ORIGINAL_ARTICLE
Electro-magneto-hydrodynamics Flows of Burgers' Fluids in Cylindrical Domains with Time Exponential Memory
This paper investigates the axial unsteady flow of a generalized Burgers’ fluid with fractional constitutive equation in a circular micro-tube, in presence of a time-dependent pressure gradient and an electric field parallel to flow direction and a magnetic field perpendicular on the flow direction. The mathematical model used in this work is based on a time-nonlocal constitutive equation for shear stress with time-fractional Caputo-Fabrizio derivatives; therefore, the histories of the velocity gradient will influence the shear stress and fluid motion. Thermal transport is considered in the hypothesis that the temperature of the cylindrical surface is constant. Analytical solutions for the fractional differential momentum equation and energy equation are obtained by employing the Laplace transform with respect to the time variable t and the finite Hankel transform with respect to the radial coordinate r. It is important to note that the analytical solutions for many particular models such as, ordinary/fractional Burgers fluids, ordinary/fractional Oldryd-B fluids, ordinary/fractional Maxwell fluids and Newtonian fluids, can be obtained from the solutions for the generalized fractional Burgers' fluid by particularizing the material coefficients and fractional parameters. By using the obtained analytical solutions and the Mathcad software, we have carried out numerical calculations in order to analyze the influence of the memory parameters and magnetic parameter on the fluid velocity and temperature. Numerical results are presented in graphical illustrations. It is found that ordinary generalized Burgers’ fluids flow faster than the fractional generalized Burgers’ fluids.
http://jacm.scu.ac.ir/article_13836_e556b6c7bf8d84b8fa143a7168482864.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
577
591
10.22055/jacm.2018.26478.1336
Electro-magneto-hydrodynamic (EMHD) flow
Porous medium
Thermal-fluidic transports
Fractional model
Micro scale flow
Abdul
Rauf
abdul.rauf@aumc.edu.pk
true
1
Department of Computer Science and Engineering, Air University Multan, Abdali Road, Multan, 60000, Pakistan
Department of Computer Science and Engineering, Air University Multan, Abdali Road, Multan, 60000, Pakistan
Department of Computer Science and Engineering, Air University Multan, Abdali Road, Multan, 60000, Pakistan
LEAD_AUTHOR
Yasir
Mahsud
yasir.mahsud@sms.edu.pk
true
2
Abdus Salam School of Mathematical Sciences, GC University Lahore, 68-B, New Muslim Town, Lahore, 54600, Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, 68-B, New Muslim Town, Lahore, 54600, Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, 68-B, New Muslim Town, Lahore, 54600, Pakistan
AUTHOR
[1] Huang, J., He, G. and Liu, C., Analysis of general second-order fluid flow in double cylinder rheometer. Science in China Series A: Mathematics, 40(2) (1997) 183-190.
1
[2] Tan, W., Xian, F. and Wei, L., An exact solution of unsteady Couette flow of generalized second grade fluid. Chinese Science Bulletin, 47(21) (2002) 1783-1785.
2
[3] Xu, M. and Tan, W., Theoretical analysis of the velocity field, stress field and vortex sheet of generalized second order fluid with fractional anomalous diffusion. Science in China Series A: Mathematics, 44(11) (2001) 1387-1399.
3
[4] Hayat, T., Nadeem, S. and Asghar, S., Periodic unidirectional flows of a viscoelastic fluid with the fractional Maxwell model. Applied Mathematics and Computation, 151(1) (2004) 153-161.
4
[5] Khan, M., Maqbool, K. and Hayat, T., Influence of Hall current on the flows of a generalized Oldroyd-B fluid in a porous space. Acta Mechanica, 184(1-4) (2006) 1-13.
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[6] Qi, H. and Jin, H., Unsteady rotating flows of a viscoelastic fluid with the fractional Maxwell model between coaxial cylinders. Acta Mechanica Sinica, 22(4) (2006) 301-305.
6
[7] Chakraborty, R., Dey, R. and Chakraborty, S., Thermal characteristics of electromagnetohydrodynamic flows in narrow channels with viscous dissipation and Joule heating under constant wall heat flux. International Journal of Heat and Mass Transfer, 67 (2013) 1151-1162.
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[8] Jian, Y., Si, D., Chang, L. and Liu, Q., Transient rotating electromagnetohydrodynamic micropumps between two infinite microparallel plates. Chemical Engineering Science, 134 (2015) 12-22.
8
[9] Sinha, A. and Shit, G.C., Electromagnetohydrodynamic flow of blood and heat transfer in a capillary with thermal radiation. Journal of Magnetism and Magnetic Materials, 378 (2015) 143-151.
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[10] Wang, L., Jian, Y., Liu, Q., Li, F. and Chang, L., Electromagnetohydrodynamic flow and heat transfer of third grade fluids between two micro-parallel plates. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 494 (2016) 87-94.
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[11] Jyothi, K.L., Devaki, P. and Sreenadh, S., Pulsatile flow of a Jeffrey fluid in a circular tube having internal porous lining. International Journal of Mathematical Archive, 4(5) (2013) 75-82.
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[14] Hayat, T., Khan, S. B., Khan, M., Exact solution for rotating flows of a generalized Burgers’s fluid in a porous space. Applied Mathematical Modelling, 32 (2008) 749-760.
14
[15] Das, S. and Chakraborty, S., Analytical solutions for velocity, temperature and concentration distribution in electroosmotic microchannel flows of a non-Newtonian bio-fluid. Analytica Chimica Acta, 559(1) (2009) 15-24.
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[16] Zhao, C. and Yang, C., Exact solutions for electro-osmotic flow of viscoelastic fluids in rectangular micro-channels. Applied Mathematics and Computation, 211(2) (2009) 502-509.
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[17] Chakraborty, S., Electroosmotically driven capillary transport of typical non-Newtonian biofluids in rectangular microchannels. Analytica Chimica Acta, 605(2) (2007) 175-184.
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[18] Zhao, C. and Yang, C., Nonlinear Smoluchowski velocity for electroosmosis of Power‐law fluids over a surface with arbitrary zeta potentials. Electrophoresis, 31(5) (2010) 973-979.
18
[19] Kang, Y., Yang, C. and Huang, X., Electroosmotic flow in a capillary annulus with high zeta potentials. Journal of Colloid and Interface Science, 253(2) (2002) 285-294.
19
[20] Chakraborty, R., Dey, R. and Chakraborty, S., Thermal characteristics of electromagnetohydrodynamic flows in narrow channels with viscous dissipation and Joule heating under constant wall heat flux. International Journal of Heat and Mass Transfer, 67 (2013) 1151-1162.
20
[21] Jian, Y., Si, D., Chang, L. and Liu, Q., Transient rotating electromagnetohydrodynamic micropumps between two infinite microparallel plates. Chemical Engineering Science, 134 (2015) 12-22.
21
[22] Sinha, A. and Shit, G.C., Electromagnetohydrodynamic flow of blood and heat transfer in a capillary with thermal radiation. Journal of Magnetism and Magnetic Materials, 378 (2015) 143-151.
22
[23] Buren, M., Jian, Y., Chang, L., Li, F. and Liu, Q., Combined electromagnetohydrodynamic flow in a microparallel channel with slightly corrugated walls. Fluid Dynamics Research, 49(2) (2017) 25517.
23
[24] Escandón, J.P., Bautista, O.E., Santiago, F. and Méndez, F., Asymptotic analysis of non-Newtonian fluid flow in a microchannel under a combination of EO and MHD micropumps. Defect and Diffusion Forum, 348 (2014) 147-152.
24
[25] Chakraborty, S. and Paul, D., Microchannel flow control through a combined electromagnetohydrodynamic transport. Journal of Physics D: Applied Physics, 39(24) (2006) 5364.
25
[26] Khuzhayorov, B., Auriault, J.L. and Royer, P., Derivation of macroscopic filtration law for transient linear viscoelastic fluid flow in porous media. International Journal of Engineering Science, 38(5) (2000) 487-504.
26
[27] Escandón, J., Santiago, F., Bautista, O. and Méndez, F., Hydrodynamics and thermal analysis of a mixed electromagnetohydrodynamic-pressure driven flow for Phan–Thien–Tanner fluids in a microchannel. International Journal of Thermal Sciences, 86 (2004) 246-257.
27
[28] Hayat, T., Khan, M. and Asghar, S., On the MHD flow of fractional generalized Burgers’ fluid with modified Darcy’s law. Acta Mechanica Sinica, 23(3) (2007) 257-261.
28
[29] Caputo, M. and Fabrizio, M., A new definition of fractional derivative without singular kernel. Progress in Fractional Differentiation and Applications, 1(2) (2015) 1-13.
29
[30] Jian, Y., Transient MHD heat transfer and entropy generation in a microparallel channel combined with pressure and electroosmotic effects. International Journal of Heat and Mass Transfer, 89 (2015) 193-205.
30
[31] Maynes, D. and Webb, B.W., The effect of viscous dissipation in thermally fully-developed electro-osmotic heat transfer in microchannels. International Journal of Heat and Mass Transfer, 47(5) (2004) 987-999.
31
[32] Abdulhameed, M., Vieru, D. and Roslan, R., Modeling electro-magneto-hydrodynamic thermo-fluidic transport of biofluids with new trend of fractional derivative without singular kernel. Physica A: Statistical Mechanics and its Applications, 484 (2017) 233-252.
32
[33] Bhatti, M.M., Zeeshan, A., Ijaz, N., Bég, O.A. and Kadir, A., Mathematical modelling of nonlinear thermal radiation effects on EMHD peristaltic pumping of viscoelastic dusty fluid through a porous medium duct. Engineering Science and Technology, An International Journal, 20(3) (2017) 1129-1139.
33
ORIGINAL_ARTICLE
Transient MHD Convective Flow of Fractional Nanofluid between Vertical Plates
Effects of the uniform transverse magnetic field on the transient free convective flows of a nanofluid with generalized thermal transport between two vertical parallel plates have been analyzed. The fluid temperature is described by a time-fractional differential equation with Caputo derivatives. Closed form of the temperature field is obtained by using the Laplace transform and fractional derivatives of the Wright’s functions. A semi-analytical solution for the velocity field is obtained by using the Laplace transform coupled with the numerical algorithms for the inverse Laplace transform elaborated by Stehfest and Tzou. Effects of the derivative fractional order and physical parameters on the nanofluid flow and heat transfer are graphically investigated.
http://jacm.scu.ac.ir/article_13837_0344f863af54b921ee820206f1b3d005.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
592
602
10.22055/jacm.2018.26947.1364
Convection flows
Nanofluids
Caputo fractional derivative
Laplace transform
Najma
Ahmed
najmaahmed11@gmail.com
true
1
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan
LEAD_AUTHOR
Nehad
Ali Shah
nehadali199@yahoo.com
true
2
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan | Department of Mathematics, Lahore Leads University, Lahore Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan | Department of Mathematics, Lahore Leads University, Lahore Pakistan
Abdus Salam School of Mathematical Sciences, GC University Lahore, Pakistan | Department of Mathematics, Lahore Leads University, Lahore Pakistan
AUTHOR
Bakhtiar
Ahmad
bakhtiarahmad881@gmail.com
true
3
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
AUTHOR
Syed Inayat
Shah
inayat64@gmail.com
true
4
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
AUTHOR
Sam
Ulhaq
samiulhaqmaths@yahoo.com
true
5
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
Department of Mathematics, Islamia College University Peshawar Khyber Pakhtunkhwa 25000, Pakistan
AUTHOR
Mohamad Rahimi
-Gorji
mohammad.rahimigorji@ugent.be
true
6
Experimental Surgery Lab, Department of Surgery, Ghent University, De Pintelaan 185, 9000 Ghent, Belgium | Biofluid, Tissue and Solid Mechanics for Medical Applications Lab (IBiTech, bioMMeda), Ghent University, Gent, Belgium
Experimental Surgery Lab, Department of Surgery, Ghent University, De Pintelaan 185, 9000 Ghent, Belgium | Biofluid, Tissue and Solid Mechanics for Medical Applications Lab (IBiTech, bioMMeda), Ghent University, Gent, Belgium
Experimental Surgery Lab, Department of Surgery, Ghent University, De Pintelaan 185, 9000 Ghent, Belgium | Biofluid, Tissue and Solid Mechanics for Medical Applications Lab (IBiTech, bioMMeda), Ghent University, Gent, Belgium
AUTHOR
[1] Choi, S.U.S., Enhancing thermal conductivity of fluids with nanoparticles, in: The proceeding of the 1995 ASME International Mechanical Engineering Congress and Exposition, San Francisco, USA, ASME, FED 231/MD 66 (1995) p. 99-105.
1
[2] Xuan, Y. and Li, Q., Heat Transfer enhancement of nanofluids, International Journal of Heat and Fluid Flow, 21 (2000) 58-64.
2
[3] Khanafer, K. and Vafai, K., A critical synthesis of thermophysical characteristics of nanofluids, International Journal of Heat and Mass Transfer, 54 (2011) 4410-4428.
3
[4] Khanafer, K., Vafai, K. and Lightstone, M., Buoyancy-driven heat transfer enhancement in a two-dimensional enclosure utilizing nanofluids, International Journal of Heat and Mass Transfer, 46 (2003) 3639-3653.
4
[5] Santra, A.K., Sen, S. and Chakraborty, N., Study of heat transfer augmentation in a differently heated square cavity using copper-water nanofluid, International Journal of Thermal Sciences, 47 (2008) 1113-1122.
5
[6] Oztop, H.F. and Abu-Nada, E., Numerical study of natural convection in partially heated rectangular enclosures filled with nanofluids, International Journal of Heat and Fluid Flow, 29 (2008) 1326-1336.
6
[7] Basak, T. and Chamkha, A.J., Heatline analysis on nanural convection for nanofluids confined within square cavities with various thermal boundary conditions, International Journal of Heat and Mass Transfer, 55 (2012) 5526-5543.
7
[8] Oztop, H.F., Abu-Nada, E., Varol, Y. and Al-Salem, K., Computational analysis of non-isotherm temperature distribution on natural convection in nanofluid filled enclosures, Superlattices and Microstructures, 49(4) (2011) 453-467.
8
[9] Lin, K.C. and Violi, A., Natural convection heat transfer of nanofluid in a vertical cavity: Effects of nonuniform particle diameter and temperature on thermal conductivity, International Journal of Heat and Fluid Flow, 31 (2010) 236-245.
9
[10] Abu-Nada, E., Application of nanofluids for heat transfer enhancement of separated flows encountered in a back ground facing step, International Journal of Heat and Fluid Flow, 29 (2008) 242-249.
10
[11] Wang, X.Q. and Mujumder, A.S., Heat transfer characteristics of nanofluid: a review, International Journal of Thermal Sciences, 46 (2007) 1-19.
11
[12] Eastman, J.A., Choi, S.U.S., Li, S., Thompson, L.J. and Lee, S., Enhanced thermal conductivity through the development of nanofluids, in: 1996 Fall meeting of the Materials Research Society (MRS), Boston, USA (1997) p. 3-11.
12
[13] Oldham, K. B. and Spainier, J., The Fractional Calculus, Academic Press, New York, 1974.
13
[14] Benson, D. A., Wheatcraft, S. W. and Meerschaert, M. M., Application of a fractional advection-dispersion equation, Water Resources Research, 36(6) (2000) 1403-1412.
14
[15] Metzler, R. and Klafter, J., The random walk’s guide to anomalous diffusion: A fractional dynamic approach, Physics Reports, 339 (2000) 1-77.
15
[16] Zaslavsky, G. M., Choas Fractional kinetics and anomalous transport, Physics Reports, 371(6) (2002) 461-580.
16
[17] Podlubny, Igor J., Fractional differential equation, Academic Press, New York, 1999.
17
[18] Azhar, W. A., Vieru, D., Fetecau, C., Free convection flow of some fractional nanofluids over a moving vertical plate with uniform heat flux and heat source, Physics of Fluids, 29 (2017) 082001.
18
[19] Imran, M.A., Shah, N.A., Khan, I., Aleem, M., Applications of non-integer Caputo time fractional derivatives to natural convection flow subject to arbitrary velocity and Newtonian heating, Neural Computing and Applications, 30(5) (2018) 1589-1599.
19
[20] Shah, N.A., Khan, I., Heat transfer analysis in a second grade fluid over and oscillating vertical plate using fractional Caputo–Fabrizio derivatives, European Physical Journal C, 76 (2016) p. 362.
