Search

Your search keyword '"Emdad, Homayoun"' showing total 19 results
Start Over Author "Emdad, Homayoun" Publisher elsevier bv
19 results on '"Emdad, Homayoun"'

1. Wall-modeled large eddy simulation of 90° bent pipe flows with/without particles : A comparative study

Author

Fazeli, Maryam, Emdad, Homayoun, Mehdi Alishahi, Mohammad, Rezaeiravesh, Saleh, Fazeli, Maryam, Emdad, Homayoun, Mehdi Alishahi, Mohammad, and Rezaeiravesh, Saleh

Abstract

Wall-modeled large eddy simulation (WMLES) has been proven to be a cost-effective approach capable of resolving turbulence up to certain resolutions. Among the simplest wall models used are the equilibrium wall models, assuming the pressure gradient and convective terms balance out in the momentum equations. There is a lack of studies to assess the performance of these standard wall models in internal turbulent flows including separation regions with/without particles. Regarding this research gap, we have conducted WMLES of incompressible turbulent flows, to the authors’ knowledge, for the first time, in 90° bent pipes with and without particles using an algebraic equilibrium wall model (Spalding's function). A pipe flow simulation was conducted to confirm the simulation setup and assess the sensitivity with respect to the modeling parameters. In each case, comparisons are made with experiment or direct numerical simulation (DNS), and depending on the case, with other existing simulation methods in the literature: WMLES, standard (wall-resolving) LES, and Reynolds stress model (RSM) for Reynolds-averaged Navier-Stokes (RANS) simulations. Despite the controversy on the performance of equilibrium wall models in nonequilibrium flows, our results show acceptable accuracy of this type of wall models. Specifically in the bent pipe flow with particles, WMLES succeeded in predicting particle deposition efficiency at Stokes numbers greater than 0.5, but obtained less accurate results for smaller Stokes numbers. The WMLES errors were, however, on par with those of the standard LES employed with a tenfold higher grid cell count. Improved results would be expected if combined with auxiliary mechanisms such as stochastic models., QC 20240108

Published
2024
Full Text
View/download PDF

16. Fractal-Markovian scaling of turbulent bursting process in open channel flow

Author

Ali Naghi Ziaei, Alireza Keshavarzi, Amin Shirvani, and Emdad Homayoun

Subjects
Chézy formula, Turbulence, Stochastic process, General Mathematics, Applied Mathematics, Mathematical analysis, General Physics and Astronomy, Markov process, Statistical and Nonlinear Physics, Fractal dimension, Open-channel flow, Physics::Fluid Dynamics, Combinatorics, symbols.namesake, Fractal, Flow velocity, symbols, Mathematics
Abstract

The turbulent coherent structure of flow in open channel is a chaotic and stochastic process in nature. The coherence structure of the flow or bursting process consists of a series of eddies with a variety of different length scales and it is very important for the entrainment of sediment particles from the bed. In this study, a fractal-Markovian process is applied to the measured turbulent data in open channel. The turbulent data was measured in an experimental flume using three-dimensional acoustic Doppler velocity meter (ADV). A fractal interpolation function (FIF) algorithm was used to simulate more than 500,000 time series data of measured instantaneous velocity fluctuations and Reynolds shear stress. The fractal interpolation functions (FIF) enables to simulate and construct time series of u ′, v ′, and u ′ v ′ for any particular movement and state in the Markov process. The fractal dimension of the bursting events is calculated for 16 particular movements with the transition probability of the events based on 1st order Markov process. It was found that the average fractal dimensions of the streamwise flow velocity ( u ′) are; 1.73, 1.74, 1.71 and 1.74 with the transition probability of 60.82%, 63.77%, 59.23% and 62.09% for the 1–1, 2–2, 3–3 and 4–4 movements, respectively. It was also found that the fractal dimensions of Reynold stress u ′ v ′ for quadrants 1, 2, 3 and 4 are 1.623, 1.623, 1.625 and 1.618, respectively.

Published
2005

17. Fractal scaling and simulation of velocity components and turbulent shear stress in open channel flow

Author

Alireza Keshavarzi, Emdad Homayoun, and Ali Naghi Ziaei

Subjects
Turbulence, General Mathematics, Applied Mathematics, General Physics and Astronomy, Reynolds number, Statistical and Nonlinear Physics, Geometry, Fractal dimension, Open-channel flow, Physics::Fluid Dynamics, symbols.namesake, Fractal, Fractal derivative, Flow conditioning, symbols, Froude number, Mathematics
Abstract

Fully developed turbulent flow indeed consists of a hierarchy of eddies or scales of various disorders. Due to the complexity of turbulence, the turbulent flow structure has not been completely understood. Thus, abundant empirical observations have been made about fractality in hydrodynamic turbulence. In this study, the fractal scaling of velocity components (u′, v′) and Reynolds shear stress (u′v′) for fully developed flow in an open channel were studied for Reynolds number in the range of 29,000–85,000. An efficient algorithm was developed to construct Fractal Interpolation Functions (FIF). The algorithm was used to simulate more than 200,000 time series of u′, v′, and u′v′ that were measured in a laboratory flume. The algorithm was also used to compute fractal dimension. The fractal dimensions of the turbulent data were accurately obtained by applying only as few as 500 data points. It was found that the fractal dimension of u′, v′, and u′v′ were 1.615, 1.657, and 1.559, respectively. The relationships between the fractal dimension and Froude number (Fr) and Reynolds number (Re) were also investigated. It was found that the fractal dimension of turbulent data and Re and Fr were reasonably correlated. Moreover, the fractal dimension of Reynolds shear stress in bursting events (outward interaction, ejection, inward interaction, and sweep) was calculated and compared with each other. There were some differences among the fractal dimension of Reynolds shear stress for four quadrants of bursting process. The fractal dimension of u′v′ in sweep and ejection events were more than the fractal dimension of the overall Reynolds shear stress.

Published
2005

Catalog

Books, media, physical & digital resources
See catalog results