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432 results on '"Ghassemi, Hassan"'

151. NUMERICAL INVESTIGATION ON THE EFFECTS OF OBSTRUCTION AND SIDE RATIO ON NON-NEWTONIAN FLUID FLOW BEHAVIOR AROUND A RECTANGULAR BARRIER.

Author

Noferesti, Sara, Ghassemi, Hassan, and Nowruzi, Hashem

Subjects
FLUID flow, DRUG side effects, FINITE volume method, NON-Newtonian fluids, DRAG coefficient, REYNOLDS number
Abstract

In this paper, the characteristics of the flow and forced heat transfer of power law non-Newtonian fluids that flow around a quadrilateral and rectangular cylinder that are located in a 2D channel are investigated by use of the finite volume method (FVM) in a steady state flow regime. To this accomplishment, in the constant temperature, the effects of a different obstruction ratio, aspect ratio and Reynolds number are investigated. The Reynolds number in the range 5 ≤ Re ≤ 40, the power index in the range 0.5 ≤ n ≤ 1.4, the aspect ratio in the range 0.5 ≤ a ≤ 2, and the obstruction ratio in the range 0.125 ≤ b ≤ 0.5 were selected. By surveying the drag coefficient profiles, it's concluded that as the obstruction ratio increases, the drag coefficient is increased, while an increase in the Reynolds number causes the lower drag coefficient. In addition, the drag coefficient is strongly increased by aspect ratio enhancements. [ABSTRACT FROM AUTHOR]

Published
2019
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157. Practical approach to calculating the hydrodynamic oscillating loads of a ship propeller under non-uniform wake field.

Author

Ghassemi, Hassan

Subjects
*HYDRODYNAMICS, *NAVAL architects, *OSCILLATIONS, *SHIP propulsion, *SHIP hydrodynamics
Abstract

Propellers usually operate in the ship's stern, where the inflow of the non-uniform wake generates oscillating loads and changes the hydrodynamic performance. Therefore, determination of the forces on propellers and hydrodynamic performance due to a non-uniform wake field are the challenging problems for naval architects and hydrodynamists. The main objectives of the present study are to assess the hydrodynamic performance for a single blade and all the blades. The propeller is a B-series propeller under non-uniform wake field behind the Seiun-Maru (hereafter SM) ship hull. A practical approach is employed to calculate the hydrodynamic oscillating loads of the ship propeller under a non-uniform wake field. Results of the computations on the propeller behind the SM ship, due to a non-uniform wake field, are presented and analyzed using classical mathematical methods over a single cycle. The results show that a variation of thrust with the discussed parameters is the same as that shown for torque, also the blade-frequency of the total force, thrust and torque is an increasing function of radial sections, whereas these parameters decrease with increasing radial blade sections. [ABSTRACT FROM AUTHOR]

Published
2018
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158. Hydrodynamic performance of the horizontal axis tidal stream turbine using RANS solver.

Author

Ghassemi, Hassan, Ghafari, Hamidreza, and Homayoun, Esmaeil

Subjects
*HYDRODYNAMICS, *HORIZONTAL axis wind turbines, *NUMERICAL analysis, *TIDAL currents, *EXPERIMENTAL design
Abstract

This current work investigates the effect of duct and number of blades on the hydrodynamic performance of the horizontal axis tidal stream turbine (HATST). The numerical method based on Reynolds averaged Navier- Stokes (RANS) equations is employed to compare the hydrodynamic performance for various cases of this device. For validation of the numerical results, a 3-blade HATST without-duct has been compared against experimental data. The analysis and comparison of the simulation results show that using duct for HATST has increased the power coefficient, the torque coefficient, the trust coefficient, and the force on the blade. In addition, the simulation results of the cases with a greater number of blades shows that the trust coefficient increased and the force on the blade decreased. Therefore, it is recommended to use ducted HATST with a great number of blades to extract more energy from the tidal stream. [ABSTRACT FROM AUTHOR]

Published
2018
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159. Using computational fluid dynamic and artificial neural networks to predict the performance and cavitation volume of a propeller under different geometrical and physical characteristics.

