2020-06-02T22:46:27Z
http://jacm.scu.ac.ir/?_action=export&rf=summon&issue=1911
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Viscoelastic Micropolar Convection Flows from an Inclined Plane with Nonlinear Temperature: A Numerical Study
S.
Abdul Gaffar
P.
Ramesh Reddy
V.
Ramachandra Prasad
A.
Subba Rao
B. Md. Hidayathulla
Khan
An analytical model is developed to study the viscoelastic micropolar fluid convection from an inclined plate as a simulation of electro-conductive polymer materials processing with nonlinear temperature. Jeffery’s viscoelastic model is deployed to describe the non-Newtonian characteristics of the fluid and provides a good approximation for polymers. Micro-structural is one of the characteristics of non-Newtonian fluid that represents certain polymers, which constitutes a novelty of the present work. The normalized nonlinear boundary value problem is solved computationally with the Keller-Box implicit finite-difference technique. Extensive solutions for velocity, surface temperature, angular velocity, skin friction, heat transfer rate and wall couple stress are visualized numerically and graphically for various thermophysical parameters. Validation is conducted with earlier published work for the case of a vertical plate in the absence of viscous dissipation, chemical reaction and non-Newtonian effects. This particle study finds applications in different industries like reliable equipment design, nuclear plants, paint spray, thermal fabrication, water-based gel solvents, polymeric manufacturing process, gas turbines and different propulsion devices.
Viscoelastic fluid
Micropolar Fluid
Nonlinear Temperature
Retardation time
Vorticity
2020
04
01
183
199
http://jacm.scu.ac.ir/article_14296_bb014b40dd323f5984e72b340333153b.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Exact Solution for Nonlinear Local Fractional Partial Differential Equations
Djelloul
Ziane
Mountassir
Hamdi Cherif
Dumitru
Baleanu
Kacem
Belghaba
In this work, we extend the existing local fractional Sumudu decomposition method to solve the nonlinear local fractional partial differential equations. Then, we apply this new algorithm to resolve the nonlinear local fractional gas dynamics equation and nonlinear local fractional Klein-Gordon equation, so we get the desired non-differentiable exact solutions. The steps to solve the examples and the results obtained, showed the flexibility of applying this algorithm, and therefore, it can be applied to similar examples.
Adomian decomposition method
Sumudu transform method
Local fractional derivative operator
Local fractional
Nonlinear local fractional gas dynamics equation
Nonlinear local fractional Klein-Gordon equation
2020
04
01
200
208
http://jacm.scu.ac.ir/article_14550_b9fbc3b03e787b53897af757aa0fa2c9.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Effect of Corrugated Baffles on the Flow and Thermal Fields in a Channel Heat Exchanger
Houari
Ameur
The performance of corrugated baffles inserted in a rectangular channel heat exchanger is investigated. The fluid flows and thermal distribution are determined via numerical simulations. The working fluid has a shear thinning behavior. The influence of the baffle design is explored, we interest to the “wavy” shape. The corrugation angle of baffle (<em>α</em>) is changed from 0° (i.e. a straight baffle) to 45°. Also, the height (<em>h</em>) of the corrugated baffle is changed and three cases are considered, namely: <em>h/H</em> = 0.4, 0.5 and 0.6, where “<em>H</em>” is the channel height. In comparison with the unbaffled channel, the overall performance factor has increased from 1.27 up to 1.53 when the corrugation angle is increased from 0° to 45°. Concerning the corrugation height, the predicted results allowed us to select the case <em>h/H</em> = 0.5 as the best configuration from the cases studied.
