Modeling of Carburization and Thermal Stress Analysis for Ethylene Cracking Furnace Tube

Lu Yang Geng; Jian Ming Gong; Xiao Yan Qin; Li Min Shen

doi:10.4028/www.scientific.net/MSF.704-705.1136

Paper Titles

Simulation of the Young’s Modulus Anisotropy in CVD Diamond Film
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Effect of Bell-Type Annealing Process on Properties of SPCC Cold-Rolled Steel Sheet
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Thermal Simulation Study of 900MPa Grade High-Strength Low Alloy Steel in Welding Procedures
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Surface Finishing for Al₂O₃ Ceramics
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Modeling of Carburization and Thermal Stress Analysis for Ethylene Cracking Furnace Tube
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Analysis of Unit and Binary Diffusion in Glow Plasma Surface Alloying Process
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Research on W-Mo-Y Multi-Elements Co-Diffusion Treatment and Plasma Nitriding
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Research on Corrosion Resistance of Titanizing and Nitriding on Carbon Steel in H₂SO₄Solution
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Hot Rolling of FeSi Steels – Effects by Hot Rolling in the Two Phase Region
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HomeMaterials Science ForumMaterials Science Forum Vols. 704-705Modeling of Carburization and Thermal Stress...

Modeling of Carburization and Thermal Stress Analysis for Ethylene Cracking Furnace Tube

Abstract:

The ethylene cracking furnace tube is one of the most important components of an ethylene cracking furnace. Carburization of furnace tube is one of the most important causes which lead the tube to fail. In this paper, the model that describes diffusion of carbon and the precipitation of carbides was established based on Fick’ law and equilibrium constant method. The finite difference method was adopted to simulate the distribution of carbon concentration. By applying the model, the distribution of carbon concentration along thickness in HP-Nb tubes was predicted for the different service times. According to the temperature distribution of furnace tube, obtained by the analysis of heat transfer, the thermal stresses of the furnace tube with various carburization extents were analyzed by using the finite element code ABAQUS for the actual heating process of an ethylene cracking furnace. The analysis results show that the maximum circumferential thermal stress exists near the inner wall of the carburized tube, which usually causes cracking of the carburized tube along the longitudinal direction.