Research Article
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Year 2024, Volume: 10 Issue: 4, 961 - 977, 29.07.2024

Abstract

References

  • [1] Meslem A, Bode F, Nastase I, Martin O. Optimization of lobed perforated panel diffuser: Numerical study of orifice geometry. Mod Appl Sci 2012;6:59–73. [CrossRef]
  • [2] Khelil A, Naji H, Loukarfi L, Meliani MH, Braikia M. Numerical simulation of the interactions among multiple turbulent swirling jets mounted in unbalanced positions. Appl Math Model 2016;40:3749–3763. [CrossRef]
  • [3] Bedrouni M, Khelil A. Numerical study on the performance of rounded corners on the top of electronic components on cooling effectiveness. Int J Heat Mass Transf 2020;150:119391. [CrossRef]
  • [4] Braikia M, Naji H, Khelil A, Maammar A. Experimental and CFD-based study of the interaction of lobed multi-jet diffusers in unbalanced positions. J Braz Soc Mech Sci Engineer 2022;44:264. [CrossRef]
  • [5] Ingole S. Temperature analysis for the horizontal target cooling with non-confined and inclined air jet. J Ther Engineer 2023;9:342–355. [CrossRef]
  • [6] Popovac M, Hanjalić K. Large-eddy simulations of flow over a jet-impinged wall-mounted cube in a cross stream. Int J Heat Fluid Flow 2007;28:1360–1378. [CrossRef]
  • [7] Kanbur BB, Wu C, Fan S, Duan F. System-level experimental investigations of the direct immersion cooling data center units with thermodynamic and thermoeconomic. Energy 2020;217:119373. [CrossRef]
  • [8] Hussain CM. Handbook of Nanomaterials for Industrial Applications: Micro and Nano Technologies. Amsterdam: Elsevier; 2018.
  • [9] Datta A, Halder P. Field-synergy and nanoparticle’s diameter analysis on circular jet impingement using three oxide–water-based nanofluids. J Therm Engineer 2023;9:179–190. [CrossRef]
  • [10] Jalili B, Jalili P. Numerical analysis of airflow turbulence intensity effect on liquid jet trajectory and breakup in two-phase cross flow. Alexandria Engineer J 2023;68:577–585. [CrossRef]
  • [11] Jalili P, Ganji DD, Nourazar SS. Investigation of convective-conductive heat transfer in geothermal system. Results Phys 2018;10:568–587. [CrossRef]
  • [12] Jalili P, Kazerani K, Jalili B, Ganji DD. Investigation of thermal analysis and pressure drop in non-continuous helical baffle with different helix angles and hybrid nano-particles. Case Stud Ther Engineer 2022;36:102209. [CrossRef]
  • [13] Kaplan S, Bayramoğlu K, Sarikanat M, Altay L. Numerical study on heat transfer and fluid dynamics in plate heat exchangers: Effects of chevron angle and aspect ratio. J Therm Engineer 2024;10:638–656. [CrossRef] [CrossRef]
  • [14] Jalili B, Aghaee N, Jalili P, Domiri Ganji D. Novel usage of the curved rectangular fin on the heat transfer of a double-pipe heat exchanger with a nanofluid. Case Stud Therm Engineer 2022;35:102086. [CrossRef]
  • [15] Rupesh PL, Raja K, Sathyaseelan, Sunil Kumar K, Vijaydharan S, Mohan Reddy AM, et al. Experimental evaluation of thermal stress on the surface of butterfly specimen through irreversible colour change of thermal paint. Mater Today Proc 2022;59:1768–1775. [CrossRef]
  • [16] Kumar KS, Muniamuthu S, Mohan A, Amirthalingam P, Muthuraja MA. Effect of charging and discharging process of PCM with paraffin and Al2O3 additive subjected to three point temperature locations. J Ecol Engineer 2022;23:34–42. [CrossRef]
