High-speed and accurate simulations of landslide-generated tsunamis are of great importance for the understanding of generation and propagation of water waves and for prediction of these natural disasters. A three-dimensional numerical model, based on Reynolds-averaged Navier–Stokes equations, is developed to simulate the landslide-generated tsunami. Available experiment data is used to validate the numerical model and to investigate the scale effect of numerical model according to the Froude similarity criterion. Based on grid convergence index (GCI) analysis, fourteen cases are arranged to study the sensitivity of numerical results to mesh resolution. Results show that numerical results are more sensitive to mesh resolution in near field than that in the propagation field. Nonuniform meshes can be used to balance the computational efficiency and accuracy. A mesh generation strategy is proposed and validated, achieving an accurate prediction and nearly 22 times reduction of computational cost. Further, this strategy of mesh generation is applied to simulate the Laxiwa Reservoir landslide tsunami. The results of this study provide an important guide for the establishment of a numerical model of the real-world problem of landslide tsunami.
The microstructure and mechanical properties of the deposited metals of five metal cored wires for welding 600-900 MPa ultralow carbon bainitic steels were investigated. It was found that lowering the C content and optimising the Mn, Ni, Mo and Cr contents of the deposited metal significantly improved the strength and toughness. At the lowest strength level (627 MPa), ferrite dominated, mainly acicular ferrite and proeutectoid ferrite. However, at the highest strength level (.800 MPa), bainite dominated, mainly degenerate upper bainite and granular bainite. Good strength toughness match was achieved by a deposited metal having an interlaced multiphase microstructure with degenerate upper bainite and martensite acting as main strengthening phases, and granular bainite and acicular ferrite acting as toughening phases.
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