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Year 2024, Volume: 10 Issue: 4, 868 - 879, 29.07.2024

Abstract

References

  • [1] Webb RL. Principles of Enhanced Heat Transfer. 2nd ed. New York: John Wiley & Sons; 1994.
  • [2] Choudhury R, Das UJ. Viscoelastic effects on the three-dimensional hydrodynamic flow past a vertical porous plate. Int J Heat Technol 2013;31:1–8.
  • [3] Ali Q, Riaz S, Memon IQ, Chandio IA, Amir M, Sarris IE, et al. Investigation of magnetized convection for second-grade nanofluids via Prabhakar differentiation. Nonlinear Engineer 2023;12:286. [CrossRef]
  • [4] Gupta SK, Misra RD. Flow boiling heat transfer performance of copper-alumina micro-nanostructured surfaces developed by forced convection electrodeposition technique. Chem Engineer Process 2021;164:108408. [CrossRef]
  • [5] Ahmadi N, Ashrafi H, Rostami S, Vatankhah R. Investigation of the effect of gradual change of the inner tube geometrical configuration on the thermal performance of the double-pipe heat exchanger. Iran J Chem Chem Engineer 2023;42:2305–2317.
  • [6] Gupta AK, Lilley DG, Syred N. Swirl Flows. London: Abacus Press; 1984.
  • [7] Thianpong C, Yongsiri K, Nanan K, Eiamsa-ard S. Thermal performance evaluation of heat exchangers fitted with twisted-rings turbulators. Int Commun Heat Mass Transf 2012;39:861–868. [CrossRef]
  • [8] Sheikholeslami M, Gorji-Bandpy M, Ganji DD. Review of heat transfer enhancement methods: Focus on passive methods using swirl flow devices. Renew Sustain Energy Rev 2015;49:444–469. [CrossRef]
  • [9] Alam HS, Redhyka GG, Bahrudin B, Sugiarto AT, Salim TI, Mardhiya IR. Design and performance of swirl flow microbubble generator. Int J Engineer Technol 2018;7:66–69.
  • [10] Carlos Berrio J, Pereyra E, Ratkovich N. Computational fluid dynamics modelling of gas-liquid cylindrical cyclones, geometrical analysis. ASME J Energy Resour Technol 2018;140:092003. [CrossRef]
  • [11] Erdal FM, Shirazi SA. Local velocity measurements and computational fluid dynamics (CFD) simulations of swirling flow in a cylindrical cyclone separator. J Energy Resour Technol 2004;126:326–333. [CrossRef]
  • [12] Pang X, Wang C, Yang W, Fan H, Zhong S, Zheng W, et al. Numerical simulation of a cyclone separator to recycle the active components of waste lithium batteries. Engineer Appl Comput Fluid Mech 2022;16:937–951. [CrossRef]
  • [13] Guillaume DW, Judge TA. Improving the efficiency of a jet pump using a swirling primary jet. Rev Sci Instrum 2004;75:553–555. [CrossRef]
  • [14] Zhao H, Wang F, Wang C, Chen W, Yao Z, Shi X, et al. Study on the characteristics of horn-like vortices in an axial flow pump impeller under off-design conditions. Engineer Appl Comput Fluid Mech 2021;15:1613–1628. [CrossRef]
  • [15] Granados-Ortiz FJ, Leon-Prieto L, Ortega-Casanova J. Computational study of the application of Al2O3 nanoparticles to forced convection of high-Reynolds swirling jets for engineering cooling processes. Engineer Appl Comput Fluid Mech 2021;15:1–22. [CrossRef]
  • [16] Ali Q, Amir M, Raza A, Khan U, Eldin SM, Alotaibi AM, et al. Thermal investigation into the Oldroyd-B hybrid nanofluid with the slip and Newtonian heating effect: Atangana-Baleanu fractional simulation. Front Mater 2023;10:1114665. [CrossRef]
  • [17] Hamzaoui MMA, Al-Khaled K, Farid S, Ali Q, Raza A, Khan SU, et al. Thermal transport of mixed convective flow of carbon nanotubes with Fourier heat flux model: Prabhakar-time derivatives assessment. Int J Mod Phys B 2023;2450057. [CrossRef]
  • [18] Le QH, Ali Q, Al-Khaled K, Amir M, Riaz S, Khan SU, et al. Study of hybrid nanofluid containing graphene oxide and molybdenum disulfide nanoparticles with engine oil base fluid: A non-singular fractional approach. Ain Shams Engineer J 2023;15:102317. [CrossRef]
  • [19] Riaz S, Ali Q, Khanam Z, Rezazadeh H, Esfandian H. Modeling and computation of nanofluid for thermo-dynamical analysis between vertical plates. Proc Inst Mech Engineer 2023;237:1750–1760. [CrossRef]