  • [17] Kumar KS, Raju BN, Arulmani J, Amirthalingam P. Design and structural analysis of liquified cryogenic tank under seismic and operating loading. Int J Mech Engineer Technol 2016;7:345–366.
  • [18] Castro IP, Robins AG. The flow around a surface-mounted cube in uniform and turbulent streams. J Fluid Mech 1977;79:307–335. [CrossRef]
  • [19] Hearst RJ, Gomit G, Ganapathisubramani B. Effect of turbulence on the wake of a wall-mounted cube. J Fluid Mech 2016;804:513–530. [CrossRef]
  • [20] Tummers MJ, Flikweert MA, Hanjalić K, Rodink R, Moshfegh B. Impinging jet cooling of wall mounted cubes. In: Procedings of the ERCOFTAC International Symposium on Engineering Turbulence Modelling and Measurements; 2005 May 23–25; Sardinia, Italy; 2005. pp. 773–782. [CrossRef]
  • [21] Nakamura H, Igarashi T, Tsutsui T. Local heat transfer around a wall-mounted cube. Int J Heat Mass Transf 2001;44:3385–3395. [CrossRef]
  • [22] Masip Y, Rivas A, Larraona GS, Anton R, Ramos JC, Moshfegh B. Experimental study of the turbulent flow around a single wall-mounted cube exposed to a cross-flow and an impinging jet. Int J Heat Fluid Flow 2012;38:50–71. [CrossRef]
  • [23] Attalla M, Abdel Samee AA, Salem NN. Experimental investigation of heat transfer of impinging jet on a roughened plate by a micro cubic shape. Exp Heat Transf 2020;33:210– 225. [CrossRef]
  • [24] Saleha N, Fadèla N, Abbès A. Improving cooling effectiveness by use of chamfers on the top of electronic components. Microelectron Reliab 2015;55:1067–1076. [CrossRef]
  • [25] Boudraa B, Bessaїh R. Three-dimensional turbulent forced convection around a hot cubic block exposed to a cross-flow and an impinging jet. Heat Transf 2021;50:413–431. [CrossRef]
  • [26] Macia YM, Rodriguez Soto AA, Nunez Gonzalez SM, Yanes JP. Parametric study of electronic cooling by means of a combination of crossflow and an impinging jet. IEEE Access 2022;10:103749–103764. [CrossRef]
  • [27] Khan BA, Saha AK. Turbulent flow and heat transfer characteristics of an impinging jet over a heated wall-mounted cube placed in a cross-flow. Phys Fluids 2022;34:025120. [CrossRef]
  • [28] Joshi T, Parkash O, Krishan G. Estimation of energy consumption and transportation characteristics for slurry flow through a horizontal straight pipe using computational fluid dynamics. Phys Fluids 2023;35:053303. [CrossRef]
  • [29] Joshi T, Parkash O, Krishan G. CFD modeling for slurry flow through a horizontal pipe bend at different Prandtl number. Int J Hydrogen Energy 2022;47:23731–23750. [CrossRef]
  • [30] Joshi T, Parkash O, Krishan G. Slurry flow characteristics through a horizontal pipeline at different Prandtl number. Powder Technol 2023;413:118008. [CrossRef]
  • [31] Joshi T, Parkash O, Krishan G, Murthy AA. Numerical investigation of Bi-model slurry transportation through horizontal pipe bend. Powder Technol 2023;418:118284. [CrossRef]
  • [32] Meslem A, Nastase I, Allard F. Passive mixing control for innovative air diffusion terminal devices for buildings. Build Environ 2010;45:2679–2688. [CrossRef]
  • [33] Meslem A, El Hassan M, Nastase I. Analysis of jet entrainment mechanism in the transitional regime by time-resolved PIV. J Vis 2011;14:41–52. [CrossRef]
  • [34] Choi SK, Kim SO. Turbulence modeling of natural convection in enclosures: A review. J Mech Sci Technol 2012;26:283–297. [CrossRef]
  • [35] Joshi T, Parkash O, Krishan G. Numerical investigation of slurry pressure drop at different pipe roughness in a straight pipe using CFD. Arab J Sci Engineer 2022;47:15391–15414. [CrossRef]
