Application of Improved Blocked-Off Method to Simulate the Interacting Influences of Obstacle Shape and Wall Velocity on the Turbulent Mixed Convection Flow in a Trapezoidal Cavity
محورهای موضوعی :
Mechanical Engineering
Meysam Atashafrooz
1
1 - Department of Mechanical Engineering
Sirjan University of Technology, Sirjan, Iran
تاریخ دریافت : 1400/11/29
تاریخ پذیرش : 1401/01/11
تاریخ انتشار : 1401/03/11
کلید واژه:
Rectangular obstacle,
Semicircular obstacle,
Improved blocked-off method,
RNG k-ε MethodTurbulent Flow,
Triangular obstacle,
چکیده مقاله :
In the current research, interaction influences of obstacle shape and top wall velocity on the hydrothermal behaviours of the turbulent mixed convection flow in a trapezoidal cavity are numerically simulated. To achieve this goal, three different shapes of the obstacles including semicircular, triangular, rectangular are considered. Dimensions of these obstacles are chosen so that the environment around all three of them is same. The RNG model is chosen to simulate the turbulent flow. To model the inclined or curved walls of trapezoidal cavity and obstacles, the improved blocked-off method is applied. Results show that the obstacle shape and top wall velocity have a significant influence on the thermal and hydrodynamic behaviours. In fact, the highest magnitude of heat transfer rate along the bottom wall occurs in the cavity with the rectangular obstacle and for the highest magnitude of top wall velocity; whilst its lowest magnitude is related to the pure free convection and for the cavity with the semicircular obstacle. Besides, the lowest and highest magnitudes of temperatures fields occur for the cavities with rectangular and triangular obstacles, respectively.
منابع و مأخذ:
Yang, G., Huang, Y., Wu, J., Zhang, L., Chen, G., Lv, R., and Cai, A., Experimental Study and Numerical Models Assessment of Turbulent Mixed Convection Heat Transfer in a Vertical Open Cavity, Building and Environment, Vol. 115, 2017, pp. 91-103.
Miroshnichenko, I. V., Sheremet, M. A., Radiation Effect on Conjugate Turbulent Natural Convection in a Cavity with a Discrete Heater, Applied Mathematics and Computation, Vol. 321, 2018, pp. 358-371.
Mahmoodabadi, M. J., Mahmoodabadi, F., and Atashafrooz, M., Development of the Meshless Local Petrov-Galerkin Method to Analyze Three-Dimensional Transient Incompressible Laminar Fluid Flow, Journal of the Serbian Society for Computational Mechanics, Vol. 12, No. 2, 2018, pp. 128-152.
Hegele, J. R, L. A., Scagliarini, A., Sbragaglia, M., Mattila, K. K., Philippi, P. C., Puleri, D. F., Gounley, J., and Randles, A., High-Reynolds-Number Turbulent Cavity Flow using the Lattice Boltzmann Method, Physical Review E, Vol. 98, No. 4, 2018, Article Number: 043302.
Benyahia, N., Aksouh, M., Mataoui, A., and Oztop, H. F., Coupling Turbulent Natural Convection-Radiation-Conduction in Differentially Heated Cavity with High Aspect Ratio, International Journal of Thermal Sciences, Vol. 158, 2020, pp. 106518.
Sun, Y., Liu, Q., Cattafesta III, L. N., Ukeiley, L. S., and Taira, K., Resolvent Analysis of Compressible Laminar and Turbulent Cavity Flows, AIAA Journal, Vol. 58, No. 3, 2020, Article Number: 1046-1055.
Wen, X., Wang, L. P., Guo, Z., and Zhakebayev, D. B., Laminar to Turbulent Flow Transition inside the Boundary Layer Adjacent to Isothermal Wall of Natural Convection Flow in a Cubical Cavity, International Journal of Heat and Mass Transfer, Vol. 167, 2021, Article Number: 120822.
