Research Article
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Year 2022, , 176 - 185, 15.12.2022
https://doi.org/10.35860/iarej.1136354

Abstract

References

  • 1. Menni, Y., A. Azzi, and A. Chamkha, Enhancement of convective heat transfer in smooth air channels with all-mounted obstacles in the flow path: A review. Journal of Thermal Analysis and Calorimetry, 2019. 135: p. 1951-1976.
  • 2. Ekiciler, R., M.S.A. Çetinkaya, and K. Arslan, Effect of shape of nanoparticle on heat transfer and entropy generation of nanofluid-jet impingement cooling. International Journal of Green Energy, 2020. 17(10): p. 555-567.
  • 3. Husain, S., S.A. Khan, and M.A. Siddiqui, Wall boiling of Al2O3-water nanofluid: Effect of nanoparticle concentration. Progress in Nuclear Energy, 2021. 133: p. 103614.
  • 4. Altun, A H., H. Nacak, and E. Canli, Effects of trapezoidal and twisted trapezoidal tapes on turbulent heat transfer in tubes. Applied Thermal Engineering, 2022. 211: p. 118386.
  • 5. Akdag, U., S. Akcay, and D. Demiral, Heat transfer enhancement with laminar pulsating nanofluid flow in a wavy channel. International Communications in Heat and Mass Transfer, 2014. 59: p. 17–23.
  • 6. Arslan, K. and R. Ekiciler, Effects of SiO2/water nanofluid flow in a square cross-sectioned curved duct. European Journal of Engineering and Natural Sciences, 2019. 3(2): p. 101-109.
  • 7. Akdag, U., S. Akcay, and D. Demiral, Heat transfer in a triangular wavy channel with CuO-water nanofluids under pulsating flow. Thermal Science, 2019. 23(1): p. 191-205.
  • 8. El Habet, M.A., S.A. Ahmed, and M.A. Saleh, The effect of using staggered and partially tilted perforated baffles on heat transfer and flow characteristics in a rectangular channel. International Journal of Thermal Sciences, 2022. 174: p. 107422.
  • 9. Kilic, M., M. Yavuz, and I.H., Yilmaz, Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. International Advanced Researches and Engineering Journal, 2018. 2(1): p. 14-19.
  • 10. Li, Z. and Y. Gao, Numerical study of turbulent flow and heat transfer in cross corrugated triangular ducts with delta-shaped baffles. International Journal of Heat and Mass Transfer, 2017. 108: p. 658–670.
  • 11. Sriromreun, P., Numerical study on heat transfer enhancement in a rectangular duct with incline shaped baffles. Chemical Engineering Transactions, 2017. 57: p. 1243–1248.
  • 12. Mellal, M., R. Benzeguir, D. Sahel, and H. Ameur, Hydro-thermal shell-side performance evaluation of a shell and tube heat exchanger under different baffle arrangement and orientation. International Journal of Thermal Sciences, 2017. 121: p. 138-149.
  • 13. Ekiciler, R. and M.S.A. Çetinkaya, A comparative heat transfer study between monotype and hybrid nanofluid in a duct with various shapes of ribs. Thermal Science and Engineering Progress, 2021. 23: p. 100913.
  • 14. Akcay, S., Numerical analysis of heat transfer improvement for pulsating flow in a periodic corrugated channel with discrete V-type winglets. International Communications in Heat and Mass Transfer, 2022. 134: p. 105991.
  • 15. Ameur, H., Effect of Corrugated Baffles on the Flow and Thermal Fields in a Channel Heat Exchanger. Journal of Applied and Computational Mechanics, 2020. 6(2): p. 209-218.
  • 16. Menni, Y., A. Azzi, and A. Chamkha, Modeling and analysis of solar air channels with attachments of different shapes. International Journal of Numerical Methods for Heat & Fluid Flow, 2019. 29(5): p. 1815-1845.
  • 17. Menni, Y., M. Ghazvini, H. Ameur, M.H. Ahmadi, M. Sharifpur, and M. Sadeghzadeh, Numerical calculations of the thermal-aerodynamic characteristics in a solar duct with multiple V-baffles. Engineering Application of Computational Fluid Mechanics, 2020. 14(1): p. 1173–1197.
  • 18. Salhi, J.E., T. Zarrouk, N. Hmidi, M. Salhi, N. Salhi, and M. Chennaif, Three-dimensional numerical analysis of the impact of the orientation of partially inclined baffles on the combined mass and heat transfer by a turbulent convective airflow. International Journal of Energy and Environmental Engineering, Published online 01 June 2022. https://doi.org/10.1007/s40095-022-00505-5.
  • 19. Salhi, J.E., T. Zarrouk, and N. Salhi, Numerical study of the thermo-energy of a tubular heat exchanger with longitudinal baffles. Materials Today: Proceedings, 2021. 45: p. 7306–7313.
