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Application of FactSage thermodynamic modeling of recycled slags (Al2O3–CaO–FeO–Fe2O3–SiO2–PbO–ZnO) in the treatment of wastes from end-of-life-vehicles

  • E. Jak , P. Hayes , C. W. Bale and S. A. Decterov
Published/Copyright: May 23, 2013
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 98 Issue 9

Abstract

The FactSage thermochemical software and databases calculates complex, multi-component, multi-phase equilibria involving simultaneously slag, metal, ceramic, and gas phases, over wide ranges of temperature, oxygen potential and pressure. The databases are automatically accessed by the software and the outputs of the Gibbs free energy minimization calculations can be presented in ways that are convenient to engineering practice, and as functions of key process variables.

The new thermodynamic databases for slag and solid oxide phases in the Al2O3 – CaO – FeO – Fe2O3 – SiO2 – PbO – ZnO system have been developed by critical evaluation/optimization of all available phase equilibrium and thermodynamic data. By means of the optimization process, model parameters are found which reproduce all thermodynamic and phase equilibrium data within experimental error limits. Furthermore, the models permit extrapolation into regions of temperature and composition where data are not available.

Phase equilibrium calculations have been undertaken, that are of interest in the thermal treatment of Automobile Shredder Residue (ASR) in the Al2O3 – CaO – FeO – Fe2O3 – SiO2 – PbO – ZnO system. This 7-component system represents only the major components of ASR. There are at least a dozen other important components in ASR not to mention the organic matter. The operating conditions deviate from thermodynamic equilibrium and the oxygen potential during the treatment of wastes is not well established. Consequently, the calculated diagrams are intended only to give an idea to industrial engineers about the trends in the liquidus temperature, extent of crystallization and partial pressures of volatile components as functions of temperature, composition and oxygen potential. These diagrams may also help to identify the process variables that are most important for industrial practice significantly reducing the amount of experimental work that has to be done to optimize the operations.

Keywords: Thermodynamics; Phase diagrams; Databases; Slags; Recycling
* Correspondence address, Dr. Sergei A. Decterov, Center for Research in Computational Thermochemistry, Department of Chemical Engineering, École Polytechnique de Montréal, C.P. 6079, succ. Centre-ville, Montréal (Québec) Canada, H3C 2A7, Tel.: +514 340 4711 ext. 5796, Fax: +514 340 5840, E-mail: .

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Received: 2007-4-10
Accepted: 2007-7-3
Published Online: 2013-05-23
Published in Print: 2007-09-01

© 2007, Carl Hanser Verlag, München

Articles in the same Issue

  1. Contents
  2. Contents
  3. Editorial
  4. Computational Thermochemistry
  5. Gunnar Eriksson 65 years
  6. Basic
  7. Vegard's law: a fundamental relation or an approximation?
  8. Is it a compound or cluster energy formalism?
  9. Post-optimization elimination of inverted miscibility gaps
  10. Thermodynamic evaluation of the Au–Sn system
  11. Applications of thermodynamic calculations to Mg alloy design: Mg–Sn based alloy development
  12. Thermodynamic modeling of the CoO–SiO2 and CoO–FeO–Fe2O3–SiO2 systems
  13. Scheil–Gulliver simulation with partial redistribution of fast diffusers and simultaneous solid–solid phase transformations
  14. Analysis of X-ray extinction due to homogeneously distributed dislocations – Bragg case
  15. Applied
  16. Thermodynamic modelling in the ZrO2–La2O3–Y2O3–Al2O3 system
  17. Thermodynamic optimisation of the FeO–Fe2O3–SiO2 (Fe–O–Si) system with FactSage
  18. Reassessment of the Al–Mn system and a thermodynamic description of the Al–Mg–Mn system
  19. Application of FactSage thermodynamic modeling of recycled slags (Al2O3–CaO–FeO–Fe2O3–SiO2–PbO–ZnO) in the treatment of wastes from end-of-life-vehicles
  20. Bio-inspired syntheses of ZnO-protein composites
  21. Preparation and characterization of cobalt–bismuth nano- and micro-particles
  22. Strain rate dependency on deformation texture for pure polycrystalline tantalum
  23. Notifications
  24. DGM News
https://doi.org/10.3139/146.101546
Keywords for this article
Thermodynamics; Phase diagrams; Databases; Slags; Recycling

Articles in the same Issue

  1. Contents
  2. Contents
  3. Editorial
  4. Computational Thermochemistry
  5. Gunnar Eriksson 65 years
  6. Basic
  7. Vegard's law: a fundamental relation or an approximation?
  8. Is it a compound or cluster energy formalism?
  9. Post-optimization elimination of inverted miscibility gaps
  10. Thermodynamic evaluation of the Au–Sn system
  11. Applications of thermodynamic calculations to Mg alloy design: Mg–Sn based alloy development
  12. Thermodynamic modeling of the CoO–SiO2 and CoO–FeO–Fe2O3–SiO2 systems
  13. Scheil–Gulliver simulation with partial redistribution of fast diffusers and simultaneous solid–solid phase transformations
  14. Analysis of X-ray extinction due to homogeneously distributed dislocations – Bragg case
  15. Applied
  16. Thermodynamic modelling in the ZrO2–La2O3–Y2O3–Al2O3 system
  17. Thermodynamic optimisation of the FeO–Fe2O3–SiO2 (Fe–O–Si) system with FactSage
  18. Reassessment of the Al–Mn system and a thermodynamic description of the Al–Mg–Mn system
  19. Application of FactSage thermodynamic modeling of recycled slags (Al2O3–CaO–FeO–Fe2O3–SiO2–PbO–ZnO) in the treatment of wastes from end-of-life-vehicles
  20. Bio-inspired syntheses of ZnO-protein composites
  21. Preparation and characterization of cobalt–bismuth nano- and micro-particles
  22. Strain rate dependency on deformation texture for pure polycrystalline tantalum
  23. Notifications
  24. DGM News
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