Numerical Computation for Modified Cross Model Fluid Flow Around the Circular Cylinder with Symmetric Trapezoidal Cavities

Mahmood, Rashid; Siddique, Imran; Khan, Ilyas; Badran, Mohamed M.; Mehrez, Sadok; Majeed, Afraz Hussain; Naaz, Sehrish

doi:10.3389/fphy.2022.912213

Cited by 8 publications

(3 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Mahmood et al 29 investigated the properties of flow of modified Cross model (MCM) using finite element method. The hydrodynamic forces are computed for a variety of parameters involved.…”

Section: Introductionmentioning

confidence: 99%

AI-based predictive approach via FFB propagation in a driven-cavity of Ostwald de-Waele fluid using CFD-ANN and Levenberg–Marquardt

Refaie Ali,

Mahmood,

Asghar

et al. 2024

Sci Rep

Self Cite

View full text Add to dashboard Cite

The integration of Artificial Intelligence (AI) and Machine Learning (ML) techniques into computational science has ushered in a new era of innovation and efficiency in various fields, with particular significance in computational fluid dynamics (CFD). Several methods based on AI and Machine Learning (ML) have been standardized in many fields of computational science, including computational fluid dynamics (CFD). This study aims to couple CFD with artificial neural networks (ANNs) to predict the fluid forces that arise when a flowing fluid interacts with obstacles installed in the flow domain. The momentum equation elucidating the flow has been simulated by adopting the finite element method (FEM) for a range of rheological and kinematic conditions. Hydrodynamic forces, including pressure drop between the back and front of the obstacle, surface drag, and lift variations, are measured on the outer surface of the cylinder via CFD simulations. This data has subsequently been fed into a Feed-Forward Back (FFB) propagation neural network for the prediction of such forces with completely unknown data. For all cases, higher predictivity is achieved for the drag coefficient (CD) and lift coefficient (CL) since the mean square error (MSE) is within ± 2% and the coefficient of determination (R) is approximately 99% for all the cases. The influence of pertinent parameters like the power law index (n) and Reynolds number (Re) on velocity, pressure, and drag and lift coefficients is also presented for limited cases. Moreover, a significant reduction in computing time has been noticed while applying hybrid CFD-ANN approach as compared with CFD simulations only.

show abstract

“…Mahmood et al 29 investigated the properties of flow of modified Cross model (MCM) using finite element method. The hydrodynamic forces are computed for a variety of parameters involved.…”

Section: Introductionmentioning

confidence: 99%

AI-based predictive approach via FFB propagation in a driven-cavity of Ostwald de-Waele fluid using CFD-ANN and Levenberg–Marquardt

Refaie Ali,

Mahmood,

Asghar

et al. 2024

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…For dynamic analysis of an electromagnetic pneumatic fow servo valve, Rashid et al evaluated diferent fow features for a modifed cross-model fuid fow, which aims to analyze the parameters and choose accurate solutions. A wide range of parameters and coefcients of drag and lift had been performed [23,24]. Shi et al proposed a transfer feature learning method that applied a new method to achieve the acquired parameters and dynamic characteristics of the valve [25,26].…”

Section: Introductionmentioning

confidence: 99%

Finite Element Modeling and Optimal Design of an Electromagnetic Pneumatic Flow Servo Valve

Zedan

Guo²,

Zhu

et al. 2023

Mathematical Problems in Engineering

View full text Add to dashboard Cite

The electromagnet pneumatic proportional servo valve is widely used in industrial automation, medical equipment, scientific composition detectors, and other fields that require precise adjustment of high-pressure air flow due to its simple working structure, large output power, large working frequency response, and good control performance. However, the output pressure of the valve is small, making it vulnerable to the impact of the external environment. Based on the practical electromagnet-type pneumatic proportional servo valve, this paper establishes a finite element dynamic mathematical model, conducts finite element analysis on the electromagnet magnetic field in the valve, then improves the structural parameters of the original proportional valve through the analysis of the valve performance parameters and structural optimization, and finally, the physical experiment proves that the optimized electric proportional valve can effectively reduce the hysteresis within the working pressure range and has good response characteristics to step signals. This paper can provide support for performance analysis and structural parameter improvement of the electric proportional valve.

show abstract

“…Te seepage mechanism is complex for low-permeability oil reservoirs. It is difcult to exploit low-permeability reservoirs because of low-permeability characteristics [1,2]. Since lowpermeability characteristics have complex pore structures, some scholars have studied the seepage mechanism of complex pore throat structures using fnite element simulation [3,4].…”

Section: Introductionmentioning

confidence: 99%

A Semianalytical Mathematical Model and Seepage Characteristics of Off‐Center Fractured Vertical Wells with Multiwing Asymmetrical Fractures

Wang

et al. 2023

Mathematical Problems in Engineering

View full text Add to dashboard Cite

The complexity of formation conditions leads to multiwing asymmetric fractures after large-scale fracturing. According to a well pattern model and reservoir characteristics, a testing well is away from the center of the reservoir, and the existing well-test mathematical model cannot meet the field data analysis demand. Therefore, the mathematical model for the fractured wells with multiwing asymmetrical fractures is established. The model solution of the Laplace domain is obtained by the Laplace transform, nonuniform fracture discretization, and pressure drop superposition principle. The model is compared with the numerical model in this paper, and the result shows that the presented semianalytical model and the calculation method are correct. The eight main flow stages are divided according to pressure derivative characteristics and the seepage process of off-center fractured vertical wells with multiwing asymmetrical fractures. The larger off-center distance will lead to higher pressures and derivative curves. Larger fracture asymmetry factors are higher pressures and derivative curves during bilinear and linear flow regimes. The field data show that the model is applicable and that the model can give the guidance of fractured well formation evaluation.

show abstract

Numerical Computation for Modified Cross Model Fluid Flow Around the Circular Cylinder with Symmetric Trapezoidal Cavities

Cited by 8 publications

References 24 publications

AI-based predictive approach via FFB propagation in a driven-cavity of Ostwald de-Waele fluid using CFD-ANN and Levenberg–Marquardt

AI-based predictive approach via FFB propagation in a driven-cavity of Ostwald de-Waele fluid using CFD-ANN and Levenberg–Marquardt

Finite Element Modeling and Optimal Design of an Electromagnetic Pneumatic Flow Servo Valve

A Semianalytical Mathematical Model and Seepage Characteristics of Off‐Center Fractured Vertical Wells with Multiwing Asymmetrical Fractures

Contact Info

Product

Resources

About