Home Technology Numerical Study of the Dynamics of Particles Motion with Different Sizes from Coal-Based Thermal Power Plant
Article
Licensed
Unlicensed Requires Authentication

Numerical Study of the Dynamics of Particles Motion with Different Sizes from Coal-Based Thermal Power Plant

  • Alibek Issakhov EMAIL logo , Ruslan Bulgakov and Yeldos Zhandaulet
Published/Copyright: January 26, 2019
Become an author with De Gruyter Brill
Author Information
International Journal of Nonlinear Sciences and Numerical Simulation
From the journal International Journal of Nonlinear Sciences and Numerical Simulation Volume 20 Issue 2

Abstract

In this paper, the propagation of particles with different sizes from a coal-based thermal power plant was investigated. It was found that the deterioration of the environment is due to the release of a large amount of SOx, NOx and the volatile particles of Suspended Particulate Matter and Respirable Suspended Particles matter, which cause human and animal diseases. This paper presents the numerical simulation results of air pollution by particles which having different sizes from thermal power plants in real sizes using a 3D model. For the adequacy of the mathematical model, a test problem was solved using different turbulent models. To assess the applicability of the mathematical model, the numerical algorithm and the choice of the optimal turbulent model, experimental data and numerical results of other authors were used. The obtained numerical simulation results are in good agreement with the experimental results and the numerical results of other authors. And to obtain more accurate numerical results for the experimental data for turbulent models (kε, kω), there were certain corresponding boundary conditions for kinetic energy. Also, profiles of all flow characteristics were compared with and without particles and some effects of the particle on the flow were identified.

Keywords: large eddy simulation (LES); reynolds averaged Navier-Stokes (RANS); detached eddy simulation (DES); jet in crossflow; particle dispersion
PACS: 47.11.Df; 47.27.E-; 47.27.ep; 47.27.wb; 47.32.C-; 45.50.-j

Acknowledgements

This work is supported by the grant from the Ministry of education and science of the Republic of Kazakhstan.

References

[1] G. Flermoneca, Report of quality of air, (2013), 15.Search in Google Scholar

[2] R. Wilson and J. Spengler, Particles in our air, Harvard University Press, Cambridge, MA. 265, 1996.Search in Google Scholar

[3] V. Vasistha, Effects of pollutants produced by thermal power plant on environment: A review, Int. J. Mech. Eng. Rob. Res. 3 (2) April (2014), 202–207.Search in Google Scholar

[4] W. K. Pokale, Effects of thermal power plant on environment, Sci. Res. Chem.Commun. 2 (3) (2012), 212–215.Search in Google Scholar

[5] S. Balachandar and J. K. Eaton, Turbulent dispersed multiphase flow, Annu. Rev. Fluid Mech. 42 (2010), 111–133.10.1146/annurev.fluid.010908.165243Search in Google Scholar

[6] R. Monchaux, M. Bourgoin and A. Cartellier, Analyzing preferential concentration and clustering of inertial particles in turbulence, Int. J. Multiph. Flow. 40 (2012), 1–18.10.1016/j.ijmultiphaseflow.2011.12.001Search in Google Scholar

[7] S. Goto and J. C. Vassilicos, Sweep-stick mechanism of heavy particle clustering in fluid turbulence, Phys. Rev. Lett. 100 (5) (2008), 054503.10.1103/PhysRevLett.100.054503Search in Google Scholar

[8] A. M. Ahmed and S. Elghobashi, Direct numerical simulation of particle dispersion in homogeneous turbulent shear flows, Phys. Fluids. 13 (11) (2001), 3346–3364.10.1063/1.1405443Search in Google Scholar

[9] X. Liu, C. Ji, X. Xu, D. Xu and J. J. Williams, Distribution characteristics of inertial sediment particles in the turbulent boundary layer of an open channel flow determined using Voronoï analysis, Int. J. Sedim. Res. 32 (3) (2017), 401–409.10.1016/j.ijsrc.2017.07.004Search in Google Scholar

[10] C. Marchioli, A. Soldati, J. G. M. Kuerten, B. Arcen, A. Taniere, G. Goldensoph, K. D. Squires, M. F. Cargnelutti and L. M. Portela, Statistics of particle dispersion in direct numerical simulations of wall-bounded turbulence: Results of an international collaborative benchmark test, Int. J. Multiph. Flow. 34 (9) (2008), 879–893.10.1016/j.ijmultiphaseflow.2008.01.009Search in Google Scholar

