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International Journal for Multiscale Computational Engineering

Publicado 6 números por año

ISSN Imprimir: 1543-1649

ISSN En Línea: 1940-4352

The Impact Factor measures the average number of citations received in a particular year by papers published in the journal during the two preceding years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) IF: 1.4 To calculate the five year Impact Factor, citations are counted in 2017 to the previous five years and divided by the source items published in the previous five years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) 5-Year IF: 1.3 The Immediacy Index is the average number of times an article is cited in the year it is published. The journal Immediacy Index indicates how quickly articles in a journal are cited. Immediacy Index: 2.2 The Eigenfactor score, developed by Jevin West and Carl Bergstrom at the University of Washington, is a rating of the total importance of a scientific journal. Journals are rated according to the number of incoming citations, with citations from highly ranked journals weighted to make a larger contribution to the eigenfactor than those from poorly ranked journals. Eigenfactor: 0.00034 The Journal Citation Indicator (JCI) is a single measurement of the field-normalized citation impact of journals in the Web of Science Core Collection across disciplines. The key words here are that the metric is normalized and cross-disciplinary. JCI: 0.46 SJR: 0.333 SNIP: 0.606 CiteScore™:: 3.1 H-Index: 31

Indexed in

PERISTALTIC TRANSPORTATION OF FLUID THROUGH SIMPLE AND COMPLEX WAVY NONUNIFORM CHANNELS: A BIOENGINEERING APPLICATION

Volumen 17, Edición 6, 2019, pp. 623-638
DOI: 10.1615/IntJMultCompEng.2020032905
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SINOPSIS

In the current research study, a mathematical modeling is developed that is associated with the transportation phenomena due to peristaltic waves in a curve. Because of the complex nature of the regime, curvilinear coordinates are used to govern the system of equations in a fixed frame of reference and then converted into a wave frame by using linear transformations. The analysis is restricted under the creeping hydrodynamic and long wavelength assumptions. The impact of embedded physical parameters, i.e., the dimensionless curvature parameter, phase difference, and nonuniform parameters on the velocity profile, pumping, and trapping phenomena is discussed in detail. Another imperative phenomenon is also discussed that is associated with a comparative study between trains of peristaltic wave and single peristaltic wave propagations on the motion of an incompressible viscous fluid. The results of a straight channel are retrieved from both simple and wavy channels when taking the large value of the radius of the curvature. The pressure gradient in the straight channel is observed to be greater than in the curved channel.

REFERENCIAS
  1. Abd Elmaboud, Y., Thermo-Micro-Polar Fluid Flow in a Porous Channel with Peristalsis, J. Porous Media, vol. 14, pp. 1033-1045, 2011.

  2. Abdelsalam, S.I., Bhatti, M.M., Zeeshan, A., Riaz, A., and Beg, O.A., Metachronal Propulsion of a Magnetized Particle-Fluid Suspension in a Ciliated Channel with Heat and Mass Transfer, Phys. Scr., vol. 11, p. 115301,2019.

  3. Ali, N., Sajid, M., and Hayat, T., Long Wavelength Flow Analysis in a Curved Channel, Z. Naturforsch., A, vol. 65a, pp. 191-196, 2010a.

  4. Ali, N., Sajid, M., Abbas, Z., and Javed, T., Non-Newtonian Fluid Flow Induced by Peristaltic Waves in a Curved Channel, Eur. J. Mech. B/Fluids, vol. 29, pp. 387-394, 2010b.

  5. Ali, N., Sajid, M., Javed, T., and Abbas, Z., Heat Transfer Analysis of Peristaltic Flow in a Curved Channel, Int. J. Heat Mass Transf., vol. 53, pp. 3319-3325, 2010c.

  6. Ali, N., Javid, K., Sajid, M., and Beg, O.A., Numerical Simulation of Peristaltic Flow of a Biorheological Fluid with Shear-Dependent Viscosity in a Curved Channel, Comput. Methods Biomech. Biomed. Eng., vol. 19, pp. 614-627, 2016a.

