Collaborative Research: Wave, Surge, and Tsunami Overland Hazard, Loading and Structural Response for Developed Shorelines

合作研究：波浪、浪涌和海啸陆上灾害、荷载和已开发海岸线的结构响应

• 批准号: 1661052
• 负责人: Patrick Lynett
• 金额: $ 38.24万
• 依托单位: University of Southern California
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-08-01 至 2021-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1661052&HistoricalAwards=false
• 关键词: Collaborative; Research; Wave; Surge; Tsunami

Inundation from storms like Hurricanes Katrina and Sandy, and the 2011 East Japan tsunami, has caused catastrophic damage to coastal communities. With increasing coastal population, and trillions of dollars of infrastructure at risk, storms and tsunamis will continue to be threats to coastal communities. Improving community resilience to these Inundation Events (IEs) requires an understanding of how they damage buildings. Prediction of structural damage in IEs can be quite difficult along developed shorelines, where some structures may partially shield buildings behind them, reducing damage in ways that are not easily predictable using the existing state-of-the-art. This project will create new tools to predict structural damage from IEs along developed shorelines. The team from the University of Notre Dame, Oregon State University, and the University of Southern California will develop computer-based predictive methods for detailed building damage using laboratory tests and field data to guide development and validate accuracy. These new models will provide increased inundation and damage prediction accuracy, resulting in improved community resilience efforts and more efficient building design. Input from industry and professional standards committees will ensure that these results reach engineering practitioners. Prediction of surge, wave, and tsunami flow transformation over the built and natural environment is essential in determining survival and failure of near-coast structures during Inundation Events. However, unlike earthquake and wind hazards, IE loading and damage often vary strongly at a parcel scale in built-up coastal regions due to the influence of nearby structures on hydrodynamic transformation. Additionally, IE hydrodynamics and loading are presently treated using a variety of simplified methods (e.g. bare earth method) which introduce significant uncertainty and/or bias. Furthermore, existing evaluations of structural damage during IEs do not employ standard structural techniques, in large part because of uncertainties in the hydrodynamics and loading. This collaborative project will examine probabilistic structural vulnerability to storm waves and tsunamis in developed regions, where structures are most concentrated but existing models perform poorly due to complex flow transformation around these structures. The laboratory and computational methodologies developed here will employ deterministic and stochastic models with scales able to resolve local transformation, and that directly represent relevant processes. Resolving the local transformation at fine scales will provide improved accuracy in the prediction of structural vulnerability during IEs, enabling improved design, mitigation, and risk-informed decision making. Results of the detailed methodology, which will be computationally intensive, will be used where appropriate to develop more tractable methodologies for the probabilistic prediction of hydrodynamic transformation, loading, and structural response by engineering practitioners.

卡特里娜和桑迪等飓风以及2011年东日本海啸造成的洪水对沿海社区造成了灾难性的破坏。 随着沿海人口的增加，以及数万亿美元的基础设施处于危险之中，风暴和海啸将继续对沿海社区构成威胁。 提高社区对这些洪水事件（IE）的复原力需要了解它们如何破坏建筑物。 沿着发达的海岸线，在IE中预测结构损坏可能是相当困难的，其中一些结构可能会部分屏蔽其后面的建筑物，减少损害的方式是不容易预测使用现有的最先进的。 来自圣母大学、俄勒冈州州立大学和南加州大学的研究小组将开发基于计算机的预测方法，利用实验室测试和现场数据来指导开发和验证准确性。 这些新模型将提高洪水和损害预测的准确性，从而改善社区的抗灾能力，提高建筑设计的效率。 来自行业和专业标准委员会的意见将确保这些结果到达工程从业人员。 预测建筑物和自然环境中的涌浪、波浪和海啸流的变化对于确定洪水事件期间近岸结构物的存活和失效至关重要。 然而，与地震和风灾害，IE加载和损坏往往变化强烈，在一个包裹规模在建成的沿海地区，由于附近的结构对水动力转换的影响。 此外，IE流体动力学和负载目前使用各种简化方法（例如裸地球方法）进行处理，这些方法引入了显著的不确定性和/或偏差。 此外，现有的结构损伤评估在IE不采用标准的结构技术，在很大程度上是因为流体力学和负载的不确定性。 该合作项目将研究发达地区结构对风暴波和海啸的概率脆弱性，这些地区的结构最集中，但由于这些结构周围复杂的流动变化，现有模型表现不佳。 这里开发的实验室和计算方法将采用确定性和随机模型，其尺度能够解决局部变换，并直接代表相关过程。 在细尺度上解决局部转换将提高工业经济期间结构脆弱性预测的准确性，从而能够改进设计、缓解和风险决策。 详细的方法，这将是计算密集型的结果，将在适当的情况下使用开发更容易处理的方法，由工程从业人员的水动力转换，负载和结构响应的概率预测。

项目成果

Three-Dimensional Hydrodynamics Associated with a Solitary Wave Traveling over an Alongshore Variable Shallow Shelf

与沿岸可变浅陆架行进的孤立波相关的三维流体动力学

• DOI: 10.1061/(asce)ww.1943-5460.0000525
• 发表时间: 2019
• 期刊: and Ocean Engineering
• 作者: Lynett, Patrick J.;Swigler, David;El Safty, Hoda;Montoya, Luis;Keen, Adam S.;Son, Sangyoung;Higuera, Pablo
• 通讯作者: Higuera, Pablo

Wave-induced shallow-water monopolar vortex: large-scale experiments

• DOI: 10.1017/jfm.2020.980
• 发表时间: 2021-01-11
• 期刊: JOURNAL OF FLUID MECHANICS
• 影响因子: 3.7
• 作者: Kalligeris, N.;Kim, Y.;Lynett, P. J.
• 通讯作者: Lynett, P. J.

TSUNAMI RUNUP AMPLIFICATION OF BREAKING AND NON-BREAKING ERROR-FUNCTION WAVES OVER A SLOPING BEACH IN SHADOW ZONE BY A SMALL ISLAND

海啸对小岛阴影区倾斜海滩上破碎和非破碎误差函数波的增强

• DOI: 10.9753/icce.v36v.papers.13
• 发表时间: 2020
• 期刊: Coastal Engineering Proceedings
• 作者: Han, Sunghoon;Kaihatu, James;Lynett, Patrick;Synolakis, Costas
• 通讯作者: Synolakis, Costas

Tsunami versus Infragravity Surge: Comparison of the Physical Character of Extreme Runup

• DOI: 10.1029/2018gl080594
• 发表时间: 2018-12
• 期刊: Geophysical Research Letters
• 影响因子: 5.2
• 作者: Luis Montoya;P. Lynett

DATA-MODEL COMPARISONS OF STORM PROCESSES DURING HURRICANE HARVEY

• DOI: 10.9753/icce.v36v.waves.40
• 发表时间: 2020-12
• 作者: K. Anarde;J. Figlus;Wei Cheng;J. Horrillo;M. Tissier;P. Lynett;F. Shi