里她喜欢严谨的课程和研究,她的课外活动,如学生钢桥比赛团队和路易斯安那州立大学女子橄榄球俱乐部,并在巴吞鲁日的Stantec公司兼职担任土木工程师实习生。完成硕士学位后,Emily晋升为Stantec的全职员工。
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来源期刊
CiteScore
7.60
自引率
10.20%
发文量
34
期刊介绍: Sustainable and Resilient Infrastructure is an interdisciplinary journal that focuses on the sustainable development of resilient communities. Sustainability is defined in relation to the ability of infrastructure to address the needs of the present without sacrificing the ability of future generations to meet their needs. Resilience is considered in relation to both natural hazards (like earthquakes, tsunami, hurricanes, cyclones, tornado, flooding and drought) and anthropogenic hazards (like human errors and malevolent attacks.) Resilience is taken to depend both on the performance of the built and modified natural environment and on the contextual characteristics of social, economic and political institutions. Sustainability and resilience are considered both for physical and non-physical infrastructure.
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