Navarro, J. M. A., Hinojosa, J. F., and Piña-Ortiz, A., Computational Fluid Dynamics and Experimental Study of Turbulent Natural Convection Coupled with Surface Thermal Radiation in a Cubic Open Cavity, International Journal of Mechanical Sciences, Vol. 198, 2021, Article Number: 106360.
Koufi, L., Younsi, Z., Cherif, Y., and Naji, H., Numerical Investigation of Turbulent Mixed Convection in an Open Cavity: Effect of Inlet and Outlet Openings, International Journal of Thermal Sciences, Vol. 116, 2017, pp. 103-117.
Miroshnichenko, I., Sheremet, M., and Chamkha, A.J., Turbulent Natural Convection Combined with Surface Thermal Radiation in a Square Cavity with Local Heater, International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 28, No. 7, 2018, pp. 1698-1715.
Huang, Y. Y., Yang, G., and Wu, J. Y., Large Eddy Simulation and Experimental Study of Turbulent Mixed Convection inside a Cavity with Large Rayleigh Number: Effect of Buoyancy, Building and Environment, Vol. 151, 2019, pp. 268-279.
Olazo-Gómez, Y., Xamán, J., Gijón-Rivera, M., Noh-Pat, F., Simá, E., and Chávez, Y., Mathematical Modelling of Conjugate Laminar and Turbulent Heat Transfer in a Cavity: Effect of a Vertical Glazed Wall, International Journal of Thermal Sciences, Vol. 152, 2020, Article Number: 106310.
Rodrigues, F. A., De Lemos, M. J., Turbulent Flow and Heat Transfer in a Partially Filled Ventilated Cavity using the Local Thermal Non-Equilibrium Method, International Journal of Thermal Sciences, Vol. 164, 2021, Article Number: 106844.
Salari, M., Rashidi, M. M., Malekshah, E. H., and Malekshah, M. H., Numerical Analysis of Turbulent/Transitional Natural Convection in Trapezoidal Enclosures, International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 27, No. 12, 2017, pp. 2902-2923.
Miroshnichenko, I. V., Sheremet, M. A., Turbulent Natural Convection Combined with Thermal Surface Radiation inside an Inclined Cavity Having Local Heater, International Journal of Thermal Sciences, Vol. 124, 2018, pp. 122-130.
Zhang, L., Huang, Y., Yang, G., and Wu, J., Numerical Simulation of Conjugate Turbulent Mixed Convection in an Open Cavity: Evaluation of Different Wall Heat Conduction Models, Numerical Heat Transfer, Part A: Applications, Vol. 74, No. 5, 2018, pp. 1244-1264.
Atashafrooz, M., Sajjadi, H., and Delouei, A. A., Interacting Influences of Lorentz Force and Bleeding on the Hydrothermal Behaviors of Nanofluid Flow in a Trapezoidal Recess with the Second Law of Thermodynamics Analysis, International Communications in Heat and Mass Transfer, Vol. 110, 2020, Article Number: 104411.
Fabregat, A., Pallarès, J., Heat Transfer and Boundary Layer Analyses of Laminar and Turbulent Natural Convection in a Cubical Cavity with Differently Heated Opposed Walls, International Journal of Heat and Mass Transfer, Vol. 151, 2020, Article Number: 119409.
Wu, S., Yaras, M. I., Interaction of a Turbulent Spot with a Two-Dimensional Cavity, Physics of Fluids, Vol. 33, No. 9, 2021, Article Number: 094114.
Atashafrooz, M., Gandjalikhan, Nassab S. A., and Lari, K., Numerical Analysis of Interaction between Non-Gray Radiation and Forced Convection Flow over a Recess using the Full-Spectrum K-Distribution Method, Heat and Mass Transfer, Vol. 52, No. 2, 2016, pp. 361-377.
