SubjectsSubjects(version: 965)
Course, academic year 2019/2020
  
Mathematical modeling of processes in chemical engineering - M409013
Title: Modelování procesů v chemickém inženýrství
Guaranteed by: Department of Chemical Engineering (409)
Faculty: Faculty of Chemical Engineering
Actual: from 2019
Semester: winter
Points: winter s.:5
E-Credits: winter s.:5
Examination process: winter s.:
Hours per week, examination: winter s.:2/2, C+Ex [HT]
Capacity: 30 / 30 (unknown)
Min. number of students: unlimited
State of the course: taught
Language: Czech
Teaching methods: full-time
Level:  
Note: course can be enrolled in outside the study plan
enabled for web enrollment
Guarantor: Kosek Juraj prof. Dr. Ing.
Grof Zdeněk doc. Ing. Ph.D.
Interchangeability : AM409013, N409064
Is interchangeable with: AM409013
Examination dates   Schedule   
This subject contains the following additional online materials
Annotation -
The subject is oriented to develop practical skills of students in the formulation of model equations of various chemical-engineering problems, their arrangement in the form suitable for the solution by equation-oriented program and acquirement of practical skills with simulations. Program MATLAB is selected as the basic tool for the modeling and alternative freely-available programs working with the same syntax of model equations are mentioned.
Last update: Hladíková Jana (16.01.2018)
Literature -

R: Bequette, B.W.: Process Dynamics. Modeling, Analysis, and Simulation, Prentice Hall PTR, N.J., 1998

A: Burianec Z.: Analýza dynamických procesů, Učební texty VŠCHT , Praha, 1979

A: Ingham, J., Dunn, I.J., et al.:Chemical Engineering Dynamics, VCH, Weinheim, 1994

A: Hangos, K.M., Cameron, I.T.: Process Modelling and Model Analysis, Academic Press, N.Y., 2001

Last update: Hladíková Jana (16.01.2018)
Teaching methods -

Lectures two hours a week.

Practical seminars two hours a week.

Last update: Hladíková Jana (16.01.2018)
Requirements to the exam -

Two written tests on computers during the course.

Oral exam with two questions.

Last update: Hladíková Jana (16.01.2018)
Syllabus -

1. Model and modeling, classification of models.

2. Types of problems described by algebraic equations. Methods for phase-equilibria calculations.

3. Transformation of balance bilinear equation into linear equations. Sequential and global solution of balance problems.

4. Flash destillation with enthalpy balance for multi-component system.

5. Systems of ordinary differential equations. Case studies of reaction kinetics in the batch reactor.

6. Models with enthalpy balances. PID controller of temperature and its incorporation into model of stirred reactor.

7. Differential-algebraic equations and their classification. Index and consistent initial conditions.

8. Semi-batch reactor with non-constant density of liquid phase. Transformation into linear-implicit form.

9. Batch rectification of multicomponent mixture. Model equations and simplifying assumptions.

10. Finite Volume Method for spatially distributed problems. Application to reaction-diffusion problem in spherical particle.

11. Application of Finite Volume Method on the problem of meat can heating/sterlization and on heat exchanger with loop.

12. Axial dispersion and description of adsorption column by the Finite Volume Method and kinetics of mass transfer.

13. Boundary value problem for ordinary differential equations. Case problem of Stefan tube. Shooting method.

14. Convection-dispersion problems. Tubular reactor with axial dispersion. Differential approximation of "up-wind" type.

Last update: Hladíková Jana (16.01.2018)
Learning resources -

Examples of various problems arranged for MATLAB are provided at seminars.

Last update: Hladíková Jana (16.01.2018)
Learning outcomes -

Students will acquire theoretical and practical skills for:

1. Writing of model equations for a broad class of chemical-engineering problems.

2. Processing of model equations by various methods, for example, by the finite volume method.

3. Arrangement of equations in the form suitable for equation-oriented simulators.

4. Simulation and vizualization of obtained results.

Last update: Hladíková Jana (16.01.2018)
Registration requirements -

Chemical Engineering I (or equivalent)

Last update: Hladíková Jana (16.01.2018)
Teaching methods
Activity Credits Hours
Účast na přednáškách 1 28
Příprava na přednášky, semináře, laboratoře, exkurzi nebo praxi 1.5 42
Příprava na zkoušku a její absolvování 1.5 42
Účast na seminářích 1 28
5 / 5 140 / 140
Coursework assessment
Form Significance
Continuous assessment of study performance and course -credit tests 50
Oral examination 50

 
VŠCHT Praha