Career: The Use of the Geotechnical Centrifuge for Physical Modelling of Geo-Environmental and Geotechnical Problems

职业：使用岩土离心机进行地质环境和岩土问题的物理建模

• 批准号: 0422746
• 负责人: Patricia Culligan
• 金额: $ 20.86万
• 依托单位: Columbia University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-01-01 至 2005-05-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0422746&HistoricalAwards=false
• 关键词: Career; Use; Geotechnical; Centrifuge; Physical

9875883 Patricia J. Culligan MIT CAREER: The use of the geotechnical centrifuge for physical modeling of geo-environmental and geotechnical problems Abstract This project will use the geotechnical centrifuge as (a) a research tool to investigate the behavior and remediation of organic contaminants in aquifer systems, and (b) an educational tool to integrate physical modeling studies into civil and environmental engineering curricula. Geotechnical centrifuge modeling is an experimental method that allows the small-scale physical modeling of complicated problems affected by gravitational forces under realistic, but well controlled, boundary conditions. By using this method, both soil stress distributions and gravity (or buoyancy)-driven fluid displacements can be replicated at a reduced scale in a laboratory environment. Correct (scaleable) replication of these effects is not possible outside a centrifugal field unless a full-scale field experiment is carried out. For this reason, the geotechnical centrifuge offers an ideal tool for the physical modeling of many geo-environmental and geotechnical engineering problems. The research component of this project proposes to use the geotechnical centrifuge to investigate (i) the effects of unstable nonaqueous phase liquid (NAPL) flow and soil heterogeneity on NAPL movement through the vadose zone; (ii) the mechanisms determining NAPL entrapment in saturated soils under a range of flow conditions, and (iii) factors affecting the performance of two recent NAPL remediation technologies, air sparging and surfactant-enhanced hydraulic flushing. The results of this program will produce experimental results representative of field behavior that can be used to (i) quantify the timing and rate of aquifer contaminant loading due, for example, to a surface NAPL spill; (ii) provide estimates of NAPL volume in aquifers under given hydraulic conditions; and (iii) develop quantitative guidelines for the deployment of two emerging remediation technologies. Data from the study will also be invaluable for the parameterization, testing and validation of conceptual transport models and numerical codes. The educational plan will use the geotechnical centrifuge as a vehicle for introducing hands-on-experience and problem based learning into the civil and environmental engineering (CEE) undergraduate curricula. The objectives of the educational plan are to (i) develop a means of allowing CEE students to see the effects of their engineering design, and (ii) to explore whether the fundamentals of engineering mechanics can be better taught by exposing students to principles of physical modeling and scaling. The project will make use of the geotechnical centrifuge facility in the Department of Civil and Environmental Engineering at MIT. This facility consists of a 1.0 m radius balanced arm centrifuge, which is capable of spinning a 90 kg package of soil around a central axis at 400 rpm, and a new 1.0 m diameter mini-drum centrifuge, which is capable of spinning a 1000 kg annulus of soil around a central axis at 1000 rpm. Both centrifuges will be used in the execution of this work.

9875883帕特里夏J.卡利根麻省理工学院职业生涯：使用土工离心机的地质环境和岩土工程问题的物理建模摘要本项目将使用土工离心机作为（a）一个研究工具，以调查含水层系统中的有机污染物的行为和补救，和（B）一个教育工具，将物理建模研究纳入土木和环境工程课程。 土工离心模型是一种实验方法，允许在真实但控制良好的边界条件下对受重力影响的复杂问题进行小规模物理建模。 通过使用这种方法，土壤应力分布和重力（或浮力）驱动的流体位移可以在实验室环境中以减小的规模复制。 正确的（可缩放的）复制这些效果是不可能的离心场外，除非进行全面的现场实验。 因此，土工离心机为许多地质环境和岩土工程问题的物理建模提供了理想的工具。本项目的研究部分建议使用土工离心机来研究（i）不稳定非水相液体（NAPL）流动和土壤非均匀性对NAPL通过包气带运动的影响;（ii）在一系列水流条件下，非水相液体在饱和土壤中截留的机理，以及（iii）影响两种最新非水相液体修复技术性能的因素，空气喷射和表面活性剂增强的水力冲洗。 该计划的结果将产生代表现场行为的实验结果，可用于（一）量化含水层污染物负荷的时间和速率，例如，由于表面非水相液体溢出;（二）提供在给定的水力条件下含水层的非水相液体体积的估计;和（三）制定定量准则部署两个新兴的补救技术。 这项研究的数据对于概念性运输模型和数字代码的参数化、测试和验证也将是非常宝贵的。 该教育计划将使用土工离心机作为工具，将实践经验和基于问题的学习引入土木与环境工程（CEE）本科课程。 教育计划的目标是（一）开发一种方法，让中东欧学生看到他们的工程设计的效果，以及（二）探索是否可以通过让学生接触物理建模和缩放的原则，更好地教授工程力学的基础知识。该项目将利用麻省理工学院土木和环境工程系的土工离心设施。 该设施包括一台半径为1.0米的平衡臂离心机，能够以每分钟400转的速度围绕中心轴旋转90公斤的土壤包，以及一台新的直径为1.0米的小型转鼓离心机，能够以每分钟1000转的速度围绕中心轴旋转1 000公斤的土壤环。这两台离心机将用于执行本工作。