[11] D. W. Rouson and J. K. Eaton, On the preferential concentration of solid particles in turbulent channel flow, J. Fluid Mech. 428 (2001), 149–169.10.1017/S0022112000002627Search in Google Scholar

[12] C. Marchioli, A. Giusti, M. V. Salvetti and A. Soldati, Direct numerical simulation of particle wall transfer and deposition in upward turbulent pipe flow, Int. J. Multiphase Flow. 29 (6) (2003), 1017–1038.10.1016/S0301-9322(03)00036-3Search in Google Scholar

[13] A. W. Vreman, Turbulence characteristics of particle-laden pipe flow, J. Fluid Mech. 584 (2007), 235–279.10.1017/S0022112007006556Search in Google Scholar

[14] C. Marchioli, M. Picciotto and A. Soldati, Influence of gravity and lift on particle velocity statistics and transfer rates in turbulent vertical channel flow, Int. J. Multiph. Flow. 33 (3) (2007), 227–251.10.1016/j.ijmultiphaseflow.2006.09.005Search in Google Scholar

[15] V. Armenio and V. Fiorotto, The importance of the forces acting on particles in turbulent flows, Phys. Fluids. 13 (8) (2001), 2437–2440.10.1063/1.1385390Search in Google Scholar

[16] J. N. Chung and T. R. Troutt, Simulation of particle dispersion in an axisymmetric jet, J. Fluid Mech. 186 (1988), 199–222.10.1017/S0022112088000102Search in Google Scholar

[17] E. K. Longmire and J. K. Eaton, Structure of a particle-laden round jet, J. Fluid Mech. 236 (1992), 217–257.10.1017/S002211209200140XSearch in Google Scholar

[18] R. J. Margason (1993) Fifty years of jet in crossflow research. In AGARD Symp. on a Jet in Cross Flow, Winchester, UK. AGARD CP 534.Search in Google Scholar

[19] K. Kalita, A. Dewan and A. K. Dass, Prediction of turbulent plane jet in crossflow, Numer. Heat Transfer A. 41 (2002), 1–12.10.1080/104077802317221465Search in Google Scholar

[20] R. M. Kelso, T. T. Lim and A. E. Perry, An experimental study of round jets in cross-flow, J. Fluid Mech. 306 (1996), 111–144.10.1017/S0022112096001255Search in Google Scholar

[21] A. R. Karagozian, The jet in crossflow, Phys. Fluids. 26 (2014)101303.10.1063/1.4895900Search in Google Scholar

[22] R. M. Keimasi and M. Taeibi-Rahni, Numerical simulation of jets in a crossflow using different turbulence models, Aiaa J. 12 (39) December (2001), 2268–2277.10.2514/2.1264Search in Google Scholar

[23] A. Hoda and S. Acharya, Predictions of a film coolant jet in crossflow with different turbulence models, ASME J. Turbomach. 122 (2000), 558–569.10.1115/1.1302322Search in Google Scholar

[24] J. W. Shan and P. E. Dimotakis, Reynolds-number effects and anisotropy in transverse-jet mixing, J. Fluid. Mech. 566 (2006), 47–96.10.1017/S0022112006001224Search in Google Scholar

[25] L. K. Su and M. G. Mungal, Simultaneous measurement of scalar and velocity field evolution in turbulent crossflowing jets, J. Fluid Mech. 513 (2004), 1–45.10.1017/S0022112004009401Search in Google Scholar

[26] S. Muppidi and K. Mahesh, Study of trajectories of jets in crossflow using direct numerical simulations, J. Fluid. Mech. 530 (2005), 81–100.10.1017/S0022112005003514Search in Google Scholar

[27] S. Muppidi and K. Mahesh, Direct numerical simulation of passive scalar transport in transverse jet, J. Fluid Mech. 598 (2008), 335–360.10.1017/S0022112007000055Search in Google Scholar

[28] K. Mahesh, The interaction of jets with crossflow, Ann. Rev. Fluid Mech. 45 (2013), 379–407.10.1146/annurev-fluid-120710-101115Search in Google Scholar

[29] E. F. Hasselbrink and M. G. Mungal, Transverse jets and jet flames. Part 1. Scaling laws for strong transverse jets, J. Fluid Mech. 443 (2001), 1–25.10.1017/S0022112001005146Search in Google Scholar

[30] G. Chochua, W. Shyy, S. Thakur, A. Brankovic, K. Lienau, L. Porter and D. Lischinsky, A computational and experimental investigation of turbulent jet and crossflow interaction, Numer. Heat Transfer A. 38 (2000), 557–572.10.1080/104077800750021134Search in Google Scholar