  7. Ali, N., Javid, K., Sajid, M., Zaman, A., and Hayat, T., Numerical Simulations of Oldroyd 8-Constant Fluid Flow and Heat Transfer in a Curved Channel, Int. J. Heat Mass Transf, vol. 94, vol. 500-508, 2016b.

  8. Ali, N., Wang, Y., Hayat, T., and Oberlack, M., Long Wavelength Approximation to Peristaltic Motion of an Oldroyd 4-Constant Fluid in a Planar Channel, Biorheology, vol. 45, pp. 611-628, 2008.

  9. Ali, N. and Javed, T., Flow of a Giesekus Fluid in a Planar Channel due to Peristalsis, Z. Naturforsch., A, vol. 68a, pp. 515-523, 2013.

  10. Bayliss, W.M. and Starling, H.E., The Movements and Innervation of the Small Intestine, J. Physiol, vol. 26, pp. 125-138,1901.

  11. Beg, O.A. and Tripathi, D., Mathematica Simulation of Peristaltic Pumping with Double-Diffusive Convection in Nanofluids: A Bio-Nano-Engineering Model, Proc. Inst. Mech. Eng., Part N, vol. 225, pp. 99-114, 2012.

  12. Bhatti, M.M., Zeeshan, A., and Ellahi, R., Simultaneous Effects of Coagulation and Variable Magnetic Field on Peristaltically Induced Motion of Jeffrey Nanofluid Containing Gyrotactic Microorganism, Microvascular Res, vol. 110, pp. 32-42, 2017.

  13. Bhatti, M.M., Zeeshan, A., Ellahi, R., and Kadir, A., Effects of Coagulation on the Two Phase Peristaltic Pumping of Magnetized Prandtl Biofluid through an Endoscopic Annular Geometry Containing a Porous Medium, Chin. J. Phys., vol. 58, pp. 222-234, 2019.

  14. Bhatti, M.M., Zeeshan, A., Tripathi, D., and Ellahi, R., Thermally Developed Peristaltic Propulsion of Magnetic Solid Particles in Biorheological Fluids, Indian J. Phys, vol. 92, pp. 423-430, 2018a.

  15. Bhatti, M.M., Zeeshan, A., Ellahi, R., and Shit, G.C., Mathematical Modeling of Heat and Mass Transfer Effects on MHD Peristaltic Propulsion of Two-Phase Flow through a Darcy-Brinkman-Forchheimer Porous Medium, Adv. Powder Technol., vol. 29, pp. 1189-1197,2018b.

  16. Bhatti, M.M., Riaz, A., Sheikholeslami, M., and Ellahi, R., Effects of Magnetohydrodynamics on Peristaltic Flow of Jeffrey Fluid in a Rectangular Duct through a Porous Medium, J. Porous Media, vol. 17, pp. 143-157, 2014.

  17. Ellahi, R., Hussain, F., Ishtiaq, F., and Hussain, A., Peristaltic Transport of Jeffrey Fluid in a Rectangular Duct through a Porous Medium under the Effect of Partial Slip: An Approach to Upgrade Industrial Sieves/Filters, Pramana, vol. 93, p. 0034, 2019a.

  18. Ellahi, R., Zeeshan, A., Hussain, F., and Asadollahi, A., Peristaltic Blood Flow of Couple Stress Fluid Suspended with Nanoparticles under the Influence of Chemical Reaction and Activation Energy, Symmetry, vol. 11, p. 276,2019b.

  19. Ellahi, R., Khan, A.A., and Usman, M., The Effects of Variable Viscosity on the Peristaltic Flow of Non-Newtonian Fluid through a Porous Medium in an Inclined Channel with Slip Boundary Conditions, J. Porous Media, vol. 16, pp. 59-67,2013.