  • 20. Nedunchezhiyan, M., R. Karthikeyan, S. Ramalingam, D. Damodaran, J. Ravikumar, S. Sampath, and G. Kaliyaperumal, Influence of baffles in heat transfer fluid characteristics using CFD evaluation. International Journal of Ambient Energy, 2022. p. 1–29 https://doi.org/10.1080/01430750.2022.2063175.
  • 21. Razavi, S.E., T. Adibi, and S. Faramarzi, Impact of inclined and perforated baffles on the laminar thermo-flow behavior in rectangular channels, SN Applied Sciences, 2020. 2:284, http://doi.org/10.1007/s42452-020-2078-8.
  • 22. El Habet, M.A., S.A. Ahmed, and M.A. Saleh, Thermal/hydraulic characteristics of a rectangular channel with inline/staggered perforated baffles. International Communications in Heat Mass Transfer, 2021. 128: p. 105591.
  • 23. Manca O., S. Nardini, and D. Ricci, A numerical study of nanofluid forced convection in ribbed channels. Applied Thermal Engineering, 2012. 37: p. 280-297.
  • 24. Sriromreun, P., C. Thianpong, and P. Promvonge, Experimental and numerical study on heat transfer enhancement in a channel with Z-shaped baffles. International Communications in Heat and Mass Transfer, 2012. 39(7): p. 945–952.
  • 25. Turgut, O. and E. Kızılırmak, Effects of Reynolds number, baffle angle, and baffle distance on 3-d turbulent flow and heat transfer in a circular pipe. Thermal Science, 2015. 19(5): p. 1633-1648.
  • 26. Promvonge, P., S. Tamna, M. Pimsarn, and C. Thianpong, Thermal characterization in a circular tube fitted with inclined horseshoe baffles. Applied Thermal Engineering, 2015. 75: p. 1147–1155.
  • 27. Kumar, R., A. Kumar, R. Chauhan, and M. Sethi, Heat transfer enhancement in solar air channel with broken multiple V-type baffle. Case Studies Thermal Engineering, 2016. 8: p. 187–197.
  • 28. Sahel, D., H. Ameur, R. Benzeguir, and Y. Kamla, Enhancement of heat transfer in a rectangular channel with perforated baffles. Applied Thermal Engineering, 2016. 101: p. 156–164.
  • 29. Jung, S.Y. and H. Park, Experimental investigation of heat transfer of Al2O3 nanofluid in a microchannel heat sink. International Journal of Heat and Mass Transfer, 2021. 179: p. 121729.
  • 30. Akdag, U., S. Akcay, and D. Demiral, Heat transfer enhancement with nanofluids under laminar pulsating flow in a trapezoidal-corrugated channel. Progress in Computational Fluid Dynamics, An International Journal, 2017. 17(5): p. 302-312.
  • 31. Akcay, S. Investigation of thermo-hydraulic performance of nanofluids in a zigzag channel with baffles. Adiyaman University Engineering Sciences Journal, 2021. 15: p. 525-534.
  • 32. Akcay, S. Numerical Analysis of Hydraulic and Thermal Performance of Al2O3-Water Nanofluid in a Zigzag Channel with Central Winglets. Gazi University Journal of Science, 2023. 36(2): in press.
  • 33. Heshmati, A., H.A. Mohammed, and A.N. Darus, Mixed convection heat transfer of nanofluids over backward facing step having a slotted baffle. Applied Mathematics and Computation, 2014. 240: p. 368–386.
  • 34. Alnak, D.E., Thermohydraulic performance study of different square baffle angles in cross-corrugated channel. Journal of Energy Storage, 2020. 28: p. 101295.
  • 35. Ajeel, R.K., K. Sopian, and R. Zulkifli, Thermal-hydraulic performance and design parameters in acurved-corrugated channel with L-shaped baffles and nanofluid. Journal of Energy Storage, 2021. 34: p. 101996.
  • 36. Menni, Y., A.J. Chamkha, M. Ghazvini, M.H. Ahmadi, H. Ameur, A. Issakhov, and M. Inc, Enhancement of the turbulent convective heat transfer in channels through the baffling technique and oil/multiwalled carbon nanotube nanofluids. Numerical Heat Transfer, Part A: Applications, 2021. 79(4): p. 311-351.
  • 37. Canli, E., Ates, A. and Bilir, S. Derivation of dimensionless governing equations for axisymmetric incompressible turbulent flow heat transfer based on standard k-ϵ model. Afyon Kocatepe University Journal of Science and Engineering, 2020; 20(6): p. 1096-1111.
  • 38. ANSYS Fluent user guide & theory guide-Release 15.0, 2015, USA: Fluent Ansys Inc.
  • 39. Pak, B. and Y.I. Cho, Hydrodynamic and heat transfer study of dispersed fluids with submicron metallic oxide particles. Experimental Heat Transfer, 1998. 11(2): p. 151–170.
  • 40. Kakac, S. and A. Pramuanjaroenkij, Review of convective heat transfer enhancement with nanofluids. International Journal of Heat and Mass Transfer, 2009. 52: p. 3187–3196.
  • 41. Meyer, J.P. and S.M. Abolarin, Heat transfer and pressure drop in the transitional flow regime for a smooth circular tube with twisted tape inserts and a square-edged inlet. International Journal of Heat and Mass Transfer, 2018. 117: p. 11-29.

Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids

Year 2022, , 176 - 185, 15.12.2022
https://doi.org/10.35860/iarej.1136354

Abstract

This work numerically analyzes the hydraulic and thermal performance of CuO-water nanofluid in a circular duct with different baffle angles. In the numerical work, governing equations are discretized with the finite volume method, and the simulations are solved with SIMPLE algorithm. The surfaces of the duct containing baffles are kept at 340 K. In the analysis, the effects of different Reynolds numbers (200 ≤ Re ≤ 1000), nanoparticle volume fractions (1% ≤ ϕ ≤ 3%), and baffle angles (30º ≤ α ≤ 150º) on the thermal enhancement factor (η) and the friction factor are investigated. In addition, the flow and temperature contours are presented for different parameters within the duct. From those contours, it is observed that the baffles cause flow oscillation and recirculation zones are formed. The numerical results show that baffles and nanofluid flow contribute significantly to the thermal enhancement. The Nusselt number (Nu) and relative friction factor (r) increase as the Reynolds number and nanoparticle volume fraction increase. While the highest thermal enhancement factor and relative friction factor are obtained at α = 90º baffle angle, the best performance evaluation criterion (PEC) value is found at α = 150º baffle angle.

References

  • 1. Menni, Y., A. Azzi, and A. Chamkha, Enhancement of convective heat transfer in smooth air channels with all-mounted obstacles in the flow path: A review. Journal of Thermal Analysis and Calorimetry, 2019. 135: p. 1951-1976.
  • 2. Ekiciler, R., M.S.A. Çetinkaya, and K. Arslan, Effect of shape of nanoparticle on heat transfer and entropy generation of nanofluid-jet impingement cooling. International Journal of Green Energy, 2020. 17(10): p. 555-567.
  • 3. Husain, S., S.A. Khan, and M.A. Siddiqui, Wall boiling of Al2O3-water nanofluid: Effect of nanoparticle concentration. Progress in Nuclear Energy, 2021. 133: p. 103614.
  • 4. Altun, A H., H. Nacak, and E. Canli, Effects of trapezoidal and twisted trapezoidal tapes on turbulent heat transfer in tubes. Applied Thermal Engineering, 2022. 211: p. 118386.
  • 5. Akdag, U., S. Akcay, and D. Demiral, Heat transfer enhancement with laminar pulsating nanofluid flow in a wavy channel. International Communications in Heat and Mass Transfer, 2014. 59: p. 17–23.
  • 6. Arslan, K. and R. Ekiciler, Effects of SiO2/water nanofluid flow in a square cross-sectioned curved duct. European Journal of Engineering and Natural Sciences, 2019. 3(2): p. 101-109.
  • 7. Akdag, U., S. Akcay, and D. Demiral, Heat transfer in a triangular wavy channel with CuO-water nanofluids under pulsating flow. Thermal Science, 2019. 23(1): p. 191-205.
  • 8. El Habet, M.A., S.A. Ahmed, and M.A. Saleh, The effect of using staggered and partially tilted perforated baffles on heat transfer and flow characteristics in a rectangular channel. International Journal of Thermal Sciences, 2022. 174: p. 107422.
  • 9. Kilic, M., M. Yavuz, and I.H., Yilmaz, Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. International Advanced Researches and Engineering Journal, 2018. 2(1): p. 14-19.
  • 10. Li, Z. and Y. Gao, Numerical study of turbulent flow and heat transfer in cross corrugated triangular ducts with delta-shaped baffles. International Journal of Heat and Mass Transfer, 2017. 108: p. 658–670.
