Course detail
Metallurgy of Steel
FSI-9MEOAcad. year: 2023/2024
Further to the courses given under 'prerequisites' the student will acquire the necessary theoretical foundations for his/her own modelling of physical-chemical processes in the production of steel and in secondary metallurgy.
Language of instruction
Czech
Mode of study
Not applicable.
Guarantor
Entry knowledge
A good knowledge of the subject matter of the courses Metallurgy of steel, Theory of metallurgical processes, and Theory of foundry processes.
Rules for evaluation and completion of the course
Oral examination with preparation in writing.
The lecturer assigns to students independent work. Attendance at lecture is required.
The lecturer assigns to students independent work. Attendance at lecture is required.
Aims
The objective is to prepare the student for independent calculation work in the area of modelling the processes taking place in the production of steel and in secondary processing. Prediction of manufacturing processes.
Application of thermodynamic equilibria in calculations that are necessary in the production of steel and in secondary metallurgy. Exploitation of simple kinetic relations in the course of metallurgical reactions. In-depth knowledge of applying thermodynamic data from databases.
Application of thermodynamic equilibria in calculations that are necessary in the production of steel and in secondary metallurgy. Exploitation of simple kinetic relations in the course of metallurgical reactions. In-depth knowledge of applying thermodynamic data from databases.
Study aids
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
Hae-Geon-Lee: Chemical thermodynamics for metals and Material. Imperial College Press, 57 Shelton Str. London WC2H 9HE, Reprint 2001.
Internet http://ust.fme.vutbr.cz/slevarenstvi/opory/
Myslivec T.:Fyzikálně chemické základy ocelářství, SNTL Praha 1971.
Turgdogan E. T.: Fundamentals of Steelmaking. The Institute of Materials 1996, ISBN186125 004 5.
1. Šenberger,J.: Metalurgie oceli. (skripta VUT, FSI). 2. Myslivec T.:Fyzikálně chemické základy ocelářství, SNTL Praha 1971. 3. Hae-Geon-Lee: Chemical thermodynamics for metals and Material. Imperial College Press, 57 Shelton Str. London WC2H 9HE, Reprint 2001. 4. Turgdogan E. T.: Fundamentals of Steelmaking. The Institute of Materials 1996, ISBN186125 004 5.
Internet http://ust.fme.vutbr.cz/slevarenstvi/opory/
Myslivec T.:Fyzikálně chemické základy ocelářství, SNTL Praha 1971.
Turgdogan E. T.: Fundamentals of Steelmaking. The Institute of Materials 1996, ISBN186125 004 5.
1. Šenberger,J.: Metalurgie oceli. (skripta VUT, FSI). 2. Myslivec T.:Fyzikálně chemické základy ocelářství, SNTL Praha 1971. 3. Hae-Geon-Lee: Chemical thermodynamics for metals and Material. Imperial College Press, 57 Shelton Str. London WC2H 9HE, Reprint 2001. 4. Turgdogan E. T.: Fundamentals of Steelmaking. The Institute of Materials 1996, ISBN186125 004 5.
Recommended reading
[2] Myslivec,T.: Fyzikálně chemické základy ocelářství, SNTL Praha 1971. Bratislava 1985.
[2] Myslivec,T.: Fyzikálně chemické základy ocelářství, SNTL Praha 1971.
[3] Brdička, -Kalousek,M.-Schutz,A : Úvod do fyzikální chemie, SNTL Praha 1972.
[4] Moore,W. : Fyzikální chemie, SNTL Praha 1981.
[6] Barin,I.- Knacke,O.:Thermochemical properties of inorganic subsatnces, Spriger- Verlag Berlin 1973.
[7] Bůžek, Z.: Hutnické aktuality 28 (1988), č. 7.
Classification of course in study plans
- Programme D-MAT-P Doctoral 1 year of study, summer semester, recommended course
- Programme D-STG-P Doctoral 1 year of study, winter semester, recommended course
- Programme D-MAT-K Doctoral 1 year of study, summer semester, recommended course
- Programme D-STG-K Doctoral 1 year of study, winter semester, recommended course
Type of course unit
Lecture
20 hod., optionally
Teacher / Lecturer
Syllabus
1. Thermodynamics of solutions.
2. Partial molar state quantities.
3. Thermodynamic equilibria.
4. Interaction coefficients.
5. The Gibbs-Duhem equation.
6. Fundamentals of the kinetics of metallurgical reactions.
7. Iron solutions saturated with carbon.
8. Theoretical foundations of vacuum-treatment of steel.
9. Theoretical foundations of the production of high-alloy steels and cast irons.
10. Theoretical foundations of degasing and decarbonizing steel by Ar + O2 mixture.
2. Partial molar state quantities.
3. Thermodynamic equilibria.
4. Interaction coefficients.
5. The Gibbs-Duhem equation.
6. Fundamentals of the kinetics of metallurgical reactions.
7. Iron solutions saturated with carbon.
8. Theoretical foundations of vacuum-treatment of steel.
9. Theoretical foundations of the production of high-alloy steels and cast irons.
10. Theoretical foundations of degasing and decarbonizing steel by Ar + O2 mixture.