Author

Shora, Mohammad Mahdi, Ghassemi, Hassan, and Nowruzi, Hashem

Subjects
*COMPUTATIONAL fluid dynamics, *ARTIFICIAL neural networks, *NAVIER-Stokes equations, *HYDRODYNAMICS, *LARGE eddy simulation models
Abstract

In the current study, simulations of hydrodynamic characteristics of a propeller under different geometrical and physical characteristics are conducted by the computational fluid dynamic (CFD). Then, by designing appropriate artificial neural networks (ANNs), the hydrodynamic performance and cavitation volume of propellers are predicted under intended conditions. For this accomplishment, finite volume-based Navier-Stokes equations associated with incompressible large eddy simulation turbulence model are used. In order to verify the computational procedure, mesh sensitivity analysis and validation study are conducted and appropriate accuracy is observed. In the CFD simulations, propeller thrust, torque and cavitation volume are computed under different pitch ratio (P/D), rake angle (RA) and skew angle (SA), advance velocity ratio (J) and cavitation number (σ). By the CFD results, a significant increase in propeller thrust and torque is observable by enhancement of P/D and positive value of RA. Moreover, maximum mean square errors of ANNs output in the prediction of propeller thrust, torque and cavitation volume achieved are 0.000111, 7.4206E−5 and 0.000667, respectively. Also, related to ANNs’ weights and bias, four set of equations are proposed to predict the performance and cavitation volume of propellers. [ABSTRACT FROM AUTHOR]

Published
2018
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161. Hydrodynamic multidisciplinary optimization of a container ship and its propeller using comprehensive HPSOP code.

Author

Zakerdoost, Hassan and Ghassemi, Hassan

Subjects
*HYDRODYNAMICS, *CONTAINER ships, *MARITIME shipping, *PROPULSION systems, *SHIP propulsion
Abstract

Hydrodynamic shape optimization plays an increasingly important role in the shipping industry. To optimize ship hull and propeller shapes for minimum total (friction+wave) calm-water resistance and maximum open water efficiency, respectively, the main particulars of a hull and propeller model are considered as design variables. The optimization problem is performed by using an integrated hull-propeller system optimization problem (HPSOP) code in a multi-level and multi-point methodology in early-stage ship design. Three numerical methods with variable fidelity are employed to carry out the hydrodynamic performance analysis of a ship's hull and propeller. A ship and its propeller are selected as initial models to illustrate the effectiveness of the proposed optimization procedure. The numerical results show that the developed technique is efficient and robust for hydrodynamic design problems. [ABSTRACT FROM AUTHOR]

Published
2018
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165. Numerical study of step forward swept angle effects on the hydrodynamic performance of a planing hull.

Author

Nourghasemi, Hadi, Bakhtiari, Mohammad, and Ghassemi, Hassan

Subjects
PLANING hulls, COMPUTER simulation, HYDRODYNAMICS, SHIP propulsion, NAVIER-Stokes equations
Abstract

One of the most effective methods to diminish the drag of a planing craft is to use a step at the bottom of the hull. A stepped hull causes a reduction of the wetted area and, as a result, a decrease in the drag. The step may be designed as a straight line through the entire width of the hull or may be V-shaped with a forward or backward swept angle. In this paper, the effects of the step forward swept angle on the hydrodynamic performance of a hard chine planing vessel are investigated by finite volume method (FVM). Reynolds-Averaged Navier Stokes (RANS) equations with a standard k-ε turbulence model coupled with volume of fluid (VOF) equations are solved in order to simulate a transient turbulent free surface flow around the hull with the help of Ansys CFX software. In order to predict hull motions, equations of rigid body motions for two degrees of freedom (2-DOF) are coupled with fluid flow governing equations. To validate the presented numerical model, first the numerical results are compared with available experimental data, and then the obtained numerical results of the drag, dynamic trim, sinkage, wetted keel length, wetted chine length, pressure distribution on the hull, wetted surface and wake profile at different Froude numbers and step angles are presented and discussed. [ABSTRACT FROM AUTHOR]

Published
2017
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166. Data mining models to predict ocean wave energy flux in the absence of wave records.