  • [36] Joshi T, Parkash O, Murthy AA, Krishan G. Numerical investigation of Bi-model slurry transportation in a straight pipe. Results Eng 2023;17:100858. [CrossRef]
  • [37] Koseoglu MF, Baskaya S. The effect of flow field and turbulence on heat transfer characteristics of confined circular and elliptic impinging jets. Int J Ther Sci 2008;47:1332–1346. [CrossRef]
  • [38] Podila K, Rao Y. CFD modelling of supercritical water flow and heat transfer in a 2 × 2 fuel rod bundle. Nucl Engineer Des 2016;301:279–289.v
  • [39] Zahout N, Braikia M, Khelil A, Naji H. Thermal and dynamic characterization of a multi-jet system with different geometry diffusers. J Therm Engineer 2024;10:404–429. [CrossRef]
  • [40] Prasad KSR, Krishna V, Bharadwaj S. Effect of heat flux and mass flux on the heat transfer characteristics of supercritical carbon dioxide for a vertically downward flow using computational fluid dynamics and artificial neural networks. J Therm Engineer 2023;9:1291–1306. [CrossRef]
  • [41] Attou Y, Bouhafs M, Feddal A. Numerical analysis of turbulent flow and heat transfer enhancement using V-shaped Grooves mounted on the Rotary Kiln’s outer Walls. J Therm Engineer 2023;10:350–359. [CrossRef]
  • [42] Khelil A, Naji H, Braikia M, Loukarfi L. Comparative investigation on heated swirling jets using experimental and numerical computations. Heat Transf Engineer 2015;36:43–57. [CrossRef]
  • [43] Wasewar KL, Sarathi JV. CFD Modelling and simulation of jet mixed tanks. Engineer Appl Comput Fluid Mech 2008;2:155–171. [CrossRef]
  • [44] Wilcox DC. Reassessment of the scale-determining equation for advanced turbulence models. AIAA J 1988;26:1299–1310. [CrossRef]
  • [45] Basiri M, Goshayeshi HR, Chaer I, Pourpasha H, Heris SZ. Experimental study on heat transfer from rectangular fins in combined convection. J Ther Engineer 2023;9:1632–1642. [CrossRef]
  • [46] Basiri M, Goshayeshi HR, Chaer I, Pourpasha H, Heris SZ. Experimental study on heat transfer from rectangular fins in combined convection. J Ther Eng 2023;9:1632–1642.
  • [47] Menter FR. Review of the shear-stress transport turbulence model experience from an industrial perspective. Int J Comput Fluid Dyn 2009;23:305–316. [CrossRef]
  • [48] Safaei MR, Togun H, Vafai K, Kazi SN, Badarudin A. Investigation of heat transfer enhancement in a forward-facing contracting channel using FMWCNT nanofluids. Numer Heat Transf Appl 2014;66:1321–1340. [CrossRef]
  • [49] Nadooshan AA, Mohammadi S, Bayareh M. Heat transfer and friction characteristics of an array of perforated fins under laminar forced convection. J Ther Engineer 2019;5:115– 122. [CrossRef]
  • [50] Rana S, Dura HB, Bhattrai S, Shrestha R. Impact of baffle on forced convection heat transfer of CuO/water nanofluid in a micro-scale backward facing step channel. J Ther Engineer 2022;8:310–322. [CrossRef]
  • [51] Kumar SK, Bishnoi D. Pressure exertion and heat dissipation analysis on uncoated and ceramic (Al2O3, TiO2 and ZrO2) coated braking pads. Mater Today Proc 2023;74:774–787. [CrossRef]
  • [52] ANSYS. ANSYS Fluent Theory Guide. Available at: https://dl.cfdexperts.net/cfd_resources/Ansys_Documentation/Fluent/Ansys_Fluent_Theory_Guide.pdf. Accessed Jun 26, 2024.
  • [53] Kilic M, Ullah A. Numerical investigation of effect of different parameter on heat transfer for a crossflow heat exchanger by using nanofluids. J Ther Engineer 2021;7:1980–1989. [CrossRef]

Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet

Year 2024, Volume: 10 Issue: 4, 961 - 977, 29.07.2024

Abstract

This article investigates the influence of altering the geometry of a jet diffuser and modifying the top corners of electronic components on cooling effectiveness. Computational simulations using the Shear stress transport turbulence model (k-ω SST) are conducted. The study considers a cross-flow Reynolds number of 3410 and varying impinging jet Reynolds numbers (α = Rej/ReH = 0.5, 1, and 1.5). Results show a clear relationship between flow structure and cooling effectiveness. At α = 0.5, cubes with rounded edges and chamfered corners have lower cool-ing efficiency. At α = 1.0, chamfered cubes demonstrate enhanced cooling efficiency (4.7% increase in average Nusselt number). At α = 1.5, rounded cubes exhibit superior cooling performance (3.7% higher Nusselt number). A lobed diffuser configuration achieves outstanding cooling effectiveness, with a Nusselt number 15% higher than a circular jet. These findings provide insights for improving cooling efficiency in electronic components under cross-flow and impinging jet conditions.

References

  • [1] Meslem A, Bode F, Nastase I, Martin O. Optimization of lobed perforated panel diffuser: Numerical study of orifice geometry. Mod Appl Sci 2012;6:59–73. [CrossRef]
  • [2] Khelil A, Naji H, Loukarfi L, Meliani MH, Braikia M. Numerical simulation of the interactions among multiple turbulent swirling jets mounted in unbalanced positions. Appl Math Model 2016;40:3749–3763. [CrossRef]
  • [3] Bedrouni M, Khelil A. Numerical study on the performance of rounded corners on the top of electronic components on cooling effectiveness. Int J Heat Mass Transf 2020;150:119391. [CrossRef]
  • [4] Braikia M, Naji H, Khelil A, Maammar A. Experimental and CFD-based study of the interaction of lobed multi-jet diffusers in unbalanced positions. J Braz Soc Mech Sci Engineer 2022;44:264. [CrossRef]
  • [5] Ingole S. Temperature analysis for the horizontal target cooling with non-confined and inclined air jet. J Ther Engineer 2023;9:342–355. [CrossRef]
  • [6] Popovac M, Hanjalić K. Large-eddy simulations of flow over a jet-impinged wall-mounted cube in a cross stream. Int J Heat Fluid Flow 2007;28:1360–1378. [CrossRef]
  • [7] Kanbur BB, Wu C, Fan S, Duan F. System-level experimental investigations of the direct immersion cooling data center units with thermodynamic and thermoeconomic. Energy 2020;217:119373. [CrossRef]
  • [8] Hussain CM. Handbook of Nanomaterials for Industrial Applications: Micro and Nano Technologies. Amsterdam: Elsevier; 2018.
  • [9] Datta A, Halder P. Field-synergy and nanoparticle’s diameter analysis on circular jet impingement using three oxide–water-based nanofluids. J Therm Engineer 2023;9:179–190. [CrossRef]
  • [10] Jalili B, Jalili P. Numerical analysis of airflow turbulence intensity effect on liquid jet trajectory and breakup in two-phase cross flow. Alexandria Engineer J 2023;68:577–585. [CrossRef]
  • [11] Jalili P, Ganji DD, Nourazar SS. Investigation of convective-conductive heat transfer in geothermal system. Results Phys 2018;10:568–587. [CrossRef]
  • [12] Jalili P, Kazerani K, Jalili B, Ganji DD. Investigation of thermal analysis and pressure drop in non-continuous helical baffle with different helix angles and hybrid nano-particles. Case Stud Ther Engineer 2022;36:102209. [CrossRef]
  • [13] Kaplan S, Bayramoğlu K, Sarikanat M, Altay L. Numerical study on heat transfer and fluid dynamics in plate heat exchangers: Effects of chevron angle and aspect ratio. J Therm Engineer 2024;10:638–656. [CrossRef] [CrossRef]
  • [14] Jalili B, Aghaee N, Jalili P, Domiri Ganji D. Novel usage of the curved rectangular fin on the heat transfer of a double-pipe heat exchanger with a nanofluid. Case Stud Therm Engineer 2022;35:102086. [CrossRef]