20
[21] Imran, M.A., Khan, I., Ahmad, M., Shah, N.A., Nazar, M., Heat and mass transport of differential type fluid with non-integer order time-fractional Caputo derivatives, Journal of Molecular Liquids, 229 (2016) 67-75.
21
[22] Prakash, D., Suriyakumar, P., Transient hydromagnetic convection flow of nanofluid between asymmetric vertical plates with heat generation, International Journal of Pure and Applied Mathematics, 113(12) (2017) 1-10.
22
[23] Ahmed, N., Shah, N. A., Vieru, D., Natural convection with damped thermal flux in a vertical circular cylinder, Chinese Journal of Physics, 56 (2018) 630-644.
23
[24] Hristov, J., Derivatives with non-singular kernels. From Caputo-Fabrizio definition and beyond. Frontiers in Fractional Calculus, 1st Edition, Betham Science Publishers, Editor Sachin Bhalekar, p. 269-340, 2017.
24
[25] Stehfest, H., Algorithm 368: Numerical inversion of Laplace transforms, Communications of the ACM, 13 (1970) 47-49.
25
[26] Tzou, D.Y., Macro to micro scale heat transfer: The lagging behavior, Taylor and Francis, Washington, 1997.
26
ORIGINAL_ARTICLE
Residual Power Series Method for Solving Time-fractional Model of Vibration Equation of Large Membranes
The primary aim of this manuscript is to present the approximate analytical solutions of the time fractional order α (1<α≤2) Vibration Equation (VE) of large membranes with the use of an iterative technique namely Residual Power Series Method (RPSM). The fractional derivative is defined in the Caputo sense. Example problems have been solved to demonstrate the efficacy of the present method and the results obtained are verified graphically. The convergence analysis of the proposed method has also been included in this article. It is seen that the present method is found to be reliable, very effective and easy to implement for various kinds of fractional differential equations used in science and engineering.
http://jacm.scu.ac.ir/article_13838_70ed6fb779bee4d57b2d80cca3bc2ad2.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
603
615
10.22055/jacm.2018.26668.1347
Fractional vibration equation
Caputo derivative
Residual Power Series
Mittag-Leffler function
Rajarama Mohan
Jena
rajarama1994@gmail.com
true
1
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
AUTHOR
S.
Chakraverty
sne_chak@yahoo.com
true
2
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
National Institute of Technology Rourkela, Department of Mathematics, Odisha, Rourkela, 769008, India
LEAD_AUTHOR
[1] Jena, R.M. and Chakraverty, S., A new iterative method based solution for fractional Black–Scholes option pricing equations (BSOPE). SN Appl. Sci, 1 (2019) 95.
1
[2] Podlubny, I., Fractional Differential Equations, Academic Press, New York, 1999.
2
[3] Jena, R.M. and Chakraverty, S., Analytical solution of Bagley-Torvik equations using Sumudu transformation method. SN Appl. Sci, 1(3) (2019) 246.
3
[4] Miller, K.S. and Ross, B., An Introduction to the Fractional Calculus and Fractional Differential Equations, A Wiley-Interscience Publication, John Wiley and Sons, New York, Chichester, Brisbane, Toronto and Singapore, 1993.
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[5] Kilbas, A.A., Srivastava, H.M. and Trujillo, J.J., Theory and Applications of Fractional Differential Equations, North-Holland Mathematical Studies, Elsevier (North-Holland) Science Publishers, Amsterdam, London, and New York, 2006.
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[6] Heydari, M.H., Hooshmandasl, M.R., Ghaini, F.M.M. and Cattani, C., Wavelets method for solving fractional optimal control problems. Appl. Math. Comput., 286 (2016) 139–154.
6
[7] Jena, R.M., Chakraverty, S. and Jena, S.K., Dynamic Response Analysis of Fractionally Damped Beams Subjected to External Loads using Homotopy Analysis Method. Journal of Applied and Computational Mechanics, 5(2) (2019) 355-366.
7
[8] Srivastava, H.M., Kumar, D. and Singh, J., An efficient analytical technique for fractional model of vibration equation. Applied Mathematical Modelling, 45 (2017) 192–204.
8
[9] Arqub, O.A., Series solution of fuzzy differential equations under strongly generalized differentiability. J. Adv. Res. Appl. Math, 5 (2013) 31–52.
9
[10] Arqub, O.A., El-Ajou, A., Bataineh, A. and Hashim, I., A representation of the exact solution of generalized Lane Emden equations using a new analytical method. Abstr. Appl. Anal., 2013 (2013) p. 10.
10
[11] El-Ajou, A., Arqub, O.A. and Momani, S., Approximate analytical solution of the nonlinear fractional KdVBurgers equation: a new iterative algorithm. J. Comput. Phys., 293 (2015) 81–95.
11
[12] Alquran, M., Analytical solutions of fractional foam drainage equation by residual power series method. Math. Sci., 8(4) (2014) 153–160.
12
[13] Zhang, Y., Kumar, A., Kumar, S., Baleanu, D. and Yang, X.J., Residual power series method for time-fractional Schrodinger equations. J. Nonlinear Sci. Appl., 9 (2016) 5821-5829.
13
[14] Tariq, H. and Akram, G., Residual power series method for solving time-space-fractional Benney-Lin equation arising in falling film problems. J. Appl. Math. Comput., 55 (2017) 683–708.
14
[15] El-Ajou, A., Arqub O.A., Momani, S., Baleanu, D. and Alsaedi, A., A novel expansion iterative method for solving linear partial differential equations of fractional order. Applied Mathematics and Computation, 257 (2015) 119–133.
15
[16] El-Ajou, A., Arqub O.A., Zhour, Z.A. and Momani, S., New Results on Fractional Power Series: Theories and Applications. Entropy, 15 (2013) 5305-5323.
16
[17] Arqub, O.A., El-Ajou, A., Zhour, Z.A. and Momani, S., Multiple Solutions of Nonlinear Boundary Value Problems of Fractional Order: A New Analytic Iterative Technique. Entropy, 16 (2014) 471-493.
17
[18] Arqub, O.A., El-Ajou, A. and Momani, S., Construct and predicts solitary pattern solutions for nonlinear time-fractional dispersive partial differential equations. Journal of Computational Physics, 293 (2015) 385-399.
18
[19] El-Ajou, A., Arqub O, A. and Al-Smadi, M., A general form of the generalized Taylor's formula with some applications, Applied Mathematics and Computation, 256 (2015) 851-859.
19
ORIGINAL_ARTICLE
The Solar Air Channels: Comparative Analysis, Introduction of Arc-shaped Fins to Improve the Thermal Transfer
The problem under investigation contains a computational simulation of a specific heat exchanger with complex geometry fins. The problem solved is potentially interesting for researchers and engineers working on solar collectors and aerospace industry. It is known that heat transfer enhancement can be achieved by creating longitudinal vortices in the flow. These vortices can be generated by arc-shaped fins, and a computational analysis of such solar air channels is not a simple task. Therefore, we used a present-day commercial CFD code to solve the problem. The mathematical problem including the main equations and their explanation, as well as the numerical procedure was presented. The impact of arc-fins’ spacings on streamlines and temperature distributions was completely investigated, as well as the heat transfer rate, pressure drop and thermal enhancement factor. The Nusselt number (Nu) and friction loss (f) values of the solar air channel at AR = 1.321 (aspect ratio of channel width-to-height) and S = Pi/2 are found to be around 11.963% and 26.006%; 21.645% and 40.789%; 26.196% and 50.314%; and 30.322% and 58.355% higher than that with S = 3Pi/4, Pi, 5Pi/4 and 3Pi/2, respectively. Importantly, the arc-fins with Re = 12,000 at S = Pi/2 showed higher thermal enhancement performance than the one at S = 3Pi/4, Pi, 5Pi/4 and 3Pi/2 around 2.530%, 6.576%, 6.615% and 6.762%, respectively. This study contains the information which seems to be important for practical engineers.
http://jacm.scu.ac.ir/article_13839_d8c012af8b704ecf4d77b5c20970c259.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
616
626
10.22055/jacm.2018.26785.1356
Solar air channel
Comparative analysis
Introduction of arc-shaped fins
Heat transfer enhancement
Younes
Menni
menniyounes.cfd@gmail.com
true
1
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria
LEAD_AUTHOR
Ahmed
Azzi
a.ahmed.univ@gmail.com
true
2
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria | Department of Mechanical Engineering, Faculty of Technology, Abou Bekr Belkaid University, BP 230-13000-Tlemcen, Algeria
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria | Department of Mechanical Engineering, Faculty of Technology, Abou Bekr Belkaid University, BP 230-13000-Tlemcen, Algeria
Unit of Research on Materials and Renewable Energies, Department of Physics, Faculty of Sciences, Abou Bekr Belkaid University, BP 119-13000-Tlemcen, Algeria | Department of Mechanical Engineering, Faculty of Technology, Abou Bekr Belkaid University, BP 230-13000-Tlemcen, Algeria
AUTHOR
Ali. J
Chamkha
achamkha@yahoo.com
true
3
echanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, United Arab Emirates
echanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, United Arab Emirates
echanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, United Arab Emirates
AUTHOR
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1
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ORIGINAL_ARTICLE
Modified Multi-level Residue Harmonic Balance Method for Solving Nonlinear Vibration Problem of Beam Resting on Nonlinear Elastic Foundation
Nonlinear vibration behavior of beam is an important issue of structural engineering. In this study, a mathematical modeling of a forced nonlinear vibration of Euler-Bernoulli beam resting on nonlinear elastic foundation is presented. The nonlinear vibration behavior of the beam is investigated by using a modified multi-level residue harmonic balance method. The main advantage of the method is that only one nonlinear algebraic equation is generated at each solution level. The computational time of using the new method is much less than that spent on solving the set nonlinear algebraic equations generated in the classical harmonic balance method. Besides the new method can generate higher-level nonlinear solutions neglected by previous multi-level residue harmonic balance methods. The results obtained from the proposed method compared with those obtained by a classical harmonic balance method to verify the accuracy of the method which shows good agreement between the proposed and classical harmonic balance method. Besides, the effect of various parameters such as excitation magnitude, linear and nonlinear foundation stiffness, shearing stiffness etc. on the nonlinear vibration behaviors are examined
http://jacm.scu.ac.ir/article_13841_fc277fb49e1c23b2f454cce9c6745ef9.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
627
638
10.22055/jacm.2018.26729.1352
Harmonic balance
Nonlinear dynamics
Nonlinear foundation
Large amplitude vibration
Md. Saifur
Rahman
msr_math_1980@yahoo.com
true
1
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
LEAD_AUTHOR
Abu Sufian
Hasan
ziaruet@gmail.com
true
2
Department of Civil Engineering, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Civil Engineering, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Civil Engineering, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
AUTHOR
Ismot Ara
Yeasmin
ismot.yeasmin@yahoo.com
true
3
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
Department of Mathematics, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh
AUTHOR
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[59] Hasan, A. S. M. Z., Lee, Y. Y., Leung, A. Y. T., The multi-level residue harmonic balance solutions of multi-mode nonlinearly vibrating beams on an elastic foundation, Journal of Vibration and Control, 22(14), 2016, pp. 3218-3235.
59
[60] Rahman, M. S., Lee, Y. Y., New modified multi-level residue harmonic balance method for solving nonlinearly vibrating double-beam problem, Journal of Sound and Vibration,406, 2017, pp. 295-327.
60
ORIGINAL_ARTICLE
Scalings of Inverse Energy Transfer and Energy Decay in 3-D Decaying Isotropic Turbulence with Non-rotating or Rotating Frame of Reference
Energy development of decaying isotropic turbulence in a 3-D periodic cube with non-rotating or rotating frames of reference is studied through direct numerical simulation using GPU accelerated lattice Boltzmann method. The initial turbulence is isotropic, generated in spectral space with prescribed energy spectrum E(κ)~κm in a range between κmin and κmax. The Taylor microscale Reynolds number Reλ and Rossby number Ro are introduced to characterize the inertial, viscous, and rotational attributes of the system. The focus of this study is on the scalings of early inverse energy transfer and late energy decay in the development of turbulent energy under various conditions through combinations of m, κmin, κmax, Reλ and Ro. First, we demonstrate the validity of the simulation by confirming the quantitative dependence of the decay exponent n on the initial energy spectrum exponent m, at Reλ =255 and Ro=∞, varying the values of m, κmin and κmax. Second, at relatively low Reλ, the decay exponent for different initial spectra statistically fall in respective ranges, all of which agree well with the corresponding analytical predictions. Third, we quantitatively investigate the 3-D inverse energy transfer. Our findings include (i) the exponent of inverse energy transfer spectrum E(κ)~κσ depends on the initial spectrum exponent E(κ) ~ κm: if m<4, σ=m while if m≥4, σ=4; (ii) rotation alters the inverse energy transfer rate when Reλ≤255 and Ro≥0.8; (iii) the energy increase in large scale during inverse energy transfer exhibits a bell shape, the peak of which varies with Reλ and Ro.
http://jacm.scu.ac.ir/article_13845_4a1abed345a435381af1e0afb7afb238.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
639
646
10.22055/jacm.2018.26826.1361
Inverse energy transfer
Decaying isotropic turbulence
Rotational turbulence
Lattice Boltzmann method
GPU parallel computation
Rou
Chen
rouchen@iu.edu
true
1
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
AUTHOR
Whitney
Yu
whyu@iupui.edu
true
2
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
Department of Mechanical & Energy Engineering, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA
LEAD_AUTHOR
Yousheng
Xu
113003@zust.edu.cn
true
3
School of Light Industry, Zhejiang University of Science and Technology, Hangzhou 310023, China
School of Light Industry, Zhejiang University of Science and Technology, Hangzhou 310023, China
School of Light Industry, Zhejiang University of Science and Technology, Hangzhou 310023, China
AUTHOR
Luoding
Zhu
luozhu@iupui.edu
true
4
Department of Mathematical Sciences, Indiana University-Purdue University Indianapolis, IN 46202, USA
Department of Mathematical Sciences, Indiana University-Purdue University Indianapolis, IN 46202, USA
Department of Mathematical Sciences, Indiana University-Purdue University Indianapolis, IN 46202, USA
AUTHOR
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[22] Xia H., Punzmann H., Falkovich G., Shats M.G., Turbulence-condensate interaction in two dimensions. Physical review letters.101(19), 2008, 194504.
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[23] Baggaley A.W., Barenghi C.F., Sergeev Y.A., Three-dimensional inverse energy transfer induced by vortex reconnections. Physical Review E.89(1), 2014, 013002.
23
[24] Galanti B., Sulem P.L., Inverse cascades in three-dimensional anisotropic flows lacking parity invariance. Physics of Fluids A: Fluid Dynamics.3(7), 1991, 1778-1784.
24
[25] Hefer D., Yakhot V., Inverse energy cascade in a time-dependent flow. Physics of Fluids A: Fluid Dynamics.1(8), 1989, 1383-1386.
25
[26] Yakhot V., Pelz R., Large-scale structure generation by anisotropic small-scale flows. Physics of Fluids.30(5), 1987, 1272-1277.
26
[27] Yakhot V., Sivashinsky G., Negative-viscosity phenomena in three-dimensional flows. Physical Review A.35(2), 1987, 815.
27
[28] Waite L.M., Bartello P., The transition from geostrophic to stratified turbulence. J. Fluid Mech. 568, 2006, 89-108.
28
[29] Mininni P.D., Pouquet A., Rotating helical turbulence. I. Global evolution and spectral behavior. Physics of Fluids.22(3), 2010, 035105.
29
[30] Pouquet A., Sen A., Rosenberg D., Mininni P.D., Baerenzung J., Inverse cascades in turbulence and the case of rotating flows. Physica Scripta.2013, 2013, 014032.
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[31] Smith L.M., Waleffe F., Transfer of energy to two-dimensional large scales in forced, rotating three-dimensional turbulence. Physics of fluids.11, 1999, 1608-1622.
31
[32] Biferale L., Musacchio S., Toschi F., Inverse energy cascade in three-dimensional isotropic turbulence. Physical review letters.108(16), 2012, 164501.
32
[33] Chen H., Chen S., Matthaeus W.H., Recovery of the Navier-Stokes equations using a lattice-gas Boltzmann method. Physical Review A.45(8), 1992, R5339.
33
[34] Qian Y.H., Dhumieres D., Lallemand P., Lattice Boltzmann Model for Navier-Stokes Equation. Europhysics Letters.17, 1992, 479-484.
