Abstract
Concrete buttress dams could potentially be susceptible to high-frequency vibrations, especially in the cross-stream direction, due to their slender design. Previous studies have mainly focused on low-frequency vibrations in stream direction using a simplified foundation model with the massless method, which does not consider topographic amplifications. This paper therefore investigates the nonlinear behaviour of concrete buttress dams subjected to high-frequency excitations, considering cross-stream vibrations. For comparison, the effect of low-frequency excitations is also investigated. The influence of the irregular topography of the foundation surface on the amplification of seismic waves at the foundation surface and thus in the dam is considered by a rigorous method based on the domain-reduction method using the direct finite element method. The sensitivity of the calculated response of the dam to the free-field modelling approach is investigated by comparing the result with analyses using an analytical method based on one-dimensional wave propagation theory and a massless approach. Available deconvolution software is based on the one-dimensional shear wave propagation to transform the earthquake motion from the foundation surface to the corresponding input motion at depth. Here, a new deconvolution method for both shear and pressure wave propagation is developed based on an iterative time-domain procedure using a one-dimensional finite element column. The examples presented showed that topographic amplifications of high-frequency excitations have a significant impact on the response of this type of dam. Cross-stream vibrations reduced the safety of the dam due to the opening of the joints and the increasing stresses. The foundation modelling approach had a significant impact on the calculated response of the dam. The massless method produced unreliable results, especially for high-frequency excitations. The free-field modelling with the analytical method led to unreliable joint openings. It is therefore recommended to use an accurate approach for foundation modelling, especially in cases where nonlinearity is considered.
Highlights
Seismic evaluation of concrete dams is essential because of the catastrophic consequences in case of their failure
Concrete buttress dams are designed as individual monoliths separated by vertical contraction joints that are expected to open/close and slide cyclically when subjected to strong earthquake ground motions. erefore, it is important to study the seismic response of such structures, especially in the cross-stream direction
Lokke and Chopra [16] developed a method based on domain-reduction method (DRM), using the direct finite element (FE) method for viscous boundaries
Summary
Seismic evaluation of concrete dams is essential because of the catastrophic consequences in case of their failure. Concrete buttress dams have a much lower mass than, for example, a corresponding massive gravity dam Both the front-plate and the supporting buttresses are relatively slender, but due to their design the stiffness of a monolith is quite high, resulting in high natural vibration frequencies of the dams and low resistance to cross-stream vibrations. Lokke and Chopra [16] developed a method based on DRM, using the direct finite element (FE) method for viscous boundaries. In this method, effective earthquake forces are applied at nonreflecting boundaries. A deconvolution to transform the earthquake motion from the foundation surface to the corresponding input motion at depth is performed with a new time-domain deconvolution method for both shear and pressure wave propagation based on an iterative procedure using a one-dimensional FE column
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