Heat exchanger
Corrugated baffles
Baffle design
Laminar flow
Non-Newtonian fluids
2020
04
01
209
218
http://jacm.scu.ac.ir/article_14531_785a8f150d172eb143fc866195246a40.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Efficient Solution of Nonlinear Duffing Oscillator
Iman
Khatami
Ehsan
Zahedi
Mohsen
Zahedi
In this paper, the efficient multi-step differential transform method (EMsDTM) is applied to get the accurate approximate solutions for strongly nonlinear duffing oscillator. The main improvement of EMsDTM which is to reduce the number of arithmetic operations, is thoroughly investigated and compared with the classic multi-step differential transform method (MsDTM). To illustrate the applicability and accuracy of the new method, six case studies of the free undamped and forced damped conditions are considered. The periodic response curves of both MsDTM and EMsDTM methods are obtained and contrasted with the exact solution or the numerical solution of Runge Kutta 4<sup>th</sup> order (RK4) method. This approach can be easily extended to other nonlinear systems and therefore is widely applicable in engineering and other sciences.
Efficient multi-step transforms method
Duffing oscillator
Nonlinear equation
Differential transformation method
2020
04
01
219
234
http://jacm.scu.ac.ir/article_14428_f7aa848cda780cf38498e06079a75b23.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Implicit RBF Meshless Method for the Solution of Two-dimensional Variable Order Fractional Cable Equation
Akbar
Mohebbi
Marziyeh
Saffarian
In the present work, the numerical solution of two-dimensional variable-order fractional cable (VOFC) equation using meshless collocation methods with thin plate spline radial basis functions is considered. In the proposed methods, we first use two schemes of order O(τ<sup>2</sup>) for the time derivatives and then meshless approach is applied to the space component. Numerical results obtained from solving considered model on regular and irregular domains, demonstrate the accuracy and efficiency of the proposed schemes.
Variable order fractional cable equation
Meshless method
Radial basis functions
Thin plate spline
2020
04
01
235
247
http://jacm.scu.ac.ir/article_14509_1912c71c376dc776522713124f8da483.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
On the Influence of Riveting Process Parameters on Fatigue Life of Riveted Lap Joint
Pedram
Zamani
Khalil
Farhangdoost
In this paper, influence of riveting process parameters, namely, riveting force, sheet thickness, friction coefficient and clearance fit are investigated on residual stress field and fatigue life of single riveted lap joint of AA2024 type. According to the effect of riveting induced residual stresses on fatigue life of riveted lap joint, these parameters are optimized to maximize the residual stress field. For this purpose, finite element simulations are performed for various combinations of the parameters according to Taguchi design of experiments. Afterwards, the parameter combination that maximize the residual stress field and the most effective parameters are obtained. The joint with maximum residual stress field is considered to have a semi-elliptical crack emanating from the rivet hole as an initial defect. Stress intensity factors are calculated by implementing two approaches: First, formulation overview that considers the effect of residual stress field, geometry and secondary bending, and second, the finite element method. The fatigue life of the joint is estimated using the obtained stress intensity factors and Paris-Erdogan rule. Finally, good accordance is found between results of these two approaches.
Single lap joint
Residual stress
Stress intensity factor
Taguchi method
Fatigue life
Paris-Erdogan rule
2020
04
01
248
258
http://jacm.scu.ac.ir/article_14533_911a0f6ba088b183cbbc6bc5f6fd2076.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Unsteady Hydromagnetic Flow of Eyring-Powell Nanofluid over an Inclined Permeable Stretching Sheet with Joule Heating and Thermal Radiation
Bharath
Kumar
Suripeddi
Srinivas
The present analysis deals with an unsteady magnetohydrodynamic flow of Eyring-Powell nanofluid over an inclined permeable stretching sheet. Effects of thermal radiation, Joule heating, and chemical reaction are considered. The effects of Brownian motion and thermophoresis on the flow over the permeable stretching sheet are discussed. Using Runge-Kutta fourth-order along with shooting technique, numerical and graphical results were obtained for the governing flow equations. The influence of various parameters on flow variables have been examined in detail. The results reveal that the temperature of the fluid enhanced with increasing Brownian and thermophoresis parameters. The increase of fluid velocity with the local Grashof number, the solutal Grashof number has been noticed. Further, the nanoparticles concentration decreased for a given increase in Brownian motion and chemical reaction parameters, while it increased with an increase in the thermophoresis parameter.
