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Sensor Fusion for Intelligent Process Control
Donald A. Sheaffer
Lee A. Bertram
Alan J. Miller
William G. Houf
Philip J. Smith
Kevin Hill
John J. Connors
Robert J. Gallagher
Peter M. Walsh
Michael R. Stokes
Yu Jiao
David Hanekamp
William F. Haley
Craig Gowin
Arthur R. Farrar
Mark A. DeYoung
Craig Dodge
Bruce Binion
Padmabhushana R. Desam
Rajiv Tiwary
Richard W. Michael
Raymond M. Mayer
Mehran Arbab
Robert G. Hillaire
出版
United States. Department of Energy
, 2004
URL
http://books.google.com.hk/books?id=DsnvjwEACAAJ&hl=&source=gbs_api
註釋
An integrated system for the fusion of product and process sensors and controls for production of flat glass was envisioned, having as its objective the maximization of throughput and product quality subject to emission limits, furnace refractory wear, and other constraints. Although the project was prematurely terminated, stopping the work short of its goal, the tasks that were completed show the value of the approach and objectives. Though the demonstration was to have been done on a flat glass production line, the approach is applicable to control of production in the other sectors of the glass industry. Furthermore, the system architecture is also applicable in other industries utilizing processes in which product uniformity is determined by ability to control feed composition, mixing, heating and cooling, chemical reactions, and physical processes such as distillation, crystallization, drying, etc. The first phase of the project, with Visteon Automotive Systems as industrial partner, was focused on simulation and control of the glass annealing lehr. That work produced the analysis and computer code that provide the foundation for model-based control of annealing lehrs during steady state operation and through color and thickness changes. In the second phase of the work, with PPG Industries as the industrial partner, the emphasis was on control of temperature and combustion stoichiometry in the melting furnace, to provide a wider operating window, improve product yield, and increase energy efficiency. A program of experiments with the furnace, CFD modeling and simulation, flow measurements, and sensor fusion was undertaken to provide the experimental and theoretical basis for an integrated, model-based control system utilizing the new infrastructure installed at the demonstration site for the purpose. In spite of the fact that the project was terminated during the first year of the second phase of the work, the results of these first steps toward implementation of model-based control were sufficient to demonstrate the value of the approach to improving the productivity of glass manufacture.
