The Effects of Grid Accuracy on Flow Simulations: A Numerical Assessment

Allahyari, Majid; Esfahanian, Vahid; Yousefi, Kianoosh

doi:10.3390/fluids5030110

Cited by 7 publications

(3 citation statements)

References 42 publications

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“…The accuracy of the numerical simulation is affected by factors such as grid quality, grid number, and time step size. 39,40 Therefore, the circular nozzle was selected before the formal simulation to explore the influence of different grid numbers and time steps on the simulation results. During the simulation, the water jet axial dynamic pressure, total pressure, and velocity distribution located on the central axis of the nozzle are used as the basis for the analysis of each nozzle jet characteristic.…”

Section: Finite Element Modelingmentioning

confidence: 99%

A new calculation formula to describe the dynamic pressure of water jet peening with elliptical nozzle for high-efficiency treatment

Zheng

Luo

Zhang

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part C:

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Water jet peening is a good potential method to control welding residual stresses. The water jet with elliptical nozzle can improve the treatment efficiency due to its large treatment area. In this article, the water jet velocity and dynamic pressure for different elliptical nozzle dimensions and standoff distances are discussed by numerical simulation. The results show that when the axial distance is 10 mm, the effective impact diameter of the elliptical nozzle a/b=8–12 is about 2 times or more than that of the circular nozzle. The length of the jet core of the elliptical nozzle is only related to the outlet structure and is independent of the inlet pressure. The correlation between the dimensionless core length of the elliptical water jet and its long and short axes is derived. When the ratio of the major axis to the minor axis is between 7 and 13, the core length of the elliptical water jet is 7–7.5 times that of its minor axis. Combining the suitable treatment area and dynamic pressure, the elliptical nozzle with an axis ratio of 8 is recommended to control the welding residual stress. Finally, a new formula for calculating dynamic pressure distribution is proposed for the elliptical nozzle water jet at different stages.

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Section: Finite Element Modelingmentioning

confidence: 99%

A new calculation formula to describe the dynamic pressure of water jet peening with elliptical nozzle for high-efficiency treatment

Zheng

Luo

Zhang

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part C:

View full text Add to dashboard Cite

show abstract

“…Compact FDMs offer additional advantages compared to their non-compact counterparts (see Dennis and Hudson, 1989;Li et al 1995;Cui, 2009;Esfahanian et al 2013, Allahyari et al, 2020. Highorder compact finite difference schemes (Hirsh, 1975;Lele, 1992) are thus widely employed in various fields of computational fluid dynamics.…”

Section: Introductionmentioning

confidence: 99%

A Block–Interface Approach for High–Order Finite–Difference Simulations of Compressible Flows

2021

JAFM

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The application of the high-order accurate schemes with multi-block domains is essential in problems with complex geometries. Primarily, accurate block-interface treatment is found to be of significant importance for precisely capturing discontinuities in such complex configurations. In the current study, a conservative and accurate multi-block strategy is proposed and implemented for a high-order compact finite-difference solver. For numerical discretization, the Beam-Warming linearization scheme is used and further extended for threedimensional problems. Moreover, the fourth-order compact finite-difference scheme is employed for spatial discretization. The capability of the high-order multi-block approach is then evaluated for the onedimensional flow inside a Shubin nozzle, two-dimensional flow over a circular bump, and three-dimensional flow around a NACA 0012 airfoil. The results showed a reasonable agreement with the available exact solutions and simulation results in the literature. Further, the proposed block-interface treatment performed quite well in capturing shock waves, even in situations that the location of the shock coincides with block interfaces.

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“…These two reasons make the solution convergence difficult or even impossible in most cases. Please note that the dependence of the flow accuracy and the quality of the mesh in N-S solvers as been widely explored in the past, e.g., [1,2].…”

Section: Introductionmentioning

confidence: 99%

Simulations of Aerodynamic Separated Flows Using the Lattice Boltzmann Solver XFlow

et al. 2020

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We present simulations of turbulent detached flows using the commercial lattice Boltzmann solver XFlow (by Dassault Systemes). XFlow’s lattice Boltzmann formulation together with an efficient octree mesh generator reduce substantially the cost of generating complex meshes for industrial flows. In this work, we challenge these meshes and quantify the accuracy of the solver for detached turbulent flows. The good performance of XFlow when combined with a Large-Eddy Simulation turbulence model is demonstrated for different industrial benchmarks and validated using experimental data or fine numerical simulations. We select five test cases: the Backward-facing step the Goldschmied Body the HLPW-2 (2nd High-Lift Prediction Workshop) full aircraft geometry, a NACA0012 under dynamic stall conditions and a parametric study of leading edge tubercles to improve stall behavior on a 3D wing.

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The Effects of Grid Accuracy on Flow Simulations: A Numerical Assessment

Cited by 7 publications

References 42 publications

A new calculation formula to describe the dynamic pressure of water jet peening with elliptical nozzle for high-efficiency treatment

A new calculation formula to describe the dynamic pressure of water jet peening with elliptical nozzle for high-efficiency treatment

A Block–Interface Approach for High–Order Finite–Difference Simulations of Compressible Flows

Simulations of Aerodynamic Separated Flows Using the Lattice Boltzmann Solver XFlow

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