Author

Mahmoodi, Kumars, Ghassemi, Hassan, and Nowruzi, Hashem

Subjects
*DATA mining, *OCEAN waves, *FLUX (Energy), *RENEWABLE energy sources, *ENVIRONMENTAL impact analysis
Abstract

Ocean wave energy is known as a renewable energy resource with high power potential and without negative environmental impacts. Wave energy has a direct relationship with the ocean's meteorological parameters. The aim of the current study is to investigate the dependency between ocean wave energy flux and meteorological parameters by using data mining methods (DMMs). For this purpose, a feed-forward neural network (FFNN), a cascade-forward neural network (CFNN), and gene expression programming (GEP) are implemented as different DMMs. The modeling is based on historical meteorological and wave data taken from the National Data Buoy Center (NDBC). In all models, wind speed, air temperature, and sea temperature are input parameters. In addition, the output is the wave energy flux which is obtained from the classical wave energy flux equation. It is notable that, initially, outliers in the data sets were removed by the local distribution based outlier detector (LDBOD) method to obtain the best and most accurate results. To evaluate the performance and accuracy of the proposed models, two statistical measures, root mean square error (RMSE) and regression coefficient (R), were used. From the results obtained, it was found that, in general, the FFNN and CFNN models gave a more accurate prediction of wave energy from meteorological parameters in the absence of wave records than the GEP method. [ABSTRACT FROM AUTHOR]

Published
2017
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167. Ship hull–propeller system optimization based on the multi-objective evolutionary algorithm.

Author

Ghassemi, Hassan and Zakerdoost, Hassan

Abstract

The optimization of the hull–propeller system of a ship has always been one of the most important aspects of design in order to reduce the costs, mechanical losses and increase the life of system components. The proposed design methodology represents a comprehensive approach to optimize the hull–propeller system simultaneously. In this study, two objective functions are considered, i.e. lifetime fuel consumption (LFC) and lifetime cost function (Cost). The mission profile of the vessel is adopted to minimize the LFC and Cost over their operational life. The well-known evolutionary algorithm based on NSGA-II is employed to handle the multi-objective problems, where the main propeller and hull coefficients are the unknown and are considered as design variables. The results are presented for a commercial container ship driven by B-series propeller. Three different engines with the same mission profile were taken and the results revealed that the proposed method is an appropriate and effective approach for finding Pareto optimal solutions distributed uniformly and is able to improve both of the objective functions significantly and other performances of the system. [ABSTRACT FROM AUTHOR]

Published
2017
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178. On the solution of linear hydrodynamic stability of dean flow by using three semi-analytical approaches

Author

Nowruzi, Hashem, Salman Nourazar, S., and Ghassemi, Hassan

Abstract

In the present paper, three semi-analytical techniques are examined for solving eigenvalue problem arising from linear hydrodynamics stability of Dean Flow. To this accomplishment, hybrid of Fourier transform and Adomian decomposition method (FTADM), differential transform method (DTM) and Homotopy perturbation method (HPM) is selected and applied on the eigenvalue problem. Semi-analytical results are validated against the existing data with high accuracy. The comparison between FTADM, DTM and HPM reveals that for the same number of truncated terms, the accuracy of the FTADM is more pronounced. This may be attributed to the incorporation of all boundary conditions into our solution when using the FTADM. The results also indicate that the value of wave number (i.e., parameter engaged in our eigenvalue problem) is remarkably impressive on the convergence trend and effectiveness (i.e., the occurrence of becoming nearer to the numerical results) of our solution. In addition, critical wave number and Dean number for the onset of Dean flow instability are successfully reported.

Published
2018
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179. Outlier Detection in Ocean Wave Measurements by Using Unsupervised Data Mining Methods

Author

Mahmoodi, Kumars and Ghassemi, Hassan

Abstract

Outliers are considerably inconsistent and exceptional objects in the data set that do not adapt to expected normal condition. An outlier in wave measurements may be due to experimental and configuration errors, technical defects in equipment, variability in the measurement conditions, rare or unknown conditions such as tsunami, windstorm and etc. To improve the accuracy and reliability of an built ocean wave model, or to extract important and valuable information from collected wave data, detecting of outlying observations in wave measurements is very important. In this study, three typical outlier detection algorithms:Box-plot (BP), Local Distance-based Outlier Factor (LDOF), and Local Outlier Factor (LOF) methods are used to detect outliers in significant wave height (Hs) records. The historical wave data are taken from National Data Buoy Center (NDBC). Finally, those data points are considered as outlier identified by at least two methods which are presented and discussed. Then, Hsprediction has been modelled with and without the presence of outliers by using Regression trees (RTs).

Published
2018
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180. Performance Prediction of the River Craft using Numerical Approach.

Author

Kamarlouei, Mojtaba, Ghassemi, Hassan, and Safaei, Aliakbar

Subjects
*WATER waves, *NUMERICAL analysis, *PREDICTION theory, *PERFORMANCE evaluation, *WATER depth
Abstract

This paper presents the numerical method applied to predict the performance and wave wash of the river craft. In recent years fast ferries have been introduced on many ferry routes all over the world. Mainly when operating in shallow waters and near the coast, the waves generated by these crafts give escalate to clash with recreational use of beaches and coastal waters. The performance of HSC vehicle in these areas and the potential coastal erosion caused by a changed wave impact has been a subject of concern. In this paper, a finite volume method (FVM) and RANS approach was applied to investigate the wave wash, resistance, trim, and pressure acted on the craft. Actually a dynamic mesh with two degrees of freedom was used and the results were compared with a markedly proper experimental results and the competency of applied method was proved. [ABSTRACT FROM AUTHOR]

Published
2015
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188. Numerical Prediction of Wave Patterns Due to Motion of 3D Bodies by Kelvin-Havelock Sources.

Author

Ghassemi, Hassan, Ghamari, Isar, and Ashrafi, Arash

Subjects
*KELVIN'S circulation theorem, *HYDRODYNAMICS, *RANKINE cycle, *ELLIPSOIDS, POTENTIAL distribution
Abstract

This paper discusses the numerical evaluation of the hydrodynamic characteristics of submerged and surface piercing moving bodies. Generally, two main classes of potential methods are used for hydrodynamic characteristic analysis of steady moving bodies which are Rankine and Kelvin-Havelock singularity distribution. In this paper, the Kelvin- Havelock sources are used for simulating the moving bodies and then free surface wave patterns are obtained. Numerical evaluation of potential distribution of a Kelvin-Havelock source is completely presented and discussed. Numerical results are calculated and presented for a 2D cylinder, single source, two parallel moving source, sphere, ellipsoid and standard Wigley hull in different situation that show acceptable agreement with results of other literatures or experiments. [ABSTRACT FROM AUTHOR]

Published
2016
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189. Numerical analysis of the hydrodynamic characteristics of the accelerating and decelerating ducted propeller.

Author

Razaghian, Amir Hossein and Ghassemi, Hassan

Subjects
*HYDRODYNAMICS, *NUMERICAL analysis, *PROPELLERS, *SHEARING force, *SIMULATION methods & models, *AERODYNAMIC load
Abstract

This paper investigates the open-water characteristics of the 5-blade propeller with accelerating and decelerating ducts using the Reynolds-Averaged Navier-Stokes (RANS) equation code. In the first step, numerical open-water hydrodynamic characteristics of the propeller in the absence of a duct were validated using the available experimental data. The shear stress transport (SST) turbulence model was chosen, which shows less error in thrust and torque coefficients than others. In the second step, two accelerating and decelerating ducts, namely ducts 19A and N32, were modeled. In these simulations, the clearance value was selected at 3 percent of the propeller's diameter and uniform-flow conditions were assumed. After analysis of the mesh sensitivity for the propeller thrust, the results were compared to the corresponding open-water condition values. In this regard, results of the hydrodynamic coefficients, pressure distribution, and coefficients on the propeller-blade surface and ducts were also analyzed and discussed. [ABSTRACT FROM AUTHOR]

Published
2016
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190. Boundary Element Method Applied to Added Mass Coefficient Calculation of the Skewed Marine Propellers.

