Research Article
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Numerical Examination of Heat Transfer Augmentation between the Plates with Square Cross-Sectional Ribs for the Staggered Arrangement

Year 2020, Volume: 3 Issue: 2, 33 - 40, 30.11.2020
https://doi.org/10.34088/kojose.657462

Abstract

Heat transfer enhancement inside the ducts is significantly related with flow separation and flow reattachment regions. Therefore, ribs are used to trigger the rotational flows in the vicinity of the wall since the fluctuations in the thermal and hydrodynamic boundary layers are effective for the increment of heat transfer by convection. Even though heat transfer surface area is also enlarged by placing the ribs into the channels, the pressure loss due to the ribs has to be taken into account and controlled in these systems. Based on the aforementioned explanations, the square cross-sectional ribs have been mounted on the bottom and the top walls of horizontal parallel plates in terms of staggered arrangement. In the present paper, numerical analyses have been conducted via k-ω SST turbulence model at Re = 10000, 15000 and 20000 for different spacing values between two successive ribs. For the constant rib dimensions, the ribbed models have been compared among them by referring to smooth plates as reference model. For this reason; time-averaged results including streamwise velocity components, temperature distributions, pressure values, streamline patterns and Nusselt numbers for the ribbed and the smooth plates have been separately presented and compared.

Supporting Institution

Konya Technical University - Academic Staff Training Program (OYP)

Project Number

2018-OYP-046

Thanks

The authors would like to acknowledge the funding of Academic Staff Training Program (OYP) for Project No. of 2018-OYP-046.

References

  • [1] Sundén B., 2011. Convective Heat Transfer and Fluid Flow Physics in Some Ribbed Ducts Using Liquid Crystal Thermography and PIV Measuring Techniques. Heat and Mass Transfer, 47(8), pp.899‒910.
  • [2] Alfarawi S., Abdel-Moneim S., Bodalal A., 2017. Experimental İnvestigations of Heat Transfer Enhancement From Rectangular Duct Roughened by Hybrid Ribs. International Journal of Thermal Sciences, 118, pp.123‒138.
  • [3] Tiggelbeck S., Mitra N.K., Fiebig M., 1993. Experimental İnvestigations of Heat Transfer Enhancement and Flow Losses in A Channel with Double Rows of Longitudinal Vortex Generators. International Journal of Heat and Mass Transfer, 36(9), pp.2327‒2337.
  • [4] Abdollahi A., Shams M., 2015. Optimization of Shape and Angle of Attack of Winglet Vortex Generator in A Rectangular Channel for Heat Transfer Enhancement. Applied Thermal Engineering, 81, pp.376‒387.
  • [5] Sripattanapipat S., Promvonge P., 2009. Numerical Analysis of Laminar Heat Transfer in A Channel with Diamond-Shaped Baffles. International Communications in Heat and Mass Transfer, 36(1), pp.32‒38.
  • [6] Manca O., Nardini S., Ricci D., 2011. Numerical Analysis of Water Forced Convection in Channels with Differently Shaped Transverse Ribs. Journal of Applied Mathematics 2011, 323485.
  • [7] Ahmed M., Yusoff M., Shuaib N., 2013. Effects of Geometrical Parameters on The Flow and Heat Transfer Characteristics in Trapezoidal-Corrugated Channel Using Nanofluid. International Communications in Heat and Mass Transfer, 42, pp.69‒74.
