Acta Mechanica Slovaca 2022, 26(3):64-69 | DOI: 10.21496/ams.2023.008

Mathematical Simulation of Pulverized Coal Combustion

Yesudass Arasappan1
Department of Thermal Engineering, Faculty of Materials Science and Technology, VŠB-Technical University of Ostrava, 17. listopadu 2172/15, 708 00 Ostrava-Poruba, Czech Republic

Two different computational fluid dynamic models for the combustion of species were applied for the study of the combustion of pulverized coal in a drop tube. The drop tube is available in the department of energy research of the technical university of Ostrava. The purpose of this work is to find out the main characteristics of the combustion of pulverized coal using data gathered at the laboratory where the drop tube is installed. Some characteristics studied were the total heat transfer involved in the combustion, highest temperature and pressure gradients. A 2d mesh of the drop tube was created in gambit pre-processor and the simulations were performed using the CFD program Ansys fluent. The simulations were performed with double precision (dp mode) in order to get accurate results. In order to simulate the pulverized coal combustion, it was necessary to study turbulence, turbulence models (RNG k-e), combustion models (species transport and non-premixed model) as the modeling in gambit and the setting up of a case in Ansys Fluent. The main goal was to get similar results in the simulations using distinct approaches (different methods of studying the combustion) in Ansys Fluent and the results were satisfying. The total amount of heat transfer results, for example, was quite similar in both experiences.

Keywords: Pulverized coal combustion, particles, species, coal.

Received: January 10, 2022; Revised: January 31, 2022; Accepted: February 6, 2022; Published: September 15, 2022  Show citation

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Arasappan, Y. (2022). Mathematical Simulation of Pulverized Coal Combustion. Acta Mechanica Slovaca26(3), 64-69. doi: 10.21496/ams.2023.008
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    References

    1. HANNABUSS, S. (2008). Ethics and technology: ethical issues in an age of information and communication technology, John Wiley & Sons, Hoboken, New Jersey, USA.
    2. SUN, R. (2006). Numerical simulation on pulverized coal combustion process in a tangential firing furnace. Chinese Journal of Mechanical Engineering, 42(08), 107. Go to original source...
    3. HWANG, M. Y. et al. (2013). Simulation studies on direct ash recycling and reburning technology in a tangentially fired 500 MW pulverized coal boiler. Fuel, 114, 78-87. Go to original source...
    4. YANG, J. G., YU, H. M., FAN, L. A., ZHAO, H. (2012). Flow Characteristic of a New Type of Double-Channel Air Burner in Direct Flow Pulverized Coal Boiler. In Advanced Materials Research, 614-615, 59-63. Go to original source...
    5. KOZUBKOVA, M., JABLONSKA, J., BOJKO, M., MARCALIK, P. (2018). Optimization method for designing of hydraulic elements. MM Science Journal, 03, 2484-2489. Go to original source...
    6. ARASAPPAN, Y. (2019). Mathematical Simulation of Pulverized Coal Combustion. Diploma thesis, VSB-TUO, Ostrava, 52.
    7. RAHAT, A. A. M., WANG, CH., EVERSON, R. M., FIELDSEND, J. E. (2018). Data-driven multi-objective optimisation of coal-fired boiler combustion systems. Applied Energy, 229, 446-458. Go to original source...
    8. WANG, H., ZHANG, CH., LIU, X. (2020). Heat transfer calculation methods in three-dimensional CFD model for pulverized coal-fired boilers. Applied Thermal Engineering, 166, 114633. Go to original source...
    9. HART, J., BHUIYAN, A. A., NASER, J. (2018). Aerodynamics of burner jet in a tangentially-fired boiler: A CFD modelling and experiment. International Journal of Thermal Sciences,129, 238-253. Go to original source...
    10. MILIĆEVIĆ, A. et. al. (2020). Mathematical modelling and optimisation of lignite and wheat straw co-combustion in 350 MWe boiler furnace. Applied Energy, 260, 114206. Go to original source...
    11. QIN, M., LIU, D., WU, S., CAO, Q. (2017). Numerical Simulations on Flow Characteristics of Flue Gas in Furnace with Four-Wall Tangential Firing. Combustion Science and Technology, 189(12), 2135-2153. Go to original source...
    12. TIAN, D. et al. (2015). Influence of vertical burner tilt angle on the gas temperature deviation in a 700 MW low NOx tangentially fired pulverised-coal boiler. Fuel Processing Technology, 138, 616641-646628. Go to original source...
    13. LIU, Y., FAN, W., LI, Y. (2016). Numerical investigation of air-staged combustion emphasizing char gasification and gas temperature deviation in a large-scale, tangentially fired pulverized-coal boiler. Applied Energy, 177, 323-334. Go to original source...
    14. PARK, H. Y. (2013). Numerical and experimental investigations on the gas temperature deviation in a large scale, advanced low NOx, tangentially fired pulverized coal boiler. Fuel, 104, 641641-646646. Go to original source...
    15. LI, Z., QIAO, X., MIAO, Z. (2021). A novel burner arrangement scheme with annularly combined multiple airflows for wall-tangentially fired pulverized coal boiler. Energy, 222, 119912. Go to original source...

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