Dissipativity-based analysis for plantwide chemical process systems

Author

Hioe, Denny ; Bao, Jie

Author_Institution

Sch. of Chem. Eng., Univ. of New South Wales, Sydney, NSW, Australia

fYear

2011

fDate

10-11 Nov. 2011

Firstpage

428

Lastpage

433

Abstract

Most modern chemical plants are complex system with multiple interconnected nonlinear process units, often with recycle and by-pass streams and energy integration. Interactions between process units often lead to plant-wide operability problems. In this work, a plantwide chemical process is viewed as a network of process units. These process units, namely process systems, possess some special nonlinearity properties. In this paper, a plantwide operability analysis is developed based on the concept of dissipativity. Using thermodynamics and geometric properties of process systems, a new construction of a storage function is proposed. Based on the above results, plantwide stability and stabilizability conditions are derived.

Keywords

chemical engineering; control nonlinearities; industrial plants; interconnected systems; stability; thermodynamics; chemical plant; complex system; dissipativity-based analysis; geometric properties; interconnected nonlinear process unit; nonlinearity property; plantwide chemical process system; plantwide operability analysis; plantwide stability; thermodynamics; Availability; Linear matrix inequalities; Nonlinear systems; Process control; Silicon; Stability analysis; Thermodynamics;

fLanguage

English

Publisher

ieee

Conference_Titel

Australian Control Conference (AUCC), 2011

Conference_Location

Melbourne, VIC

Print_ISBN

978-1-4244-9245-9

Type

conf

Filename

6114316