  • [8] Aslan E., Taymaz I., Islamoglu Y., 2016. Finite Volume Simulation for Convective Heat Transfer in Wavy Channels. Heat and Mass Transfer, 52(3), pp.483‒497.
  • [9] Moon M.A., Park M.J., Kim K.Y., 2014. Evaluation of Heat Transfer Performances of Various Rib Shapes. International Journal of Heat and Mass Transfer, 71, pp.275‒284.
  • [10] Kaewkohkiat Y., Promvonge P., Eiamsa-Ard S., 2017. Turbulent Periodic Flow and Heat Transfer in A Rectangular Channel with Detached V-Baffles. Journal of Engineering Thermophysics, 26(4), pp.542‒552.
  • [11] Patankar S., Liu C., Sparrow E., 1977. Fully Developed Flow and Heat Transfer in Ducts Having Streamwise-Periodic Variations of Cross-Sectional Area. Journal of Heat Transfer, 99(2), pp.180‒186.
  • [12] Liu H., Wang J., 2011. Numerical Investigation on Synthetical Performances of Fluid Flow and Heat Transfer of Semiattached Rib-Channels. International Journal of Heat and Mass Transfer, 54(1-3), pp.575‒583.
  • [13] Wongcharee K., Changcharoen W., Eiamsa-Ard S., 2011. Numerical Investigation of Flow Friction and Heat Transfer in A Channel With Various Shaped Ribs Mounted on Two Opposite Ribbed Walls. International Journal of Chemical Reactor Engineering, 9(1), A26.
  • [14] Desrues T., Marty P., Fourmigué J., 2012. Numerical Prediction of Heat Transfer and Pressure Drop in Three-Dimensional Channels with Alternated Opposed Ribs. Applied Thermal Engineering, 45‒46, pp.52‒63.
  • [15] Xie G., Li S., Zhang W., Sundén B., 2013. Computational Fluid Dynamics Modeling Flow Field and Side-Wall Heat Transfer in Rectangular Rib-Roughened Passages. Journal of Energy Resources Technology, 135, 042001.
  • [16] Marocco L., Franco A., 2017, Direct Numerical Simulation and RANS Comparison of Turbulent Convective Heat Transfer in A Staggered Ribbed Channel with High Blockage. Journal of Heat Transfer, 139(2), 021701.
  • [17] Promvonge P., Thianpong C., 2008. Thermal Performance Assessment of Turbulent Channel Flows over Different Shaped Ribs. International Communications in Heat and Mass Transfer, 35(10), pp.1327‒1334.
  • [18] Skullong S., Thianpong C., Promvonge P., 2015. Effects of Rib Size and Arrangement on Forced Convective Heat Transfer in A Solar Air Heater Channel. Heat and Mass Transfer, 51(10), pp.1475‒1485.
  • [19] Vanaki S.M., Mohammed H., 2015. Numerical study of nanofluid forced convection flow in channels using different shaped transverse ribs. International Communications in Heat and Mass Transfer, 67, pp.176‒188.
  • [20] Yang W., Xue S., He Y., Li W., 2017. Experimental Study On The Heat Transfer Characteristics of High Blockage Ribs Channel. Experimental Thermal and Fluid Science 83, pp.248‒259.
  • [21] Cengel Y.A. and Cimbala J.M., 2006. Fluid Mechanics Fundamentals and Applications, International Edition, McGraw Hill Publication, 185201.
  • [22] Matsubara K., Ohta H., Miura T., 2016. Entrance Region Heat Transfer in A Channel with A Ribbed Wall. Journal of Heat Transfer 138(12), 122001.
  • [23] Anonymous, 2009. ANSYS-Fluent 12.0 Theory Guide, ANSYS Inc., USA.
  • [24] Yemenici O., Umur H., 2016. Experimental Aspect of Heat Transfer Enhancement over Various Flow Surfaces. Heat Transfer Engineering 37(5), pp.435‒442
Year 2020, Volume: 3 Issue: 2, 33 - 40, 30.11.2020
https://doi.org/10.34088/kojose.657462