34
[35] Yu H., Girimaji S.S., Luo L.S., DNS and LES of decaying isotropic turbulence with and without frame rotation using lattice Boltzmann method. Journal of Computational Physics.209(2), 2005, 599-616.
35
[36] Yu H., Girimaji S.S., Luo L.S., Lattice Boltzmann simulations of decaying homogeneous isotropic turbulence. Physical Review E.71(1), 2005, 016708.
36
[37] Yu H., Chen R., Wang H., Yuan Z., Zhao Y., An Y., et al., GPU accelerated lattice Boltzmann simulation for rotational turbulence. Computers & Mathematics with Applications.67(2), 2014, 445-451.
37
[38] Chen S., Doolen G.D., Lattice Boltzmann method for fluid flows. Annual review of fluid mechanics.30(1), 1998, 329-364.
38
[39] Aidun C.K., Clausen J.R., Lattice-Boltzmann Method for Complex Flows. Annual Review of Fluid Mechanics.2010, 439-472.
39
[40] Wang Z., Zhao Y., Sawchuck A.P., Dalsing M.C., Yu H., GPU acceleration of Volumetric Lattice Boltzmann Method for patient-specific computational hemodynamics. Computers & Fluids.115, 2015, 192-200.
40
[41] Mei R., Shyy W., Yu D., Luo L.S., Lattice Boltzmann method for 3-D flows with curved boundary. Journal of Computational Physics.161(2), 2000, 680-699.
41
[42] He X.Y., Luo L.S., Lattice Boltzmann model for the incompressible Navier–Stokes equation. Journal of statistical Physics.88(3), 1997, 927-944.
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[43] Luo L.S., Theory of the lattice Boltzmann method: Lattice Boltzmann models for nonideal gases. Physical Review E.62(4), 2000, 4982.
43
[44] Chapman S., Cowling T.G., The mathematical theory of non-uniform gases: an account of the kinetic theory of viscosity, thermal conduction and diffusion in gases, Cambridge university press, 1970.
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[45] Miyauchi T., Ishizu T., Direct Numerical Simulation of Homogeneous Turbulence (Decay of Passive Scalar Fluctuation). Trans. JSME.57(544), 1991, 4085-4091.
45
[46] Mansour N.N., Wray A.A., Decay of isotropic turbulence at low Reynolds number. Physics of Fluids.6(2), 1994, 808-814.
46
[47] Djenidi L., Kamruzzaman M., Antonia R.A., Power-law exponent in the transition period of decay in grid turbulence. Journal of Fluid Mechanics.779, 2015, 544-555.
47
[48] Burattini P., Lavoie P., Agrawal A., Djenidi L., Antonia R.A., Power law of decaying homogeneous isotropic turbulence at low Reynolds number. Physical Review E.73(6), 2006, 066304.
48
[49] Kamruzzaman M., Djenidi L., Antonia R.A., Effects of low Reynolds number on decay exponent in grid turbulence. Procedia Engineering.90, 2014, 327-332.
49
[50] Yamazaki Y., Kaneda Y., Rubinstein R., Dynamics of inviscid truncated model of rotating turbulence. Journal of the Physical Society of Japan.71(1), 2002, 81-92.
50
[51] Fang L., Background scalar-level anisotropy caused by low-wave-number truncation in turbulent flows. Physical Review E.95(3), 2017, 033102.
51
[52] Qin Z., Fang L., Fang J., How isotropic are turbulent flows generated by using periodic conditions in a cube? Physics Letters A.380(13), 2016, 1310-1317.
52
ORIGINAL_ARTICLE
Failure Procedure in Adhesive Composite Joints under Different Types of Loading
In this paper, we have used numerical simulation to study failure of adhesive joints in composite plates. To determine the failure load, adhesive joints are subjected to different types of loading and gradual failure of the joint is studied using the finite element method. The composite material failure theory is implemented into the FEM software. Also different geometries for the joint edge are considered and effect of these geometries and fillet chamfer angle on the failure load are investigated.
http://jacm.scu.ac.ir/article_13878_390d8f6bbcd67c776d2141450aaa383b.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
647
651
10.22055/jacm.2018.26794.1358
Composite
Adhesive joint
Failure
Tsai-Wu criterion
Chamfer angle
Dara
Fazel
dara_fazel@yahoo.com
true
1
Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
AUTHOR
Mohammad Hassan
Kadivar
kadivar@yahoo.com
true
2
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
LEAD_AUTHOR
Hassan
Zohoor
zohoor@sharif.edu
true
3
Mechanical Engineering Department, Sharif University of Technology, Tehran, Iran
Mechanical Engineering Department, Sharif University of Technology, Tehran, Iran
Mechanical Engineering Department, Sharif University of Technology, Tehran, Iran
AUTHOR
Mohammad Rahim
Hematiyan
mo.hematiayan@gmail.com
true
4
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
AUTHOR
Mehrdad
Farid
farid@shirazu.ac.ir
true
5
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
School of Mechanical Engineering, Shiraz University, Shiraz, Iran
AUTHOR
[1] Volkersen, O., Die Niektraftverteilung in Zugbeanspruchten mit Konstanten Laschenquerschritten, Luftfahrtforschung, 15 (1938) 41-68.
1
[2] Adams, R.D., Peppiatt, N.A., Effect of Poisson’s ratio strains in adherends on stresses of an idealized lap joint, Journal of Strain Analysis, 8 (1973) 134-139.
2
[3] Herris, J.A., Adams, R.D., Strength prediction of bonded single lap joints by non-linear finite element methods, International Journal of Adhesion and Adhesives, 4 (1984) 65-78.
3
[4] Oplinger, D.W., Effects of adherend deflections in single lap joints, International Journal of Solids and Structures, 31(18) (1994) 2561-2587.
4
[5] Golang, M., Reissner, E., The stress in cemented joints, Journal of Applied Mechanics, 66 (1974) 17-27.
5
[6] Tsai, M.Y., Morton, J., An evaluation of analytical and numerical solutions to the single-lap joint, International Journal of Solids and Structures, 31(18) (1994) 2537-2563.
6
[7] Kadioglu, F., Es-Soun, E., Use of thin adherends in adhesively bonded joints under different loading modes, Science and Technology of Welding and Joining, 8(6) (2003) 437-442.
7
[8] Shahin, K., Taheri, F., Analysis of deformations and stresses in balanced and unbalanced adhesively bonded single-strap joints, Composite Structures, 81 (2007) 511-524.
8
[9] Afendi, M., Teramoto, T., Bakri, H.B., Strength prediction of epoxy adhesively bonded scarf joints of dissimilar adherends, International Journal of Adhesion & Adhesives, 31 (2011) 402-411.
9
[10] Da Costa Mattos, H.S., Sampaio, E.M., Monteiro, A.H., Static failure analysis of adhesive single lap joints, International Journal of Adhesion & Adhesives, 31 (2011) 446-454.
10
ORIGINAL_ARTICLE
Impact of Magnetic Field on Convective Flow of a Micropolar Fluid with two Parallel Heat Source
A numerical study is performed to analysis the buoyancy convection induced by the parallel heated baffles in an inclined square cavity. The two side walls of the cavity are maintained at a constant temperature. A uniformly thin heated plate is placed at the centre of the cavity. The horizontal top and bottom walls are adiabatic. Numerical solutions of governing equations are obtained using the finite volume method coupled with the upwind and central difference technique. Numerical results of the two-dimensional flow field governed by the Navier-Stokes equations are obtained over a wide range of physical parameters, namely the Rayleigh number, the Hartmann number, the inclined angle of the magnetic parameter and the vortex viscosity parameter. It is observed from the results, the heat transfer rate is reduced when increasing Hartmann number, inclination angle and vortex viscosity parameter. The higher heat transfer rate is obtained based on the Newtonian fluid compared to the micropolar fluid.
http://jacm.scu.ac.ir/article_13902_45d83ee6f127bd7c0c50128e0ef35187.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
652
666
10.22055/jacm.2018.26787.1357
Micropolar fluids
Numerical simulation
Magnetic field
Parallel plates
K
Periyadurai
kperiyadurai@gmail.com
true
1
Department of Mathematics, Hindustan Institute of Technology and Science, Chennai - 603 103, India
Department of Mathematics, Hindustan Institute of Technology and Science, Chennai - 603 103, India
Department of Mathematics, Hindustan Institute of Technology and Science, Chennai - 603 103, India
AUTHOR
Muthtamil
Selvan
muthtamil1@buc.edu.in
true
2
Department of Mathematics, Bharathiar University, Coimbatore – 641 046, India
Department of Mathematics, Bharathiar University, Coimbatore – 641 046, India
Department of Mathematics, Bharathiar University, Coimbatore – 641 046, India
LEAD_AUTHOR
Deog-Hee
Doh
doh@kmou.ac.kr
true
3
Division of Mechanical Engineering College of Engineering, Korea Maritime and Ocean University, Busan - 49112, South Korea
Division of Mechanical Engineering College of Engineering, Korea Maritime and Ocean University, Busan - 49112, South Korea
Division of Mechanical Engineering College of Engineering, Korea Maritime and Ocean University, Busan - 49112, South Korea
AUTHOR
[1] Al-Najem, N.M., Khanafer, K.M., El-Refaee M.M., Numerical study of laminar natural convection in tilted enclosure with transverse magnetic field, International Journal of Numerical Methods and Heat Fluid Flow, 8(6), 1998, pp. 651-672.
1
[2] Ece, M.C., Buyuk, E., Natural-convection flow under a magnetic field in an inclined rectangular enclosure heated and cooled on adjacent walls, Fluid Dynamic Research, 38, 2006, pp. 564-590.
2
[3] Jalil, J.M, Al-Taey K.A., The Effect of Nonuniform Magnetic Field on Natural Convection in an Enclosure, Numerical Heat Transfer Part A: Applications, 51(9), 2007, pp. 899-917.
3
[4] Pirmohammadi, M., Ghassemi, M., Effect of magnetic field on convection heat transfer inside a tilted square enclosure, International Communications in Heat and Mass Transfer, 36, 2009, pp. 776-780.
4
[5] Teamah, M.A, Elsafty, A.F., Massoud E.Z., Numerical simulation of double-diffusive natural convective flow in an inclined rectangular enclosure in the presence of magnetic field and heat source, International Journal Mechanical Sciences, 52, 2012, pp. 161-175.
5
[6] Sivaraj, C., Sheremet, M.A., MHD natural convection in an inclined square porous cavity with a heat conducting solid block, Journal Magnetism and Magnetic Materials, 426, 2017, pp. 351-360.
6
[7] Jetli, R., Acharya, S., Zimmerman, E., Influence of baffle location on natural convection in a partially divided enclosure, Numerical Heat Transfer, 10, 1986 pp. 521-536.
7
[8] Oztop, H.F., Dagtekin, I., Bahloul A., Comparison of position of a heated thin plate located in a cavity for natural convection, International Communications in Heat Mass Transfer, 31, 2004, pp. 121-132.
8
[9] Kandaswamy, P., Lee, J., Abdul Hakeem, A.K., Saravanan, S., Effect of baffle-cavity ratios on buoyancy convection in a cavity with mutually orthogonal heated baffles. International Journal Heat and Mass Transfer, 51, 2008, pp. 1830-1837.
9
[10] Garoosi, F., Shakibaeinia, A., Bagheri, G., Eulerian-Lagrangian modeling of solid particle behavior in a square cavity with several pairs of heaters and coolers inside, Powder Technology, 280, 2015, pp. 239-255.
10
[11] Eringen, A.C., Theory of micropolar fluids, Journal Mathematical Mechanics, 16, 1966, pp. 1-18.
11
[12] Eringen, A.C., Theory of thermomicrofluids. Journal Mathematical Analysis and Applications, 38, 1972, pp. 480-496.
12
[13]Wang, S.G., Li, T.Y., Hsu, P.T., Natural convection flow of micropolar fluid in a partially divided enclosure, Acta Mechanica, 136, 1999, pp. 41-53.
13
[14] Zadravec, M., Hribersek, M., Skerget, L., Natural convection of micropolar fluid in an enclosure with boundary element method, Engineering Analysis and Boundary Elements, 33, 2009, pp. 485-492.
14
[15] Alloui, Z., Beji, H., Vasseur, P., Double-diffusive and Soret-induced convection of a micropolar fluid in a vertical channel, Computers & Mathematics with Applications, 62, 2011 pp. 725-36.
15
[16] Periyadurai, K., Muthtamilselvan, M., Doh, D.H., Influence of inclined Lorentz force on micropolar fluids in a square cavity with uniform and non-uniform heated thin plate, Journal of Magnetism and Magnetic Materials, 420, 2016 pp. 343-355.
16
[17] Muthtamilselvan, M., Periyadurai, K., Doh, D.H., Convection of micropolar fluid in a square cavity with an inside heater, AIAA- Journal of Thermophysics and heat Transfer, 31(4), 2017, pp. 817-831.
17
[18] Gibanov, N.S., Sheremet, M.A., Pop, I., Free convection in a trapezoidal cavity filled with a micropolar fluid, International Journal of Heat and Mass Transfer, 99, 2016, pp. 831-38.
18
[19] Turkyilmazoglu, M., Mixed convection flow of magnetohydrodynamic micropolar fluid due to a porous heated/cooled deformable plate: Exact solutions, International Journal of Heat and Mass Transfer, 106, 2017, pp. 127-134.
19
[20] Turkyilmazoglu, M., Flow of a micropolar fluid due to a porous stretching sheet and heat transfer, International Journal of Non-Linear Mechanics, 83, 2016, pp. 59-64.
20
[21] Sheremet, M.A., Pop, I, Ishak, A., Time-dependent natural convection of micropolar fluid in a wavy triangular cavity. International Journal Heat and Mass Transfer, 105, 2017, pp. 610-622.
21
[22] Versteeg, H.K., Malalasekera W., An Introduction to Computational Fluid Dynamic: The Finite Volume Method. John Wiley and Sons Inc. New York, 1995.
22
[23] Aydin, O., Pop, I., Natural convection from a discrete heater in enclosures filled with a micropolar fluid. International Journal Engineering Science, 43, 2005, pp. 1409-1418.
23
[24] Corvaro, F., Paroncini, M., Experimental analysis of natural convection in square cavities heated from below with 2D-PIV and holographic interferometry techniques, Experimental Thermal Fluid Science, 31, 2007, pp. 721-739.
24
ORIGINAL_ARTICLE
Elastic Behavior of Functionally Graded Two Tangled Circles Chamber
This paper presents the numerical elastic solution for a real problem, functionally graded chamber of hydraulic gear pumps under internal pressure. Because of the similarity and complexity for the considering geometry, a bipolar cylindrical coordinate system is used to extract the governing equations. The material properties are considered to vary along the two tangled circles with a power-law function. The two coupled governing equations solved by the differential quadrature method. The results are presented for various material index and show that the complexity in considering geometry and material inhomogeneity can change the stress and displacements value through the geometry efficiently. The results and presented method in this paper for extracting and solving the problem can be used for designing similar geometry more accurate. The results of this research are compared with those reported in the previous work.
http://jacm.scu.ac.ir/article_14043_ce4e00c871c87d2eebfc677a065dba77.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
667
679
10.22055/jacm.2019.27058.1372
Complex geometry
Bipolar cylindrical coordinate
Functionally graded material
Differential quadrature method
Two tangled circles chamber
Javad
Jafari Fesharaki
jjafari.f@gmail.com
true
1
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
LEAD_AUTHOR
Mehran
Roghani
j_jne@yahoo.com
true
2
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, 8514143131, Iran
AUTHOR
[1] Ersoy, H., Mercan K., Civalek O., Frequencies of FGM shells and annular plates by the methods of discrete singular convolution and differential quadrature methods, Composite Structures, 183, 2018, 7-20.
1
[2] Naderi Beni, N., Botshekanan Dehkordi M., An extension of Carrera unified formulation in polar coordinate for analysis of circular sandwich plate with FGM core using GDQ method, Composite Structures, 185, 2018, 421-434.
2
[3] Wang, X., Yuan Z., Accurate stress analysis of sandwich panels by the differential quadrature method, Applied Mathematical Modelling, 43, 2017, 548-565.
3
[4] Hosseini, M., Dini A., Eftekhari M., Strain gradient effects on the thermoelastic analysis of a functionally graded micro-rotating cylinder using generalized differential quadrature method, Acta Mechanica, 228(5), 2017, 1563-1580.
4
[5] Demirbas M.D., Thermal stress analysis of functionally graded plates with temperature-dependent material properties using theory of elasticity, Composites Part B: Engineering, 131, 2017, 100-124.