  • [20] Shirvan MK, Mamourian M, Esfahani AJ. Experimental investigation on thermal performance and economic analysis of cosine wave tube structure in a shell and tube heat exchanger. Energy Conver Manage 2018;175:86–98. [CrossRef]
  • [21] Pal E, Kumar I, Joshi JB, Maheshwari NK. CFD simulations of shell-side flow in a shell-and-tube type heat exchanger with and without baffles. Chem Engineer Sci 2016;143:314–340. [CrossRef]
  • [22] Abd AA, Kareem MQ, Naji SZ. Performance analysis of shell and tube heat exchanger: Parametric study. Case Stud Therm Engineer 2018;12:563–568. [CrossRef]
  • [23] Moharana S, Bhattacharya A, Das MK. A critical review of parameters governing the boiling characteristics of tube bundle on shell side of two-phase shell and tube heat exchangers. Therm Sci Engineer Prog 2022;29:101220. [CrossRef]
  • [24] Salahuddin U, Bilal M, Ejaz H. A review of the advancements made in helical baffles used in shell and tube heat exchangers. Int Comm Heat Mass Transf 2015;67:104–108. [CrossRef]
  • [25] Chit SP, San NA, Soe MM. Flow analysis in shell side on the effect of baffle spacing of shell and tube heat exchanger. Int J Sci Technol Soc 2015;3:254–259. [CrossRef]
  • [26] Bell KJ, Mueller AC. The Heat Transfer Data Book II: Fundamental Heat Transfer and Application Know-How. Lisbon: Publico Publications; 2016.
  • [27] Raju SN. Fluid Mechanics, Heat Transfer, and Mass Transfer Chemical Engineering Practice. 1st ed. New York: John Wiley & Sons; 2011. [CrossRef]
  • [28] Kongkaitpaiboon V, Nanan K, Eiamsa-ard S. Experimental investigation of heat transfer and turbulent flow friction in a tube fitted with perforated conical rings. Int Comm Heat Mass Transf 2010;37:560–567. [CrossRef]
  • [29] Kongkaitpaiboon V, Nanan K, Eiamsa-ard S. Experimental investigation of convective heat transfer and pressure loss in a round tube fitted with circular-ring turbulators. Int Comm Heat Mass Transf 2010;37:568–574. [CrossRef]
  • [30] Rahman MA, Dhiman SK. Investigations of the turbulent thermo-fluid performance in a circular heat exchanger with a novel flow deflector-type baffle plate. Bull Pol Acad Sci 2023;71:e145939. [CrossRef]
  • [31] Rahman MA, Dhiman SK. Performance evaluation of turbulent circular heat exchanger with a novel flow deflector-type baffle plate. J Engineer Res 2023;100105. [CrossRef]
  • [32] Rahman MA. Effectiveness of a tubular heat exchanger and a novel perforated rectangular flow-deflector type baffle plate with opposing orientation. World J Engineer 2023 Sept 27. doi: https://doi.org/10.1108/WJE-06-2023-0233. [Epub ahead of print]. [CrossRef]
  • [33] Rahman MA. Experimental investigations on single-phase heat transfer enhancement in an air-to-water heat exchanger with rectangular perforated flow deflector baffle plate. Int J Thermodyn 2023;26:31–39. [CrossRef]
  • [34] Coleman HW, Steele WG. Experimentation, Validation, and Uncertainty Analysis for Engineers. New York: John Wiley & Sons; 2018. [CrossRef]
  • [35] Cao YZ. Experimental Heat Transfer. 1st ed. Beijing: National Defence Industry Press; 1998.
  • [36] Hwang SW, Kim DH, Min JK. CFD analysis of fin tube heat exchanger with a pair of delta winglet vortex generators. J Mech Sci Technol 2012;26:2949–2958. [CrossRef]
  • [37] Dittus FW, Boelter LMK. Heat Transfer in Automobile Radiators of the Tubular Type. Publication on Engineering. 2nd ed. Berkeley: University of California Press; 1930. pp. 443–461.
  • [38] Gnielinski V. New equations for heat and mass transfer in turbulent pipe and channel flow. Int Chem Engineer 1976;16:359–368.
  • [39] White FM. Fluid Mechanics. Boston: McGraw-Hill Press; 2003.
  • [40] Blasius H. Das Ähnlichkeitsgesetz bei Reibungsvorgängen in Flüssigkeiten. In: Mitteilungen über Forschungsarbeiten auf dem Gebiete des Ingenieurwesens. Mitteilungen über Forschungsarbeiten auf dem Gebiete des Ingenieurwesens, vol 131. Berlin, Heidelberg: Springer; 1913. pp. 1–41. [CrossRef]
  • [41] Zhao H, Wang F, Wang C, Chen W, Yao Z, Shi X, et al. Study on the characteristics of horn-like vortices in an axial flow pump impeller under off-design conditions. Engineer Appl Comput Fluid Mech 2021;15:1613–1628. [CrossRef]

Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles

Year 2024, Volume: 10 Issue: 4, 868 - 879, 29.07.2024

Abstract

A study investigated how a new swirl airflow design could impact the heat transfer rate in a tubular heat exchanger with axial flow. A perforated conical baffle plate with rectangular air deflectors of different inclination angles was created to generate a swirl flow. The tubes in the heat exchanger were aligned longitudinally, and the heat flux across their surface was kept constant. Each plate had four deflectors with equal deflector angles and adjustable pitch ratios, which created a swirling airflow inside the circular duct containing the heated tubes. This increased turbulence and the rate of heat transfer across the tube surface. The Reynolds number stayed within the range of 93,500 to 160,500. The result indicates that the inclination angle and Pitch ratio profoundly impact the Nusselt number, while the pitch ratio has a greater effect on the friction factor. Furthermore, the conical baffle plate design resulted in an average improvement of 2.51 in thermal efficiency compared to a segmental baffle design with a deflector angle of 30° and a pitch ratio of 1, all under similar Reynolds number, pitch ratio, and blockage ratio conditions.

References

  • [1] Webb RL. Principles of Enhanced Heat Transfer. 2nd ed. New York: John Wiley & Sons; 1994.
  • [2] Choudhury R, Das UJ. Viscoelastic effects on the three-dimensional hydrodynamic flow past a vertical porous plate. Int J Heat Technol 2013;31:1–8.
  • [3] Ali Q, Riaz S, Memon IQ, Chandio IA, Amir M, Sarris IE, et al. Investigation of magnetized convection for second-grade nanofluids via Prabhakar differentiation. Nonlinear Engineer 2023;12:286. [CrossRef]
  • [4] Gupta SK, Misra RD. Flow boiling heat transfer performance of copper-alumina micro-nanostructured surfaces developed by forced convection electrodeposition technique. Chem Engineer Process 2021;164:108408. [CrossRef]
  • [5] Ahmadi N, Ashrafi H, Rostami S, Vatankhah R. Investigation of the effect of gradual change of the inner tube geometrical configuration on the thermal performance of the double-pipe heat exchanger. Iran J Chem Chem Engineer 2023;42:2305–2317.
  • [6] Gupta AK, Lilley DG, Syred N. Swirl Flows. London: Abacus Press; 1984.
  • [7] Thianpong C, Yongsiri K, Nanan K, Eiamsa-ard S. Thermal performance evaluation of heat exchangers fitted with twisted-rings turbulators. Int Commun Heat Mass Transf 2012;39:861–868. [CrossRef]
  • [8] Sheikholeslami M, Gorji-Bandpy M, Ganji DD. Review of heat transfer enhancement methods: Focus on passive methods using swirl flow devices. Renew Sustain Energy Rev 2015;49:444–469. [CrossRef]
  • [9] Alam HS, Redhyka GG, Bahrudin B, Sugiarto AT, Salim TI, Mardhiya IR. Design and performance of swirl flow microbubble generator. Int J Engineer Technol 2018;7:66–69.
  • [10] Carlos Berrio J, Pereyra E, Ratkovich N. Computational fluid dynamics modelling of gas-liquid cylindrical cyclones, geometrical analysis. ASME J Energy Resour Technol 2018;140:092003. [CrossRef]
  • [11] Erdal FM, Shirazi SA. Local velocity measurements and computational fluid dynamics (CFD) simulations of swirling flow in a cylindrical cyclone separator. J Energy Resour Technol 2004;126:326–333. [CrossRef]
  • [12] Pang X, Wang C, Yang W, Fan H, Zhong S, Zheng W, et al. Numerical simulation of a cyclone separator to recycle the active components of waste lithium batteries. Engineer Appl Comput Fluid Mech 2022;16:937–951. [CrossRef]
  • [13] Guillaume DW, Judge TA. Improving the efficiency of a jet pump using a swirling primary jet. Rev Sci Instrum 2004;75:553–555. [CrossRef]
  • [14] Zhao H, Wang F, Wang C, Chen W, Yao Z, Shi X, et al. Study on the characteristics of horn-like vortices in an axial flow pump impeller under off-design conditions. Engineer Appl Comput Fluid Mech 2021;15:1613–1628. [CrossRef]
  • [15] Granados-Ortiz FJ, Leon-Prieto L, Ortega-Casanova J. Computational study of the application of Al2O3 nanoparticles to forced convection of high-Reynolds swirling jets for engineering cooling processes. Engineer Appl Comput Fluid Mech 2021;15:1–22. [CrossRef]
  • [16] Ali Q, Amir M, Raza A, Khan U, Eldin SM, Alotaibi AM, et al. Thermal investigation into the Oldroyd-B hybrid nanofluid with the slip and Newtonian heating effect: Atangana-Baleanu fractional simulation. Front Mater 2023;10:1114665. [CrossRef]
  • [17] Hamzaoui MMA, Al-Khaled K, Farid S, Ali Q, Raza A, Khan SU, et al. Thermal transport of mixed convective flow of carbon nanotubes with Fourier heat flux model: Prabhakar-time derivatives assessment. Int J Mod Phys B 2023;2450057. [CrossRef]
