www.ireng.org to even overpass the service properties of Coranit Al.
This new design combining both larger thickness and new quality is part of the Saint-Gobain High Performance Refractories’ strategy to reinforce its leading position and to make our Ceramic Cup a major contributor in hearth life extension and performance.
REFERENCES
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Technical Paper
This new design combining both larger thickness and further improved quality is part of the Saint-Gobain High Performance Refractories’ strategy to reinforce our leading position and to make the Saint-Gobain Ceramic Cup a major contributor in hearth life extension and performance.
flow and heat transfer in the hearth of a blast furnace during tapping process, Chemical engineering science, 60(16), pp 4485-4492.
14. Post, J.R., Peeters, T., Yang, Y., Reuter, M.A., (2003), “Hot metal flow in the blast furnace hearth: thermal and carbon dissolution effects on buoyancy, flow and refractory wear”, Proceedings of the 3rd International Conference on Computational Fluid Dynamics in the Minerals & Process Industries, eds. P.J. Witt and M.P. Schwarz, CSIRO Australia, 10-12 December, Melbourne, pp 433-440.
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19. Hong-Wei Guo, Bing-Ji Yan, Jian-Liang Zhang, He-Lan Liang and Yi-Li Liu, Influence of Hot Metal Flow State to the Hearth Flow Field during Blast Furnace Tapping, Research Journal of Applied Sciences, Engineering and Technology, 6(13): 2409-2414, 2013.
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21. Brulin, J. (2010), Modélisation thermomécanique d'un creuset de haut fourneau, Doctoral Thesis of Orleans University.
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24. Albert J. Dzermejko, The End of Carbonaceous Blast Furnace Hearth Working Linings?, AISTech Conference Proceedings, 2015.
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ENGINEER THE REFRACTORIES
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