[31] S. Acharya, M. Tyagi and A. Hoda, Flow and heat transfer predictions for film cooling, heat transfer in gas turbine systems, Ann. N.Y. Acad. Sci. 934 (2001), 110–125.10.1111/j.1749-6632.2001.tb05846.xSearch in Google Scholar PubMed

[32] X. Chai, P. S. Iyer and K. Mahesh, Numerical study of high speed jets in crossflow, J. Fluid Mech. 785 (2015), 152–188.10.1017/jfm.2015.612Search in Google Scholar

[33] J. U. Schluter and T. Schonfeld, LES of jets in crossflow and its application to a gas turbine burner, Flow Turbul. Combust. 65 (2000), 177–203.10.1023/A:1011412810639Search in Google Scholar

[34] F. R. Menter and M. Kuntz, Development and application of a zonal des turbulence model for CFX-5, CFX-Validation Report, CFX-VAL17/0503, (2003).Search in Google Scholar

[35] A. Issakhov, Y. Zhandaulet and A. Nogaeva, Numerical simulation of dam break flow for various forms of the obstacle by VOF method, Int. J. Multiphase Flow. (2018). doi: https://doi.org/10.1016/j.ijmultiphaseflow.2018.08.003,.Search in Google Scholar

[36] A. Issakhov and G. Mussakulova, Numerical study for forecasting the dam break flooding flows impacts on different shaped obstacles, Int. J. Mech. 11 (2017c), 273–280.10.1063/1.5044123Search in Google Scholar

[37] A. Issakhov Numerical modelling of distribution the discharged heat water from thermal power plant on the aquatic environment. AIP Conference Proceedings 1738, 480025 (2016b); doi: 10.1063/1.4952261.Search in Google Scholar

[38] A. Issakhov, Modeling of synthetic turbulence generation in boundary layer by using Zonal RANS/LES method, Int. J. Nonlinear Sci. Numer. Simul. 15 (2) (2014), 115–120. doi: 10.1515/ijnsns-2012-0029,.Search in Google Scholar

[39] A. Issakhov, Numerical study of the discharged heat water effect on the aquatic environment from thermal power plant by using two water discharged pipes, Int. J. Nonlinear Sci. Numer. Simul. 18 (6) (2017a), 469–483.10.1515/ijnsns-2016-0011Search in Google Scholar

[40] A. Issakhov Numerical modelling of the thermal effects on the aquatic environment from the thermal power plant by using two water discharge pipes. AIP Conference Proceedings 1863, 560050 (2017b); doi: http://dx.doi.org/10.1063/1.4992733.Search in Google Scholar

[41] A. Issakhov, Mathematical modeling of the discharged heat water effect on the aquatic environment from thermal power plant under various operational capacities, Appl. Math. Model. 40 (2) (2016a), 1082–1096.10.1016/j.apm.2015.06.024Search in Google Scholar

[42] A. Issakhov, Numerical modeling of the effect of discharged hot water on the aquatic environment from a thermal power plant, Int. J. Energy Clean Environ. 16 (1–4) (2015b), 23–28.10.1615/InterJEnerCleanEnv.2016015438Search in Google Scholar

[43] A. Issakhov, Mathematical modeling of the discharged heat water effect on the aquatic environment from thermal power plant, Int. J. Nonlinear Sci. Numer. Simul. 16 (5) (2015a), 229–238. doi: 10.1515/ijnsns-2015-0047.Search in Google Scholar

[44] P. Ajersch, J. M. Zhou, S. Ketler, M. Salcudean and I. S. Gartshore, Multiple jets in a cross flow: Detailed measurements and numerical simulations, international gas turbine and aeroengine congress and exposition, ASME Paper 95-GT-9, Houston, TX, June (1995), pp. 1–16.10.1115/95-GT-009Search in Google Scholar

[45] H. K. Versteeg and W. Malalasekera, An introduction to computational fluid dynamics—The finite volume method, Logman, Malaysia, reprinted 1996, Chaps. 5–7, .Search in Google Scholar

[46] F. R. Menter, Two-equation Eddy-viscosity turbulence models for engineering applications, Aiaa J. 8 (32) (1994), 1598–1605.10.2514/3.12149Search in Google Scholar

[47] J. Uthuppan and S. K. Aggarwal, Particle dispersion in a transitional axisymmetric jet: A numerical simulation, Aiaa J. 32 (1994), 10.10.2514/3.12245Search in Google Scholar

