Showing total 7 results

1. Efficient and accurate exponential SAV algorithms with relaxation for dissipative system.

Author

Zhang, Yanrong and Li, Xiaoli

Subjects

*NAVIER-Stokes equations, *LINEAR systems, *ALGORITHMS, *COMPUTER simulation, *CAHN-Hilliard-Cook equation

Abstract

In this paper, we construct two kinds of exponential SAV approach with relaxation (R-ESAV) for dissipative system. The constructed schemes are linear and unconditionally energy stable. They can guarantee the positive property of SAV without any assumption compared with R-SAV and R-GSAV approaches, preserve all the advantages of the ESAV approach and satisfy dissipation law with respect to a modified energy which is directly related to the original free energy. We also give the rigorous consistency estimates of the constructed schemes for the L 2 gradient flows. Moreover, the second version of R-ESAV approach is easy to construct high-order BDF k schemes. Especially for Navier–Stokes equations, we construct two kinds of novel schemes based on the R-ESAV method. Finally, ample numerical examples are presented to exhibit that the proposed approaches are accurate and effective. • R-ESAV schemes can improve the accuracy of the solution significantly compared with the original ESAV approach. • We construct two kinds of novel schemes based on the R-ESAV method for Navier–Stokes equations. • Only one linear system with constant coefficients at each time step needs to be solved. • The positive property of SAV without any assumption can be guaranteed. • Numerical simulations are tested to show that the modified energy equals to the original free energy at almost all times. [ABSTRACT FROM AUTHOR]

Published

2023

2. Investigation on the effect of trailing edge ejection on a turbine cascade

Author

Wang, Yangang and Zhao, Longbo

Subjects

*TRAILING edges (Aerodynamics), *TURBINE aerodynamics, *CASCADES (Fluid dynamics), *NAVIER-Stokes equations, *COMPUTER simulation, *TURBULENCE, *MATHEMATICAL models, *ALGORITHMS

Abstract

Abstract: This paper presents a detailed experimental and numerical investigation for a turbine cascade with different trailing edge ejection. The numerical simulation is based on Three-Dimensional Navier–Stokes equations coupled with an effective ejection model, where a high resolution non-oscillatory scheme, LU-SGS implicit algorithm and Baldwin-Lomax turbulence model are employed. The experiments presented in this paper focused on a transonic turbine cascade performance with different ejection to validate the numerical simulation results. The results show that the blowing ratio has a small effect on the Mach number distribution and exit flow angle with two slot types. However the energy loss coefficient increases initially, and subsequently has a decrease tendency with the increasing of blowing ratio. The ejection from the symmetry slot blows away the vortex at the blade trailing edge and strengthens the mixing between the wake and main flow. The ejection from the pressure side cutback only clears up the vortex near the slot surface, and has small effect on the flow field near the trailing edge. [Copyright &y& Elsevier]

Published

2013

3. NUMERICAL UNDERSTANDING OF THE SELF-INDUCED OSCILLATION OF FLOW PAST THE OPEN CAVITY WITH A STORE.

Author

SI, HAI-QING and WANG, TONG-GUANG

Subjects

*TURBULENCE, *NUMERICAL analysis, *NAVIER-Stokes equations, *COMPUTER simulation, *VISCOSITY, *FOURIER transforms, *SPECTRAL energy distribution, *ALGORITHMS, *REYNOLDS number

Abstract

The flows around a typical open cavity with a store are numerically simulated in this paper. A fully implicit unfactored method is employed in the solver of RANS equations, where the S-A turbulent model is implemented to calculate the turbulent eddy viscosity. The flow-induced oscillation of the free shear layer around the cavity lip is captured and analyzed. Comparisons for the different cases of the cavity flow are made. The calculated results show that the pressure fluctuation is pertinent to the different positions of the store inside the cavity. The power spectral density (PSD) of the pressure by fast Fourier transformations (FFT) is also displayed in the paper. For the Rossiter's oscillatory mode, the numerical results compare well with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2010

4. Grid-Generation Algorithms for Complex Glaze-Ice Shapes Reynolds-Averaged Navier-Stokes Simulations.

Author

Hasanzadeh, K., Laurendeau, E., and Paraschivoiu, I.