Alinejad, J., Esfahani, J. A., Taguchi Design of Three-Dimensional Simulations for Optimization of Turbulent Mixed Convection in a Cavity, Meccanica, Vol. 52, No. 4-5, 2017, pp. 925-938.
Kogawa, T., Chen, L., Okajima, J., Sakurai, A., Komiya, A., and Maruyama, S., Effects of Concentration of Participating Media on Turbulent Natural Convection in Cubic Cavity, Applied Thermal Engineering, Vol. 131, 2018, pp. 141-149.
Samantaray, D., Das, M. K., High Reynolds Number Incompressible Turbulent Flow inside a Lid-Driven Cavity with Multiple Aspect Ratios, Physics of Fluids, Vol. 30, No. 7, 2018, Article Number: 075107.
Pinã-Ortiz, A., Hinojosa, J. F., and Hernández-López, I., Computational Fluid Dynamics and Experimental Study of the Effect of Inclination Angle on Turbulent Natural Convection in an Upward Open Cubic Cavity, International Journal of Modern Physics C, Vol. 32, No. 4, 2021, Article Number: 2150056.
Loksupapaiboon, K., Suvanjumrat, C., Assessment of Turbulence Models for Low Turbulent Natural Convection Heat Transfer in Rectangular Enclosed Cavity using Open Foam, In IOP Conference Series: Materials Science and Engineering, Vol. 1137, No. 1, 2021, Article Number: 012044, IOP Publishing.
Lafdaili, Z., El-Hamdani, S., Bendou, A., Limam, K., and El-Hafad, B., Numerical Study of the Turbulent Natural Convection of Nanofluids in a Partially Heated Cubic Cavity, Thermal Science, Vol. 25, No. 4, 2021, pp. 2741-2754.
Promvonge, P., Heat Transfer and Pressure Drop in a Channel with Multiple 60 V-Baffles, International Communications in Heat and Mass Transfer, Vol. 37, No. 7, 2010, pp. 835-840.
Koolnapadol, N., Hoonpong, P., Skullong, S., Kammul, P., and Promvonge, P., Turbulent Heat Transfer and Pressure Loss in a Square-Duct Heat Exchanger with Inclined-Baffle Inserts, Engineering Journal, Vol. 21, No. 7, 2017, pp. 485-497.
Fawaz, H. E., Badawy, M. T. S., Abd Rabbo, M. F., and Elfeky, A., Numerical Investigation of Fully Developed Periodic Turbulent Flow in a Square Channel Fitted with 45 in-Line V-Baffle Turbulators Pointing Upstream, Alexandria Engineering Journal, Vol. 57, No. 2, 2018, pp. 633-642.
Li, Z., Hussein, A. K., Younis, O., Afrand, M., and Feng, S., Natural Convection and Entropy Generation of a Nanofluid Around a Circular Baffle inside an Inclined Square Cavity under Thermal Radiation and Magnetic Field Effects, International Communications in Heat and Mass Transfer, Vol. 116, 2020, Article Number: 104650.
Singh, S. K., Raushan, P. K., Debnath, K., and Mazumder, B. S., Higher Order Turbulent Flow Characteristics of Oscillatory Flow over a Wall-Mounted Obstacle, ISH Journal of Hydraulic Engineering, Vol. 26, No. 1, 2020, pp. 84-95.
Du, R., Gokulavani, P., Muthtamilselvan, M., Al-Amri, F., and Abdalla, B., Influence of the Lorentz Force on the Ventilation Cavity Having a Centrally Placed Heated Baffle Filled with The Cu−Al2O3−H2O Hybrid Nanofluid, International Communications in Heat and Mass Transfer, Vol. 116, 2020, Article Number: 104676.
Levchenya, A. M., Smirnov, E. M., Smirnovsky, A. A., and Zasimova, M. A., Disturbing Action of a Cubical Obstacle on the Turbulent Vertical-Plate Free Convection Boundary Layer: RANS-Based Simulation, In Journal of Physics: Conference Series, Vol. 1697, No. 1, 2020, pp. 012215, IOP Publishing.