5
[6] Mehditabar, A., Rahimi G., Sadrabadi S.A., Three-dimensional magneto-thermo-elastic analysis of functionally graded cylindrical shell, Applied Mathematics and Mechanics, 38(4), 2017, 479-494.
6
[7] Brischetto, S., Tornabene f., Fantuzzi N., Viola E., 3D exact and 2D generalized differential quadrature models for free vibration analysis of functionally graded plates and cylinders, Meccanica, 51(9), 2016, 2059-2098.
7
[8] Aliyari Parand, A., Alibeigloo A., Static and vibration analysis of sandwich cylindrical shell with functionally graded core and viscoelastic interface using DQM, Composites Part B: Engineering, 126, 2017, 1-16.
8
[9] Adineh, M., Kadkhodayan M., Three-dimensional thermo-elastic analysis and dynamic response of a multi-directional functionally graded skew plate on elastic foundation, Composites Part B: Engineering, 125, 2017, 227-240.
9
[10] Jafari Fesharaki J., Jafari Fesharaki V., Yazdipoor M., Razavian B., Two-dimensional solution for electro-mechanical behavior of functionally graded piezoelectric hollow cylinder, Applied Mathematical Modelling, 36(11), 2012, 5521-5533.
10
[11] Shafiei, N., Mirjavadi S.S., Afshari B.M., Rabby S., Hamouda A. M. S., Nonlinear thermal buckling of axially functionally graded micro and nanobeams, Composite Structures, 168, 2017, 428-439.
11
[12] Zghal, S., Frikha A., Dammak F., Mechanical buckling analysis of functionally graded power-based and carbon nanotubes-reinforced composite plates and curved panels, Composites Part B: Engineering, 150, 2018, 165-183.
12
[13] Zghal, S., Frikha A., Dammak F., Free vibration analysis of carbon nanotube-reinforced functionally graded composite shell structures, Applied Mathematical Modelling, 53, 2018, 132-155.
13
[14] Yang J., Wu H., Kitipornchai S., Buckling and postbuckling of functionally graded multilayer graphene platelet-reinforced composite beams, Composite Structures, 161, 2017, 111-118.
14
[15] Daviran S., Sassan M., Alibakhsh K., Omid A., Differential quadrature method for thermal shock analysis of CNT reinforced metal-ceramic functionally graded disc, Composite Structures, 161, 2017, 299-307.
15
[16] Ansari R., Shojaei M.F., Gholami R., Size-dependent nonlinear mechanical behavior of third-order shear deformable functionally graded microbeams using the variational differential quadrature method, Composite Structures, 136, 2016, 669-683.
16
[17] Atrian, A., Jafari Fesharaki J., Nourbakhsh S.H., Thermo-electromechanical behavior of functionally graded piezoelectric hollow cylinder under non-axisymmetric loads, Applied Mathematics and Mechanics, 36(7), 2015, 939-954.
17
[18] Bahadori R., Najafizadeh M.M., Free vibration analysis of two-dimensional functionally graded axisymmetric cylindrical shell on Winkler–Pasternak elastic foundation by First-order Shear Deformation Theory and using Navier-differential quadrature solution methods, Applied Mathematical Modelling, 39(16), 2015, 4877-4894.
18
[19] Ansari R., Faghih Shojaei M., Shahabodini A., Bazdid-Vahdati M., Three-dimensional bending and vibration analysis of functionally graded nanoplates by a novel differential quadrature-based approach, Composite Structures, 131, 2015, 753-764.
19
[20] Zghal S., Frikha A., Dammak F., Static analysis of functionally graded carbon nanotube-reinforced plate and shell structures, Composite Structures, 176, 2017, 1107-1123.
20
[21] Frikha A., Zghal S., Dammak F., Dynamic analysis of functionally graded carbon nanotubes-reinforced plate and shell structures using a double directors finite shell element, Aerospace Science and Technology, 78, 2018, 438-451.
21
[22] Alibeigloo A., Nouri V., Static analysis of functionally graded cylindrical shell with piezoelectric layers using differential quadrature method, Composite Structures, 92(8), 2010, 1775-1785.
22
[23] Li D., Deng Z., Chen G., Xiao H., Zhu L., Thermomechanical bending analysis of sandwich plates with both functionally graded face sheets and functionally graded core, Composite Structures, 169, 2017, 29-41.
23
[24] Norouzi H., Alibeigloo A., Three dimensional static analysis of viscoelastic FGM cylindrical panel using state space differential quadrature method, European Journal of Mechanics - A/Solids, 61, 2017, 254-266.
24
[25] Civalek Ö., Free vibration of carbon nanotubes reinforced (CNTR) and functionally graded shells and plates based on FSDT via discrete singular convolution method, Composites Part B: Engineering, 111, 2017, 45-59.
25
[26] Akbari Alashti R., Khorsand M., Three-dimensional dynamo-thermo-elastic analysis of a functionally graded cylindrical shell with piezoelectric layers by DQ-FD coupled, International Journal of Pressure Vessels and Piping, 96, 2012, 49-67.
26
[27] Zghal S., Frikha A., Dammak F., Non-linear bending analysis of nanocomposites reinforced by graphene-nanotubes with finite shell element and membrane enhancement, Engineering Structures, 158, 2018, 95-109.
27
[28] Frikha A., Zghal S., Dammak F., Finite rotation three and four nodes shell elements for functionally graded carbon nanotubes-reinforced thin composite shells analysis, Computer Methods in Applied Mechanics and Engineering, 329, 2018, 289-311.
28
[29] Yas M.H., Sobhani Aragh B., Elasticity solution for free vibration analysis of four-parameter functionally graded fiber orientation cylindrical panels using differential quadrature method, European Journal of Mechanics - A/Solids, 30(5), 2011, 631-638.
29
[30] Shojaei M.F., Ansari R., Variational differential quadrature: a technique to simplify numerical analysis of structures, Applied Mathematical Modelling, 49, 2017, 705-738.
30
[31] Setoodeh, A.R., Tahani M., Selahi E., Hybrid layerwise-differential quadrature transient dynamic analysis of functionally graded axisymmetric cylindrical shells subjected to dynamic pressure, Composite Structures, 93(11), 2011, 2663-2670.
31
[32] Malekzadeh P., Three-dimensional thermal buckling analysis of functionally graded arbitrary straight-sided quadrilateral plates using differential quadrature method, Composite Structures, 93(4), 2011, 1246-1254.
32
[33] Jodaei A., Jalal M., Yas M.H., Free vibration analysis of functionally graded annular plates by state-space based differential quadrature method and comparative modeling by ANN, Composites Part B: Engineering, 43(2), 2012, 340-353.
33
[34] Janghorban M., Zare A., Free vibration analysis of functionally graded carbon nanotubes with variable thickness by differential quadrature method, Physica E: Low-dimensional Systems and Nanostructures, 43(9), 2011, 1602-1604.
34
[35] Alibeigloo A., Liew K., Elasticity solution of free vibration and bending behavior of functionally graded carbon nanotube-reinforced composite beam with thin piezoelectric layers using differential quadrature method, International Journal of Applied Mechanics, 7(01), 2015, 1550002.
35
[36] Trabelsi S., Frikha A., Zghal S., Dammak F., Thermal post-buckling analysis of functionally graded material structures using a modified FSDT, International Journal of Mechanical Sciences, 144, 2018, 74-89.
36
[37] Trabelsi S., Frikha A., Zghal S., Dammak F., A modified FSDT-based four nodes finite shell element for thermal buckling analysis of functionally graded plates and cylindrical shells, Engineering Structures, 178, 2019, 444-459.
37
[38] Heydarpour Y., Malekzadeh P., Golbahar Haghighi M., Vaghefi M., Thermoelastic analysis of rotating laminated functionally graded cylindrical shells using layerwise differential quadrature method, Acta Mechanica, 223(1), 2012, 81-93.
38
[39] Alashti R.A., Khorsand M., Three-dimensional thermo-elastic analysis of a functionally graded cylindrical shell with piezoelectric layers by differential quadrature method, International Journal of Pressure Vessels and Piping, 88(5), 2011, 167-180.
39
[40] Bellman R., Kashef B.G., Casti J., Differential quadrature: A technique for the rapid solution of nonlinear partial differential equations, Journal of Computational Physics, 10(1), 1972, 40-52.
40
[41] Shu C., Differential Quadrature and Its Application in Engineering. 2000, London: Springer-Verla.
41
[42] Horgan C.O., Chan A.M., The Pressurized Hollow Cylinder or Disk Problem for Functionally Graded Isotropic Linearly Elastic Materials, Journal of Elasticity, 55(1), 1999, 43-59.
42
[43] Heinbockel J.H., Introduction to Tensor Calculus and Continuum Mechanics. 2001: Trafford.
43
ORIGINAL_ARTICLE
Introduction to the Slide Modeling Method for the Efficient Solution of Heat Conduction Calculations
Determination of the maximum temperature and its location is the matter of the greatest importance in many technological and scientific engineering applications. In terms of numerical calculations of the heat conduction equation by using uniform mesh increments in space, large computational cost is sometimes countered. However, adaptive grid refinement method could be computationally efficient both in terms of accuracy and execution time. In this work, the numerical solution of the heat conduction equation based on the slide modeling method (SMM) is introduced. This method is based on a pre-determined mesh density approach which divides each homogeneous region into different slides and then assigns higher mesh point densities to slides of interest regarding their relative importance by performing some mathematical calculations. The importance of each region is determined by some formulated weighting factors which rely on the estimation of temperature profiles in all regions and slides. To investigate the accuracy and efficiency of the proposed method, a number of different case studies have been considered. The results all revealed the strength of the proposed SMM in comparison with the conventional method (based on uniform mesh point distribution).
http://jacm.scu.ac.ir/article_14053_6926f12106fdf4a7b807fef334e3c3c4.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
680
695
10.22055/jacm.2019.27402.1399
Slide modeling method
Efficient finite volume method
Heat conduction calculations
Unstructured meshes
Mehran
Vagheian
mehran.vagheian@gmail.com
true
1
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
LEAD_AUTHOR
Saeed
Talebi
sa.talebi@aut.ac.ir
true
2
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
Department of Energy Engineering and Physics, Amirkabir University of Technology (Tehran Polytechnic), 424 Hafez Avenue, P.O. Box 15875-4413, Tehran, Iran
AUTHOR
[1] Bergman, Th., Lavine, A. S., Incropera, F. P., Dewitt, D. P., Fundamentals of heat and mass transfer. The United States, John Wiley & Sons (2011)
1
[2] Wakil, M. M. El., Nuclear heat transport. The United States, The Haddon Craftsmen Inc (1971)
2
[3] Wang, C., Dong, X., Shu, C. H., Parallel adaptive mesh refinement method based on WENO finite difference scheme for the simulation of multi-dimensional detonation. J Comput Phys 298 (2015) 161–175
3
[4] Fengzhi, L., Penghao, R., A novel solution for heat conduction problems by extending scaled boundary finite element method. Int J Heat Mass Transf 95 (2016) 678-688
4
[5] Wang, P., Yu, B., Li, J., Zhao, Y., Shao, Q., A novel finite volume method for cylindrical heat conduction problems. Int Commun Heat Mass 63 (2015) 8–16
5
[6] Haddad, H., Guessasma, M., Fortin, J., Heat transfer by conduction using DEM–FEM coupling method. Comp Mater Sci 81 (2014) 339-347
6
[7] Yao, W., Yu, B., Gao, X., Gao, Q., A precise integration boundary element method for solving transient heat conduction problems. Int J Heat Mass Transf 78 (2014) 883-891
7
[8] Kovtanyuk, A. E., Botkin, N. D., Hoffmann, K., Numerical simulations of a coupled radiative–conductive heat transfer model using a modified Monte Carlo method. Int J Heat Mass Transf 55 (2012) 649-654
8
[9] Zhang, X., Xiang, H., A fast meshless method based on proper orthogonal decomposition for the transient heat conduction problems. Int J Heat Mass Transf 84 (2015) 729-739
9
[10] Malmir, H., Moghaddam, N. M., Zahedinejad, E., Comparison between triangular and hexagonal modeling of a hexagonal-structured reactor core using box method. Ann Nucl Energy 38 (2011) 371-378
10
[11] Vagheian, M., Ochbelagh, D. R., Gharib, M., On an improved box-scheme finite difference method based on the relative event probabilities. Prog Nucl Energy 88 (2016) 33-42
11
[12] Cao, J., Zhoua, G., Wang, C., Dong, X., A hybrid adaptive finite difference method powered by a posteriori error estimation technique. J Comput Appl Math 259 (2014) 117–128
12
[13] Lee, T. E., Baines, M. J., Langdona, S., A finite difference moving mesh method based on conservation for moving boundary problems. J Comput Appl Math 288 (2015) 1–17
13
[14] Zhai, S. H., Weng, Z. H., Feng, X., An adaptive local grid refinement method for 2D diffusion equation with variable coefficients based on block-centered finite differences. Appl Math Comput 268 (2015) 284–294
14
[15] Zhai, S. H., Qian, I., Gui, D., Fengd, X., A block-centered characteristic finite difference method for convection-dominated diffusion equation. Int Commun Heat Mass 61 (2015) 1–7
15
[16] Mallik, R. K., Mahapatra, S. K., Sarkar, A., Neural-finite difference method (NFDM) in development of improved differential approximation (IDA) and its application for coupled conduction and radiation heat transfer in a square enclosure: An experimental validation. Int J Heat Mass 52 (2009) 504–515
16
[17] Grzywiński, M., Sluzalec, A., Stochastic convective heat transfer equations in finite differences method. Int J Heat Mass Transf 43 (2000) 4003-4008.
17
[18] Kalis, H., Efficient finite-difference scheme for solving some heat transfer problems with convection in multilayer media. Int J Heat Mass Transf 43 (2000) 4467-4474
18
[19] Talebi, S., Kazeminejad, H. A mathematical approach to predict dry-out in a rod bundle. Nucl Eng Des 249 (2012) 348– 356
19
[20] Talebi, S., Kazeminejad, H., Davilu, H., Prediction of dry-out and post dry-out wall temperature using film thickness model. Predict Eng Des 244 (2012) 73–82
20
[21] IAEA-Safety Reports Series No. 30. Accident Analysis for Nuclear Power Plants with Pressurized Water Reactors. Austria: International Atomic Energy Agency (2004)
21
[22] Ordonez, Miranda J., Lemonnier, D., Ezzahri Y., Joulain K., Analytical description of the radiative-conductive heat transfer in a gray medium contained between two diffuse parallel plates. Appl Math Model 56 (2018) 51-64.
22
ORIGINAL_ARTICLE
The Urban Path Routing Adjustable Optimization by Means of Wavelet Transform and Multistage Genetic Algorithm
This paper introduces the optimization algorithm to improve search rate in urban path routing problems using viral infection and local search in urban environment. This algorithm operates based on two different approaches including wavelet transform and genetic algorithm. The variables proposed by driver such as degree of difficulty and difficulty traffic are of the essence in this technique. Wavelet transform as the first part of proposed algorithm derives edges risk. Finally, multistage genetic algorithm operates to find the optimal solution which is defined as the shortest path. The proposed algorithm is applied to the case study. The performances of the algorithm is investigated by comparing with other methods.
http://jacm.scu.ac.ir/article_14070_db999285920dab46e169c6c7de7b1b03.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
696
703
10.22055/jacm.2019.27219.1384
Adjustment Parameter
Multistage Genetic Algorithm
Routing Optimization
Wavelet Transform
Seid Miad
Zandavi
sm.zandavi@gmail.com
true
1
Department of Aerospace Engineering, Sharif University of Technology, 1458889694 Tehran, Iran
Department of Aerospace Engineering, Sharif University of Technology, 1458889694 Tehran, Iran
Department of Aerospace Engineering, Sharif University of Technology, 1458889694 Tehran, Iran
AUTHOR
Hamoon
Pourmirzaagha
h.pourmirzaagha@yahoo.com
true
2
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
AUTHOR
Alireza
Yekrangi Sendi
yekrangi_ali@yahoo.com
true
3
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
LEAD_AUTHOR
Ershad
Sadeghi Toosi
ershad.sadeghi@gmail.com
true
4
Department of Physics, Neka Branch, Islamic Azad University, Neka, Iran
Department of Physics, Neka Branch, Islamic Azad University, Neka, Iran
Department of Physics, Neka Branch, Islamic Azad University, Neka, Iran
AUTHOR
Mostafa
Zakariapour
mzakariapour@yahoo.com
true
5
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
Department of Mechanical Engineering, Ramsar Branch, Islamic Azad University, Ramsar, Iran
AUTHOR
[1] McQuillan, J., Richer, I., & Rosen, E., The new routing algorithm for the ARPANET, IEEE Transactions on Communications, 28(5), 1980, 711-719.