Subjects

*NUMERICAL grid generation (Numerical analysis), *NAVIER-Stokes equations, *ALGORITHMS, *GLAZE (Meteorology), *REYNOLDS number, *COMPUTER simulation

Abstract

The paper presents the developments of novel mesh generation algorithms over complex glaze-ice shapes containing multicurvature ice-accretion geometries, such as single/double ice horns. The twofold approaches tackle surface geometry discretization as well as field mesh generation. First, an adaptive curvilinear curvature control algorithm is constructed, solving a one-dimensional elliptic partial differential equation with periodic source terms. This method controls the arc length grid spacing, so that high convex and concave curvature regions around ice horns are appropriately captured, and is shown to effectively treat the grid shock problem. Second, a novel blended method is developed by defining combinations of source terms with two-dimensional elliptic equations. The source terms include two common control functions, Sorenson and Spekreijse, and an additional third source term to improve orthogonality. This blended method is shown to be very effective for improving grid quality metrics for complex glaze-ice meshes with Reynolds-averaged Navier-Stokes resolution. The performance in terms of residual reduction per nonlinear iteration of several solution algorithms (point-Jacobi, Gauss-Seidel, alternating direction implicit, point, and line Successive Over-Relaxation) are discussed within the context of a full multigrid operator. Details are given on the various formulations used in the linearization process. It is shown that this performance of the solution algorithm depends on the type of control function used. Finally, the algorithms are validated on standard complex experimental ice shapes, demonstrating the applicability of the methods. [ABSTRACT FROM AUTHOR]

Published

2016

5. Fully-implicit log-conformation formulation of constitutive laws.

Author

Knechtges, Philipp, Behr, Marek, and Elgeti, Stefanie

Subjects

*NUMERICAL solutions to partial differential equations, *CONFORMATIONAL analysis, *NAVIER-Stokes equations, *NEWTON-Raphson method, *ALGORITHMS, *COMPUTER simulation

Abstract

Subject of this paper is the derivation of a new constitutive law in terms of the logarithm of the conformation tensor that can be used as a full substitute for the 2D governing equations of the Oldroyd-B, Giesekus and other models. One of the key features of these new equations is that – in contrast to the original log-conf equations given by Fattal and Kupferman (2004) – these constitutive equations combined with the Navier–Stokes equations constitute a self-contained, non-iterative system of partial differential equations. In addition to its potential as a fruitful source for understanding the mathematical subtleties of the models from a new perspective, this analytical description also allows us to fully utilize the Newton–Raphson algorithm in numerical simulations, which by design should lead to reduced computational effort. By means of the confined cylinder benchmark we will show that a finite element discretization of these new equations delivers results of comparable accuracy to known methods. [ABSTRACT FROM AUTHOR]

Published

2014

6. Numerical simulation of an oscillating water column device using a code based on Navier–Stokes equations.

Author

Teixeira, Paulo R.F., Davyt, Djavan P., Didier, Eric, and Ramalhais, Rubén

Subjects

*OCEAN wave power, *COMPUTER simulation, *NAVIER-Stokes equations, *ALGORITHMS, *INCOMPRESSIBLE flow, MATHEMATICAL models of aerodynamics

Abstract

Abstract: The study of ways of converting ocean wave energy into a useful one and the improvement of the existing equipment are complex engineering problems and very important issues in today's society. In this paper, the onshore oscillating water column device, in a 10 m deep channel subjected to 1 m high incident wave and wave periods from 4 s to 15 s, is investigated. The numerical analyses are carried out using Fluinco model that deals with incompressible flow problems based on the Navier–Stokes equations and employs the two-step semi-implicit Taylor–Galerkin method. An aerodynamic model is implemented in the algorithm to determine the air pressure that is imposed on the free surface. Analyses are divided into two sections. In the first section, the flow variables obtained by Fluinco and the commercial model Fluent are compared and similar results are obtained. In the second section, an investigation of the chamber geometry and turbine characteristic relation that provide the best device performance is carried out. In this case, variations in the front wall depth, the chamber length, the turbine characteristic relation and the chamber height, are made. [Copyright &y& Elsevier]

Published

2013

7. Block-Jacobi Implicit Algorithms for the Time Spectral Method.

Author

Sicot, Frédéric, Puigt, Guillaume, and Montagnac, Marc

Subjects

*ALGORITHMS, *STOCHASTIC convergence, *FOURIER analysis, *JACOBI method, *COMPUTER simulation, *NAVIER-Stokes equations, *UNSTEADY flow, *TIME-domain analysis

Abstract

Many industrial applications involve flows periodic in time. Such flows are not simulated with enough efficiency when using classical unsteady techniques, as a transient regime must be bypassed. New techniques, dedicated to time- periodic flows and based on Fourier analysis, have been developed recently. Among these, the time spectral method casts a time-periodic flow computation in several coupled steady computations, corresponding to a uniform sampling of the period. Up until now, the steady states were reached using an explicit pseudotime algorithm. Thus, very small time steps were needed and the convergence rate slowed down when increasing the number of harmonics. In this paper, a block-Jacobi approach is presented to solve the stationary problems with an implicit algorithm. Numerical simulations show, on one hand, the good quality of the results and, on the other hand, the interest of the proposed method to reduce the sensitivity of computations to a large number of harmonics. [ABSTRACT FROM AUTHOR]

Published

2008