22OHT33 - Process Modeling and Simulation
| Course specification | ||||
|---|---|---|---|---|
| Course title | Process Modeling and Simulation | |||
| Acronym | 22OHT33 | |||
| Study programme | ||||
| Module | ||||
| Lecturer (for classes) | ||||
| Lecturer/Associate (for practice) | ||||
| Lecturer/Associate (for OTC) | ||||
| ESPB | 5.0 | Status | ||
| Condition | Differential Equations, Thermodynamics, Introduction to Chemical Engineering, Programming, Physical Chemistry I, Fluid Mechanics | Облик условљености | ||
| The goal | The course goals are to acquire knowledge of mathematical modeling and to integrate fundamental knowledge of unit operations and reaction engineering. The theoretical basics of the subject are studied through examples of processes and devices that are essential for chemical engineering. These examples are used to illustrate different approaches and scales in process modeling. Students are referred to advanced computational methods and are familiarized with software packages for modeling and simulation. | |||
| The outcome | After completing and passing the exam, students will be able to: 1. Set up simple mathematical models of basic processes and equipment in chemical engineering. 2. Select a method and software package for deploying and solving a model. 3. Recognize and understand applied modeling approach and level of detail of a mathematical description of an existing complex model of chemical engineering system. | |||
| Contents | ||||
| Contents of lectures | 1. The purpose and objectives of the mathematical modeling for chemical engineering, classification of mathematical models, approaches to modeling; 2. Empirical approach to modeling of chemical engineering systems; 3. Fundamental approach - levels of mathematical description, microscopic - mechanisms of chemical reaction kinetics; mesoscopic - description of flow at vortex level, transport phenomena at particle level; macroscopic - flow regimes and phases, unit, process, plant; megascopic - systems integration, dispersion of pollutants and impact on the environment; 4. Dynamic modeling and simulations, models of inherently dynamical processes; 5. Stochastic modeling approach and its application to chemical engineering systems; 6. Population balance approach and nonideal flow models. | |||
| Contents of exercises | The practical classes are conducted in the computer lab, where students set up and solve simple models of chemical engineering systems. Examples are directly connected with the theory, and the models are solved using programming languages and packages. In the examples parameters and operating conditions are varied, so that students perceive possibilities and the roles of computer simulations. Students also learn the basic functions and capabilities of the process simulators and CFD simulators through several simple examples. | |||
| Literature | ||||
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| Number of hours per week during the semester/trimester/year | ||||
| Lectures | Exercises | OTC | Study and Research | Other classes |
| 2 | 2 | |||
| Methods of teaching | Lectures with examples, practical classes in the computer laboratory, consultations | |||
| Knowledge score (maximum points 100) | ||||
| Pre obligations | Points | Final exam | Points | |
| Activites during lectures | Test paper | 40 | ||
| Practical lessons | Oral examination | |||
| Projects | ||||
| Colloquia | 60 | |||
| Seminars | ||||