Automatic load change system of cryogenic air separation process

Automatic load change system of cryogenic air separation process

► An automatic load change system of air separation process is developed. ► A two-layer framework integrated with SSO and NMPC is designed. ► Homotopy-based backtracking method is performed to overcome convergence problem. ► An operating trajectory LPV model is identified to represent nonlinear beha...

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Bibliographic Details
Published in:Separation and purification technology Vol. 81; no. 3; pp. 451 - 465
Main Authors: Xu, Zuhua, Zhao, Jun, Chen, Xi, Shao, Zhijiang, Qian, Jixin, Zhu, Lingyu, Zhou, Zhiyong, Qin, Haizhong
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 10-10-2011
Elsevier
Subjects:
air
Air separation
Applied sciences
Automatic load change
Chemical engineering
consumers (people)
Demand
energy
Exact sciences and technology
Homotopy-based backtracking
industrial applications
Marketing
Mathematical models
Nonlinear dynamics
Nonlinear model predictive control
nonlinear models
Nonlinearity
Operating trajectory LPV model
Optimization
oxygen
Predictive control
regression analysis
Steady-state optimization
Operating trajectory LPV model
Automatic load change
Nonlinear model predictive control
Homotopy-based backtracking
Steady-state optimization
Modeling
Steady state
Optimization
Design
Energy balance
Regression model
Homotopy
Non linear model
Cryogenics
Separation process
Nonlinearity
Predictive control
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Summary:► An automatic load change system of air separation process is developed. ► A two-layer framework integrated with SSO and NMPC is designed. ► Homotopy-based backtracking method is performed to overcome convergence problem. ► An operating trajectory LPV model is identified to represent nonlinear behavior. ► Oxygen release ratio and unit electric consumption are greatly reduced by ALC system. In this paper, an automatic load change (ALC) system of cryogenic air separation process is developed to automatically and rapidly respond to the changing product demand from customers. In this automatic load change system, a two-layer framework integrated with nonlinear steady-state optimization and nonlinear model predictive control is designed. Nonlinear steady-state optimization based on homotopy-based backtracking method is performed offline to obtain optimal operating points at various load demands. Nonlinear regression models between optimal operating point and load demand are fitted, which can be easily evaluated online to avoid computational effort and convergence problem. To overcome the pronounced nonlinearities caused by load change, an operating trajectory linear parameter varying (LPV) model is identified to represent the nonlinear dynamic behavior of air separation process. A nonlinear model predictive control (MPC) based on LPV model is designed to drive air separation process rapidly to the optimal operating point of target load demand. Under this framework, material and energy balances of air separation process is actively established during the load change, and load transition time can be shortened. Industrial application results show that oxygen release ratio and unit electric consumption of air separation process are reduced by the implementation of ALC system.
Bibliography:http://dx.doi.org/10.1016/j.seppur.2011.08.024
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2011.08.024