  • 11. Sriromreun, P., Numerical study on heat transfer enhancement in a rectangular duct with incline shaped baffles. Chemical Engineering Transactions, 2017. 57: p. 1243–1248.
  • 12. Mellal, M., R. Benzeguir, D. Sahel, and H. Ameur, Hydro-thermal shell-side performance evaluation of a shell and tube heat exchanger under different baffle arrangement and orientation. International Journal of Thermal Sciences, 2017. 121: p. 138-149.
  • 13. Ekiciler, R. and M.S.A. Çetinkaya, A comparative heat transfer study between monotype and hybrid nanofluid in a duct with various shapes of ribs. Thermal Science and Engineering Progress, 2021. 23: p. 100913.
  • 14. Akcay, S., Numerical analysis of heat transfer improvement for pulsating flow in a periodic corrugated channel with discrete V-type winglets. International Communications in Heat and Mass Transfer, 2022. 134: p. 105991.
  • 15. Ameur, H., Effect of Corrugated Baffles on the Flow and Thermal Fields in a Channel Heat Exchanger. Journal of Applied and Computational Mechanics, 2020. 6(2): p. 209-218.
  • 16. Menni, Y., A. Azzi, and A. Chamkha, Modeling and analysis of solar air channels with attachments of different shapes. International Journal of Numerical Methods for Heat & Fluid Flow, 2019. 29(5): p. 1815-1845.
  • 17. Menni, Y., M. Ghazvini, H. Ameur, M.H. Ahmadi, M. Sharifpur, and M. Sadeghzadeh, Numerical calculations of the thermal-aerodynamic characteristics in a solar duct with multiple V-baffles. Engineering Application of Computational Fluid Mechanics, 2020. 14(1): p. 1173–1197.
  • 18. Salhi, J.E., T. Zarrouk, N. Hmidi, M. Salhi, N. Salhi, and M. Chennaif, Three-dimensional numerical analysis of the impact of the orientation of partially inclined baffles on the combined mass and heat transfer by a turbulent convective airflow. International Journal of Energy and Environmental Engineering, Published online 01 June 2022. https://doi.org/10.1007/s40095-022-00505-5.
  • 19. Salhi, J.E., T. Zarrouk, and N. Salhi, Numerical study of the thermo-energy of a tubular heat exchanger with longitudinal baffles. Materials Today: Proceedings, 2021. 45: p. 7306–7313.
  • 20. Nedunchezhiyan, M., R. Karthikeyan, S. Ramalingam, D. Damodaran, J. Ravikumar, S. Sampath, and G. Kaliyaperumal, Influence of baffles in heat transfer fluid characteristics using CFD evaluation. International Journal of Ambient Energy, 2022. p. 1–29 https://doi.org/10.1080/01430750.2022.2063175.
  • 21. Razavi, S.E., T. Adibi, and S. Faramarzi, Impact of inclined and perforated baffles on the laminar thermo-flow behavior in rectangular channels, SN Applied Sciences, 2020. 2:284, http://doi.org/10.1007/s42452-020-2078-8.
  • 22. El Habet, M.A., S.A. Ahmed, and M.A. Saleh, Thermal/hydraulic characteristics of a rectangular channel with inline/staggered perforated baffles. International Communications in Heat Mass Transfer, 2021. 128: p. 105591.
  • 23. Manca O., S. Nardini, and D. Ricci, A numerical study of nanofluid forced convection in ribbed channels. Applied Thermal Engineering, 2012. 37: p. 280-297.
  • 24. Sriromreun, P., C. Thianpong, and P. Promvonge, Experimental and numerical study on heat transfer enhancement in a channel with Z-shaped baffles. International Communications in Heat and Mass Transfer, 2012. 39(7): p. 945–952.
  • 25. Turgut, O. and E. Kızılırmak, Effects of Reynolds number, baffle angle, and baffle distance on 3-d turbulent flow and heat transfer in a circular pipe. Thermal Science, 2015. 19(5): p. 1633-1648.