1
[2] Frank, H., Shortest paths in probabilistic graphs, Operations Research, 17(4), 1969, 583-599.
2
[3] Beigy, H., & Meybodi, M. R., Utilizing distributed learning automata to solve stochastic shortest path problems, International Journal of Uncertainty, Fuzziness and Knowledge-Based Systems, 14(05), 2006, 591-615.
3
[4] Misra, S., & Oommen, B. J., Dynamic algorithms for the shortest path routing problem: learning automata-based solutions, IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics), 35(6), 2005, 1179-1192.
4
[5] Burton, D., On the inverse shortest path problem, Département de Mathématique, Faculté des Sciences, Facultés Universitaires Notre-Dame de la Paix de Namur, 1993.
5
[6] Waller, S. T., & Ziliaskopoulos, A. K., On the online shortest path problem with limited arc cost dependencies, Networks: An International Journal, 40(4), 2002, 216-227.
6
[7] Pritchard, D., & Thurimella, R., Fast computation of small cuts via cycle space sampling, ACM Transactions on Algorithms (TALG), 7(4), 2011, 46.
7
[8] T. time-volume function Studies, Tehran Comprehensive Transportation and Traffic Studies (TCTTS), a division of the Municipality of Tehran, Tehran, 1995.
8
[9] Zitzler, E., Evolutionary algorithms for multiobjective optimization: Methods and applications, ed. 63, Ithaca: Shaker, 1999.
9
[10] Satoh, H., Minimal generation gap model for GAs considering both exploration and exploitation, In Proc. of the 4th International Conference on Fuzzy Logic, Neural Nets and Soft Computing, 1996, 494-497.
10
[11] Pourtakdoust, S. H., & Zandavi, S. M., A hybrid simplex non-dominated sorting genetic algorithm for multi-objective optimization, International Journal of Swarm Intelligence & Evolutionary Computation, 5(3), 2016, 1-11.
11
[12] Gouveia, L., Simonetti, L., & Uchoa, E., Modeling hop-constrained and diameter-constrained minimum spanning tree problems as Steiner tree problems over layered graphs, Mathematical Programming, 128(1-2), 2011, 123-148.
12
[13] Hao, H., & Barooah, P., Stability and robustness of large platoons of vehicles with double‐integrator models and nearest neighbor interaction, International Journal of Robust and Nonlinear Control, 23(18), 2013, 2097-2122.
13
[14] Alam, A., Fuel-efficient heavy-duty vehicle platooning, Doctoral dissertation, KTH Royal Institute of Technology, 2014.
14
[15] Lenzen, C., & Patt-Shamir, B., Fast routing table construction using small messages, In Proceedings of the Forty-Fifth Annual ACM Symposium on Theory of Computing, 2013, 381-390.
15
ORIGINAL_ARTICLE
Evaluation of Turbulence on the Dynamics of Monopile Offshore Wind Turbine under the Wave and Wind Excitations
In recent years, the use of offshore wind turbines has been considered on the agenda of the countries which have a significant maritime boundary due to more speed and stability of wind at sea. The aim of this study is to investigate the effect of wind turbulence on the aero-hydrodynamic behavior of offshore wind turbines with a monopile platform. Since in the sea, the wind turbine structures are under water and structures interactions, the dynamic analysis has been conducted under combined wind and wave loadings. The offshore wind turbines have been investigated under two models of normal and severe wind turbulence, and the results of this study show that the amplitude of fluctuation of dynamic response is increased with increasing amount of wind turbulence, and this increase is not necessarily observed in the mean values of responses. Therefore, conducting the dynamic analysis is inevitable in order to observe the effect of wind turbulence on the structures response.
http://jacm.scu.ac.ir/article_14071_0d4b5e5734f6324ec20576ea646e37eb.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
704
716
10.22055/jacm.2019.27242.1387
Offshore wind turbine
Wind turbulence
Wind and wave excitations
Monopile
Reza
Dezvareh
rdezvareh@nit.ac.ir
true
1
Assistant Professor, Faculty of Civil Engineering, Babol Noshirvani University of Technology, Shariati Av., Babol, Mazandaran, 47148 - 71167, Iran
Assistant Professor, Faculty of Civil Engineering, Babol Noshirvani University of Technology, Shariati Av., Babol, Mazandaran, 47148 - 71167, Iran
Assistant Professor, Faculty of Civil Engineering, Babol Noshirvani University of Technology, Shariati Av., Babol, Mazandaran, 47148 - 71167, Iran
LEAD_AUTHOR
[1] Dodge, D., Wind Power's Beginnings (1000 B.C. - 1300 A.D.). Illustrated History of Wind Power Development, 2009.
1
[2] Brown, L.R., World on the edge: How to prevent environmental and economic collapse, WW Norton & Company 2011.
2
[3] Kühn, M., Dynamics and design optimization of OWECS, Institute for Wind Energy, Delft University of Technology 2001.
3
[4] Matha, D., Cordle, A., Pereira, R., Jonkman, J., Challenges in simulation of aerodynamic, hydrodynamics, and mooring-line dynamics of floating offshore wind turbines, Presented at the 21st Offshore and Polar Engineering Conference Maui, Hawaii June 19-24, 2011.
4
[5] Karimirad, M., Moan, T., A simplified method for coupled analysis offloating offshore wind turbines, Marine Structures 27 (2012) 45-63.
5
[6] Dezvareh, R., Bargi, K., Mousavi, S.A., Control of wind/wave induced vibrations of jacket-type offshore wind turbines through tuned liquid column gas dampers, Structure and Infrastructure Engineering, 12(3) (2016) 312–326.
6
[7] Bargi, K., Dezvareh, R. Mousavi, S.A., Contribution of tuned liquid column gas dampers to the performance of offshore wind turbines under wind, wave, and seismic excitations, Earthquake Engineering and Engineering Vibration, 15 (2016) 551-561.
7
[8] Jonkman, J., Musial, W., Offshore Code Comparison Collaboration (OC3) for IEA Task 23 Offshore Wind Technology and Deployment, National Renewable Energy Laboratory, Technical Report NREL/TP 5000-48191, December 2010.
8
[9] Laya, E.J., Connor, J., Sunder, S.S., Hydrodynamic Forces on Flexible Offshore Structures, Journal of Engineering Mechanics, 110(3) (1984) 433-448.
9
[10] Martin, O., Hansen, L., Aerodynamics of Wind Turbines, Second Edition published by Etherscan in the UK and USA in 2008. ISBN: 978-1-84407-438-9.
10
[11] IEC. Wind Turbines, Part3: design requirements for offshore wind turbines,IEC International Standard 61400-3, 2009.
11
[12] Manual, S.P., Coastal Engineering Research Center, US Army Corps of Engineers, Washington, DC, 1984.
12
ORIGINAL_ARTICLE
Viscous Dissipation Impact on Free Convection Flow of Cu-water Nanofluid in a Circular Enclosure with Porosity Considering Internal Heat Source
In this work, free convection of Cu-water nanofluid in an enclosure by considering internally heat generated in the porous circular cavity and the impacts of viscous dissipation are numerically evaluated by control volume finite element method (CVFEM). The outer and inner sides of the circular porous enclosure are maintained at a fixed temperature while insulating the other two walls. The impacts of diverse effective parameters including the Rayleigh number, viscous dissipation, and nanofluid concentration on features of heat transfer and fluid flow are examined. Moreover, a new correlation for the average Nusselt number is developed according to the study’s active parameters. It can be deduced by the results that the maximum value of the temperature is proportional to the viscous dissipation parameter.
http://jacm.scu.ac.ir/article_14076_0ca4fe7f01fe78d757ec18c1453b2519.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
717
726
10.22055/jacm.2019.27465.1402
Free convection of nanofluid
Porous circular enclosure
Viscous dissipation
CVFEM
Nusselt number
Abdul Sattar
Dogonchi
sattar.dogonchi@yahoo.com
true
1
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
LEAD_AUTHOR
Ali J.
Chamkha
achamkha@pmu.edu.sa
true
2
Mechanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, Ras Al Khaimah, United Arab Emirates
Mechanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, Ras Al Khaimah, United Arab Emirates
Mechanical Engineering Department, Prince Sultan Endowment for Energy and Environment, Prince Mohammad Bin Fahd University, Al-Khobar 31952, Saudi Arabia | RAK Research and Innovation Center, American University of Ras Al Khaimah, Ras Al Khaimah, United Arab Emirates
AUTHOR
Seyyed Masoud
Seyyedi
s.masoud_seyedi@yahoo.com
true
3
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
AUTHOR
Mehdi
Hashemi-Tilehnoee
mehdi.hashemi.t@gmail.com
true
4
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
Department of Mechanical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
AUTHOR
Davood Domiri
Ganji
mirgang@nt.ac.ir
true
5
Mechanical Engineering Department, Babol Noshirvani University of Technology, Babol, Iran
Mechanical Engineering Department, Babol Noshirvani University of Technology, Babol, Iran
Mechanical Engineering Department, Babol Noshirvani University of Technology, Babol, Iran
AUTHOR
[1] Hayat, T., Sajjad, R., Alsaedi, A., Muhammad, T., Ellahi, R., On squeezed flow of couple stress nanofluid between two parallel plates, Results in Physics, 7, 2017, 553-561.
1
[2] Ellahi, R., Hassan, M., Zeeshan, A., Aggregation effects on water base Al2O3-nanofluid over permeable wedge in mixed convection, Asia-Pacific Journal of Chemical Engineering, 11, 2016, 179-186.
2
[3] Zhang, Y., Zhang, M., Bai, Y., Unsteady flow and heat transfer of power-law nanofluid thin film over a stretching sheet with variable magnetic field and power-law velocity slip effect, Journal of the Taiwan Institute of Chemical Engineers, 70, 2017, 104-110.
3
[4] Dogonchi, A.S., Ganji, D.D., Impact of Cattaneo-Christov heat flux on MHD nanofluid flow and heat transfer between parallel plates considering thermal radiation effect, Journal of the Taiwan Institute of Chemical Engineers, 80, 2017, 52-63.
4
[5] Bhatti, M.M., Rashidi, M.M., Numerical simulation of entropy generation on mhd nanofluid towards a stagnation point flow over a stretching surface, International Journal of Applied and Computational Mathematics, 3, 2017, 2275-2289.
5
[6] Dogonchi, A.S., Ganji, D.D., Analytical Solution and heat transfer of two-phase nanofluid flow between Non-parallel walls considering Joule heating effect, Powder Technology, 318, 2017, 390-400.
6
[7] Hsiao, Kai-Long, Micropolar Nanofluid Flow with MHD and Viscous Dissipation Effects Towards a Stretching Sheet with Multimedia Feature, International Journal of Heat and Mass Transfer, 112, 2017, 983-990.
7
[8] Rashidi, M.M., Vishnu Ganesh, N., Abdul Hakeem, A.K., Ganga, B., Buoyancy effect on MHD flow of nanofluid over a stretching sheet in the presence of thermal radiation, Journal of Molecular Liquids, 198, 2014, 234-238.
8
[9] Hsiao, Kai-Long, Stagnation Electrical MHD Nanofluid Mixed Convection with Slip Boundary on a Stretching Sheet, Applied Thermal Engineering, 98, 2016, 850-861.
9
[10] Hsiao, Kai-Long, Combined Electrical MHD Heat Transfer Thermal Extrusion System Using Maxwell Fluid with Radiative and Viscous Dissipation Effects, Applied Thermal Engineering, 112, 2016, 1281-1288.
10
[11] Hsiao, Kai-Long, To Promote Radiation Electrical MHD Activation Energy Thermal Extrusion Manufacturing System Efficiency by Using Carreau-Nanofluid with Parameters Control Method, Energy, 130, 2017, 486-499.
11
[12] Hung, Y.M., Analytical study on forced convection of nanoﬂuids with viscous dissipation in microchannels, Heat Transfer Engineering, 31, 2010, 1184-1192.
12
[13] Wang, K., Li, P., Forced convection in bidisperse porous media incorporating viscous dissipation, Applied Thermal Engineering, 140, 2018, 86-94.
13
[14] Mehmood, A., Ali, A., Analytic Solution of Three-Dimensional Viscous Flow and Heat Transfer Over a Stretching Flat Surface by Homotopy Analysis Method, Journal of Heat Transfer, 130(12), 2008, 121701.
14
[15] Dogonchi, A.S., Divsalar, K., Ganji, D.D., Flow and heat transfer of MHD nanofluid between parallel plates in the presence of thermal radiation, Computer Methods in Applied Mechanics and Engineering, 310, 2016, 58-76.
15
[16] Dogonchi, A.S., Alizadeh, M., Ganji, D.D., Investigation of MHD Go-water nanofluid flow and heat transfer in a porous channel in the presence of thermal radiation effect, Advanced Powder Technology, 28, 2017, 1815-1825.
16
[17] Dib, A., Haiahem, A., Bou-said, B., Approximate analytical solution of squeezing unsteady nanofluid flow, Powder Technology, 269, 2015, 193-199.
17
[18] Ellahi, R., Bhatti, M.M., Khalique, C.M., Three-dimensional flow analysis of Carreau fluid model induced by peristaltic wave in the presence of magnetic field, Journal of Molecular Liquids, 241, 2017, 1059-1068.
18
[19] Dogonchi, A.S., Ganji, D.D., Thermal radiation effect on the nano-fluid buoyancy flow and heat transfer over a stretching sheet considering Brownian motion, Journal of Molecular Liquids, 223, 2016, 521-527.
19
[20] Dogonchi, A.S., Ganji, D.D., Investigation of MHD nanofluid flow and heat transfer in a stretching/shrinking convergent/divergent channel considering thermal radiation, Journal of Molecular Liquids, 220, 2016, 592-603.
20
[21] Dogonchi, A.S., Ganji, D.D., Study of nanofluid flow and heat transfer between non-parallel stretching walls considering Brownian motion, Journal of the Taiwan Institute of Chemical Engineers, 69, 2016, 1-13.
21
[22] Akbarzadeh, M., Rashidi, S., Bovand, M., Ellahi, R., A sensitivity analysis on thermal and pumping power for the flow of nanofluid inside a wavy channel, Journal of Molecular Liquids, 220, 2016, 1-13.
22
[23] Dogonchi, A.S., Chamkha, A.J., Seyyedi, S.M., Ganji, D.D., Radiative nanofluid flow and heat transfer between parallel disks with penetrable and stretchable walls considering Cattaneo-Christov heat flux model, Heat Transfer-Asian Research, 47, 2018, 735-753.
23
[24] Ellahi, R., Tariq, M.H., Hassan, M., Vafai, K., On boundary layer nano-ferroliquid flow under the influence of low oscillating stretchable rotating disk, Journal of Molecular Liquids, 229, 2017, 339-345.
24
[25] Dogonchi, A.S., Ganji, D.D., Effects of Cattaneo-Christov heat flux on buoyancy MHD nanofluid flow and heat transfer over a stretching sheet in the presence of Joule heating and thermal radiation impacts, Indian Journal of Physics, 92, 2018, 757–766.
25
[26] Alizadeh, M., Dogonchi, A.S., Ganji, D.D., Micropolar nanofluid flow and heat transfer between penetrable walls in the presence of thermal radiation and magnetic field, Case Studies in Thermal Engineering, 12, 2018, 319-332.
26
[27] Dogonchi, A.S., Ganji, D.D., Makinde, O.D., Impact of Stretching and Penetration of Walls on Nanofluid Flow and Heat Transfer in a Rotating System, Defect and Diffusion Forum, 387, 2018, 37-50.
27
[28] Ghalambaz, M., Doostani, A., Izadpanahi, E., Chamkha, A.J., Phase-change heat transfer in a cavity heated from below: The effect of utilizing single or hybrid nanoparticles as additives, Journal of the Taiwan Institute of Chemical Engineers, 72, 2017, 104-115.
28
[29] Seyyedi, S.M., Dogonchi, A.S., Hashemi-Tilehnoee, M., Ganji, D.D., Improved velocity and temperature profiles for integral solution in the laminar boundary layer flow on a semi-infinite flat plate, Heat Transfer-Asian Research, 48 (2019) 182-215.
