Numerical Study of Non-Gray Radiative Heat Transfer in a T-shaped Furnace
Subject Areas : optimization and simulationAmin Al Taha 1 , MohamadMehdi Keshtkar 2
1 - Department of Mechanical Engineering,
Kerman Branch, Islamic Azad University, Kerman, Iran
2 - Department of Mechanical Engineering,
Kerman Branch, Islamic Azad University, Kerman, Iran
Keywords:
Abstract :
[1] Sakami, M., Charette, A., Application of a Modifed Discrete Ordinates Method to Two-Dimensional Enclosures of Irregular Geometry, Journal of Quantitative Spectroscopy & Radiative Transfer, Vol. 64, 2000, pp. 275-298.
[2] Koo, H. M., Goutière, R. V., Le, V., and Song, T. H., Comparison of Three Discrete Ordinates Methods Applied to Two-Dimensional Curved Geometries, International Journal of Thermal Sciences, Vol. 42, 2003, pp. 343-359.
[3] Talukdar, P., Discrete Transfer Method with The Concept of Blocked-Off Region for Irregular Geometries, Journal of Quantitative Spectroscopy & Radiative Transfer, Vol. 98, 2006, pp. 238-248.
[4] Borjinia, M. N., Guedri, K., and Said, R., Modeling of Radiative Heat Transfer in 3d Complex Boiler with Non-Gray Sooting Media, Journal of Quantitative Spectroscopy & Radiative Transfer, Vol. 105, 2007, pp. 167–179.
[5] Han, S. H., Baek, S. W., and Kim, M. Y., Transient Radiative Heating Characteristics of Slabs in A Walking Beam Type Reheating Furnace, International Journal of Heat and Mass Transfer, Vol. 52, 2009, pp. 1005–1011.
[6] Jang, J. H., Lee, D. F., Kim M. Y., and Kim, H. G., Investigation of the Slab Heating Characteristics in A Reheating Furnace with The Formation and Growth of Scale On the Slab Surface, International Journal of Heat and Mass Transfer, Vol. 53, 2010, pp. 4326–4332.
[7] Keshtkar, M. M., Gandjalikhan Nassab, S. A., Theoretical Analysis of Porous Radiant Burners Under 2-D Radiation Field Using Discrete Ordinates Method, Journal of Quantitative Spectroscopy & Radiative Transfer, Vol. 110, 2009, pp. 1894-1907.
[8] Ansari, A. B., Gandjalikhan Nassab, S. A., Study of Laminar Forced Convection of Radiating Gas Over an Inclined Backward Facing Step Under Bleeding Condition Using the Blocked-Off Method, ASME, Journal of Heat Transfer, Vol. 133, 2011, pp. 72-83.
[9] Abbassi, M. A., Guedri, K., Borjini, M. N. Halouani, K., and Zeghmati, B., Modeling of Radiative Heat Transfer in 2D Complex Heat Recuperator of Biomass Pyrolysis Furnace: A Study of Baffles Shadow and Soot Volume Fraction Effects, International Journal of Physical, Nuclear Science and Engineering, Vol. 8, No. 2, 2014, pp. 119-129.
[10] Payan, S., Hosseini Sarvari, S. M., and Behzadmehr, A., Inverse Boundary Design Radiation Problem Within Combustion Enclosures with Absorbing-Emitting Non-Gray Media, Numerical Heat Transfer, Part A: Applications, Vol. 65, 2014, pp. 1114–1137.
[11] Payan, S., Farahmand, A., and Hosseini Sarvari, S. M., Inverse Boundary Design Radiation Problem with Radiative Equilibrium in Combustion Enclosures with PSO Algorithm, International Communications in Heat and Mass Transfer, Vol. 68, 2015, pp.150–157.
[12] Zeyghami, M., Rahman, M. M., Analysis of Combined Natural Convection and Radiation Heat Transfer Using a Similarity Solution, Energy Research Journal, Vol. 6, No. 2, 2015, pp. 64- 73.
[13] Nenad, D. J., Srdjan, V., Ivan, D., and Aleksandar, R., Monte Carlo Simulation for Radiative Transfer in a High-Pressure Industrial Gas Turbine Combustion Chamber, Journal of Thermal Science, Vol. 20, 2016, pp. 197- 206.
[14] Chishty, M. A., Bolla, M., Hawkes, E., Pei, Y., and Kook, S., Assessing the Importance of Radiative Heat Transfer for ECN Spray a Using the Transported PDF Method, International Journal of Fuels and Lubricants, Vol. 9, No. 1, 2016, pp. 100-107.
[15] Wang, C., Geb, W., and He, B., A Full-Spectrum K-Distribution Look-Up Table for Radiative Transfer in Nonhomogeneous Gaseous Media, Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 168, 2016, pp. 46-56.
[16] Keshtkar, M. M., Amiri, B., Numerical Simulation of Radiative-Conductive Heat Transfer in an Enclosure with an Isotherm Obstacle, Heat Transfer Engineering, Vol. 39, No.1, 2018, pp. 72–83.
[17] Ren, T., Modest, M. F., and Roy, S., Influence of the Gray Gases Number in the Weighted Sum of Gray Gases Model on the Radiative Heat Exchange Calculation Inside Pulverized Coal-Fired Furnaces, J. Eng. Gas Turbines Power, Vol. 140, No. 5, 2018, pp. 97- 108.
[18] Yang, X., Clements, A., Szuhánszki, J., Huang, X., Farias O., Lia, J., Gibbins, J., Liu, Z., Zheng, C., Ingham, D., and Ma, L., Prediction of the Radiative Heat Transfer in Small and Large Scale Oxy-Coal Furnaces, Applied Energy journal, Vol. 211, 2018, pp. 523- 537.