  • 26. Promvonge, P., S. Tamna, M. Pimsarn, and C. Thianpong, Thermal characterization in a circular tube fitted with inclined horseshoe baffles. Applied Thermal Engineering, 2015. 75: p. 1147–1155.
  • 27. Kumar, R., A. Kumar, R. Chauhan, and M. Sethi, Heat transfer enhancement in solar air channel with broken multiple V-type baffle. Case Studies Thermal Engineering, 2016. 8: p. 187–197.
  • 28. Sahel, D., H. Ameur, R. Benzeguir, and Y. Kamla, Enhancement of heat transfer in a rectangular channel with perforated baffles. Applied Thermal Engineering, 2016. 101: p. 156–164.
  • 29. Jung, S.Y. and H. Park, Experimental investigation of heat transfer of Al2O3 nanofluid in a microchannel heat sink. International Journal of Heat and Mass Transfer, 2021. 179: p. 121729.
  • 30. Akdag, U., S. Akcay, and D. Demiral, Heat transfer enhancement with nanofluids under laminar pulsating flow in a trapezoidal-corrugated channel. Progress in Computational Fluid Dynamics, An International Journal, 2017. 17(5): p. 302-312.
  • 31. Akcay, S. Investigation of thermo-hydraulic performance of nanofluids in a zigzag channel with baffles. Adiyaman University Engineering Sciences Journal, 2021. 15: p. 525-534.
  • 32. Akcay, S. Numerical Analysis of Hydraulic and Thermal Performance of Al2O3-Water Nanofluid in a Zigzag Channel with Central Winglets. Gazi University Journal of Science, 2023. 36(2): in press.
  • 33. Heshmati, A., H.A. Mohammed, and A.N. Darus, Mixed convection heat transfer of nanofluids over backward facing step having a slotted baffle. Applied Mathematics and Computation, 2014. 240: p. 368–386.
  • 34. Alnak, D.E., Thermohydraulic performance study of different square baffle angles in cross-corrugated channel. Journal of Energy Storage, 2020. 28: p. 101295.
  • 35. Ajeel, R.K., K. Sopian, and R. Zulkifli, Thermal-hydraulic performance and design parameters in acurved-corrugated channel with L-shaped baffles and nanofluid. Journal of Energy Storage, 2021. 34: p. 101996.
  • 36. Menni, Y., A.J. Chamkha, M. Ghazvini, M.H. Ahmadi, H. Ameur, A. Issakhov, and M. Inc, Enhancement of the turbulent convective heat transfer in channels through the baffling technique and oil/multiwalled carbon nanotube nanofluids. Numerical Heat Transfer, Part A: Applications, 2021. 79(4): p. 311-351.
  • 37. Canli, E., Ates, A. and Bilir, S. Derivation of dimensionless governing equations for axisymmetric incompressible turbulent flow heat transfer based on standard k-ϵ model. Afyon Kocatepe University Journal of Science and Engineering, 2020; 20(6): p. 1096-1111.
  • 38. ANSYS Fluent user guide & theory guide-Release 15.0, 2015, USA: Fluent Ansys Inc.
  • 39. Pak, B. and Y.I. Cho, Hydrodynamic and heat transfer study of dispersed fluids with submicron metallic oxide particles. Experimental Heat Transfer, 1998. 11(2): p. 151–170.
  • 40. Kakac, S. and A. Pramuanjaroenkij, Review of convective heat transfer enhancement with nanofluids. International Journal of Heat and Mass Transfer, 2009. 52: p. 3187–3196.
  • 41. Meyer, J.P. and S.M. Abolarin, Heat transfer and pressure drop in the transitional flow regime for a smooth circular tube with twisted tape inserts and a square-edged inlet. International Journal of Heat and Mass Transfer, 2018. 117: p. 11-29.
There are 41 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Research Articles
Authors