  • [15] Rupesh PL, Raja K, Sathyaseelan, Sunil Kumar K, Vijaydharan S, Mohan Reddy AM, et al. Experimental evaluation of thermal stress on the surface of butterfly specimen through irreversible colour change of thermal paint. Mater Today Proc 2022;59:1768–1775. [CrossRef]
  • [16] Kumar KS, Muniamuthu S, Mohan A, Amirthalingam P, Muthuraja MA. Effect of charging and discharging process of PCM with paraffin and Al2O3 additive subjected to three point temperature locations. J Ecol Engineer 2022;23:34–42. [CrossRef]
  • [17] Kumar KS, Raju BN, Arulmani J, Amirthalingam P. Design and structural analysis of liquified cryogenic tank under seismic and operating loading. Int J Mech Engineer Technol 2016;7:345–366.
  • [18] Castro IP, Robins AG. The flow around a surface-mounted cube in uniform and turbulent streams. J Fluid Mech 1977;79:307–335. [CrossRef]
  • [19] Hearst RJ, Gomit G, Ganapathisubramani B. Effect of turbulence on the wake of a wall-mounted cube. J Fluid Mech 2016;804:513–530. [CrossRef]
  • [20] Tummers MJ, Flikweert MA, Hanjalić K, Rodink R, Moshfegh B. Impinging jet cooling of wall mounted cubes. In: Procedings of the ERCOFTAC International Symposium on Engineering Turbulence Modelling and Measurements; 2005 May 23–25; Sardinia, Italy; 2005. pp. 773–782. [CrossRef]
  • [21] Nakamura H, Igarashi T, Tsutsui T. Local heat transfer around a wall-mounted cube. Int J Heat Mass Transf 2001;44:3385–3395. [CrossRef]
  • [22] Masip Y, Rivas A, Larraona GS, Anton R, Ramos JC, Moshfegh B. Experimental study of the turbulent flow around a single wall-mounted cube exposed to a cross-flow and an impinging jet. Int J Heat Fluid Flow 2012;38:50–71. [CrossRef]
  • [23] Attalla M, Abdel Samee AA, Salem NN. Experimental investigation of heat transfer of impinging jet on a roughened plate by a micro cubic shape. Exp Heat Transf 2020;33:210– 225. [CrossRef]
  • [24] Saleha N, Fadèla N, Abbès A. Improving cooling effectiveness by use of chamfers on the top of electronic components. Microelectron Reliab 2015;55:1067–1076. [CrossRef]
  • [25] Boudraa B, Bessaїh R. Three-dimensional turbulent forced convection around a hot cubic block exposed to a cross-flow and an impinging jet. Heat Transf 2021;50:413–431. [CrossRef]
  • [26] Macia YM, Rodriguez Soto AA, Nunez Gonzalez SM, Yanes JP. Parametric study of electronic cooling by means of a combination of crossflow and an impinging jet. IEEE Access 2022;10:103749–103764. [CrossRef]
  • [27] Khan BA, Saha AK. Turbulent flow and heat transfer characteristics of an impinging jet over a heated wall-mounted cube placed in a cross-flow. Phys Fluids 2022;34:025120. [CrossRef]
  • [28] Joshi T, Parkash O, Krishan G. Estimation of energy consumption and transportation characteristics for slurry flow through a horizontal straight pipe using computational fluid dynamics. Phys Fluids 2023;35:053303. [CrossRef]
  • [29] Joshi T, Parkash O, Krishan G. CFD modeling for slurry flow through a horizontal pipe bend at different Prandtl number. Int J Hydrogen Energy 2022;47:23731–23750. [CrossRef]
  • [30] Joshi T, Parkash O, Krishan G. Slurry flow characteristics through a horizontal pipeline at different Prandtl number. Powder Technol 2023;413:118008. [CrossRef]
  • [31] Joshi T, Parkash O, Krishan G, Murthy AA. Numerical investigation of Bi-model slurry transportation through horizontal pipe bend. Powder Technol 2023;418:118284. [CrossRef]
  • [32] Meslem A, Nastase I, Allard F. Passive mixing control for innovative air diffusion terminal devices for buildings. Build Environ 2010;45:2679–2688. [CrossRef]
  • [33] Meslem A, El Hassan M, Nastase I. Analysis of jet entrainment mechanism in the transitional regime by time-resolved PIV. J Vis 2011;14:41–52. [CrossRef]