[19] Ge, L., Gong, K., Cang, Y., Luo, Y., Shi, X., and Wu, Y., Magnetically Tunable Multiband Near-Field Radiative Heat Transfer Between Two Graphene Sheets, Phys. Rev., Vol. 2, 2019, pp. 23- 37.
[20] Shiue, R., Gao, Y., Tan, C., Peng, C., Zheng, J., Efetov, D., Kim, Y., Hone J., and Englund, D., Thermal Radiation Control from Hot Graphene Electrons Coupled to A Photonic Crystal Nanocavity, Nature Communications, Vol. 10, 2019, pp. 45- 56.
[21] Yin, C., Rosendahl, L. A., New Weighted Sum of Gray Gases Model Applicable to Computational Fluid Dynamics (CFD) Modeling of Oxy−Fuel Combustion: Derivation, Validation, and Implementation, Energy Fuels, Vol. 24, No. 10, 2010, pp. 6275-6282.
[22] Henrion, L., Gross, M. C., Fernandez, S. F., Paul, C., Kazmouz, S., Sick V., and Haworth, D. C., Characterization of Radiative Heat Transfer in A Spark-Ignition Engine Through High-Speed Experiments and Simulations, Oil & Gas Science and Technology, Vol. 74, No. 1, 2019, pp. 61-73.
[23] Dombrovsky, A., Dembelea, S., Wend, J. X., and Sikic, I., Two-Step Method for Radiative Transfer Calculations in A Developing Pool Fire at The Initial Stage of Its Suppression by A Water Spray Leonid, International Journal of Heat and Mass Transfer, Vol. 127, Part B, 2018, pp. 717-726.
[24] Atashafrooz, M., Gandjalikhan Nassab, R., 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, 2015, pp. 717-726.
[25] Fathi, M., Hosseini, R., and Rahmani, M., Calculations of Non-Gray Gas Radiative Heat Transfer by Coupling the Discrete Ordinates Method with The Leckner Model in 3d Rectangular Enclosures, Heat and Mass Transfer, Vol. 52, No. 11, 2015, pp. 1-9.
[26] Chu, H., Ren, F., and Zheng, S., A Comprehensive Evaluation of the Non Gray Gas Thermal Radiation Using the Line-By-Line Model in One- And Two-Dimensional Enclosures, Applied Thermal Engineering, Vol. 124, 2017, pp. 74-86.
[27] Boutoub, A., Benticha, H., Non-Gray Radiation Analysis in Participating Media with the Finite Volume Method, Turkish Journal of Engineering and Environmental Sciences, Vol. 30, No. 3, 2006, pp. 183-194.
[28] Jozaalizadeh, T., Toghraie, D., Numerical Investigation Behavior of Reacting Flow for Flameless Oxidation Technology of Mild Combustion: Effect of Fluctuating Temperature of Inlet Co-Flow, Energy, Vol. 178, No. 3, 2019, pp. 530-537.
[29] Golestaneh, S. M., Toghraie, D., Separation of Particles from The Gas by Using of Cyclonic Separation in The Cyclotubes of Scrubber Installed in Gas Compressor Station, Powder Technology, Vol. 343, 2019, pp. 392-421.
[30] Dabiri, S., Khodabandeh, E., Poorfar, Khoeini A., Mashayekhi, R., Toghraie, D., and Abadian Zade, A., Parametric Investigation of Thermal Characteristic in Trapezoidal Cavity Receiver for A Linear Fresnel Solar Collector Concentrator, Energy, Vol. 153, 2018, pp. 17-26.
[31] Hemmat Esfe, M., Hajmohammad, H., Toghraie, D., Rostamian, H., Mahian O., and Wongwises, S., Multi-Objective Optimization of Nanofluid Flow in Double Tube Heat Exchangers for Applications in Energy Systems, Energy, Vol. 137, 2017, pp. 160-171.
[32] Naderi, M., Ahmadi, G., Zarringhalam, M., Akbari, O., and Khalili, E., Application of Water Reheating System for Waste Heat Recovery in Ng Pressure Reduction Stations, with Experimental Verification, Energy, Vol. 162, 2018, pp. 1183-1192.
[33] Ahmadi, G., Toghraie, D., and Akbari, O., Energy, Exergy and Environmental (3e) Analysis of The Existing Chp System in A Petrochemical Plant, Renewable and Sustainable Energy Reviews, Vol. 99, 2019, pp. 234-242.
[34] Ahmadi, G., Toghraie, D., and Akbari, O. A., Technical and Environmental Analysis of Repowering the Existing Chp System in A Petrochemical Plant: A Case Study, Energy, Vol. 159, No. 3, 2018, pp. 937-949.
[35] Modest, M. F., Radiative Heat Transfer, Second ed. 2003: Academic Press, 2003.
[36] Smith, T. F., Shen, Z. F., and Friedman, J. N., Evaluation of Coefficients for The Weighted Sum of Gray Gases Model, ASME Journal of Heat Transfer, Vol. 104, 1982, pp. 602-608.
[37] Fiveland, W. A., Discrete-Ordinates Solutions of the Radiativetransport Equation for Rectangular Enclosures, ASME, Journal of Heat Transfer, Vol. 106, 1984, pp. 699-706.
[38] Goutierea, V., Liub, F., and Charette, A., An Assessment of Real-Gas Modelling in 2d Enclosures, Journal of Quantitative Spectroscopy & Radiative Transfer, Vol. 64, 2000, pp. 299-326.