29
[30] Rashad, A.M., Rashidi, M.M., Lorenzini, G., Ahmed, S.E., Aly, A.M., Magnetic field and internal heat generation effects on the free convection in a rectangular cavity filled with a porous medium saturated with Cu–water nanofluid, International Journal of Heat and Mass Transfer, 104, 2017, 878–889.
30
[31] Soleimani, S., Sheikholeslami, M., Ganji, D.D., Gorji-Bandpay, M., Natural convection heat transfer in a nanofluid filled semi-annulus enclosure, International Communications in Heat and Mass Transfer, 39, 2012, 565–574.
31
[32] Sheremet, M.A., Revnic, C., Pop, I., Free convection in a porous wavy cavity filled with a nanofluid using Buongiorno's mathematical model with thermal dispersion effect, Applied Mathematics and Computation, 299, 2017, 1-15.
32
[33] Hatami, M., Song, D., Jing, D., Optimization of a circular-wavy cavity filled by nanofluid under the natural convection heat transfer condition, International Journal of Heat and Mass Transfer, 98, 2016, 758–767.
33
[34] Sheremet, M.A., Cimpean, D.S., Pop, I., Free convection in a partially heated wavy porous cavity filled with a nanofluid under the effects of Brownian diffusion and thermophoresis, Applied Thermal Engineering, 113, 2017, 413-418.
34
[35] Sheremet, M.A., Grosan, T., Pop, I., Natural convection and entropy generation in a square cavity with variable temperature side walls filled with a nanofluid: buongiorno’s mathematical model, Entropy, 19, 2017, 337.
35
[36] Dogonchi, A.S., Hashim, Heat transfer by natural convection of Fe3O4-water nanofluid in an annulus between a wavy circular cylinder and a rhombus. International Journal of Heat and Mass Transfer, 130, 2019, 320–332.
36
[37] Sheremet, M.A., Grosan, T., Pop, I., Free convection in a square cavity filled with a porous medium saturated by nanofluid using Tiwari and Das’ nanofluid model, Transport in Porous Media, 106, 2015, 595-610.
37
[38] Dogonchi, A.S., Ismael, M., Chamkha, A.J., Ganji, D.D., Numerical analysis of natural convection of Cu-water nanofluid filling triangular cavity with semi-circular bottom wall, Journal of Thermal Analysis and Calorimetry, 135(6), 2019, 3485–3497.
38
[39] Seyyedi, S.M., Sahebi, N., Dogonchi, A.S., Hashemi-Tilehnoee, M., Numerical and experimental analysis of a rectangular single-phase natural circulation loop with asymmetric heater position, International Journal of Heat and Mass Transfer, 130, 2019, 1343-1357.
39
[40] Dogonchi, A.S., Chamkha, A.J., Ganji, D.D., A numerical investigation of magneto-hydrodynamic natural convection of Cu-water nanofluid in a wavy cavity using CVFEM, Journal of Thermal Analysis and Calorimetry, 135(4), 2019, 2599–2611.
40
[41] Abu-Nada, E., Masoud, Z., Hijazi, A., Natural convection heat transfer enhancement in horizontal concentric annuli using nanofluids, International Communications in Heat and Mass Transfer, 35, 2008, 657-665.
41
[42] Dogonchi, A.S., Sheremet, M.A., Ganji, D.D., Pop, I., Free convection of copper-water nanofluid in a porous gap between hot rectangular cylinder and cold circular cylinder, Journal of Thermal Analysis and Calorimetry, 135(2), 2019, 1171–1184.
42
[43] Jou, R.Y., Tzeng, S.C., Numerical research of nature convective heat transfer enhancement filled with nanofluids in rectangular enclosures, International Communications in Heat and Mass Transfer, 33, 2006, 727–736.
43
[44] Dogonchi, A.S., Sheremet, M.A., Pop, I., Ganji, D.D., MHD natural convection of Cu/ H2O nanofluid in a horizontal semi-cylinder with a local triangular heater, International Journal of Numerical Methods for Heat & Fluid Flow, 2018, doi:10.1108/HFF-04-2018-0160.
44
[45] Bararnia, H., Hooman, K., Ganji, D.D., Natural convection in a nanofluid filled portion cavity; the Lattice-Boltzmann method, Numerical Heat Transfer Part A, 59, 2011, 487–502.
45
[46] Dogonchi, A.S., Selimefendigil, F., Ganji, D.D., Magneto-hydrodynamic natural convection of CuO-water nanofluid in complex shaped enclosure considering various nanoparticle shapes, International Journal of Numerical Methods for Heat & Fluid Flow, 2018, doi:10.1108/HFF-06-2018-0294.
46
[47] Dogonchi, A.S., Waqas, M., Seyyedi, S.M., Hashemi-Tilehnoee, M., Ganji, D.D., CVFEM analysis for Fe3O4-H2O nanofluid in an annulus subject to thermal radiation, International Journal of Heat and Mass Transfer, 132, 2019, 473-483.
47
[48] Chamkha, A.J., Dogonchi, A.S., Ganji, D.D., Magnetohydrodynamic Nanofluid Natural Convection in a Cavity under Thermal Radiation and Shape Factor of Nanoparticles Impacts: A Numerical Study Using CVFEM, Applied Sciences, 8, 2018, 2396.
48
[49] Grosan, T., Revnic, C., Pop, I., Ingham, D.B., Magnetic field and internal heat generation effects on the free convection in a rectangular cavity filled with a porous medium, International Journal of Heat and Mass Transfer, 52, 2009, 1525–1533.
49
ORIGINAL_ARTICLE
Correlation between the Weld Residual Stresses and its Tensile and Impact Strength
In this study, the tensile strength, impact strength, and the hardness of the weld are determined. A criterion is proposed for describing the effect of residual stress on the weld mechanical properties. Dimensionless parameters such as Rya (the average of residual stress over the material yield strength), Rym (the maximum residual stress over the material yield strength), Ru2 (the difference in the residual stress over the material ultimate strength), and Ru3 (the difference ratio between the maximum and minimum of three-dimensional residual stresses over the material ultimate strength) are presented to describe the influence of residual stresses on the actual mechanical behavior of the welded pipe. Maximum Rya criterion and lowest strength are obtained at the weld gap center on the external surface of the pipe. The sharp decline in Ru2 criteria is consistent with the severe reduction in impact strength perpendicular to the weld gap.
http://jacm.scu.ac.ir/article_14093_64fc61df5e4c7ac06e809afbdb001e53.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
727
734
10.22055/jacm.2019.27491.1408
Assembling
Residual stress
Girth welding
Mechanical properties
Dimensionless parameters
Majid
Sabokrouh
majidsabokrooh@yahoo.com
true
1
Faculty of Engineering, Mahallat Institute of Higher Education, Mahallat, 3781151958, Iran
Faculty of Engineering, Mahallat Institute of Higher Education, Mahallat, 3781151958, Iran
Faculty of Engineering, Mahallat Institute of Higher Education, Mahallat, 3781151958, Iran
LEAD_AUTHOR
Mohammadreza
Farahani
mrfarahani@ut.ac.ir
true
2
School of Mechanical Engineering, College of Engineering, University of Tehran, Tehran, 1417614418, Iran
School of Mechanical Engineering, College of Engineering, University of Tehran, Tehran, 1417614418, Iran
School of Mechanical Engineering, College of Engineering, University of Tehran, Tehran, 1417614418, Iran
AUTHOR
[1] Breakthrough Strategy Committee, Construction Industry Institute. New joining technology for metal pipe in the construction industry. BTSC Document, Austin, TX: Construction Industry Institute, 2003.
1
[2] Farahani, M., Sattari-Far, I., Akbari, D., Alderliesten, R., Numerical and experimental investigations of effects of residual stresses on crack behavior in Aluminum 6082-T6, Proc IMeche Part B: Journal of Mechanical Engineering Science, 226(2), 2012, 2178-2191.
2
[3] Farahani, M., Sattari-Far, I., Effects of residual stresses on crack-tip constraints, Scientia Iranica B, 18(6), 2011, 1267–1276.
3
[4] Francis, J. A., Welding Residual Stresses in Ferritic Power Plant Steels, Materials Science and Technology, 23, 2007, 1009-1200.
4
[5] Zargar, S. H., Farahani, M., Givi, M. K. B., Numerical and experimental investigation on the effects of submerged arc welding sequence on the residual distortion of the fillet welded plates, Proc IMeche Part B: Journal of Engineering Manufacture, 230(4), 2016, 654-661.
5
[6] Hoseini, H. T., Farahani, M. and Sohrabian, M., Process analysis of resistance spot welding on the Inconel alloy 625 using artificial neural networks, International Journal of Manufacturing Research, 12(4), 2017, 444-460.
6
[7] Edwards, L., Bouchard, PJ., Dutta, M., Wang, DQ, Santisteban, JR., Hiller, S., Fitzpatrick, M.E., Direct Measurement of the Residual Stresses Near a Boat-Shaped Repair in a 20 mm Thick Stainless Steel Tube Butt Weld, International Journal of Pressure Vessels and Piping, 82, 2005, 288-298.
7
[8] Kandil, F., Lord, J., Fry, A., Grant, P., Measurement of Residual Stress in Components, A Review of Residual Stress Measurement Methods, NPL Report, 2001.
8
[9] Edwards, L., Bouchard, PJ., Dutta, M., Wang, DQ, Santisteban, JR., Hiller, S., Fitzpatrick, M.E., Direct Measurement of the Residual Stresses Near a Boat-Shaped Repair in a 20 mm Thick Stainless Steel Tube Butt Weld, International Journal of Pressure Vessels and Piping, 82, 2005, 288-298.
9
[10] Bouchard, R.P.J., George, D., Santisteban , J.R., Bruno, G., Dutta , M., Edwards, L., Kingston, E., Smith, D.J. Measurement of the Residual Stresses in a Stainless Steel Pipe Girth Weld Containing Long and Short Repairs, International Journal of Pressure Vessels and Piping, 82, 2005, 299-310.
10
[11] Law, M., Prask, H., Luzin, V., Gnaeupel-Herold, T., Residual Stress Measurements in Coil, Linepipe and Girth Welded Pipe, Materials Science and Engineering, 437, 2006, 60-63.
11
[12] Silva, C.C., Farias, J.P., Non-Uniformity of Residual Stress Profiles in Butt Welded Pipes in Manual Arc Welding, Journal of Materials Processing Technology, 99, 2007, 452-455.
12
[13] Sattari-Far, I., Farahani, M., Effect of the Weld Groove Shape and Pass Number on Residual Stresses in Butt-Welded Pipes, International Journal of Pressure Vessels and Piping, 86, 2009, 723-731.
13
[14] Ruibin, G., Yiliang, Z., Xuedong, X., Liang, S., Yong, Y., Residual Stress Measurement of New and In-Service X70 Pipelines by X-ray Diffraction Method, NDT&E International, 44, 2011, 397-393.
14
[15] Paddea, S., Francis, J.A., Paradowska, A.M., Bouchard, R.P.J., Shibli, I.A., Residual Stress Distributions in a P91 Steel-Pipe Girth Weld Before and After Post Weld Heat Treatment, Materials Science and Engineering, 534, 2012, 663-672.
15
[16] Obeid, O., Alfano, G., Bahai, H. and Jouhara, H., A parametric study of thermal and residual stress fields in lined pipe welding, Thermal Science and Engineering Progress, 4, 2017, 205-218.
16
[17] Obeid, O., Alfano, G., Bahai, H. and Jouhara, H., Experimental and numerical thermo-mechanical analysis of welding in a lined pipe, Journal of Manufacturing Processes, 32, 2018, 857-872.
17
[18] Sabokrouh, M., Hashemi, S.H and Farahani, M., Experimental study of the weld, microstructure properties in assembling of natural gas transmission pipelines, Proc IMechE, Part B: J Engineering Manufacture, 231(6), 2017, 1039-1047.
18
[19] Sabokrouh, M. and Farahani, M., Experimental study of the residual stresses in girth weld of natural gas transmission pipeline, Journal of Applied and Computational Mechanics, 5(2), 2019, 199-206.
19
[20] Akbari, D., Farahani, M. and Soltani, N., Effects of the weld groove shape and geometry on residual stresses in dissimilar butt-welded pipes. The Journal of Strain Analysis for Engineering Design, 47(2), 2012, 73-82.
20
[21] Farahani, M., Sattari-Far, I., Akbari, D. and Alderliesten, R., Effect of residual stresses on crack behavior in single edge bending specimens, Fatigue & Fracture of Engineering Materials & Structures, 36(2), 2013, 115-126.
21
ORIGINAL_ARTICLE
Estimating the Mode Shapes of a Bridge Using Short Time Transmissibility Measurement from a Passing Vehicle
This paper reports on the analysis of the signals sent by accelerometers fixed on the axles of a vehicle which passes over a bridge. The length of the bridge is divided into some parts and the transmissibility measurement is applied to the signals recorded by two following instrumented axles. As the transmissibility procedure is performed on the divided signals, the method is called Short Time Transmissibility Measurement. Afterwards, a rescaling process is accomplished in order to estimate the bridge mode shapes. The numerical results indicate that the method can calculate the mode shapes of the bridge accurately. It is demonstrated that short time transmissibility method does not depend on the excitation characteristics contrary to the other related methods which assume that the excitation should be white noise. Generally, the bridge mode shapes may be invisible due to the excitation exerted by the road profile. This issue is also resolved by subtracting the signals from the successive axles. Finally, the signals are contaminated with noise and the robustness of the method is investigated.
http://jacm.scu.ac.ir/article_14113_c6b5b210b14f0b1bc03959c73cb611f8.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
735
748
10.22055/jacm.2019.27225.1385
Transmissibility Measurement
Vehicle Bridge Interaction (VBI)
Passing vehicle
Bridge mode shapes
Road profile
Seyed Maziar
Marashi
maziar.marashi@stu.nit.ac.ir
true
1
PhD Student, Faculty of Mechanical Engineering, Babol University of Technology
Shariati Av., Babol, 47148-71167, Iran
PhD Student, Faculty of Mechanical Engineering, Babol University of Technology
Shariati Av., Babol, 47148-71167, Iran
PhD Student, Faculty of Mechanical Engineering, Babol University of Technology
Shariati Av., Babol, 47148-71167, Iran
AUTHOR
Mohammad Hadi
Pashaei
mpashaei@nit.ac.ir
true
2
Associate Professor, Faculty of Mechanical Engineering, Babol University of Technology, Shariati Av., Babol, 47148-71167, Iran
Associate Professor, Faculty of Mechanical Engineering, Babol University of Technology, Shariati Av., Babol, 47148-71167, Iran
Associate Professor, Faculty of Mechanical Engineering, Babol University of Technology, Shariati Av., Babol, 47148-71167, Iran
LEAD_AUTHOR
Mohammad Mahdi
Khatibi
mmkhatibi@semnan.ac.ir
true
3
Assistant Professor, Faculty of Mechanical Engineering, Semnan University, Central Administration of Semnan University, Campus 1, Semnan, 35131-19111, Iran
Assistant Professor, Faculty of Mechanical Engineering, Semnan University, Central Administration of Semnan University, Campus 1, Semnan, 35131-19111, Iran
Assistant Professor, Faculty of Mechanical Engineering, Semnan University, Central Administration of Semnan University, Campus 1, Semnan, 35131-19111, Iran
AUTHOR
[1] Yang, J., Lam, H., Hu, J., Ambient vibration test, modal identification and structural model updating following Bayesian framework. International Journal of Structural Stability and Dynamics, 15(7), 2015, 1540024.
1
[2] Curadelli, R., et al., Damage detection by means of structural damping identification. Engineering Structures, 30(12), 2008, 3497-3504.
2
[3] Williams, C., Salawu, O., Damping as a damage indication parameter. in Proceedings of SPIE - The International Society for Optical Engineering. 1997.
3
[4] Kim, J.-T., et al., Damage identification in beam-type structures: frequency-based method vs mode-shape-based method. Engineering Structures, 25(1), 2003, 57-67.
4
[5] Ventura, C., Felber, A., Stiemer, S., Determination of the dynamic characteristics of the Colquitz River Bridge by full-scale testing. Canadian Journal of Civil Engineering, 23(2), 1996, 536-548.
5
[6] Huang, C., et al., Dynamic testing and system identification of a multi‐span highway bridge. Earthquake Engineering & Structural Dynamics, 28(8), 1999, 857-878.