Selma Akçay 0000-0003-2654-0702

Ünal Akdağ 0000-0002-1149-7425

Publication Date December 15, 2022
Submission Date June 27, 2022
Acceptance Date October 1, 2022
Published in Issue Year 2022

Cite

APA Akçay, S., & Akdağ, Ü. (2022). Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids. International Advanced Researches and Engineering Journal, 6(3), 176-185. https://doi.org/10.35860/iarej.1136354
AMA Akçay S, Akdağ Ü. Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids. Int. Adv. Res. Eng. J. December 2022;6(3):176-185. doi:10.35860/iarej.1136354
Chicago Akçay, Selma, and Ünal Akdağ. “Effect of Baffle Angles on Flow and Heat Transfer in a Circular Duct With Nanofluids”. International Advanced Researches and Engineering Journal 6, no. 3 (December 2022): 176-85. https://doi.org/10.35860/iarej.1136354.
EndNote Akçay S, Akdağ Ü (December 1, 2022) Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids. International Advanced Researches and Engineering Journal 6 3 176–185.
IEEE S. Akçay and Ü. Akdağ, “Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids”, Int. Adv. Res. Eng. J., vol. 6, no. 3, pp. 176–185, 2022, doi: 10.35860/iarej.1136354.
ISNAD Akçay, Selma - Akdağ, Ünal. “Effect of Baffle Angles on Flow and Heat Transfer in a Circular Duct With Nanofluids”. International Advanced Researches and Engineering Journal 6/3 (December 2022), 176-185. https://doi.org/10.35860/iarej.1136354.
JAMA Akçay S, Akdağ Ü. Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids. Int. Adv. Res. Eng. J. 2022;6:176–185.
MLA Akçay, Selma and Ünal Akdağ. “Effect of Baffle Angles on Flow and Heat Transfer in a Circular Duct With Nanofluids”. International Advanced Researches and Engineering Journal, vol. 6, no. 3, 2022, pp. 176-85, doi:10.35860/iarej.1136354.
Vancouver Akçay S, Akdağ Ü. Effect of baffle angles on flow and heat transfer in a circular duct with nanofluids. Int. Adv. Res. Eng. J. 2022;6(3):176-85.



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