  • [18] Le QH, Ali Q, Al-Khaled K, Amir M, Riaz S, Khan SU, et al. Study of hybrid nanofluid containing graphene oxide and molybdenum disulfide nanoparticles with engine oil base fluid: A non-singular fractional approach. Ain Shams Engineer J 2023;15:102317. [CrossRef]
  • [19] Riaz S, Ali Q, Khanam Z, Rezazadeh H, Esfandian H. Modeling and computation of nanofluid for thermo-dynamical analysis between vertical plates. Proc Inst Mech Engineer 2023;237:1750–1760. [CrossRef]
  • [20] Shirvan MK, Mamourian M, Esfahani AJ. Experimental investigation on thermal performance and economic analysis of cosine wave tube structure in a shell and tube heat exchanger. Energy Conver Manage 2018;175:86–98. [CrossRef]
  • [21] Pal E, Kumar I, Joshi JB, Maheshwari NK. CFD simulations of shell-side flow in a shell-and-tube type heat exchanger with and without baffles. Chem Engineer Sci 2016;143:314–340. [CrossRef]
  • [22] Abd AA, Kareem MQ, Naji SZ. Performance analysis of shell and tube heat exchanger: Parametric study. Case Stud Therm Engineer 2018;12:563–568. [CrossRef]
  • [23] Moharana S, Bhattacharya A, Das MK. A critical review of parameters governing the boiling characteristics of tube bundle on shell side of two-phase shell and tube heat exchangers. Therm Sci Engineer Prog 2022;29:101220. [CrossRef]
  • [24] Salahuddin U, Bilal M, Ejaz H. A review of the advancements made in helical baffles used in shell and tube heat exchangers. Int Comm Heat Mass Transf 2015;67:104–108. [CrossRef]
  • [25] Chit SP, San NA, Soe MM. Flow analysis in shell side on the effect of baffle spacing of shell and tube heat exchanger. Int J Sci Technol Soc 2015;3:254–259. [CrossRef]
  • [26] Bell KJ, Mueller AC. The Heat Transfer Data Book II: Fundamental Heat Transfer and Application Know-How. Lisbon: Publico Publications; 2016.
  • [27] Raju SN. Fluid Mechanics, Heat Transfer, and Mass Transfer Chemical Engineering Practice. 1st ed. New York: John Wiley & Sons; 2011. [CrossRef]
  • [28] Kongkaitpaiboon V, Nanan K, Eiamsa-ard S. Experimental investigation of heat transfer and turbulent flow friction in a tube fitted with perforated conical rings. Int Comm Heat Mass Transf 2010;37:560–567. [CrossRef]
  • [29] Kongkaitpaiboon V, Nanan K, Eiamsa-ard S. Experimental investigation of convective heat transfer and pressure loss in a round tube fitted with circular-ring turbulators. Int Comm Heat Mass Transf 2010;37:568–574. [CrossRef]
  • [30] Rahman MA, Dhiman SK. Investigations of the turbulent thermo-fluid performance in a circular heat exchanger with a novel flow deflector-type baffle plate. Bull Pol Acad Sci 2023;71:e145939. [CrossRef]
  • [31] Rahman MA, Dhiman SK. Performance evaluation of turbulent circular heat exchanger with a novel flow deflector-type baffle plate. J Engineer Res 2023;100105. [CrossRef]
  • [32] Rahman MA. Effectiveness of a tubular heat exchanger and a novel perforated rectangular flow-deflector type baffle plate with opposing orientation. World J Engineer 2023 Sept 27. doi: https://doi.org/10.1108/WJE-06-2023-0233. [Epub ahead of print]. [CrossRef]
  • [33] Rahman MA. Experimental investigations on single-phase heat transfer enhancement in an air-to-water heat exchanger with rectangular perforated flow deflector baffle plate. Int J Thermodyn 2023;26:31–39. [CrossRef]
  • [34] Coleman HW, Steele WG. Experimentation, Validation, and Uncertainty Analysis for Engineers. New York: John Wiley & Sons; 2018. [CrossRef]
  • [35] Cao YZ. Experimental Heat Transfer. 1st ed. Beijing: National Defence Industry Press; 1998.
  • [36] Hwang SW, Kim DH, Min JK. CFD analysis of fin tube heat exchanger with a pair of delta winglet vortex generators. J Mech Sci Technol 2012;26:2949–2958. [CrossRef]
  • [37] Dittus FW, Boelter LMK. Heat Transfer in Automobile Radiators of the Tubular Type. Publication on Engineering. 2nd ed. Berkeley: University of California Press; 1930. pp. 443–461.
  • [38] Gnielinski V. New equations for heat and mass transfer in turbulent pipe and channel flow. Int Chem Engineer 1976;16:359–368.
  • [39] White FM. Fluid Mechanics. Boston: McGraw-Hill Press; 2003.
  • [40] Blasius H. Das Ähnlichkeitsgesetz bei Reibungsvorgängen in Flüssigkeiten. In: Mitteilungen über Forschungsarbeiten auf dem Gebiete des Ingenieurwesens. Mitteilungen über Forschungsarbeiten auf dem Gebiete des Ingenieurwesens, vol 131. Berlin, Heidelberg: Springer; 1913. pp. 1–41. [CrossRef]
  • [41] Zhao H, Wang F, Wang C, Chen W, Yao Z, Shi X, et al. Study on the characteristics of horn-like vortices in an axial flow pump impeller under off-design conditions. Engineer Appl Comput Fluid Mech 2021;15:1613–1628. [CrossRef]
There are 41 citations in total.