Abstract

Project Number

2018-OYP-046

References

  • [1] Sundén B., 2011. Convective Heat Transfer and Fluid Flow Physics in Some Ribbed Ducts Using Liquid Crystal Thermography and PIV Measuring Techniques. Heat and Mass Transfer, 47(8), pp.899‒910.
  • [2] Alfarawi S., Abdel-Moneim S., Bodalal A., 2017. Experimental İnvestigations of Heat Transfer Enhancement From Rectangular Duct Roughened by Hybrid Ribs. International Journal of Thermal Sciences, 118, pp.123‒138.
  • [3] Tiggelbeck S., Mitra N.K., Fiebig M., 1993. Experimental İnvestigations of Heat Transfer Enhancement and Flow Losses in A Channel with Double Rows of Longitudinal Vortex Generators. International Journal of Heat and Mass Transfer, 36(9), pp.2327‒2337.
  • [4] Abdollahi A., Shams M., 2015. Optimization of Shape and Angle of Attack of Winglet Vortex Generator in A Rectangular Channel for Heat Transfer Enhancement. Applied Thermal Engineering, 81, pp.376‒387.
  • [5] Sripattanapipat S., Promvonge P., 2009. Numerical Analysis of Laminar Heat Transfer in A Channel with Diamond-Shaped Baffles. International Communications in Heat and Mass Transfer, 36(1), pp.32‒38.
  • [6] Manca O., Nardini S., Ricci D., 2011. Numerical Analysis of Water Forced Convection in Channels with Differently Shaped Transverse Ribs. Journal of Applied Mathematics 2011, 323485.
  • [7] Ahmed M., Yusoff M., Shuaib N., 2013. Effects of Geometrical Parameters on The Flow and Heat Transfer Characteristics in Trapezoidal-Corrugated Channel Using Nanofluid. International Communications in Heat and Mass Transfer, 42, pp.69‒74.
  • [8] Aslan E., Taymaz I., Islamoglu Y., 2016. Finite Volume Simulation for Convective Heat Transfer in Wavy Channels. Heat and Mass Transfer, 52(3), pp.483‒497.
  • [9] Moon M.A., Park M.J., Kim K.Y., 2014. Evaluation of Heat Transfer Performances of Various Rib Shapes. International Journal of Heat and Mass Transfer, 71, pp.275‒284.
  • [10] Kaewkohkiat Y., Promvonge P., Eiamsa-Ard S., 2017. Turbulent Periodic Flow and Heat Transfer in A Rectangular Channel with Detached V-Baffles. Journal of Engineering Thermophysics, 26(4), pp.542‒552.
  • [11] Patankar S., Liu C., Sparrow E., 1977. Fully Developed Flow and Heat Transfer in Ducts Having Streamwise-Periodic Variations of Cross-Sectional Area. Journal of Heat Transfer, 99(2), pp.180‒186.
  • [12] Liu H., Wang J., 2011. Numerical Investigation on Synthetical Performances of Fluid Flow and Heat Transfer of Semiattached Rib-Channels. International Journal of Heat and Mass Transfer, 54(1-3), pp.575‒583.
  • [13] Wongcharee K., Changcharoen W., Eiamsa-Ard S., 2011. Numerical Investigation of Flow Friction and Heat Transfer in A Channel With Various Shaped Ribs Mounted on Two Opposite Ribbed Walls. International Journal of Chemical Reactor Engineering, 9(1), A26.
  • [14] Desrues T., Marty P., Fourmigué J., 2012. Numerical Prediction of Heat Transfer and Pressure Drop in Three-Dimensional Channels with Alternated Opposed Ribs. Applied Thermal Engineering, 45‒46, pp.52‒63.
  • [15] Xie G., Li S., Zhang W., Sundén B., 2013. Computational Fluid Dynamics Modeling Flow Field and Side-Wall Heat Transfer in Rectangular Rib-Roughened Passages. Journal of Energy Resources Technology, 135, 042001.
  • [16] Marocco L., Franco A., 2017, Direct Numerical Simulation and RANS Comparison of Turbulent Convective Heat Transfer in A Staggered Ribbed Channel with High Blockage. Journal of Heat Transfer, 139(2), 021701.
  • [17] Promvonge P., Thianpong C., 2008. Thermal Performance Assessment of Turbulent Channel Flows over Different Shaped Ribs. International Communications in Heat and Mass Transfer, 35(10), pp.1327‒1334.
  • [18] Skullong S., Thianpong C., Promvonge P., 2015. Effects of Rib Size and Arrangement on Forced Convective Heat Transfer in A Solar Air Heater Channel. Heat and Mass Transfer, 51(10), pp.1475‒1485.
  • [19] Vanaki S.M., Mohammed H., 2015. Numerical study of nanofluid forced convection flow in channels using different shaped transverse ribs. International Communications in Heat and Mass Transfer, 67, pp.176‒188.
  • [20] Yang W., Xue S., He Y., Li W., 2017. Experimental Study On The Heat Transfer Characteristics of High Blockage Ribs Channel. Experimental Thermal and Fluid Science 83, pp.248‒259.
  • [21] Cengel Y.A. and Cimbala J.M., 2006. Fluid Mechanics Fundamentals and Applications, International Edition, McGraw Hill Publication, 185201.
  • [22] Matsubara K., Ohta H., Miura T., 2016. Entrance Region Heat Transfer in A Channel with A Ribbed Wall. Journal of Heat Transfer 138(12), 122001.
  • [23] Anonymous, 2009. ANSYS-Fluent 12.0 Theory Guide, ANSYS Inc., USA.
  • [24] Yemenici O., Umur H., 2016. Experimental Aspect of Heat Transfer Enhancement over Various Flow Surfaces. Heat Transfer Engineering 37(5), pp.435‒442
There are 24 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

İlker Göktepeli 0000-0002-2886-8018

Ulaş Atmaca 0000-0002-9265-1446

Project Number 2018-OYP-046
Publication Date November 30, 2020
Acceptance Date October 15, 2020
Published in Issue Year 2020 Volume: 3 Issue: 2

Cite

APA Göktepeli, İ., & Atmaca, U. (2020). Numerical Examination of Heat Transfer Augmentation between the Plates with Square Cross-Sectional Ribs for the Staggered Arrangement. Kocaeli Journal of Science and Engineering, 3(2), 33-40. https://doi.org/10.34088/kojose.657462