Chemical reaction
Eyring-Powell nanofluid
Hartmann number
Inclined stretching sheet
Joule heating
2020
04
01
259
270
http://jacm.scu.ac.ir/article_14580_81175fa2eddf2a1c75c8edac8f860396.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Numerical Simulation of Non-Newtonian Inelastic Flows in Channel based on Artificial Compressibility Method
Reisan Y.
Yasir
Alaa H.
Al-Muslimawi
Bashaeer K.
Jassim
In this study, inelastic constitutive modelling is considered for the simulation of shear-thinning fluids through a circular channel. Numerical solutions are presented for power-law inelastic model, considering axisymmetric Poiseuille flow through a channel. The numerical simulation of such fluid is performed by using the Galerkin finite element approach based on artificial compression method (<em>AC</em>-method). Usually, the Naiver-Stoke partial differential equations are used to describe fluid activity. These models consist of two partial differential equations; a continuity equation (mass conservation) and time-dependent conservation of momentum, which are maintained in the cylindrical coordinate system (axisymmetric) flow in current study. The effects of many factors such as Reynolds number (<em>Re</em>) and artificial compressibility parameter (ß<sub>ac</sub>) are discussed in this study. In particular, this study confirms the effect of these parameters on the convergence level. To meet the method analysis, Poiseuille flow along a circular channel under an isothermal state is used as a simple test problem. This test is conducted by taking a circular section of the pipe. The Findings reveal that, there is a significant effect from the inelastic parameters upon the the velocity temporal convergence-rates of velocity, while for pressue, the change in convergence is modest. In addition, the rate of convergence is increased as the values of artificial compressibility parameter (ß<sub>ac</sub>) are decreased.
Finite element method
Galerkin method
Naiver-Stoke
Non-Newtonian
Artificial compressibility method
2020
04
01
271
283
http://jacm.scu.ac.ir/article_14699_fe042cf6c8c12d9b83d37e24cc9df375.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Effect of Coating Materials on the Fatigue Behavior of Hip Implants: A Three-dimensional Finite Element Analysis
Ayham
Darwich
Hasan
Nazha
Monzer
Daoud
This study aims to validate, using finite element analysis (FEA), the design concept by comparing the fatigue behavior of hip implant stems coated with composite (carbon/PEEK) and polymeric (PEEK) coating materials corresponding to different human activities: standing up, normal walking and climbing stairs under dynamic loadings to find out which of all these models have a better performance in the prosthesis-bone systems. A 3D finite element models of hip implants, femur, coating layers with polymeric (PEEK) and composite (carbon/PEEK) coating materials are created for FEA. The cyclic loads are applied on the prosthesis head. Fatigue life durations are calculated based on the Goodman mean-stress fatigue theory. The fatigue safety factor for the coated implant is increased more than 12.73% at least compared to the uncoated implant. The carbon/PEEK composite material with 0, +45, -45, and 90 degrees fiber orientation (configuration I) has the highest fatigue life and fatigue safety factor. The numerical result show that the carbon/PEEK composite material (configuration I) seems to be a good solution to increase the values of fatigue safety factor of coating layers due to highest fatigue life and fatigue safety factor. It distributes the applied load and transfers it to the bone, reducing stress-shielding effects and prolong the bone-prosthesis system life span.
Hip implants
Coatings
PEEK
Carbon/PEEK
Fatigue behavior
Finite element analysis
2020
04
01
284
295
http://jacm.scu.ac.ir/article_14665_ff5fa2d4a2b55ceaf5c2de49b243b588.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Slip Effects on Ohmic Dissipative Non-Newtonian Fluid Flow in the Presence of Aligned Magnetic Field
P.