6
[7] Yang, Y.-B., Lin, C., Yau, J., Extracting bridge frequencies from the dynamic response of a passing vehicle. Journal of Sound and Vibration, 272(3), 2004, 471-493.
7
[8] Lin, C., Yang, Y., Use of a passing vehicle to scan the fundamental bridge frequencies: An experimental verification. Engineering Structures, 27(13), 2005, 1865-1878.
8
[9] Oshima, Y., et al. Estimation of bridge eigenfrequencies based on vehicle responses using ICA. in Proceedings of the 10th International Conference on Structural Safety and Reliability (ICOSSAR’09). 2009.
9
[10] Yang, Y., Chang, K., Extraction of bridge frequencies from the dynamic response of a passing vehicle enhanced by the EMD technique. Journal of Sound and Vibration, 322(4), 2009, 718-739.
10
[11] Li, W.-m., et al., Optimization method based on Generalized Pattern Search Algorithm to identify bridge parameters indirectly by a passing vehicle. Journal of Sound and Vibration, 333(2), 2014, 364-380.
11
[12] Malekjafarian, A., O'Brien, E.J., Application of output-only modal method in monitoring of bridges using an instrumented vehicle. in Civil Engineering Research in Ireland, Belfast, UK, 28-29 August, 2014. 2014.
12
[13] Zhu, X., Law, S., Wavelet-based crack identification of bridge beam from operational deflection time history. International Journal of Solids and Structures, 43(7), 2006, 2299-2317.
13
[14] Pandey, A., Biswas, M., Samman, M., Damage detection from changes in curvature mode shapes. Journal of Sound and Vibration, 145(2), 1991, 321-332.
14
[15] Yang, Y., Li, Y., Chang, K., Constructing the mode shapes of a bridge from a passing vehicle: a theoretical study. Smart Structures and Systems, 13(5), 2014, 797-819.
15
[16] Oshima, Y., Yamamoto, K., Sugiura, K., Damage assessment of a bridge based on mode shapes estimated by responses of passing vehicles. Smart Structures and Systems, 13(5), 2014, 731-753.
16
[17] Zhang, Y., Wang, L., Xiang, Z., Damage detection by mode shape squares extracted from a passing vehicle. Journal of Sound and Vibration, 331(2), 2012, 291-307.
17
[18] Oshima, Y., et al. Eigenfrequency estimation for bridges using the response of a passing vehicle with excitation system. in Proceedings of the fourth international conference on bridge maintenance, safety and management. 2008.
18
[19] Malekjafarian, A., O'Brien, E.J., Identification of bridge mode shapes using short time frequency domain decomposition of the responses measured in a passing vehicle. Engineering Structures, 81, 2014, 386-397.
19
[20] McGetrick, P.J., Gonzlez, A., OBrien, E.J., Theoretical investigation of the use of a moving vehicle to identify bridge dynamic parameters. Insight-Non-Destructive Testing and Condition Monitoring, 51(8), 2009, 433-438.
20
[21] Chang, K., Wu, F., Yang, Y., Effect of road surface roughness on indirect approach for measuring bridge frequencies from a passing vehicle. Interaction and Multiscale Mechanics, 3(4), 2010, 299-308.
21
[22] He, W.-Y., He, J., Ren, W.-X., Damage localization of beam structures using mode shape extracted from moving vehicle response. Measurement, 121, 2018, 276-285.
22
[23] He, W.Y., Ren, W.X., Zuo, X.H., Mass‐normalized mode shape identification method for bridge structures using parking vehicle‐induced frequency change. Structural Control and Health Monitoring, 25(6), 2018, 2174.
23
[24] Malekjafarian, A., OBrien, E.J., On the use of a passing vehicle for the estimation of bridge mode shapes. Journal of Sound and Vibration, 397, 2017, 77-91.
24
[25] Yang, Y., Yang, J.P., State-of-the-art review on modal identification and damage detection of bridges by moving test vehicles. International Journal of Structural Stability and Dynamics, 18(2), 2018, 1850025.
25
[26] Brincker, R., Zhang, L., Andersen, P., Modal identification of output-only systems using frequency domain decomposition. Smart Materials and Structures, 10(3), 2001, 441.
26
[27] Devriendt, C., Guillaume, P., The use of transmissibility measurements in output-only modal analysis. Mechanical Systems and Signal Processing, 21(7), 2007, 2689-2696.
27
[28] Yan, W.J., Ren, W.X., Operational modal parameter identification from power spectrum density transmissibility. Computer‐Aided Civil and Infrastructure Engineering, 27(3), 2012, 202-217.
28
[29] Kong, X., Cai, C., Kong, B., Damage detection based on transmissibility of a vehicle and bridge coupled system. Journal of Engineering Mechanics, 141(1), 2014, 04014102.
29
[30] Ewins, D., Modal testing: theory, practice and application (mechanical engineering research studies: engineering dynamics series). 2003.
30
[31] Araújo, I.G., Laier, J.E., Operational modal analysis using SVD of power spectral density transmissibility matrices. Mechanical Systems and Signal Processing, 46(1), 2014, 129-145.
31
[32] Bu, J., Law, S., Zhu, X., Innovative bridge condition assessment from dynamic response of a passing vehicle. Journal of Engineering Mechanics, 32(12), 2006, 1372-1379.
32
[33] Yang, Y., Chang, K., Extracting the bridge frequencies indirectly from a passing vehicle: Parametric study. Engineering Structures, 31(10), 2009, 2448-2459.
33
[34] Yang, Y., Li, Y., Chang, K., Using two connected vehicles to measure the frequencies of bridges with rough surface: a theoretical study. Acta Mechanica, 223(8), 2012, 1851-1861.
34
[35] Yang, Y., Chang, K., Li, Y., Filtering techniques for extracting bridge frequencies from a test vehicle moving over the bridge. Engineering Structures, 48, 2013, 353-362.
35
[36] Organisation, I.S., Mechanical vibration-road surface profiles-reporting of measured data, in ISO 8608:1995. 1995.
36
[37] Keenahan, J., et al., The use of a dynamic truck–trailer drive-by system to monitor bridge damping. Structural Health Monitoring, 13(2), 2014, 143-157.
37
[38] Clough, R.W., Penzien, J., Dynamics of structures. Berkeley: Computers & Structures. 1995, Inc.
38
[39] Tedesco, J.W., McDougal, W.G., Ross, C.A., Structural dynamics: theory and applications. 1999: Addison-Wesley Menlo Park, CA.
39
ORIGINAL_ARTICLE
Numerical Modeling and Multi Objective Optimization of Face Milling of AISI 304 Steel
There is a requirement to find accurate parameters to accomplish precise dimensional accuracy, excellent surface integrity and maximum MRR. This work studies the influence of various cutting parameters on output parameters like Cutting force, Surface roughness, Flatness, and Material removal rate while face milling. A detailed finite element model was developed to simulate the face milling process. The material constitutive behavior is described by Johnson-Cook material model and the damage criteria is established by Johnson-Cook damage model. The result indicate significant effects of all three cutting parameters on MRR and both feed rate and depth of cut have significant effect on cutting force. Also, feed rate has significant effect on PEEQ and none of the parameters have effect on flatness.
http://jacm.scu.ac.ir/article_14114_5353af78d08c5a743dda48d341900509.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
749
762
10.22055/jacm.2019.27528.1414
Face Milling
AISI 304 Steel
Surface Roughness
Flatness
Material Removal Rate
Response Surface Methodology
K.
Krishnaprasad
kpk1110@gmail.com
true
1
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
AUTHOR
C.S.
Sumesh
cs_sumesh@cb.amrita.edu
true
2
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
LEAD_AUTHOR
A.
Ramesh
r_ajith@cb.amrita.edu
true
3
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
Department of Mechanical Engineering, Amrita school of Engineering, Coimbatore, Amrtia Vishwa Vidyapeetham, India
AUTHOR
[1] Kannan, S., Baskar, N., Sureshkumar, B., Selection of Machining Parameters in Face Milling Operations for Copper Work Piece Material Using Response Surface Methodology and Genetic Algorithm, All India Manufacturing Technology, Design and Research Conference, 2014.
1
[2] Prajapati, V., Thakkar, K., Thakkar, S., Parikh, H., Study and Investigate Effects of Cutting Parameters in CNC Milling process for Aluminium alloy-8011H14 through Taguchi design method, International Journal of Innovative Research in Science, Engineering and Technology, 2, 2013, 3271-3276.
2
[3] Yasir, M., Ginta, T., Ariwahj, B., Alkali, A., Danish, M., Effect of Spindle speed (N) and Feed rate (f) On Ra of AISI 316L SS Using End-Milling, ARPN Journal of Engineering and Applied Sciences, 11, 2016, 2496-2500.
3
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[20] Moaz, H.A., Basim, A., Khidhir, M.N.M., Ansari, B.M., FEM to predict the effect of feed rate (f) on Ra with cutting force (Fc) during face milling of titanium alloy, HBRC Journal, 9, 2013, 263-269.
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[23] Sumesh, C.S., Ramesh, A., Numerical Modelling and Optimization of Dry Orthogonal Turning of Al6061 T6 Alloy, Periodica Polytechnica Mechanical Engineering, 62(3), 2018, 196-202.
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[24] Reimer, A., Fitzpatrick, S., Luo, X.C., Zhao, J., Numerical Investigation of Mechanical Induced Stress during Precision End Milling Hardened Tool Steel, Solid State Phenomena, 261, 2017, 362-369.
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[25] Ducobu, F., Arrazola, P.J.E., Rivière, L., Ortiz, G., de Zarate, A., Filippia, M.E., The CEL Method as an Alternative to the Current Modelling Approaches for Ti6Al4V Orthogonal Cutting Simulation, Procedia CIRP, 58, 2017, 245-250.
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[29] Gao, Y., Ko, J.H., Lee, H.P., 3D coupled Eulerian Lagrangian finite element analysis of end milling, International Journal of Advanced Manufacturing Technology, 98(1-4), 2018, 849-857.
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[35] Grzenda, M., Bustillo, A., Semi-supervised roughness prediction with partly unlabeled vibration data streams, Journal of Intelligent Manufacturing, 30(2), 2019, 933-945.
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[36] Rodríguez, J.J., Quintana, G., Bustillo, A., Ciurana, J., A decision-making tool based on decision trees for roughness prediction in face milling, International Journal of Computer Integrated Manufacturing, 30(9), 2017, 943-957.
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[37] Wojciechowski, S., Maruda, R.W., Nieslony, P., Krolczyk, G.M., Application of signal to noise ratio and grey relational analysis to minimize forces and vibrations during precise ball end milling, Precision Engineering, 51, 2018, 582-596.
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[39] Wojciechowski, S., Maruda, R.W., Barranas, S., Nieslony, P., Krolczyk, G.M., Optimisation of machining parameters during ball end milling of hardened steel with various surface inclinations, Measurement, 111, 2017, 18-28.
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[40] Chen, G., Ren, C., Yang, X., Jin, X., Guo, T., Finite Element Simulation of high speed machining of Titanium alloy (Ti-6Al-4V) based on ductile failure model, International Journal of Advanced Manufacturing Technology, 56, 2011, 1027-1038.
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41
ORIGINAL_ARTICLE
Study of MHD Second Grade Flow through a Porous Microchannel under the Dual-Phase-Lag Heat and Mass Transfer Model
A semi-analytical investigation has been carried out to analyze unsteady MHD second-grade flow under the Dual-Phase-Lag (DPL) heat and mass transfer model in a vertical microchannel filled with porous material. Diffusion thermo (Dufour) effects and homogenous chemical reaction are considered as well. The governing partial differential equations are solved by using the Laplace transform method while its inversion is done numerically using INVLAP subroutine of MATLAB. The numerical values of fluid velocity, fluid temperature and species concentration are demonstrated through graphs while the numerical values of skin friction, heat transfer rate and mass transfer rate presented in tabular form for different values of parameters that govern the flow. For the first time, a comparison of heat transfer utilizing the classical Fourier’s heat conduction model, hyperbolic heat conduction Cattaneo-Vernotte (CV) model, and the DPL model is carried out for the flow of a second grade fluid. It is found that the differences between them vanish at dimensionless time t=0.4 (for temperature) and at t=0.5 (for velocity), i.e. at a time where the system reaches steady state. The influence of phase lag parameters in both thermal and solutal transport on the fluid flow characteristics have been deciphered and analyzed. The results conveyed through this article would help researchers to understand non-Fourier heat and mass transfer in the flow of second-grade fluids which may play a vital role in the design of systems in polymer industries.
http://jacm.scu.ac.ir/article_14115_d87196fc822e9a2f4534466622c69fb0.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
763
778
10.22055/jacm.2019.27500.1409
Dual-phase-lag
Double diffusion
Porous Microchannel
MHD second grade flow
Chemical reaction
Subharthi
Sarkar
sarkar.ism@gmail.com
true
1
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
LEAD_AUTHOR
Mehari Fentahun
Endalew
mehexf@gmail.com
true
2
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
Department of Mathematics, Kalinga Institute of Industrial Technology deemed to be University (KIIT), Bhubaneswar-751024, Odisha, India
AUTHOR
Oluwole Daniel
Makinde
makinded@gmail.com
true
3
Faculty of Military Science, Stellenbosch University, Private Bag X2, Saldanha 7395,South Africa
Faculty of Military Science, Stellenbosch University, Private Bag X2, Saldanha 7395,South Africa
Faculty of Military Science, Stellenbosch University, Private Bag X2, Saldanha 7395,South Africa
AUTHOR
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[16] Makinde, O.D., Sandeep, N., Ajayi, T.M., Animasaun, I.L., Numerical exploration of heat transfer and Lorentz force effects on the flow of mhd casson fluid over an upper horizontal surface of a thermally stratified melting surface of a paraboloid of revolution, International Journal of Nonlinear Sciences and Numerical Simulation, 19(2-3), 2018, 93-106.
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[17] Makinde, O.D., Reddy, M.G., Reddy, K.V., Effects of thermal radiation on MHD peristaltic motion of Walters-b fluid with heat source and slip conditions, Energy, 5(6), 2017, 7.
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[18] Sarkar, S., Seth, G.S., Unsteady Hydromagnetic Natural convection flow past a vertical plate with time-dependent free stream through a porous medium in the presence of Hall current, rotation, and heat absorption, Journal of Aerospace Engineering, 30(1), 2016, 04016081.
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[19] Seth, G.S., Sarkar, S., Chamkha, A.J., Unsteady hydromagnetic flow past a moving vertical plate with convective surface boundary condition, Journal of Applied Fluid Mechanics, 4, 2016, 1877-1886.
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[20] Seth, G.S., Sarkar, S., Makinde, O.D., Combined free and forced convection Couette-Hartmann flow in a rotating channel with arbitrary conducting walls and Hall effects, Journal of Mechanics, 32(5), 2016, 613-629.
20
[21] Seth, G.S., Kumbhakar, B., Sarkar, S., Unsteady MHD natural convection flow with exponentially accelerated free-stream past a vertical plate in the presence of Hall current and rotation, Rendiconti del Circolo Matematico di Palermo Series 2, 66(3), 2017, 263-283.
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[22] Kandlikar, S., Garimella, S., Li, D., Colin, S., King, M.R., Heat transfer and fluid flow in minichannels and microchannels Elsevier, 2005.
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[23] Shen, C., Rarefied gas dynamics: fundamentals, simulations and micro flows, Springer Science and Business Media, 2006.
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[24] Misra, J.C., Chandra, S., Electro-osmotic flow of a second-grade fluid in a porous microchannel subject to an AC electric field, Journal of Hydrodynamics, 25, 2013, 309-316.
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[25] Chen, C.K., Weng, H.C., Developing natural convection with thermal creep in a vertical microchannel, Journal of Physics D: Applied Physics, 39, 2006, 3107–3118.
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[26] Hooman, K., Heat and fluid flow in a rectangular microchannel filled with a porous medium, International Journal of Heat and Mass Transfer, 51, 2008, 5804-5810.
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[30] Das, S., Jana, R.N., Makinde, O.D., Mixed convective magnetohydrodynamic flow in a vertical channel filled with nanofluids, Engineering Science and Technology, an International Journal, 18, 2015, 244-255.
