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Journal of Taibah University for Science Volume 18, 2024 - Issue 1
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Research Article

Thermo-entropy analysis of water-FMWCNT nano-fluid flow in a backward-facing channel with obstacle

Shahul HameedDivision of Mathematics, School of Advanced Sciences, Vellore Institute of Technology Chennai, Chennai, India
&
Sandip SahaDivision of Mathematics, School of Advanced Sciences, Vellore Institute of Technology Chennai, Chennai, IndiaCorrespondence[email protected]
Article: 2314801 | Received 10 Sep 2023, Accepted 01 Feb 2024, Published online: 14 Feb 2024

References

  • Akbari OA, Toghraie D, Karimipour A, et al. Investigation of Rib’s height effect on heat transfer and flow parameters of laminar water-Al2O3 nanofluid in a two dimensional rib-micro-channel. Appl Math Comput. 2016; 290:135–153.
  • Akbari O, Marzban A, Ahmadi G. Evaluation of supply boiler repowering of anexisting natural gas-red steam power plant. Appl Therm Eng. 2017;124:897–910.
  • Behnampour A, Akbari OA, Safaei MR, et al. Analysis of heat transfer and nanofluid fluid flow in micro-channels with trapezoidal, rectangular and triangular shaped ribs. Physica. 2017;91:15–31.
  • Bahmani MH, Sheikhzadeh G, Zarringhalam M, et al. Investigation of turbulent heat transfer and nanofluid flow in a double pipe heat exchanger. Adv Powder Technol. 2018;29:273–282.
  • Chamkha AJ, Dogonchi AS, Ganji DD. Magneto-hydrodynamic nano-fluid natural convection in a cavity under thermal radiation and shape factor of nanoparticles impacts: a numerical study using CVFEM. Appl Sci. 2018;8(12):2396.
  • Ghasemi K, Siavashi M. Three-dimensional analysis of magneto hydrodynamic transverse mixed convection of nano-fluid inside a lid-driven enclosure using MRT-LBM. Int J Mech Sci. 2020;165:105–125.
  • Jino L, Kumar VA. MHD natural convection of hybrid nanofluid in a porous cavity heated with a sinusoidal temperature distribution. Comput Therm Sci. 2021;13:83–99.
  • Lv J, Huang Q, Yu X, et al. Hydrothermal performance improvement of micro-scale backward-facing step channel by employing vortex generators and nano-fluids. Comput Therm Sci. 2022;12:289–303.
  • Parsaiemehr M, Pourfattah F, Akbari OA, et al. Turbulent flow and heat transfer of water/Al2O3 nanouid inside a rectangular ribbed channel. Phys E Low-dimension Syst Nano Struct. 2018;96:73–84.
  • Mashayekhi R, Khodabandeh E, Bahiraei M, et al. Application of a novel conical strip insert to improve the efficiency of water-Ag nanofluid for utilization in thermal systems: a two-phase simulation. Energy Convers Manag. 2017;151:573–586.
  • Revathi G, Saikrishnan P, Revathy M, et al. Numerical study of Darcy Forchheimer unsteady mixed convection flow of nanofluid with an exponential decreasing free-stream velocity distribution. Comput Therm Sci. 2020;12:289–303.
  • Ushachew EG, Sharma MK, Makinde OD. Numerical study of MHD heat convection of nanofluid in an open enclosure with internal with internal heated objects and sinusoidal heated bottom. Comput Therm Sci. 2021;13:1–16.
  • Toghraie D, Abdollah MMD, Pourfattah F, et al. Numerical investigation of flow and heat transfer characteristics in smooth, sinusoidal and zigzag-shaped micro-channel with and without nano-fluid. J Therm Anal Calorim. 2018;131:1757–1766.
  • Mashaei PR, Taheri-Ghazvini M, Moghadam RS, et al. Smart role of Al2O3-water suspension on laminar heat transfer in entrance region of a channel with transverse in-line baffles. Appl Therm Eng. 2017;112:450–463.
  • Mousavi SS, Hooman K. Heat and fluid flow in entrance region of a channel with staggered baffles. Energy Convers Manage. 2016;47(15):2011–2019.
  • Sripattanapipat S, Promvonge P. Numerical analysis of laminar heat transfer in a channel with diamond-shaped baffles. Int Comm: Heat Mass Transfer. 2009;36(1):32–38.
  • Siddiqui MK. Heat transfer augmentation in a heat exchanger tube using a baffle. Int J Heat Fluid Flow. 2007;28(2):318–328.
  • Bouchenafa R, Saim R. Effect of position and height of a shield on convective heat transfer performances of plate fin heat sink. Int J Numer Methods Heat Fluid Flow. 2015;25(5):1047–1063.
  • Torii K, Kwak KM, Nishino K. Heat transfer enhancement accompanying pressure-loss reduction with winglet-type vortex generators for fin-tube heat exchangers. Int J Heat Mass Trans. 2002;45:3795–3801.
  • Boudiaf A, Danane F, Benkahla YK, et al. Heat transfer analysis of nanofluid flow through backward facing step. MATEC Web Conf; 2020; 307: 01-10.
  • Nie JY, Chen TY, et al. Effects of a baffle on separated convection flow adjacent to backward-facing step. Int J Therm Sci. 2009;48(3):618–625.
  • Abu-Nada E. Application of nanofluids for heat transfer enhancement of separated flows encountered in a backward facing step. Int J Heat Fluid Flow. 2008;29:242–249.
  • Al-Aswadi AA, Mohammed HA, Shuaib NH, et al. Laminar forced convection flow over a backward facing step using nanofluids. Int Commun Heat Mass Transfer. 2010;37:950–957.
  • Mohammed HA, Al-aswadi AA, Abu-Mulaweh HI, et al. Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step. Heat Transf Asian Res. 2011; 40(4):287–307.
  • Kherbeet AS, Mohammed HA, Salman BH, et al. Experimental study of nanofluid flow and heat transfer over microscale backward and forward-facing steps. Exp Thermal Fluid Sci. 2015;65:13–21.
  • Amiri A, Arzani HK, Kazi SN, et al. Backward-facing step heat transfer of the turbulent regime for functionalized grapheme nanoplatelets based water–ethylene glycol nanofluids. Int J Heat Mass Transf. 2016;97:538–546.
  • Nath R, Krishnan M. Numerical study of double diffusive mixed convection in a backward facing step channel filled with Cu-water nanofluid. Int J Mech Sci. 2018;153:48–63.
  • Salman S, Hilo A, Nfawa SR, et al. Numerical study on the turbulent mixed convection heat transfer over 2D microsclae backward facing step. CFD Lett. 2019;11:31–45.
  • Alrashed AA, Akbari OA, Heydari A, et al. The numerical modeling of water/FMWCNT nanofluid flow and heat transfer in a backward-facing contracting channel. Phys B. 2018;537:176–183.
  • Hilo AK, Iborra AA, Sultan MTH, et al. Experimental study of nanofluids flow and heat transfer over a backward-facing step channel. Powder Technol. 2020;372: 497–505.
  • Abdulrazzaq T, Togun H, Alsulami H, et al. Heat transfer improvement in a double backward-facing expanding channel using different working fluids. Symmetry (Basel). 2020;12:1088.
  • Ma Y, Mohebbi R, Rashidi MM, et al. Baffle and geometry effects on nanofluid forced convection over forward- and backward-facing steps channel by means of lattice Boltzmann method. Physica A. 2020;554:124696.
  • Abedalh AS, Shaalan ZA, Yassien HNS. Mixed convective of hybrid nanofluids flow in a backward facing step. Case Stud Therm Eng. 2021;25:100868.
  • Geridönmez BP, Öztop HF. Effects of inlet velocity profiles of hybrid nanofluid flow on mixed convection through a backward facing step channel under partial magnetic field. Chem Phys. 2021;540:111010.
  • Wu WC, Kumar A. Numerical investigation of nanofluid flow over a backward facing step. Aerospace. 2022;9(9):499.
  • Klazly M, Bognar G. Heat transfer enhancement for nanofluid flows over a microscale backward-facing step. Alex Eng J. 2022;61:8161–8176.
  • Klazly M, Mahabaleshwar US. Comparison of single-phase Newtonian and non-Newtonian nanofluid and two-phase models for convective heat transfer of nanofluid flow in backward-facing step. J Mol Liq. 2022;361:119607.
  • Klazly M, Bognar G. CFD investigation of backward-facing step nanofluid flow. MMCTSE 2020. J. Phys. Conf. Ser; 2020; 1564; 012010.
  • Memon AA, Usman WAK. Numerical investigation of photovoltaic thermal energy efficiency improvement using the backward step containing Cu-Al2O3 hybrid nanofluid. Alexandria Eng J. 2023;75:391–406.
  • Amrollahi A, Rashidi AM, Lotfi R, et al. Convection heat transfer of functionalized MWNT in aqueous fluids in laminar and turbulent flow at the entrance region. Int Commun Heat Mass Transfer. 2010;37:717–723.
  • Safaei MR, Togun H, Vafai K, et al. Investigation of heat transfer enchantment in a forward-facing contracting channel using FMWCNT nanofluids, Numer. Heat Transfer – Part A. 2014;66:1321–1340.
  • Nikkhah Z, Karimipour A, Safaei MR, et al. Forced convective heat transfer of water/functionalized multi-walled carbon nanotube nanofluids in a microchannel with oscillating heat flux and slip boundary condition. Int Commun Heat Mass Tran. 2015;68:69–77.
  • Gholami MR, Akbari OA, Marzban A, et al. The effect of rib shape on the behavior of laminar flow of oil/MWCNT nanofluid in a rectangular microchannel. J Therm Anal Calorim. 2018;134:1611–1628.
  • Karimipour A, Alipour H, Akbari OA, et al. Studying the effect of indentation on flow parameters and slow heat transfer of water-silver nanofluid with varying volume fraction in a rectangular two- dimensional micro-channel. Ind J Sci Tech. 2015;8:51–70.
  • Ghasemi B, Aminossadati MS. Brownian motion of nanoparticles in a triangular enclosure with natural convection. Int J Therm Sci. 2010;49:931–940.
  • Oztop FH, Abu-Nada E. Numerical study of natural convection in partially heated rectangular enclosures filled with nanofluids. Int J Heat Fluid Flow. 2008;29(5):1326–1336.
  • Palm S, Roy G. Heat transfer enhancement with the use of nanofluids in a radial flow cooling system considering temperature dependent properties. Appl Therm Eng. 2006;26:2209–2218.
  • Akbarinia A, Behzadmehr A. Numerical study of laminar mixed convection of a nanofluid in horizontal curved tubes. Appl Therm Eng. 2007;27:1327–1337.
  • Koo J, Kleinstreuer C. A new thermal conductivity model for nanofluids. J Nanopart Res. 2004;6(6):577–588.
  • Vajjha SR, Das KD. Experimental determination of thermal conductivity of three nanofluids and development of new correlations. Int J Heat Mass Transf. 2009;52(21):4675–4682.
  • Brinkman HC. The viscosity of concentrated suspensions and solution. J Chem Phys. 1952;20:571–581.
  • Tiwari MK, Das T. Heat transfer augmentation in a two-sided lid-driven differentially heated square cavity utilizing nanofluids. Int J Heat Mass Transf. 2002;50(9):2002–2018.
  • Bejan A. Entropy generation minimization: the method of thermodynamic optimization of finite-size systems and finite-time processes. New York (NY): CRC Press; 1995.
  • Bianco V, Nardini S. Enhancement of heat transfer and entropy generation analysis of nanofluids turbulent convection flow in square section tubes. Nanoscale Res Lett. 2011;6:1–12.
  • Kalinin M, Kononogov S. Boltzmann’s constant, the energy meaning of temperature, and thermodynamic irreversibility. Meas Tech. 2005;48(7):632–636.
  • Akbari AO, Toghraie D. Impact of ribs on flow parameters and laminar heat transfer of water–aluminum oxide nanofluid with different nanoparticle volume fractions in a three-dimensional rectangular microchannel. Adv Mech Eng. 2015;7(11):1–11.
  • Alipour H, Karimipour A, Safaei MR, et al. Influence of T-semi attached rib on turbulent flow and heat transfer parameters of a silver-water nanofluid with different volume fractions in a three-dimensional trapezoidal microchannel. Phys E Low-dimens Syst Nanostruct. 2017;88:60–76.
  • Hosseinnezhad R, Akbari OA, Hassanzadeh Afrouzi H, et al. The numerical study of heat transfer of turbulent nanofluid flow in a tubular heat exchanger with twin twisted-tapes inserts. J Therm Anal Calorim. 2018;132:741–759.
  • Ayad SA, Shaalan AZ. Mixed convective of hybrid nanofluids flow in a backward-facing step. Case Studies Therm Eng. 2021;25:100868.

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