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5 results on '"Yoshikatsu, Furusawa"'

1. Stability effect of multidimensional velocity components in numerical flux SLAU

Author

Yoshikatsu Furusawa and Keiichi KITAMURA

Subjects
Mechanics of Materials, Applied Mathematics, Mechanical Engineering, Computational Mechanics, Computer Science Applications
Abstract

In computational fluid dynamics of compressible fluid flow, the simple low-dissipation advection upstream (SLAU) scheme formulated with multidimensional velocity components (normal and parallel to a cell interface) is a widely employed all-speed scheme. As a variant of SLAU, the mSLAU scheme, which adopts only a velocity component normal to the cell interface instead of multidimensional velocity components, is used for rotorcraft calculations. However, although mSLAU has been claimed to be empirically stable, it has been pointed out that using only the cell-interface-normal velocity component instead of the multidimensional velocity components causes numerical instability. Therefore, to clarify the roles of the multidimensional velocity components for computational stability, we solved some benchmark problems associated with using SLAU or mSLAU. We discovered that the multidimensional velocity components contributed to stability against poor-quality grids by isotropically producing enough amount of numerical dissipation, especially in low-subsonic and supersonic flows. Although mSLAU could practically treat moderate Mach number flows (approximately 0.1

Published
2023

2. Numerical Study on Aerodynamic Characteristics of Wing within Propeller Slipstream at Low-Reynolds-Number.

Author

Yoshikatsu FURUSAWA, Keiichi KITAMURA, Tsubasa IKAMI, Hiroki NAGAI, and Akira OYAMA

Subjects
*REYNOLDS number, *PROPELLERS, *MARTIAN atmosphere
Abstract

To realize a propeller-driven Mars airplane, the propeller-wing flow interaction characteristics should be clarified. Thus, we conducted numerical simulations of the propeller-wing interaction at low Reynolds number conditions (Re = 3.0 © 104) corresponding to Mars atmosphere, focusing on the propeller slipstream effects on the fixed wing. Solutions for the tractor case (propeller in front of the fixed wing) and the wing only case were compared. The results showed that in the tractor case, the lift coefficient (CL) of the fixed wing increased with the angle of attack (¡) more linearly than for the wing only case and showed delayed stall because the propeller slipstream favorably suppressed the expansion of the recirculation region over the fixed wing in the time-averaged flow fields, supporting the experimental result. The flow over the fixed wing separated from near the leading-edge in both low and high thrust conditions even at a moderate angle of attack (¡ = 5°), whereas previous studies at relatively high Reynolds numbers (Re = O(105)) showed that almost attached flow fields were formed under the propeller slipstream influence. Additionally, it was observed that the CL fluctuation of the fixed wing increased even when the time-averaged CL was lower than that of the wing only case. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Stability effect of multidimensional velocity components in numerical flux SLAU

Author

Yoshikatsu, Furusawa, Keiichi, Kitamura, Yoshikatsu, Furusawa, and Keiichi, Kitamura

Abstract

In computational fluid dynamics of compressible fluid flow, the simple low-dissipation advection upstream (SLAU) scheme formulated with multidimensional velocity components (normal and parallel to a cell interface) is a widely employed all-speed scheme. As a variant of SLAU, the mSLAU scheme, which adopts only a velocity component normal to the cell interface instead of multidimensional velocity components, is used for rotorcraft calculations. However, although mSLAU has been claimed to be empirically stable, it has been pointed out that using only the cell-interface-normal velocity component instead of the multidimensional velocity components causes numerical instability. Therefore, to clarify the roles of the multidimensional velocity components for computational stability, we solved some benchmark problems associated with using SLAU or mSLAU. We discovered that the multidimensional velocity components contributed to stability against poor-quality grids by isotropically producing enough amount of numerical dissipation, especially in low-subsonic and supersonic flows. Although mSLAU could practically treat moderate Mach number flows (approximately 0.1 < M < 1.0) when coupled with the minmod limiter, using only the cell-interface-normal velocity component can deteriorate convergence of calculations and lead to susceptibility in the grid geometry.

Published
2023

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