Author

Yari, Ehsan and Ghassemi, Hassan

Subjects
*BOUNDARY element methods, *PROPELLERS, *INERTIA (Mechanics), *COEFFICIENTS (Statistics), *GEOMETRIC analysis
Abstract

The paper mainly aims to study computation of added mass coefficients for marine propellers. A three-dimensional boundary element method (BEM) is developed to predict the propeller added mass and moment of inertia coefficients. Actually, only few experimental data sets are available as the validation reference. Here the method is validated with experimental measurements of the B-series marine propeller. The behavior of the added mass coefficients predicted based on variation of geometric and flow parameters of the propeller is calculated and analyzed. BEM is more accurate in obtaining added mass coefficients than other fast numerical methods. All added mass coefficients are nondimensionalized by fluid density, propeller diameter, and rotational velocity. The obtained results reveal that the diameter, expanded area ratio, and thickness have dominant influence on the increase of the added mass coefficients. [ABSTRACT FROM AUTHOR]

Published
2016
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194. Prediction of impinging spray penetration and cone angle under different injection and ambient conditions by means of CFD and ANNs

Author

Nowruzi, Hashem, Ghassemi, Hassan, Amini, Ebrahim, and Sohrabi-asl, Iman

Abstract

This paper presents a numerical study on 3D non-reacting isothermal impinging spray penetration and cone angle under different injection pressure and ambient conditions. The selected ambient conditions include different nozzle diameters, injection profiles, backpressure and ambient temperature. Transient Eulerian–Lagrangian multiphase solver in open source software, i.e., OpenFOAM, has been used for modeling fuel discrete phase interacting with compressible gaseous continuous phase. In addition, hybrid breakup model of KH–RT and k–εhave been applied as the standard model in Reynolds averaged Navier–Stokes for liquid fuel core breakup and turbulence modeling, respectively. Numerical results of macroscopic spray characteristics have been validated against the experiment. On the other hand, supervised feed-forward artificial neural networks (ANNs) with back-propagation learning algorithm have been designed to predict the average impinging spray penetration and cone angle under five different injection and ambient conditions. Likewise, 51 different CFD patterns have been used as the input evidence in the selected ANNs. To optimize the learning procedure, Levenberg–Marquardt algorithm has been employed. Based on the iterative algorithm, our optimal ANNs have been selected from 260 different architectures. The selected ANNs are able to predict the impinging penetration length with mean square error (MSE) lower than 0.00097 and correlation coefficient higher than 0.98921. Moreover, the selected ANNs for predicting the spray cone angle have maximum MSE of 0.0004 and minimum correlation coefficient of 0.99439. According to weights and bias of the designed ANNs, two set of equations are proposed for predicting the impinging penetration length and cone angle. Moreover, Based on CFD results, longer impinging penetration length and larger cone angle are achieved using higher injection pressure and ambient temperature and lower backpressure.

Published
2017
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195. Determining the Hydrodynamic Loads of the Marine Propeller Forces in Oblique Flow and Off-Design Condition

Author

Shamsi, Reza and Ghassemi, Hassan

Abstract

This paper evaluates hydrodynamic force and moments applied to a marine propeller in oblique and off-design conditions. When a marine propeller operates at an off-design condition, the propeller is usually subjected to unsteady flows which can significantly change the hydrodynamic performance of the propeller. The effect of oblique angles on propeller performance is considered by implementing the numerical simulations. For the purposes of this research, a DTMB propeller is analyzed in different oblique angles. The unsteady calculations are made by applying a Reynolds-averaged Navier–Stokes solver and the sliding mesh method. The method is first verified by a propeller in straight inflow condition. The performance curves of the propellers obtained by numerical method are compared and verified by the experimental results. In the next step, the flow around the propeller in oblique conditions is simulated. The results show, in non-symmetric flow condition, the hydrodynamic forces and moment generated by the propeller become considerably larger.

Published
2017
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196. Systematic probabilistic design methodology for simultaneously optimizing the ship hull–propeller system

Author

Esmailian, Ehsan, Ghassemi, Hassan, and Zakerdoost, Hassan

Abstract

The proposed design methodology represents a new approach to optimize the propeller–hull system simultaneously. In this paper, two objective functions are considered, the first objective function is Lifetime Fuel Consumption (LFC) and the other one is cost function including thrust, torque, open water and skew efficiencies. The variables of the propeller geometries (Z, EAR, P/D and D) and ship hull parameters (L/B, B/T, T and CB) are considered to be optimized with cavitation, blades stress of propeller. The well-known evolutionary algorithm based on NSGA-II is employed to optimize a multi-objective problem, where the main propeller and hull dimensions are considered as design variables. The results are presented for a series 60 ship with B-series propeller. The results showed that the proposed method is an appropriate and effective approach for simultaneously propeller–hull system design and is able to minimize both of the objective functions significantly.

Published
2017
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