Author:

Keywords:

steam cracking furnaces, high-emissivity coatings, radiation, non-grey gas model, Science & Technology, Technology, Engineering, Environmental, Engineering, Chemical, Engineering, FINITE-VOLUME METHOD, HEAT-TRANSFER, FIRED FURNACES, ENCLOSURES, 0904 Chemical Engineering, 0905 Civil Engineering, 0907 Environmental Engineering, Chemical Engineering, 4004 Chemical engineering, 4011 Environmental engineering, 4016 Materials engineering

Abstract:

The efficiency of the application of high-emissivity coatings on the furnace walls in steam cracking technology can only be evaluated on the basis of a description of radiative heat transfer distinguishing between the frequency bands. To this end, a non-grey gas radiation model based on the exponential wide band model (EWBM) has been developed and applied in the context of three-dimensional CFD simulations of an industrial naphtha cracking furnace with side-wall radiation burners. Applying a high-emissivity coating on the furnace wall decreases the net outgoing radiation from the furnace wall in the absorption bands and increases the net outgoing radiation from the furnace wall in the clear windows. Since radiation that is emitted by the furnace wall and travels through the flue gas in the clear windows can reach the reactor tubes without partially being absorbed by the flue gas, contrary to radiation that is emitted by the furnace wall and travels through the flue gas in the absorption bands, the thermal efficiency of the furnace increases. It was found that application of a high-emissivity coating on the furnace walls improves the thermal efficiency of the furnace (∼1%), the naphtha conversion (∼1%) and the ethylene yield (∼0.5%). These differences are small but, considering the industrial importance and scale of the steam cracking process, significant. © 2007 Elsevier B.V. All rights reserved.