Renuka
B.
Ganga
K.
Kalivanan
A.K.
Abdul Hakeem
The present paper deals with the effects of Ohmic dissipative Casson fluid flow over a stretching sheet in the presence of aligned magnetic field. The present phenomenon also includes the interaction of thermal radiation and velocity slip. The governing boundary layer equations are transformed into a set of ordinary differential equations using the similarity transformations. The dimensionless velocity and temperature profiles are solved analytically using hypergeometric function and numerically by using fourth order Runge-Kutta method with shooting technique. It is noted that the increasing values of Eckert number increases the temperature profile and decreases the local Nusselt number.
Aligned magnetic field
Casson Fluid
Slip
Thermal radiation
Ohmic dissipation
2020
04
01
296
306
http://jacm.scu.ac.ir/article_14453_59762e7463c4b61369230d184fd00277.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Mesoscopic Simulation of Forced Convective Heat Transfer of Carreau-Yasuda Fluid Flow over an Inclined Square: Temperature-dependent Viscosity
Ali
Jalali
Amin
Amiri Delouei
Mojtaba
Khorashadizadeh
A.M.
Golmohamadi
Sajjad
Karimnejad
<span>In the current study, non-Newtonian flow pattern and heat transfer in an enclosure containing a tilted square are examined. In order to numerically simulate the problem, the mesoscopic lattice Boltzmann method is utilized. The non-Newtonian Carreau-Yasuda model is employed. It is able to adequately handle the shear-thinning case. The simulation results of flow and heat transfer have been successfully verified with the previous studies. Several parameters such as Nusselt number, Drag coefficient, and Carreau number are investigated in details. Considering the temperature-dependent viscosity, it is seen that with increasing the</span><span>temperature-thinning index, the drag coefficient increases, but the Nusselt number decreases. By rotating the square obstacle, the results display that increasing the angle of inclination from zero to 45 degrees, increases both the drag coefficient and the Nusselt number. Also, the highest rate of heat transfer occur at the angle of 45 degrees (diamond); however it has a negative impact on the Drag coefficient.</span>
Carreau-Yasuda model
Temperature-dependent viscosity
Inclined square
Lattice Boltzmann method
2020
04
01
307
319
http://jacm.scu.ac.ir/article_14545_89eaabd8976162ca5e5e9028936102f5.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
A Modified Energy Balance Method to Obtain Higher-order Approximations to the Oscillators with Cubic and Harmonic Restoring Force
Md Alal
Hosen
Gamal
Ismail
Ahmet
Yildirim
M.A.S.
Kamal
This article analyzes a strongly nonlinear oscillator with cubic and harmonic restoring force and proposes an efficient analytical technique based on the modified energy balance method (MEBM). The proposed method incorporates higher-order approximations. After applying the proposed MEBM, a set of complicated higher-order nonlinear algebraic equations are obtained. Higher-order nonlinear algebraic equations are cumbersome to investigate especially in the case of a large initial oscillation amplitude. This limitation is overcome in the proposed method by using the iterative procedure based on the homotopy perturbation method. The approximated results agree well with the numerically obtained exact solutions. These third-order approximate solutions are found to be almost the same as exact solutions, which cannot be found using the existing energy balance method. Highly accurate result and simple solution procedure are advantages of this proposed method, which could be applied to other nonlinear oscillatory problems arising in nonlinear science and engineering.
