Yuto Otoguro scite author profile

We focus on turbocharger computational flow analysis with a method that possesses higher accuracy in spatial and temporal representations. In the method we have developed for this purpose, we use a combination of i) the Space-Time Variational Multiscale (ST-VMS) method, which is a stabilized formulation that also serves as a turbulence model, ii) the ST Slip Interface (ST-SI) method, which maintains high-resolution representation of the boundary layers near spinning solid surfaces by allowing in a consistent fashion slip at the interface between the mesh covering a spinning surface and the mesh covering the rest of the domain, and iii) the Isogeometric Analysis (IGA), where we use NURBS basis functions in space and time. The basis functions are spatially higher-order in all representations, and temporally higher-order in representation of the solid-surface and mesh motions. The ST nature of the method gives us higher-order accuracy in the flow solver, and when combined with temporally higher-order basis functions, a more accurate representation of the surface motion, and a mesh motion consistent with that. The spatially higher-order basis functions give us again higher-order accuracy in the flow solver, a more accurate, in some parts exact, representation of the surface geometry, and better representation in evaluating the second-order spatial derivatives. Using NURBS ⇤

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Space–time VMS computational flow analysis with isogeometric discretization and a general-purpose NURBS mesh generation method

Otoguro

Takizawa

Tezduyar

2017

Computers & Fluids

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Turbocharger turbine and exhaust manifold flow computation with the Space–Time Variational Multiscale Method and Isogeometric Analysis

et al. 2019

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A General-Purpose NURBS Mesh Generation Method for Complex Geometries

Otoguro

Takizawa

Tezduyar

2018

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Computational analysis of flow-driven string dynamics in a pump and residence time calculation

Komiya

Kanai

Otoguro

et al. 2019

IOP Conf. Ser.: Earth Environ. Sci.

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Yuto Otoguro

Turbocharger flow computations with the Space–Time Isogeometric Analysis (ST-IGA)

Space–time VMS computational flow analysis with isogeometric discretization and a general-purpose NURBS mesh generation method

Turbocharger turbine and exhaust manifold flow computation with the Space–Time Variational Multiscale Method and Isogeometric Analysis

A General-Purpose NURBS Mesh Generation Method for Complex Geometries

Computational analysis of flow-driven string dynamics in a pump and residence time calculation

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