Model reduction and control for networked systems with high energy throughput

Author

Baldea, Michael ; Daoutidis, Prodromos

Author_Institution

Dept. of Chem. Eng. & Mater. Sci., Minnesota Univ., Minneapolis, MN

fYear

2006

fDate

14-16 June 2006

Abstract

The present paper analyzes the energy dynamics of networked process units. In such systems, the material recycle streams interconnecting the units take on the additional role of energy carriers. In the presence of large energy input and output flows, the process networks considered are shown to exhibit a dynamic behavior with multiple time scales, with the variables in the energy balance evolving over a short time horizon, and the variables in the material balance exhibiting both fast and slow transients. A singular perturbation analysis is employed for the derivation of reduced order models for the fast and slow dynamics, and a controller design framework that rationally accounts for this time scale separation is subsequently proposed. Finally, an illustrative example and numerical simulation results are presented

Keywords

chemical reactors; control system synthesis; interconnected systems; perturbation techniques; reduced order systems; controller design; dynamic behavior; energy balance; energy carriers; energy dynamics; high energy throughput; model reduction; networked process units; networked systems; reduced order models; singular perturbation analysis; slow transients; Chemical processes; Control system synthesis; Costs; Distributed control; Feedback; Numerical simulation; Power generation economics; Recycling; Reduced order systems; Throughput;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference, 2006

Conference_Location

Minneapolis, MN

Print_ISBN

1-4244-0209-3

Electronic_ISBN

1-4244-0209-3

Type

conf

DOI

10.1109/ACC.2006.1657684

Filename

1657684