  20. Hayat, T. and Ali, N., Peristaltic Motion of a Jeffrey Fluid under the Effect of Magnetic Field in a Tube, Commun. Nonlinear Sci. Numer. Simul., vol. 13, pp. 1343-1352, 2008.

  21. Hayat, T, Ali, N., and Asghar, S., An Analysis of Peristaltic Transport for Flow of a Jeffrey Fluid, Acta Mech., vol. 193, pp. 101-112,2010.

  22. Hayat, T., Ahmad, N., and Ali, N., Effects of an Endoscope and Magnetic Field on the Peristalsis Involving Jeffrey Fluid, Commun. Nonlinear Sci. Numer. Simul, vol. 13, pp. 1581-1591, 2008.

  23. Hayat, T., Ali, N., and Asghar, S., Hall Effects on Peristaltic Flow of a Maxwell Fluid in a Porous Medium, Phys. Lett. A, vol. 363, pp. 397-403, 2007.

  24. Hayat, T., Yasmin, H., Ahmad, B., and Chen, B., Simultaneous Effects of Convective Conditions and Nanoparticles on Peristaltic Motion, J. Mol. Liq., vol. 193, pp. 74-82,2014.

  25. Javid, K., Ali, N., and Khan, S., Numerical Study of Hall Effects on Peristaltically Induced Motion of a Viscous Fluid through a Non-Uniform Regime: An Application to the Medical Science, Eur. Phys. J. Plus, vol. 134, p. 395, 2019a.

  26. Javid, K., Ali, N., and Asghar, Z., Numerical Simulation of the Peristaltic Motion of a Viscous Fluid through a Complex Wavy Non-Uniform Channel with the Magneto-Hydrodynamic Effects, Phys. Scr., vol. 94, p. 115226, 2019b.

  27. Khan, A.A., Masood, F., Ellahi, R., and Bhatti, M.M., Mass Transport on Chemicalized Fourth-Grade Fluid Propagating Peristalti-cally through a Curved Channel with Magnetic Effects, J Mol. Liq, vol. 258, pp. 186-195, 2018.

  28. Kothandapani, M. and Prakash, J., Effect of Radiation and Magnetic Field on Peristaltic Transport of Nanofluids through a Porous Space in a Tapered Asymmetric Channel, J. Magn. Magn. Mater, vol. 378, pp. 152-163, 2015a.

  29. Kothandapani, M. and Prakash, J., Effects of Thermal Radiation Parameter and Magnetic Field on the Peristaltic Motion of Williamson Nanofluids in a Tapered Asymmetric Channel, Int. J. Heat Mass Transf., vol. 81, pp. 234-245, 2015b.

  30. Latham, T.W., Fluid Motion in a Peristaltic Pump, MS, Massachusetts Institute of Technology, 1966.

  31. Ma, X. and Zhen, W., Stepping Motor Control System Design for Peristaltic Pump, Mechatronic, vol. 7, pp. 62-64, 2008.

  32. Marin, M., Vlase, S., Ellahi, R., and Bhatti, M.M., On the Partition of Energies for the Backward in Time Problem of Thermoelastic Materials with a Dipolar Structure, Symmetry, vol. 11, p. 863,2019.

  33. Narla, V.K., Prasad, K.M., and Murthy, J.V.R., Time-Dependent Peristaltic Analysis in a Curved Conduit: Application to Chyme Movement through Intestine, Math. Biosci., vol. 293, pp. 21-28, 2017.

  34. Nguyen, T.T., Pham, M., and Goo, N.S., Development of a Peristaltic Micro-Pump for Bio-Medical Applications Based on Mini LIPCA, J Bionic Eng., vol. 5, pp. 135-141, 2008.

  35. Riaz, A., Ellahi, R., Bhatti, M.M., and Marin, M., Study of Heat and Mass Transfer in the Eyring-Powell Model of Fluid Propagating Peristaltically through a Rectangular Compliant Channel, Heat Transf. Res., vol. 50, pp. 1539-1560, 2019.