Analytical technique
Strongly nonlinear oscillator
Nonlinear algebraic equations
Energy balance method
Iterative procedure
Homotopy perturbation method
2020
04
01
320
331
http://jacm.scu.ac.ir/article_14667_4cbfbc6281d4e4a80d1dfce81a4baf65.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
Experimental Investigation and Optimizing Geometrical Characteristics and Surface Quality in Drilling of AISI H13 Steel
Farshid
Jafarian
Hojjat
Samarikhalaj
The aim of this paper is to investigate and optimize surface quality and geometrical characteristics in drilling process of AISI H13 steel, because they are critical items for precision manufacturing. After conducting the experiments, two regression models are developed to extensively evaluate the effect of drilling parameters on process outputs. After that, evolutionary multi-objective optimization algorithm is employed to find the optimal drilling conditions. Non-dominated Sorting Genetic Algorithm (NSGA-ІІ) is developed and regression functions are taken into account as objective functions of algorithm to simultaneously optimize the surface roughness and deviation of circularity. The optimization results are successfully in agreement with experimental findings and finally the set of optimal drilling conditions is reported that can be selected by process engineer according to the priority and application. It is shown that, an increase in Cutting speed and liquid coolant intensity decreases the surface quality, while higher depth of cut, tool diameter and reed rate improve it. It is also found that tool diameter and depth of cut are the most effective input parameters on deviation of circularity. Finally, it can be concluded that, the implemented approach in this research provides an efficient method for other manufacturing processes to increase the performance and reduction of production costs.
NSGA-ІІ
Multi-Objective Optimization
Drilling Process
Hardened Steel
2020
04
01
332
343
http://jacm.scu.ac.ir/article_14643_e6741aba3677a38fc8a767f214ac0b81.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
A Parameter Uniform Numerical Scheme for Singularly Perturbed Differential-difference Equations with Mixed Shifts
P.
Mushahary
S. R.
Sahu
J.
Mohapatra
In this paper, we consider a second-order singularly perturbed differential-difference equations with mixed delay and advance parameters. At first, we approximate the model problem by an upwind finite difference scheme on a Shishkin mesh. We know that the upwind scheme is stable and its solution is oscillation free, but it gives lower order of accuracy. So, to increase the convergence, we propose a hybrid finite difference scheme, in which we use the cubic spline difference method in the fine mesh regions and a midpoint upwind scheme in the coarse mesh regions. We establish a theoretical parameter uniform bound in the discrete maximum norm. To check the efficiency of the proposed methods, we consider test problems with delay, advance and the mixed parameters and the results are in agreement with our theoretical findings.
Singularly perturbed problem
Differential-difference equation
Mixed shifts
Shishkin mesh
Hybrid scheme
Uniform convergence
2020
04
01
344
356
http://jacm.scu.ac.ir/article_14461_880cc645745f67e899fdeb388bcc42c3.pdf
Journal of Applied and Computational Mechanics
J. Appl. Comput. Mech.
2020
6
2
An Analytical Approach of Nonlinear Thermo-mechanical Buckling of Functionally Graded Graphene-reinforced Composite Laminated Cylindrical Shells under Compressive Axial Load Surrounded by Elastic Foundation
Ngoc Ly
Le
Thi Phuong
Nguyen
Hoai Nam
Vu
Thoi Trung
Nguyen
Minh Duc
Vu
This paper deals with an analytical approach to predict the nonlinear buckling behavior of functionally graded graphene-reinforced composite laminated cylindrical shells under axial compressive load surrounded by Pasternak’s elastic foundation in a thermal environment. Piece-wise functionally graded graphene-reinforced, composite layers are sorted with different types of graphene distribution. The governing equations are established by using Donnell’s shell theory with von Kármán nonlinearity terms and three-term solution of deflection is chosen for modeling the uniform deflection of pre-buckling state, linear and nonlinear deflection of post-buckling state. Galerkin method is applied to determine the critical axial compressive buckling load expression, post-buckling load-deflection and load-end shortening relations of the shell. The effects of environment temperature, foundation, geometrical properties, and graphene distribution on buckling behavior of shell, are numerically evaluated.
Functionally graded graphene-reinforced composite
cylindrical shell
compressive axial load
thermo-mechanical buckling
elastic foundation
2020
04
01
357
372
http://jacm.scu.ac.ir/article_14642_69ac3298ee953e35f2aabf8424171fff.pdf