Farsani, R. Y., Mahmoudi, A., and Jahangiri, M., How a Conductive Baffle Improves Melting Characteristic and Heat Transfer in a Rectangular Cavity Filled with Gallium, Thermal Science and Engineering progress, Vol. 16, 2020, Article Number: 100453.
Lee, J. R., Numerical Simulation of Natural Convection in a Horizontal Enclosure: Part I. On the Effect of Adiabatic Obstacle in Middle, International Journal of Heat and Mass Transfer, Vol. 124, 2018, pp. 220-232.
Rahmati, A. R., Tahery, A. A., Numerical Study of Nanofluid Natural Convection in a Square Cavity with a Hot Obstacle using Lattice Boltzmann Method, Alexandria Engineering Journal, Vol. 57, No. 3, 2018, pp. 1271-1286.
Bhattacharyya, S., Benim, A. C., Pathak, M., Chamoli, S., and Gupta, A., Thermohydraulic Characteristics of Inline and Staggered Angular Cut Baffle Inserts in the Turbulent Flow Regime, Journal of Thermal Analysis and Calorimetry, Vol. 140, No. 3, 2019, pp. 1519-1536.
Mahmood, R., Bilal, S., Khan, I., Kousar, N., Seikh, A. H., and Sherif, E.S.M., A Comprehensive Finite Element Examination of Carreau Yasuda Fluid Model in a Lid Driven Cavity and Channel with Obstacle by Way of Kinetic Energy and Drag and Lift Coefficient Measurements, Journal of Materials Research and Technology, Vol. 9, No. 2, 2020, pp. 1785-1800.
Kang, S., Khosronejad, A., and Yang, X., Turbulent Flow Characteristics Around a Non-Submerged Rectangular Obstacle on the Side of an Open Channel, Physics of Fluids, Vol. 33, No. 4, 2021, Article Number: 045106.
Banihashemi, S., Assari, M. R., Javadi, S., and Vahidifar, S., Experimental Study of the Effect of Disk Obstacle Rotating with Different Angular Ratios on Heat Transfer and Pressure Drop in a Pipe with Turbulent Flow, Journal of Thermal Analysis and Calorimetry, Vol. 144, No. 4, 2021, pp. 1401-1416.
Shahid, H., Yaqoob, I., Khan, W. A., and Aslam, M., Multi Relaxation Time Lattice Boltzmann Analysis of Lid-Driven Rectangular Cavity Subject to Various Obstacle Configurations, International Communications in Heat and Mass Transfer, Vol. 129, 2021, Article Number: 105658.
Saha, S., Numerical Simulation of Turbulent Airflow and Heat Transfer Through a Rectangular Channel along with Two Trapezoidal Baffle Plates: Comparison between Plane and Trapezoidal Shape Baffles, In AIP Conference Proceedings, Vol. 2341, No. 1, 2021, Article Number: 030005, AIP Publishing LLC.
Kareem, A. K., and Gao, S., Mixed Convection Heat Transfer of Turbulent Flow in a Three-Dimensional Lid-Driven Cavity with a Rotating Cylinder, International Journal of Heat and Mass Transfer, Vol. 112, 2017, pp. 185-200.
Motlagh, S. Y., and Sarvari, P., Large Eddy Simulation of Three-Dimensional Mixed Convection Flow inside the Ventilated Cavity Containing Obstacle and Extraction of Coherent Structures using Proper Orthogonal Decomposition (Pod), Journal of Solid and Fluid Mechanics, Vol. 7, No. 3, 2017, pp. 199-212.
Barman, A., Dash, S. K., Effect of Obstacle Positions for Turbulent Forced Convection Heat Transfer and Fluid Flow over a Double Forward Facing Step, International Journal of Thermal Sciences, Vol. 134, 2018, pp. 116-128.