  36. Sato, H., Kawai, T., Fujita, T., and Okabe, M., Two-Dimensional Peristaltic Flow in Curved Channels, Trans. Jpn. Soc. Mech. Eng.,B, vol. 66, pp. 679-685, 2000.

  37. Shahid, A., Zhou, Z., Hassan, M., and Bhatti, M.M., Computational Study of Magnetized Blood Flow in the Presence of Gyrotactic Microorganisms Propagating through a Permeable Capillary in a Stretching Motion, Int. J. Multiscale Comput. Eng., vol. 16, pp. 303-320,2018.

  38. Shapiro, A.H., Jaffrin, M.Y., and Weinberg, S.L., Peristaltic Pumping with Long Wavelength at Low Reynolds Number, J. Fluid Mech., vol. 37, pp. 799-813, 1969.

  39. Siddiqui, A.M. and Schwarz, W.H., Peristaltic Pumping of a Third Order Fluid in a Planar Channel, Rheol. Acta, vol. 32, pp. 47-56, 1993.

  40. Tripathi, D., Beg, O.A., and Curiel-Sosa, J.L., Homotopy Semi-Numerical Simulation of Peristaltic Flow of Generalized Oldroyd-B Fluids with Slip Effects, Comput. Methods Biomech. Biomed. Eng., vol. 17, pp. 433-442,2014.

  41. Tripathi, D., Numerical and Analytical Simulation of Peristaltic Flows of Generalized Oldroyd-B Fluids, Int. J. Numer. Methods Fluids, vol. 67, pp. 1932-1943, 2011.

  42. Tripathi, D. and Beg, O.A., A Study on Peristaltic Flow of Nanofluids: Application in Drug Delivery Systems, Int. J. Heat Mass. Transf., vol. 70, pp. 61-70, 2014.

  43. Waqas, H., Ullah Khan, S., Hassan, M., Bhatti, M.M., and Imran, M., Analysis on the Bio Convection Flow of Modified Second-Grade Nanofluid Containing Gyrotactic Microorganisms and Nanoparticles, J. Mol. Liq, vol. 291, p. 111231,2019.

  44. Xianjun, L., Peristaltic Pump Structure Principle and Application, Fluid Machinery, vol. 26, pp. 38-40,1998.

  45. Zaman, A., Ali, N., and Sajjad, M., Effects of nanoparticles (Cu, TiO2, Al2O3) on Unsteady Blood Flow through a Curved Over-lapping Stenosed Channel, Math. Comput. Simul., vol. 156, pp. 279-293,2019.

CITADO POR
  1. Ge-JiLe Hu, Javid Khurram, Khan Sami Ullah, Raza Mohsin, Khan M. Ijaz, Qayyum Sumaira, Double diffusive convection and Hall effect in creeping flow of viscous nanofluid through a convergent microchannel: a biotechnological applications, Computer Methods in Biomechanics and Biomedical Engineering, 24, 12, 2021. Crossref

  2. Xiong Pei-Ying, Javid Khurram, Raza Mohsin, Khan Sami Ullah, Ijaz Khan M, Chu Yu-Ming, MHD flow study of viscous fluid through a complex wavy curved surface due to bio-mimetic propulsion under porosity and second-order slip effects, Communications in Theoretical Physics, 73, 8, 2021. Crossref

  3. Javid Khurram, Hassan Mohsan, Tripathi Dharmendra, Khan Salahuddin, Bobescu Elena, Bhatti Muhammad Mubashir, Double-diffusion convective biomimetic flow of nanofluid in a complex divergent porous wavy medium under magnetic effects, Journal of Biological Physics, 47, 4, 2021. Crossref

  4. Zhang Shizhong, Ahmad Faraz, Khan Amjid, Ali Nisar, Badran Mohamed, Performance improvement and thermodynamic assessment of microchannel heat sink with different types of ribs and cones, Scientific Reports, 12, 1, 2022. Crossref

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