  • [34] Choi SK, Kim SO. Turbulence modeling of natural convection in enclosures: A review. J Mech Sci Technol 2012;26:283–297. [CrossRef]
  • [35] Joshi T, Parkash O, Krishan G. Numerical investigation of slurry pressure drop at different pipe roughness in a straight pipe using CFD. Arab J Sci Engineer 2022;47:15391–15414. [CrossRef]
  • [36] Joshi T, Parkash O, Murthy AA, Krishan G. Numerical investigation of Bi-model slurry transportation in a straight pipe. Results Eng 2023;17:100858. [CrossRef]
  • [37] Koseoglu MF, Baskaya S. The effect of flow field and turbulence on heat transfer characteristics of confined circular and elliptic impinging jets. Int J Ther Sci 2008;47:1332–1346. [CrossRef]
  • [38] Podila K, Rao Y. CFD modelling of supercritical water flow and heat transfer in a 2 × 2 fuel rod bundle. Nucl Engineer Des 2016;301:279–289.v
  • [39] Zahout N, Braikia M, Khelil A, Naji H. Thermal and dynamic characterization of a multi-jet system with different geometry diffusers. J Therm Engineer 2024;10:404–429. [CrossRef]
  • [40] Prasad KSR, Krishna V, Bharadwaj S. Effect of heat flux and mass flux on the heat transfer characteristics of supercritical carbon dioxide for a vertically downward flow using computational fluid dynamics and artificial neural networks. J Therm Engineer 2023;9:1291–1306. [CrossRef]
  • [41] Attou Y, Bouhafs M, Feddal A. Numerical analysis of turbulent flow and heat transfer enhancement using V-shaped Grooves mounted on the Rotary Kiln’s outer Walls. J Therm Engineer 2023;10:350–359. [CrossRef]
  • [42] Khelil A, Naji H, Braikia M, Loukarfi L. Comparative investigation on heated swirling jets using experimental and numerical computations. Heat Transf Engineer 2015;36:43–57. [CrossRef]
  • [43] Wasewar KL, Sarathi JV. CFD Modelling and simulation of jet mixed tanks. Engineer Appl Comput Fluid Mech 2008;2:155–171. [CrossRef]
  • [44] Wilcox DC. Reassessment of the scale-determining equation for advanced turbulence models. AIAA J 1988;26:1299–1310. [CrossRef]
  • [45] Basiri M, Goshayeshi HR, Chaer I, Pourpasha H, Heris SZ. Experimental study on heat transfer from rectangular fins in combined convection. J Ther Engineer 2023;9:1632–1642. [CrossRef]
  • [46] Basiri M, Goshayeshi HR, Chaer I, Pourpasha H, Heris SZ. Experimental study on heat transfer from rectangular fins in combined convection. J Ther Eng 2023;9:1632–1642.
  • [47] Menter FR. Review of the shear-stress transport turbulence model experience from an industrial perspective. Int J Comput Fluid Dyn 2009;23:305–316. [CrossRef]
  • [48] Safaei MR, Togun H, Vafai K, Kazi SN, Badarudin A. Investigation of heat transfer enhancement in a forward-facing contracting channel using FMWCNT nanofluids. Numer Heat Transf Appl 2014;66:1321–1340. [CrossRef]
  • [49] Nadooshan AA, Mohammadi S, Bayareh M. Heat transfer and friction characteristics of an array of perforated fins under laminar forced convection. J Ther Engineer 2019;5:115– 122. [CrossRef]
  • [50] Rana S, Dura HB, Bhattrai S, Shrestha R. Impact of baffle on forced convection heat transfer of CuO/water nanofluid in a micro-scale backward facing step channel. J Ther Engineer 2022;8:310–322. [CrossRef]
  • [51] Kumar SK, Bishnoi D. Pressure exertion and heat dissipation analysis on uncoated and ceramic (Al2O3, TiO2 and ZrO2) coated braking pads. Mater Today Proc 2023;74:774–787. [CrossRef]
  • [52] ANSYS. ANSYS Fluent Theory Guide. Available at: https://dl.cfdexperts.net/cfd_resources/Ansys_Documentation/Fluent/Ansys_Fluent_Theory_Guide.pdf. Accessed Jun 26, 2024.
  • [53] Kilic M, Ullah A. Numerical investigation of effect of different parameter on heat transfer for a crossflow heat exchanger by using nanofluids. J Ther Engineer 2021;7:1980–1989. [CrossRef]
There are 53 citations in total.