Menni, Y., Chamkha, A., Zidani, C., and Benyoucef, B., Baffle Orientation and Geometry Effects on Turbulent Heat Transfer of a Constant Property Incompressible Fluid Flow inside a Rectangular Channel, International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 30, No. 6, 2019, pp. 3027-3052.
Menni, Y., Azzi, A., and Chamkha, A.J., Computational Thermal Analysis of Turbulent Forced-Convection Flow in an Air Channel with a Flat Rectangular Fin and Downstream V-Shaped Baffle, Heat Transfer Research, Vol. 50, No. 18, 2019, pp. 1781-1818.
Menni, Y., Azzi, A., Chamkha, A. J., and Harmand, S., Effect of Wall-Mounted V-Baffle Position in a Turbulent Flow Through a Channel: Analysis of Best Configuration for Optimal Heat Transfer, International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 29, No. 10, 2019, pp. 3908-3937.
Siba, M. A. A., and Jehhef, K. A., Numerical Study of Turbulent Forced Convection Flow Over Sudden Expansion with Triangular Obstacle, Journal of Mechanical Engineering Research and Developments, Vol. 43, No. 3, 2020, pp. 125-143.
Wang, J. Y., Hu, X. J., Application of RNG Turbulence Model on Numerical Simulation in Vehicle External Flow Field, In Applied Mechanics and Materials, Vol. 170, 2012, pp. 3324-3328, Trans Tech Publications Ltd.
Koutsourakis, N., Bartzis, J. G., and Markatos, N. C., Evaluation of Reynolds Stress, and RNG Turbulence Models in Street Canyon Flows using Various Experimental Datasets, Environmental Fluid Mechanics, Vol. 12, No. 4, 2012, pp. 379-403.
Zhao, X., Chen, Q., Inverse Design of Indoor Environment using an Adjoint Rng Turbulence Model, Indoor air, Vol. 29, No. 2, 2019, pp. 320-330.
Zabihi, M., Lari, K., and Amiri, H., Comparison of the Blocked-Off and Embedded Boundary Methods in Radiative Heat Transfer Problems in 2d Complex Enclosures at Radiative Equilibrium, Journal of Mechanical Science and Technology, Vol. 31, No. 7, 2017, pp. 3539-3551.
Atashafrooz, M., Shafie, M., Analysis of Entropy Generation for Mixed Convection Fluid Flow in a Trapezoidal Enclosure using the Modified Blocked Region Method, Journal of the Serbian Society for Computational Mechanics, Vol. 14, No. 2, 2020, pp. 97-116.
Atashafrooz, M., Gandjalikhan, Nassab S. A., and Ansari, A. B., Numerical Study of Entropy Generation in Laminar Forced Convection Flow Over Inclined Backward and Forward-Facing Steps in a Duct, International Review of Mechanical Engineering, Vol. 5, No. 5, 2011, pp. 898-907.
Atashafrooz, M., Gandjalikhan, Nassab S. A., and Ansari, B. A., Numerical Investigation of Entropy Generation in Laminar Forced Convection Flow Over Inclined Backward and Forward-Facing Steps in a Duct under Bleeding Condition, Thermal Science, Vol. 18, No. 2, 2014, pp. 479-492.
Atashafrooz, M., Gandjalikhan Nassab, S. A., and Sadat Behineh, E., Effects of Baffle on Separated Convection Step Flow of Radiating Gas in a Duct, International Journal of Advanced Design and Manufacturing Technology (ADMT), Vol. 8, No. 3, 2015, pp. 33-47.
Aminzadeh, N., Sotoodehnia, S., and Atashafrooz, M., Geometrical Effects of Duct on the Entropy Generation in the Laminar Forced Convection Separated Flow, International Journal of Advanced Design and Manufacturing Technology (ADMT), Vol. 11, No. 3, 2018, pp.25-34.