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42
ORIGINAL_ARTICLE
Transient Electro-osmotic Slip Flow of an Oldroyd-B Fluid with Time-fractional Caputo-Fabrizio Derivative
In this article, the electro-osmotic flow of Oldroyd-B fluid in a circular micro-channel with slip boundary condition is considered. The corresponding fractional system is represented by using a newly defined time-fractional Caputo-Fabrizio derivative without singular kernel. Closed form solutions for the velocity field are acquired by means of Laplace and finite Hankel transforms. Additionally, Stehfest’s algorithm is used for inverse Laplace transform. The solutions for fractional Maxwell, ordinary Maxwell and ordinary Newtonian fluids are obtained as limiting cases of the obtained solution. Finally, the influence of fractional and some important physical parameters on the fluid flow are spotlighted graphically.
http://jacm.scu.ac.ir/article_14128_a4303133faf77b0887f65bb6e669f935.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
779
790
10.22055/jacm.2019.27524.1412
Electro-osmotic flow
Slip boundary condition
Oldroyd-B fluid
Time-fractional Caputo-Fabrizio derivative
Stehfest’s algorithm
Nehad Ali
Shah
nehadali199@yahoo.com
true
1
Department of Mathematics, Lahore Leads University, Lahore Pakistan | Abdus Salam School of Mathematical Sciences, GC University, Lahore, 54600, Pakistan
Department of Mathematics, Lahore Leads University, Lahore Pakistan | Abdus Salam School of Mathematical Sciences, GC University, Lahore, 54600, Pakistan
Department of Mathematics, Lahore Leads University, Lahore Pakistan | Abdus Salam School of Mathematical Sciences, GC University, Lahore, 54600, Pakistan
LEAD_AUTHOR
Xiaoping
Wang
nehadali199@sms.edu.pk
true
2
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
AUTHOR
Haitao
Qi
htqi@sdu.edu.cn
true
3
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
School of Mathematics and Statistics, Shandong University, Weihai, 264209, PR China
AUTHOR
Shaowei
Wang
shaoweiwang@sdu.edu.cn
true
4
School of Civil Engineering, Shandong University, Jinan, 250061, PR China
School of Civil Engineering, Shandong University, Jinan, 250061, PR China
School of Civil Engineering, Shandong University, Jinan, 250061, PR China
AUTHOR
Ahmad
Hajizadeh
as.zada@paaet.edu.kw
true
5
FAST, University Tun Hussein Onn Malaysia, 86400, Parit Raja, Batu Pahat, Johor State, Malaysia | Public Authority of Applied Education and Training, College of Technological Studies, Applied Science Department, Shuwaikh, Kuwait
FAST, University Tun Hussein Onn Malaysia, 86400, Parit Raja, Batu Pahat, Johor State, Malaysia | Public Authority of Applied Education and Training, College of Technological Studies, Applied Science Department, Shuwaikh, Kuwait
FAST, University Tun Hussein Onn Malaysia, 86400, Parit Raja, Batu Pahat, Johor State, Malaysia | Public Authority of Applied Education and Training, College of Technological Studies, Applied Science Department, Shuwaikh, Kuwait
AUTHOR
[1] Ghosal, S., Fluid mechanics of electroosmotic flow and its effect on band broadening in capillary electrophoresis, Electrophoresis, 25 (2004) 214-228.
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[2] Wang, X., Cheng, C., Wang, S., Liu, S., Electroosmotic pumps and their applications in microfluidic systems, Microfluidics and Nanofluidics, 6 (2009) 145.
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3
[4] Wang, C.Y., Liu, Y.H., Chang, C.C., Analytical solution of electroosmotic flow in a semicircular microchannel, Physics of Fluids, 20 (2008) 063105.
4
[5] Chang, S.-H., Electroosmotic flow in a dissimilarly charged slit microchannel containing salt-free solution, European Journal of Mechanics - B/Fluids, 34 (2012) 85-90.
5
[6] Das, S., Chakraborty, S., Analytical solutions for velocity, temperature and concentration distribution in electroosmotic microchannel flows of a non-Newtonian bio-fluid, Analytica Chimica Acta, 559 (2006) 15-24.
6
[7] Chakraborty, S., Electroosmotically driven capillary transport of typical non-Newtonian biofluids in rectangular microchannels, Analytica Chimica Acta, 605 (2007) 175-184.
7
[8] Tan, Z., Qi, H., Jiang, X., Electroosmotic flow of Eyring fluid in slit microchannel with slip boundary condition, Applied Mathematics and Mechanics, 35 (2014) 689-696.
8
[9] Ferrás, L.L., Afonso, A.M., Alves, M.A., Nóbrega, J.M., Pinho, F.T., Analytical and numerical study of the electro-osmotic annular flow of viscoelastic fluids, Journal of Colloid and Interface Science, 420 (2014) 152-157.
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[10] Tang, G.H., Li, X.F., He, Y.L., Tao, W.Q., Electroosmotic flow of non-Newtonian fluid in microchannels, Journal of Non-Newtonian Fluid Mechanics, 157 (2009) 133-137.
10
[11] Hu, Y., Werner, C., Li, D., Electrokinetic Transport through Rough Microchannels, Analytical Chemistry, 75 (2003) 5747-5758.
11
[12] Sadr, R., Yoda, M., Zheng, Z., Conlisk, A.T., An experimental study of electro-osmotic flow in rectangular microchannels, Journal of Fluid Mechanics, 506 (2004) 357-367.
12
[13] Hsieh, S.S., Lin, H.C., Lin, C.Y., Electroosmotic flow velocity measurements in a square microchannel, Colloid and Polymer Science, 284 (2006) 1275-1286.
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[15] Tenreiro Machado, J.A., Silva, M.F., Barbosa, R.S., Jesus, I.S.R., Marcos, M.G., Galhano, A.F., Some Applications of Fractional Calculus in Engineering, Mathematical Problems in Engineering, 2010 (2010) 1-34.
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[16] Debnath, L., Recent applications of fractional calculus to science and engineering, International Journal of Mathematics and Mathematical Sciences, 2003 (2003) 3413-3442.
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[18] Caputo, M., Fabrizio, M., A new definition of fractional derivative without singular kernel, Progress in Fractional Differentiation and Applications, 1 (2015) 73-85.
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[19] Losada, J., Nieto, J.J., Properties of a new fractional derivative without singular kernel, Progress in Fractional Differentiation and Applications, 1 (2015) 87-92.
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[20] Alsaedi, A., Baleanu, D., Etemad, S., Rezapour, S., On Coupled Systems of Time-Fractional Differential Problems by Using a New Fractional Derivative, Journal of Function Spaces, 2016 (2016) 8.
20
[21] Baleanu, D., Agheli, B., Qurashi, M.M.A., Fractional advection differential equation within Caputo and Caputo–Fabrizio derivatives, Advances in Mechanical Engineering, 8(12) (2016) 1687814016683305.
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[22] Chatterjee, A., Statistical origins of fractional derivatives in viscoelasticity, Journal of Sound and Vibration, 284 (2005) 1239-1245.
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[24] Shah, N.A., Khan, I., Heat transfer analysis in a second grade fluid over and oscillating vertical plate using fractional Caputo–Fabrizio derivatives, The European Physical Journal C, 76 (2016) 362.
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[28] Qi, H., Xu, M., Stokes’ first problem for a viscoelastic fluid with the generalized Oldroyd-B model, Acta Mechanica Sinica, 23 (2007) 463-469.
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[29] Jiang, Y., Qi, H., Xu, H., Jiang, X., Transient electroosmotic slip flow of fractional Oldroyd-B fluids, Microfluidics and Nanofluidics, 21 (2017) 7.
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[30] Wang, S., Zhao, M., Analytical solution of the transient electro-osmotic flow of a generalized fractional Maxwell fluid in a straight pipe with a circular cross-section. European Journal of Mechanics - B/Fluids, 54 (2015), 82–86.
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[31] Guo, X., Qi, H., Analytical Solution of Electro-Osmotic Peristalsis of Fractional Jeffreys Fluid in a Micro-Channel, Micromachines (Basel), 8(12) (2017), 341.
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[33] Awan, A.U., Hisham, M.D., Raz, N., The effect of slip on electroosmotic flow of a second grade fluid between two plates with Caputo-Fabrizio time fractional derivatives. Canadian Journal of Physics, 50 (2018) doi: 10.1139/cjp-2018-0406.
33
ORIGINAL_ARTICLE
Chemical Reaction Effects on Bio-Convection Nanofluid flow between two Parallel Plates in Rotating System with Variable Viscosity: A Numerical Study
In the present work, a mathematical model is developed and analyzed to study the influence of nanoparticle concentration through Brownian motion and thermophoresis diffusion. The governing system of PDEs is transformed into a coupled non-linear ODEs by using suitable variables. The converted equations are then solved by using robust shooting method with the help of MATLAB (bvp4c). The impacts of dynamic parameters on the flow, energy and concentration are discussed graphically. It is noticed that the mass transfer rate in case of regular fluid is lower than that of nanofluid and the axial velocity converges to the boundary very fast in case of temperature dependent viscosity case than the regular viscous case.
http://jacm.scu.ac.ir/article_14142_a2f1fa74180e2d6960b50a780bee281c.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
791
803
10.22055/jacm.2019.28147.1456
Bio-convection
Magnetohydrodynamic
Thermal radiation
Chemical reaction
Variable viscosity
Nanofluid
Nainaru
Tarakaramu
nainaru143@gmail.com
true
1
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
AUTHOR
P.V.
Satya Narayana
pvsatya8@yahoo.co.in
true
2
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
Department of Mathematics, SAS, VIT, Vellore-632014, T.N, India
LEAD_AUTHOR
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[14] Li, Z., Sheikholeslami, M., Chamkha, A.J., Raizah, Z.A., Saleem, S., Control volume finite element method for nanofluid MHD natural convective flow inside a sinusoidal annulus under the impact of thermal radiation,Comp. Methods Appl. Mech. Eng.,338(15), 2018, 618-633.
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[15] Mahian, O., Kolsi, L., Amani, M., Estelle, P., Ahmadi, G., Kleinstreuer, C., Marshall, J.S., Taylor, R.A., Nada, E.A., Rashidi, S., Niazmand, H., Wongwises, S., Hayat, T., Kasaeian, A., Pop, I., Recent advances in modeling and simulation of nanofluid flows-part II: Applications Physics Reports, 791, 2019, 1-59.
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56
ORIGINAL_ARTICLE
Perturbation-Iteration Algorithm for Solving Heat and Mass Transfer in the Unsteady Squeezing Flow between Parallel Plates
In this paper, heat and mass transfer in the unsteady squeezing flow between parallel plates is analyzed using a perturbation-iteration algorithm. The similarity transformation is used to transform the governing partial differential equations into ordinary differential equations, before being solved. The solutions of the velocity, temperature and concentration are derived and sketched to explain the influence of various physical parameters. The convergence of these solutions is also discussed. The numerical results of skin friction coefficient, Nusselt number and Sherwood number are compared with previous works. The results show that the method which has been used, in this paper, gives convergent solutions with good accuracy.
http://jacm.scu.ac.ir/article_14141_729d7a3d0faf2c61970d4577653cefe4.pdf
2019-06-01T11:23:20
2020-06-05T11:23:20
804
815
10.22055/jacm.2019.28052.1453
heat transfer
Mass transfer
Unsteady squeezing flow
Perturbation-iteration algorithm
Abdul-Sattar
Al-Saif
sattaralsaif@yahoo.com
true
1
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
AUTHOR
Assma
Harfash
assmaj1974@yahoo.com
true
2
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
Department of Mathematics, College of Education for Pure Science, University of Basrah, Basrah, Iraq
LEAD_AUTHOR
[1] Mahmood, M., Asghar, S., Hossain, M.A., Squeezed Flow and Heat Transfer over a Porous Surface for Viscous Fluid, Heat Mass Transfer, 44, 2007, 165-173.
1
[2] Ibrahim, F.S., Elaiw, A.M., Bakr, A.A., Effect of the Chemical Reaction and Radiation Absorption on the Unsteady MHD Free Convection Flow past a Semi Infinite Vertical Permeable Moving Plate with Heat Source and Suction, Communications in Nonlinear Science and Numerical Simulation, 13, 2008, 1056-1066.
2
[3] Rashidi, M. M., Siddiqui, A. M., Asadi, M., Application of Homotopy Analysis Method to the Unsteady Squeezing Flow of a Second-Grade Fluid between Circular Plates, Mathematical Problems in Engineering, 2010, Article ID 706840, 1-18.
3
[4] Mustafa, M., Hayat, T., Obaidat, S., On Heat and Mass Transfer in the Unsteady Squeezing Flow between Parallel Plates, Meccanica, 47, 2012, 1581-1589.
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[5] Sheikholeslami, M., Ganji, D.D., Ashorynejad, H.R., Investigation of Squeezing Unsteady Nanofluid Flow Using ADM, Powder Technology, 239, 2013, 259-265.
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[6] Hatami, M., Ganji, D.D., Heat Transfer and Nanofluid Flow in Suction and Blowing Process between Parallel Disks in Presence of Variable Magnetic Field, Journal of Molecular Liquids, 190, 2014, 159-168.
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[7] Sheikholeslami, M., Hatami, M., Domairry, G., Numerical Simulation of Two Phase Unsteady Nanofluid Flow and Heat Transfer between Parallel Plates in Presence of Time Dependent Magnetic Field, Journal of the Taiwan Institute of Chemical Engineers, 46, 2015, 43-50.
7
[8] Pourmehran, O., Rahimi-Gorji, M., Gorji-Bandpy, M., Ganji, D.D., Analytical Investigation of Squeezing Unsteady Nanofluid Flow between Parallel Plates by LSM and CM, Alexandria Engineering Journal, 54, 2015, 17-26.
8
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[11] Singh, K., Rawat, S. K., Kumar, M., Heat and Mass Transfer on Squeezing Unsteady MHD Nanofluid Flow between Parallel Plates with Slip Velocity Effect, Journal of Nanoscience, 2016, Article ID 9708562, 1-11.
11
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12
[13] Sobamowoa M.G., Akinshiloa, A.T., Double Diffusive Magnetohydrodynamic Squeezing Flow of Nanofluid between Two Parallel Disks with Slip and Temperature Jump Boundary Conditions, Applied and Computational Mechanics, 11, 2017, 167-182.
13
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14
[15] Balazadeh, N., Sheikholeslami, M., Ganji, D.D., Li, Z., Semi Analytical Analysis for Transient Eyring-Powell Squeezing Flow in a Stretching Channel Due to Magnetic Field Using DTM, Journal of Molecular Liquids, 260, 2018, 30-36.
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[16] Seyedi, S.H., Saray, B.N., Ramazani, A., On the Multiscale Simulation of Squeezing Nanofluid Flow by a High Precision Scheme, Powder Technology, 340, 2018, 264-273.
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[17] Atlas, M., Hussain, S., Sagheer, M., Entropy Generation and Unsteady Casson Fluid Flow Squeezing between Two Parallel Plates Subject to Cattaneo-Christov Heat and Mass Flux, The European Physical Journal Plus, 134: 33, 2019, 1-17.
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[22] Şenol, M., Dolapçı, İ.T., Aksoy, Y., Pakdemirli, M., Perturbation-Iteration Method for First-Order Differential Equations and Systems, Abstract and Applied Analysis, 2013, Article ID 704137, 1-6.
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[25] Pakdemirli, M., Perturbation-Iteration Method for Strongly Nonlinear Vibrations, Journal of Vibration and Control, 23(6), 2016, 959-969.
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[26] Aksoy, Y., Goktas, U., Pakdemirli, M., Dolapçı, I.T., Application of Perturbation-Iteration Method to Lotka-Volterra Equations, Alexandria Engineering Journal, 55, 2016, 1661-1666.
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[27] Khalid, M., Khan, F.S., Iqbal, A., Perturbation-Iteration Algorithm to Solve Fractional Giving up Smoking Mathematical Model, International Journal of Computer Applications, 142(9), 2016, 1-6.
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[28] Şenol, M., Kasmaei, H.D., Perturbation-Iteration Algorithm for Systems of Fractional Differential Equations and Convergence Analysis, Progress in Fractional Differentiation and Applications, 4, 2017, 271-279.
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[29] Akinlabi G.O., Edeki, S.O., Perturbation Iteration Transform Method for the Solution of Newell-Whitehead-Segel Model Equations, Journal of Mathematics and Statistics, 13(1), 2017, 24-29.
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[30] Şenol, M., Alquran, M., Kasmaei, H.D., On the Comparison of Perturbation-Iteration Algorithm and Residual Power Series Method to Solve Fractional Zakharov-Kuznetsov Equation, Results in Physics, 9, 2018, 321-327.
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31