Details

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

Atıqur Rahman 0000-0002-2824-4483

Sushil Kumar Dhiman This is me 0000-0002-6214-6369

Publication Date July 29, 2024
Submission Date May 16, 2023
Published in Issue Year 2024 Volume: 10 Issue: 4

Cite

APA Rahman, A., & Dhiman, S. K. (2024). Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles. Journal of Thermal Engineering, 10(4), 868-879.
AMA Rahman A, Dhiman SK. Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles. Journal of Thermal Engineering. July 2024;10(4):868-879.
Chicago Rahman, Atıqur, and Sushil Kumar Dhiman. “Thermo-Fluid Performance of a Heat Exchanger With a Novel Perforated Flow Deflector Type Conical Baffles”. Journal of Thermal Engineering 10, no. 4 (July 2024): 868-79.
EndNote Rahman A, Dhiman SK (July 1, 2024) Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles. Journal of Thermal Engineering 10 4 868–879.
IEEE A. Rahman and S. K. Dhiman, “Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles”, Journal of Thermal Engineering, vol. 10, no. 4, pp. 868–879, 2024.
ISNAD Rahman, Atıqur - Dhiman, Sushil Kumar. “Thermo-Fluid Performance of a Heat Exchanger With a Novel Perforated Flow Deflector Type Conical Baffles”. Journal of Thermal Engineering 10/4 (July 2024), 868-879.
JAMA Rahman A, Dhiman SK. Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles. Journal of Thermal Engineering. 2024;10:868–879.
MLA Rahman, Atıqur and Sushil Kumar Dhiman. “Thermo-Fluid Performance of a Heat Exchanger With a Novel Perforated Flow Deflector Type Conical Baffles”. Journal of Thermal Engineering, vol. 10, no. 4, 2024, pp. 868-79.
Vancouver Rahman A, Dhiman SK. Thermo-fluid performance of a heat exchanger with a novel perforated flow deflector type conical baffles. Journal of Thermal Engineering. 2024;10(4):868-79.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering