Research Article
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Year 2023, Volume: 8 Issue: 2, 167 - 187, 23.06.2023
https://doi.org/10.58559/ijes.1263940

Abstract

References

  • [1] El-Maghlany WM, Sorour MM, Abbass AM, Alnakeeb MA. Numerical study of free surface axisymmetric jet impinging on a heated flat surface utilizing high concentration SiO2 nanofluid. Journal of the Taiwan Institute of Chemical Engineers 2022; 135: 104401.
  • [2] Zeitoun O, Ali M, Al-Ansary H. The effect of particle concentration on cooling of a circular horizontal surface using nanofluid jets. Nanoscale and Microscale Thermophysical Engineering 2013; 17: 154–171.
  • [3] Nguyen CT, Galanis N, Polidori G, Fohanno S, Popa CV, Le Bechec A. An experimental study of a confined and submerged impinging jet heat transfer using Al2O3-water nanofluid. International Journal of Thermal Sciences 2009; 48: 401–411.
  • [4] Selimefendigil F, Öztop HF. Jet impingement cooling and optimization study for a partly curved isothermal surface with CuO-water nanofluid. International Communications in Heat and Mass Transfer 2017; 89: 211–218.
  • [5] Tie P, Li Q, Xuan Y. Heat transfer performance of Cu–water nanofluids in the jet arrays impingement cooling system. International Journal of Thermal Sciences 2014; 77: 199–205.
  • [6] Khatak P, Jakhar R, Kumar M. Enhancement in cooling of electronic components by nanofluids. Journal of the Institution of Engineers (India): Series C 2015; 96: 245–251.
  • [7] Yousefi-Lafouraki B, Ramiar A, Mohsenian S. Entropy generation analysis of a confined slot impinging jet in a converging channel for a shear thinning nanofluid. Applied Thermal Engineering 2016; 105: 675–685.
  • [8] Gherasim I, Roy G, Nguyen CT, Vo-Ngoc D. Heat transfer enhancement and pumping power in confined radial flows using nanoparticle suspensions (nanofluids). International Journal of Thermal Sciences 2011; 50: 369–377.
  • [9] Faris M, Zulkifli R, Harun Z, Abdullah S, Aizon WG, Abbas AA. Experimental investigation on comparison of local nusselt number using twin jet impingement mechanism. International Journal of Mechanical & Mechatronics Engineering IJMME-IJENS 2017; 17: 60–75.
  • [10] Singh MK, Yadav D, Arpit S, Mitra S, Saha SK. Effect of nanofluid concentration and composition on laminar jet impinged cooling of heated steel plate. Applied Thermal Engineering 2016; 100: 237–246.
  • [11] Rehman MMU, Qu ZG, Fu RP, Xu HT. Numerical study on free-surface jet impingement cooling with nanoencapsulated phase-change material slurry and nanofluid. International Journal of Heat and Mass Transfer 2017; 109: 312–325.
  • [12] Akinshilo A. Geometry shape effects of nanoparticles on fluid heat transfer through porous channel. AUT Journal of Mechanical Engineering 2020; 4(1): 41-50.
  • [13] Rashid U, Lu D, Iqbal Q. Nanoparticles impacts on natural convection nanofluid flow and heat transfer inside a square cavity with fixed a circular obstacle. Case Studies in Thermal Engineering 2023; 44: 102829.
  • [14] ANSYS Fluent Theory Guide. Lebanon, New Hampshire: Fluent Corporation; 2006.
  • [15] Launder BE, Spalding DB. Paper 8 - The numerical computation of turbulent flows. In: Patankar SV, Pollard A, Singhal AK, Vanka SP, editors. Numerical Prediction of Flow, Heat Transfer, Turbulence and Combustion, Pergamon 1983; 96–116.
  • [16] Yusuf TA, Mabood F, Khan WA, Gbadeyan JA. Irreversibility analysis of Cu-TiO2-H2O hybrid-nanofluid impinging on a 3-D stretching sheet in a porous medium with nonlinear radiation: Darcy-Forchhiemer’s model. Alexandria Engineering Journal 2020; 59: 5247–5261.
  • [17] Waqas H, Farooq U, Naseem R, Hussain S, Alghamdi M. Impact of MHD radiative flow of hybrid nanofluid over a rotating disk. Case Studies in Thermal Engineering 2021; 26: 101015.
  • [18] Tan Z, Jin P, Zhang Y, Xie G. Flow and thermal performance of a multi-jet twisted square microchannel heat sink using CuO-water nanofluid. Applied Thermal Engineering 2023; 225: 120133.
  • [19] Rashid U, Liang H, Ahmad H, Abbas M, Iqbal A, Hamed YS. Study of (Ag and TiO2)/water nanoparticles shape effect on heat transfer and hybrid nanofluid flow toward stretching shrinking horizontal cylinder. Results In Physics 2021; 21: 103812.
  • [20] Karabulut K. Heat transfer increment study taking into consideration fin lengths for CuO-water nanofluid in cross flow-impinging jet flow channels. Thermal Science 2023: 35–35.
  • [21] Manca O, Mesolella P, Nardini S, Ricci D. Numerical study of a confined slot impinging jet with nanofluids. Nanoscale Research Letters 2011; 6: 188.
  • [22] Kareem ZS, Balla HH, AbdulWahid AF. Heat transfer enhancement in single circular impingement jet by CuO-water nanofluid. Case Studies in Thermal Engineering 2019; 15: 100508.
  • [23] Alabdaly IK, Ahmed MA. Numerical investigation on the heat transfer enhancement using a confined slot impinging jet with nanofluid. Propulsion and Power Research 2019; 8: 351–361.

Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid

Year 2023, Volume: 8 Issue: 2, 167 - 187, 23.06.2023
https://doi.org/10.58559/ijes.1263940

Abstract

Designing a cooling system is crucial for the thermal management of many different types of energy applications, such as fuel cells, solar panels, electronic cooling, and many more. A higher local heat transfer coefficient is attained by impinging jets, making them a viable cooling option. This study investigates a two-dimensional numerical study into the turbulent convective heat transfer in a confined slot and submerged impinging jet by using water and a nanofluid for Reynolds numbers between 6000 and 24000. The nanofluid of lamina-shaped CoFe3O2/water has been studied, with the volume concentration of nanoparticles ranging from 2.0% to 4.0%. Using a finite volume technique based on the SIMPLE algorithm, the governing momentum, continuity, and energy equations are solved. A presentation and discussion of the influence of the nanoparticle's volume fraction and the Reynolds number on the flow and thermal properties are provided. Increasing the volume fraction of nanoparticles is shown to enhance the Nusselt number and the Darcy friction factor. Entropy generation increases with the increase of the Reynolds number for all working fluids.

References

  • [1] El-Maghlany WM, Sorour MM, Abbass AM, Alnakeeb MA. Numerical study of free surface axisymmetric jet impinging on a heated flat surface utilizing high concentration SiO2 nanofluid. Journal of the Taiwan Institute of Chemical Engineers 2022; 135: 104401.
  • [2] Zeitoun O, Ali M, Al-Ansary H. The effect of particle concentration on cooling of a circular horizontal surface using nanofluid jets. Nanoscale and Microscale Thermophysical Engineering 2013; 17: 154–171.
  • [3] Nguyen CT, Galanis N, Polidori G, Fohanno S, Popa CV, Le Bechec A. An experimental study of a confined and submerged impinging jet heat transfer using Al2O3-water nanofluid. International Journal of Thermal Sciences 2009; 48: 401–411.
  • [4] Selimefendigil F, Öztop HF. Jet impingement cooling and optimization study for a partly curved isothermal surface with CuO-water nanofluid. International Communications in Heat and Mass Transfer 2017; 89: 211–218.
  • [5] Tie P, Li Q, Xuan Y. Heat transfer performance of Cu–water nanofluids in the jet arrays impingement cooling system. International Journal of Thermal Sciences 2014; 77: 199–205.
  • [6] Khatak P, Jakhar R, Kumar M. Enhancement in cooling of electronic components by nanofluids. Journal of the Institution of Engineers (India): Series C 2015; 96: 245–251.
  • [7] Yousefi-Lafouraki B, Ramiar A, Mohsenian S. Entropy generation analysis of a confined slot impinging jet in a converging channel for a shear thinning nanofluid. Applied Thermal Engineering 2016; 105: 675–685.
  • [8] Gherasim I, Roy G, Nguyen CT, Vo-Ngoc D. Heat transfer enhancement and pumping power in confined radial flows using nanoparticle suspensions (nanofluids). International Journal of Thermal Sciences 2011; 50: 369–377.
  • [9] Faris M, Zulkifli R, Harun Z, Abdullah S, Aizon WG, Abbas AA. Experimental investigation on comparison of local nusselt number using twin jet impingement mechanism. International Journal of Mechanical & Mechatronics Engineering IJMME-IJENS 2017; 17: 60–75.
  • [10] Singh MK, Yadav D, Arpit S, Mitra S, Saha SK. Effect of nanofluid concentration and composition on laminar jet impinged cooling of heated steel plate. Applied Thermal Engineering 2016; 100: 237–246.
  • [11] Rehman MMU, Qu ZG, Fu RP, Xu HT. Numerical study on free-surface jet impingement cooling with nanoencapsulated phase-change material slurry and nanofluid. International Journal of Heat and Mass Transfer 2017; 109: 312–325.
  • [12] Akinshilo A. Geometry shape effects of nanoparticles on fluid heat transfer through porous channel. AUT Journal of Mechanical Engineering 2020; 4(1): 41-50.
  • [13] Rashid U, Lu D, Iqbal Q. Nanoparticles impacts on natural convection nanofluid flow and heat transfer inside a square cavity with fixed a circular obstacle. Case Studies in Thermal Engineering 2023; 44: 102829.
  • [14] ANSYS Fluent Theory Guide. Lebanon, New Hampshire: Fluent Corporation; 2006.
  • [15] Launder BE, Spalding DB. Paper 8 - The numerical computation of turbulent flows. In: Patankar SV, Pollard A, Singhal AK, Vanka SP, editors. Numerical Prediction of Flow, Heat Transfer, Turbulence and Combustion, Pergamon 1983; 96–116.
  • [16] Yusuf TA, Mabood F, Khan WA, Gbadeyan JA. Irreversibility analysis of Cu-TiO2-H2O hybrid-nanofluid impinging on a 3-D stretching sheet in a porous medium with nonlinear radiation: Darcy-Forchhiemer’s model. Alexandria Engineering Journal 2020; 59: 5247–5261.
  • [17] Waqas H, Farooq U, Naseem R, Hussain S, Alghamdi M. Impact of MHD radiative flow of hybrid nanofluid over a rotating disk. Case Studies in Thermal Engineering 2021; 26: 101015.
  • [18] Tan Z, Jin P, Zhang Y, Xie G. Flow and thermal performance of a multi-jet twisted square microchannel heat sink using CuO-water nanofluid. Applied Thermal Engineering 2023; 225: 120133.
  • [19] Rashid U, Liang H, Ahmad H, Abbas M, Iqbal A, Hamed YS. Study of (Ag and TiO2)/water nanoparticles shape effect on heat transfer and hybrid nanofluid flow toward stretching shrinking horizontal cylinder. Results In Physics 2021; 21: 103812.
  • [20] Karabulut K. Heat transfer increment study taking into consideration fin lengths for CuO-water nanofluid in cross flow-impinging jet flow channels. Thermal Science 2023: 35–35.
  • [21] Manca O, Mesolella P, Nardini S, Ricci D. Numerical study of a confined slot impinging jet with nanofluids. Nanoscale Research Letters 2011; 6: 188.
  • [22] Kareem ZS, Balla HH, AbdulWahid AF. Heat transfer enhancement in single circular impingement jet by CuO-water nanofluid. Case Studies in Thermal Engineering 2019; 15: 100508.
  • [23] Alabdaly IK, Ahmed MA. Numerical investigation on the heat transfer enhancement using a confined slot impinging jet with nanofluid. Propulsion and Power Research 2019; 8: 351–361.
There are 23 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Research Article
Authors

Recep Ekiciler 0000-0003-1367-9465

Publication Date June 23, 2023
Submission Date March 12, 2023
Acceptance Date May 26, 2023
Published in Issue Year 2023 Volume: 8 Issue: 2

Cite

APA Ekiciler, R. (2023). Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid. International Journal of Energy Studies, 8(2), 167-187. https://doi.org/10.58559/ijes.1263940
AMA Ekiciler R. Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid. Int J Energy Studies. June 2023;8(2):167-187. doi:10.58559/ijes.1263940
Chicago Ekiciler, Recep. “Heat Transfer Enhancement of a Slot-Confined and Submerged Impinging Jet Utilizing Lamina-Shaped CoFe3O2/Water Nanofluid”. International Journal of Energy Studies 8, no. 2 (June 2023): 167-87. https://doi.org/10.58559/ijes.1263940.
EndNote Ekiciler R (June 1, 2023) Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid. International Journal of Energy Studies 8 2 167–187.
IEEE R. Ekiciler, “Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid”, Int J Energy Studies, vol. 8, no. 2, pp. 167–187, 2023, doi: 10.58559/ijes.1263940.
ISNAD Ekiciler, Recep. “Heat Transfer Enhancement of a Slot-Confined and Submerged Impinging Jet Utilizing Lamina-Shaped CoFe3O2/Water Nanofluid”. International Journal of Energy Studies 8/2 (June 2023), 167-187. https://doi.org/10.58559/ijes.1263940.
JAMA Ekiciler R. Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid. Int J Energy Studies. 2023;8:167–187.
MLA Ekiciler, Recep. “Heat Transfer Enhancement of a Slot-Confined and Submerged Impinging Jet Utilizing Lamina-Shaped CoFe3O2/Water Nanofluid”. International Journal of Energy Studies, vol. 8, no. 2, 2023, pp. 167-8, doi:10.58559/ijes.1263940.
Vancouver Ekiciler R. Heat transfer enhancement of a slot-confined and submerged impinging jet utilizing lamina-shaped CoFe3O2/water nanofluid. Int J Energy Studies. 2023;8(2):167-8.