Aims
The main themes considered in this course are :
- the dynamics and stability of processes
- the PID regulator
- the feedforward control, the delay compensation and other more advanced control methods ;
- the control of batch processes
- the inferential control and the state observers.
Main themes
The content of this course deals with the control of linear time invariant systems in the context of chemical engineering processes.
Content and teaching methods
The content of this course deals with the control of linear time invariant systems in the context of chemical engineering processes. In particular the notions of dynamical models and feedback loop will be considered. The notion of operator (implicitly connected to Laplace transform) will be used to transform differential equations into algebraic equations in order to introduce the concept of transfer functions that will ease the analysis and synthesis of controllers and closed-loop systems. The course will mainly concentrate on PID (proportional-integral-derivative) controllers, with reference to the IMC (internal model control) approach which is largely used in process control. The course will also consider topics like time-delay compensation, feedforward actions, ratio control and cascade control, and is open to topics like inferential control and state observers. The course is based in particular on the notions of mass and energy balances and of unit operations, and it is illustrated by examples drawn from applications in the process industry.
Other information (prerequisite, evaluation (assessment methods), course materials recommended readings, ...)
Written support : notes
Reference book : Seborg D.E., T.F. Edgar and D.A. Mellichamp (2003). Process Dynamics and Control, 2nd edition, John Wiley, New York.
Evaluation : final exam (75%); laboratories and homeworks (25%)
Programmes in which this activity is taught
Other credits in programs
BIR22/2C
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Deuxième année du programme conduisant au grade de bio-ingénieur : Chimie et bio-industries (Ingénierie biomoléculaire et cellulaire)
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(5 credits)
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BRAS3DS
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Diplôme d'études spécialisées en brasserie
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Mandatory
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ELEC22
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Deuxième année du programme conduisant au grade d'ingénieur civil électricien
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(5 credits)
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ELEC23
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Troisième année du programme conduisant au grade d'ingénieur civil électricien
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(5 credits)
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ELME21/E
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Première année du programme conduisant au grade d'ingénieur civil électro-mécanicien (énergie)
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(5 credits)
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ELME22/E
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Deuxième année du programme conduisant au grade d'ingénieur civil électro-mécanicien (énergie)
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(5 credits)
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ELME23/E
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Troisième année du programme conduisant au grade d'ingénieur civil électro-mécanicien (énergie)
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(5 credits)
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Mandatory
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INCH21
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Première année du programme conduisant au grade d'ingénieur civil chimiste
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(5 credits)
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INCH22
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Deuxième année du programme conduisant au grade d'ingénieur civil chimiste
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(5 credits)
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Mandatory
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MAP22
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Deuxième année du programme conduisant au grade d'ingénieur civil en mathématiques appliquées
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(5 credits)
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MECA21
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Première année du programme conduisant au grade d'ingénieur civil mécanicien
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(5 credits)
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MECA22
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Deuxième année du programme conduisant au grade d'ingénieur civil mécanicien
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(5 credits)
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Mandatory
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