Bioreactor modeling and simulation
Summary
The course of Bioreactor modeling and simulation focuses on the principles of algorithmic design and analysis of biochemical reactors. The application of these designed reactors would be in the production line of the of pharmaceutical, biotech and chemical industries.
Content
• Introduction to the enzyme and microbial kinetics
• Modeling and simulation of bioreactors
- • Design of Batch reactors
- • Design of Continuous reactors
- • Design of Fed-batch reactors
• Application of chemical engineering design principles
- • Mass and energy balance
- • Mass transfer
- • Process control
Keywords
Bioreactor, enzymatic reactions, design and modeling, optimization
Learning Prerequisites
Required courses
Biochemical engineering
Introduction to chemical engineering
Important concepts to start the course
Modeling
Differential equations
Learning Outcomes
By the end of the course, the student must be able to:
- Realize the kinetic of enzymatic reactions
- Assess / Evaluate the tools and techniques for design of bioprocesses
- Apply the basic MATLAB programming tools for modeling of enzymatic/microbial phenomena
- Analyze the biochemical processes
- Visualize the results obtained through modeling
- Model a bioreactor
Transversal skills
- Access and evaluate appropriate sources of information.
- Continue to work through difficulties or initial failure to find optimal solutions.
- Write a scientific or technical report.
- Demonstrate the capacity for critical thinking
- Keep appropriate documentation for group meetings.
- Set objectives and design an action plan to reach those objectives.
Teaching methods
The course is given in a computer room. The students form groups of 3. The background theory is given in slide
presentation. Afterwards the students are assisted to solve the exercises of the project by using MATLAB. Special
workshops of relevant toolboxes of MATLAB might take place.
Expected student activities
Each group collaborates to effectively solve the exercises of the project and produce every 2nd week project reports
focusing on the background theory of design and analysis of biochemical reactors.
Assessment methods
There will be 5 project given throughout the semester each one containing 2 to 3 problems for implementing algorithmic
techniques and solving problems in MATLAB environment.
Grading will be based on the successfulness of completion of the problems of all the projects. A breakdown of the
grading is given as follows:
Exercises: 4/6
Code format, Clarity of presentation of results: 2/6
Bonus: +0.5/6
Resources
Bibliography
Biological Reaction Engineering: Dynamic Modeling Fundamentals with Simulation Examples, I. J. Dunn,
E. Heinzle, J. Ingham, and J. E. Prenosil, Ed. Wiley-Vch.
Biochemical Engineering Fundamentals, J. E. Bailey and D. F. Ollis Ed. McGraw-Hill Science.
Ressources en bibliothèque
- Biochemical engineering fundamentals / Bailey
- Biological reaction engineering : dynamic modelling fundamentals with simulation examples / Dunn
Moodle Link
Dans les plans d'études
- Semestre: Printemps
- Forme de l'examen: Pendant le semestre (session d'été)
- Matière examinée: Bioreactor modeling and simulation
- Cours: 1 Heure(s) hebdo x 14 semaines
- Projet: 3 Heure(s) hebdo x 14 semaines
- Type: obligatoire
- Semestre: Printemps
- Forme de l'examen: Pendant le semestre (session d'été)
- Matière examinée: Bioreactor modeling and simulation
- Cours: 1 Heure(s) hebdo x 14 semaines
- Projet: 3 Heure(s) hebdo x 14 semaines
- Type: optionnel
- Semestre: Printemps
- Forme de l'examen: Pendant le semestre (session d'été)
- Matière examinée: Bioreactor modeling and simulation
- Cours: 1 Heure(s) hebdo x 14 semaines
- Projet: 3 Heure(s) hebdo x 14 semaines
- Type: obligatoire
Semaine de référence
Lu | Ma | Me | Je | Ve | |
8-9 | |||||
9-10 | |||||
10-11 | |||||
11-12 | |||||
12-13 | |||||
13-14 | |||||
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15-16 | |||||
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19-20 | |||||
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21-22 |