DocumentCode
2796222
Title
Improved generalized predictive control in polymerization process
Author
Yanfei, Ye ; Bailin, Wang ; Mingheng, Shao ; Yongqi, Zhang
Author_Institution
Coll. of Energy & Electr. Eng., Hohai Univ., Nanjing, China
fYear
2011
fDate
15-17 July 2011
Firstpage
1354
Lastpage
1357
Abstract
The polymerization process is the basis stage of PAN based carbon fiber production, and its temperature control affects directly the quality and yield of the last products. However, the polymerization process releases a lot of heat rapidly and it has the serious time delay character. These make it is very complex to control the polymerization process. The paper firstly analyzes the polymerization process model, gives its CARIMA parametric equation, provides the original data excited by the generalized binary noise (GBN) signal, and identify the model using the recursive least square algorithm with fading memory. Secondly, the paper introduces an improved generalized predictive control (GPC) method, which has stronger fault tolerance and robustness with little process overshooting. At last, a system is realized in the cascade frame based on the control layer and the monitoring layer. The former realizes the model identification and the recursive computation in the improved generalized predictive control, and sends the results to the latter, and the latter realizes PID with dead-zone control of the mixed water temperature control using the results of the main regulator. The practice shows that the polymerize temperature cascade system runs well and has evident effect with effective control.
Keywords
carbon fibres; chemical engineering; fault tolerance; least squares approximations; polymerisation; predictive control; process control; temperature control; three-term control; CARIMA parametric equation; GPC; PAN based carbon fiber production; PID; dead-zone control; fading memory; fault tolerance; generalized binary noise signal; generalized predictive control method; mixed water temperature control; model identification; polymerization process; polymerize temperature cascade system; recursive least square algorithm; time delay character; Equations; Mathematical model; Polymers; Process control; Temperature control; Temperature measurement; Viscosity; cascade control; generalized predictive control; identification; model; polymerization process;
fLanguage
English
Publisher
ieee
Conference_Titel
Mechanic Automation and Control Engineering (MACE), 2011 Second International Conference on
Conference_Location
Hohhot
Print_ISBN
978-1-4244-9436-1
Type
conf
DOI
10.1109/MACE.2011.5987195
Filename
5987195
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