Motley, Michael REberhard, Marc OWinter, Andrew Owen2020-02-042020-02-042020-02-042019Winter_washington_0250E_20850.pdfhttp://hdl.handle.net/1773/45151Thesis (Ph.D.)--University of Washington, 2019Prior efforts to numerically model the complex fluid-structure interactions that occur as tsunami inundations pass through coastal communities have failed to consistently reproduce experimentally-measured flow velocities and depths. These deficiencies have led to inaccurate estimates of the forces and pressures acting on individual structures due to shielding and channeling effects caused by neighboring structures, which tend to reduce and increase structural demands, respectively. To address these shortcomings, the primary goals of this dissertation were to produce an experimental data set for a range of neighboring structure configurations from which shielding and channeling effects on force demands were identified as well as to develop an experimentally-validated computational fluid dynamics model that was capable of accurately reproducing the observed effects. Additionally, a parametric study that varied neighboring structure locations was conducted using the validated CFD model in order to develop a streamwise force-prediction design equation, which improves upon the methods provided in the ASCE 7-16 design provisions used to estimate force amplifications due to neighboring structures.application/pdfen-USCC BY-NC-SAElevated StructureFlow ChannelingMacro-scale RoughnessShieldingTsunamiWave ForcesEngineeringMechanicsGeophysicsCivil engineeringThesis