[48] F. Sbrizzai, R. Verzicco, M. F. Pidria and A. Soldati, Mechanisms for selective radial dispersion of microparticles in the transitional region of a confined turbulent round jet, Int. J. Multiphase Flow. 30 (2004), 1389–1417.10.1016/j.ijmultiphaseflow.2004.07.004Search in Google Scholar

[49] K. D. Squires and J. K. Eaton, Preferential concentrations of particles by turbulence, Phys. Fluids A. 3 (1990), 1169–1178.10.1063/1.858045Search in Google Scholar

[50] S. Muppidi and K. Mahesh, Direct numerical simulation of round turbulent jets in crossflow, J. Fluid. Mech. 574 (2007), 59–84.10.1017/S0022112006004034Search in Google Scholar

[51] A. Issakhov Mathematical modelling of the thermal process in the aquatic environment with considering the hydrometeorological condition at the reservoir-cooler by using parallel technologies. Sustaining Power Resources through Energy Optimization and Engineering. p. 227–243, 2016c.10.4018/978-1-4666-9755-3.ch010Search in Google Scholar

Received: 2018-06-25
Accepted: 2019-01-12
Published Online: 2019-01-26
Published in Print: 2019-04-26

© 2019 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Original Research Articles
  3. Directed Transport in Symmetrically Periodic Potentials Induced by Cross-Correlation among Colored Gaussian Noises
  4. Effect of Fractional Damping in Double-Well Duffing–Vander Pol Oscillator Driven by Different Sinusoidal Forces
  5. Dynamical Behaviors of a Fractional-Order Predator–Prey Model with Holling Type IV Functional Response and Its Discretization
  6. Fourth-Order Spatial and Second-Order Temporal Accurate Compact Scheme for Cahn–Hilliard Equation
  7. Unit Root Testing in the Presence of Mean Reverting Jumps: Evidence from US T-Bond Yields
  8. Thermal Analysis of Longitudinal Fin with Temperature-Dependent Properties and Internal heat Generation by a Novel Intelligent Computational Approach Using Optimized Chebyshev Polynomials
  9. A Stream/Block Combination Image Encryption Algorithm Using Logistic Matrix to Scramble
  10. Dynamic Analysis of a Composite Structure under Random Excitation Based on the Spectral Element Method
  11. Sixth-Kind Chebyshev Spectral Approach for Solving Fractional Differential Equations
  12. Representation of Solutions and Finite Time Stability for Delay Differential Systems with Impulsive Effects
  13. Numerical Study of the Dynamics of Particles Motion with Different Sizes from Coal-Based Thermal Power Plant
https://doi.org/10.1515/ijnsns-2018-0182
Keywords for this article
large eddy simulation (LES); reynolds averaged Navier-Stokes (RANS); detached eddy simulation (DES); jet in crossflow; particle dispersion

Articles in the same Issue

  1. Frontmatter
  2. Original Research Articles
  3. Directed Transport in Symmetrically Periodic Potentials Induced by Cross-Correlation among Colored Gaussian Noises
  4. Effect of Fractional Damping in Double-Well Duffing–Vander Pol Oscillator Driven by Different Sinusoidal Forces
  5. Dynamical Behaviors of a Fractional-Order Predator–Prey Model with Holling Type IV Functional Response and Its Discretization
  6. Fourth-Order Spatial and Second-Order Temporal Accurate Compact Scheme for Cahn–Hilliard Equation
  7. Unit Root Testing in the Presence of Mean Reverting Jumps: Evidence from US T-Bond Yields
  8. Thermal Analysis of Longitudinal Fin with Temperature-Dependent Properties and Internal heat Generation by a Novel Intelligent Computational Approach Using Optimized Chebyshev Polynomials
  9. A Stream/Block Combination Image Encryption Algorithm Using Logistic Matrix to Scramble
  10. Dynamic Analysis of a Composite Structure under Random Excitation Based on the Spectral Element Method
  11. Sixth-Kind Chebyshev Spectral Approach for Solving Fractional Differential Equations
  12. Representation of Solutions and Finite Time Stability for Delay Differential Systems with Impulsive Effects
  13. Numerical Study of the Dynamics of Particles Motion with Different Sizes from Coal-Based Thermal Power Plant
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2026 De Gruyter Brill
Downloaded on 6.1.2026 from https://www.degruyterbrill.com/document/doi/10.1515/ijnsns-2018-0182/pdf
Scroll to top button