A saturated feedforward/cascade controller for passive continuous reacting systems using entropy production shaping

A saturated feedforward/cascade controller for passive continuous reacting systems using entropy production shaping

A control scheme is proposed for adiabatic continuous chemical reactors using thermodynamic properties. This control scheme is inspired by the general advantages of cascade control and Passivity-based Control, using the internal entropy production as a storage function, leading to a transparent phys...

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Bibliographic Details
Published in:European journal of control Vol. 49; pp. 53 - 61
Main Authors: Zárate-Navarro, Marco A., García-Sandoval, J. Paulo, Hudon, Nicolas
Format: Journal Article
Language:English
Published: Philadelphia Elsevier Ltd 01-09-2019
Elsevier Limited
Subjects:
Cascade control
Chemical reactors
Control systems
Control theory
Controllers
Dynamic stability
Dynamical systems
Energy
Entropy shaping
Feedforward control
Irreversible thermodynamics
Organic chemistry
Parameters
Partial differential equations
Passive systems
Physical properties
Process engineering
Process variables
Thermodynamic properties
Thermodynamics
Variables
Cascade control
Passive systems
Irreversible thermodynamics
Chemical reactors
Entropy shaping
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Description
Summary:A control scheme is proposed for adiabatic continuous chemical reactors using thermodynamic properties. This control scheme is inspired by the general advantages of cascade control and Passivity-based Control, using the internal entropy production as a storage function, leading to a transparent physical interpretation. The inner loop shapes the entropy production function (the potential that generates the dynamics) to guarantee stability, while the outer loop regulates process variables such as temperature, pressure, or conversion. The resulting control scheme is equivalent to a feedforward/PI control with control saturations, subject to the available potential and the bounds of the manipulated variable. The controller parameters are given by the physical properties of the system and only a single proportional parameter needs to be tuned to regulate a process variable to its desired value.
ISSN:0947-3580
1435-5671
DOI:10.1016/j.ejcon.2019.01.006