Details

Primary Language English
Subjects Thermodynamics and Statistical Physics
Journal Section Articles
Authors

Abdelhak Fellague Chebra This is me 0000-0001-6573-1072

Ali Khelil This is me 0000-0003-2431-2271

Mohamed Braikia This is me 0009-0003-3351-8156

Mohamed Bedrouni This is me 0000-0002-4881-8480

Publication Date July 29, 2024
Submission Date June 21, 2023
Published in Issue Year 2024 Volume: 10 Issue: 4

Cite

APA Fellague Chebra, A., Khelil, A., Braikia, M., Bedrouni, M. (2024). Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet. Journal of Thermal Engineering, 10(4), 961-977.
AMA Fellague Chebra A, Khelil A, Braikia M, Bedrouni M. Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet. Journal of Thermal Engineering. July 2024;10(4):961-977.
Chicago Fellague Chebra, Abdelhak, Ali Khelil, Mohamed Braikia, and Mohamed Bedrouni. “Comparative Analysis of Modified Jet Diffuser Geometry for Evaluating the Impact of Rounded Edges and Chamfered Design on Cooling Efficiency of Electronic Components in Cross Flow and Impinging Jet”. Journal of Thermal Engineering 10, no. 4 (July 2024): 961-77.
EndNote Fellague Chebra A, Khelil A, Braikia M, Bedrouni M (July 1, 2024) Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet. Journal of Thermal Engineering 10 4 961–977.
IEEE A. Fellague Chebra, A. Khelil, M. Braikia, and M. Bedrouni, “Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet”, Journal of Thermal Engineering, vol. 10, no. 4, pp. 961–977, 2024.
ISNAD Fellague Chebra, Abdelhak et al. “Comparative Analysis of Modified Jet Diffuser Geometry for Evaluating the Impact of Rounded Edges and Chamfered Design on Cooling Efficiency of Electronic Components in Cross Flow and Impinging Jet”. Journal of Thermal Engineering 10/4 (July 2024), 961-977.
JAMA Fellague Chebra A, Khelil A, Braikia M, Bedrouni M. Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet. Journal of Thermal Engineering. 2024;10:961–977.
MLA Fellague Chebra, Abdelhak et al. “Comparative Analysis of Modified Jet Diffuser Geometry for Evaluating the Impact of Rounded Edges and Chamfered Design on Cooling Efficiency of Electronic Components in Cross Flow and Impinging Jet”. Journal of Thermal Engineering, vol. 10, no. 4, 2024, pp. 961-77.
Vancouver Fellague Chebra A, Khelil A, Braikia M, Bedrouni M. Comparative analysis of modified jet diffuser geometry for evaluating the impact of rounded edges and chamfered design on cooling efficiency of electronic components in cross flow and impinging jet. Journal of Thermal Engineering. 2024;10(4):961-77.

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