Performance Evaluation of Critical Geosystems Using Multiscale Methods

使用多尺度方法评估关键地球系统的性能

• 批准号: RGPIN-2016-05263
• 负责人: Meguid, Mohamed
• 金额: $ 2.26万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=709626
• 关键词: Performance; Evaluation; Critical; Geosystems; Using

Countries around the world rely on various geotechnical infrastructure for flood control, water storage and hydroelectric power generation. These critical geosystems typically involve a porous media interacting with structural elements such as spillway walls, conduits associated with outlet works or adjoining gravity structures supporting the embankment. The failure of levees, or embankment dams by internal erosion may occur under high water levels during flood events or under normal operating conditions without an apparent triggering event. The latter can be attributed to various factors including decay of existing tree roots or invasive wildlife activities that result in local voids within levees or embankment dams that remain concealed until the safety of the earth structure is jeopardized. The worldwide average cost of failed or damaged earthen structures due to these factors exceeds billions of dollars per year. The negative impact of soil deterioration and erosion-related failure in geosystems is not limited to earth structures. Leaking pipes under or near existing structures are also known to cause sudden and unnoticed failure. In Canada, several regions are prone to flooding due, in large part, to the abundance of water resources and the extremes in seasonal temperatures. Extensive research has been done on intact earth structures to study the mechanisms of piping, erosion, and overtopping. However, studies related to the synthesis of failure mechanisms of earth structures with either (a) local soil deterioration, or (b) embedded structural elements are very scarce in the literature. Current engineering tools and procedures are very limited in modeling the dynamics of the interaction between the flowing water, the soil media and embedded structures. To address this issue, the present work will develop a rigorous multiscale approach to provide as much information as reasonably feasible about this complex soil-water-structure interaction problem. The theme of this Discovery Grant relates to developing new engineering tools to assess the performance of critical geotechnical structures under extreme conditions using centrifuge experiments and multiscale modeling approaches. The outcome of this research program will help engineers and researchers to evaluate the safety of existing earth dams and levees. It will also explain the soil instability and failure associated with leaking pipes buried near surface and subsurface structures. The above research program will involve training of four Master and five Doctoral students in addition to five summer undergraduate students over the five year funding period. The graduating geotechnical engineers will have a balanced outlook on the importance (and limitations) of experimental research and sophisticated modelling, and will be a real asset to the scientific communities in Canada and internationally.

世界各国依靠各种岩土工程基础设施进行防洪、蓄水和水力发电。这些关键地质系统通常涉及多孔介质与结构元件相互作用，例如溢洪道壁、与出口工程相关的管道或支撑堤坝的相邻重力结构。在洪水事件期间的高水位下或在没有明显触发事件的正常运行条件下，可能会发生堤坝或堤坝内部侵蚀的失效。后者可归因于各种因素，包括现有树根的腐烂或入侵的野生动物活动，导致堤坝或堤坝内的局部空隙，这些空隙一直隐藏着，直到地球结构的安全受到威胁。由于这些因素导致的土结构失效或损坏的全球平均成本每年超过数十亿美元。土壤退化和地质系统中与侵蚀有关的破坏的负面影响不仅限于地球结构。在现有结构下面或附近的泄漏管道也已知会导致突然和未被注意的故障。 在加拿大，有几个地区容易发生洪水，这在很大程度上是由于水资源丰富和季节性温度极端。人们对完整的土结构进行了广泛的研究，以研究管涌、侵蚀和漫顶的机理。然而，与（a）局部土壤恶化，或（B）嵌入式结构元件的土结构的破坏机制的合成相关的研究在文献中是非常罕见的。 目前的工程工具和程序是非常有限的流动的水，土壤介质和嵌入式结构之间的相互作用的动力学建模。为了解决这个问题，目前的工作将开发一个严格的多尺度方法，提供尽可能多的信息，合理可行的这个复杂的土-水-结构相互作用问题。这项发现补助金的主题涉及开发新的工程工具，以评估在极端条件下使用离心实验和多尺度建模方法的关键岩土结构的性能。这项研究计划的成果将有助于工程师和研究人员评估现有土坝和堤坝的安全性。它还将解释土壤的不稳定性和故障与泄漏管道埋在附近的表面和地下结构。 上述研究计划将涉及在五年资助期内培训四名硕士和五名博士生以及五名暑期本科生。即将毕业的岩土工程师将对实验研究和复杂建模的重要性（和局限性）有一个平衡的观点，并将成为加拿大和国际科学界的真实的资产。