TY - JOUR

T1 - Direct flame impingement heating for rapid thermal materials processing

AU - Malikov, G. K.

AU - Lobanov, D. L.

AU - Malikov, K. Y.

AU - Lisienko, V.

AU - Viskanta, R.

AU - Fedorov, A. G.

PY - 2001/5

Y1 - 2001/5

N2 - Combined experimental and theoretical investigations have been carried out to study heat/mass transfer and combustion in the direct flame impingement (DFI) furnace for rapid heating of metals in materials processing. A large-size industrial DFI furnace, equipped with a multiflame combustion system, has been instrumented for performing detailed fluid dynamics and heat transfer measurements. The mean and local pressure, fuel mass fractions, temperatures and convective/radiative heat fluxes have been measured and are reported for high jet velocities (up to 230 m/s) and firing rates. In the case of natural gas–air firing, the convective heat fluxes as high as 500 kW/m2 were recorded with relatively ‘cold’ refractory wall temperatures (<1400 K). The combustion gas temperature varied between 1500 and 1800 K. A simplified two-dimensional theoretical model was developed to analyze gas flow, flame jet combustion and heat/mass transfer in the DFI furnace. The model developed has been validated against the experimental data and was used to obtain a fundamental understanding of the physical processes taking place in the furnace. In addition, the model has been used as a tool to optimize design and operation of the DFI furnace.

AB - Combined experimental and theoretical investigations have been carried out to study heat/mass transfer and combustion in the direct flame impingement (DFI) furnace for rapid heating of metals in materials processing. A large-size industrial DFI furnace, equipped with a multiflame combustion system, has been instrumented for performing detailed fluid dynamics and heat transfer measurements. The mean and local pressure, fuel mass fractions, temperatures and convective/radiative heat fluxes have been measured and are reported for high jet velocities (up to 230 m/s) and firing rates. In the case of natural gas–air firing, the convective heat fluxes as high as 500 kW/m2 were recorded with relatively ‘cold’ refractory wall temperatures (<1400 K). The combustion gas temperature varied between 1500 and 1800 K. A simplified two-dimensional theoretical model was developed to analyze gas flow, flame jet combustion and heat/mass transfer in the DFI furnace. The model developed has been validated against the experimental data and was used to obtain a fundamental understanding of the physical processes taking place in the furnace. In addition, the model has been used as a tool to optimize design and operation of the DFI furnace.

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UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=0035916807

U2 - 10.1016/S0017-9310(00)00204-0

DO - 10.1016/S0017-9310(00)00204-0

M3 - Article

VL - 44

SP - 1751

EP - 1758

JO - International Journal of Heat and Mass Transfer

JF - International Journal of Heat and Mass Transfer

SN - 0017-9310

IS - 9

ER -