Abstract
To integrate measurements of eco-efficiency with control loop configuration has become an important topic since all industrial processes/plants are requested to increase their eco-efficiency. The exergy eco-efficiency factor, a new measure of eco-efficiency for control loop configuration, has been developed recently [1]. The exergy eco-efficiency factor is based on the thermodynamic concept of exergy, which can be used to analyze a process in terms of its efficiency. The combination of the relative gain array (RGA), NI, CN, dynamic RGA, and the exergy eco-efficiency factor will help guide the process designer to find the optimal control design with low operating cost/eco-efficiency. In this paper, we validate the proposed exergy eco-efficiency factor for processes with recycles which are very common industrially.
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M. T. Munir, W. Yu and B. R. Young, Plant-wide control: Eco-efficiency and control loop configuration, ISA Transactions, 52(1), 162 (2013).
D. E. Seborg, T. F. Edgar and D. A. Mellichamp, Process dynamics and control, New York: John Wiley & Sons (1989).
W.Y. Svrcek, D. P. Mahoney and B.R. Young, A real-time approach to process control, Chichester: John Wiley & Sons Ltd. (2006).
D. L. Westphalen, B. R. Young and W.Y. Svrcek, Ind. Eng. Chem. Res., 42(20), 4659 (2003).
M.-J. He and W.-J. Cai, Ind. Eng. Chem. Res., 43(22), 7057 (2004).
T. J. McAvoy, Y. Arkun, R. Chen, D. Robinson and P. D. Schnelle, Control Eng. Practice, 11(8), 907 (2003).
Q. Xiong, W.-J. Cai and M.-J. He, J. Process Control, 15(7), 741 (2005).
S. Vasudevan and G. P. Rangaiah, Ind. Eng. Chem. Res., 49(19), 9209 (2010).
T. Larsson and S. Skogestad, Modeling, Identification and Control, 21(4), 209 (2000).
J. Szargut, D. R. Morris and F. R. Steward, Exergy analysis of thermal, chemical, and metallurgical processes, New York: Hemisphere (1988).
J.M. Montelongo-Luna, W.Y. Svrcek and B.R. Young, Asia-Pacific J. Chem. Eng., 2(5), 431 (2007).
T. Muangnoi, W. Asvapoositkul and S. Wongwises, Appl. Therm. Eng., 27(5–6), 910 (2007).
M. J. Moran and E. Sciubba, J. Eng. Gas Turbines Power, 116(2), 285 (1994).
M. A. Rosen and I. Dincer, Int. J. Energy Res., 21, 643 (1997).
M. A. Rosen and I. Dincer, Int. J. Energy Res., 23, 1153 (1999).
M. A. Rosen and I. Dincer, Exergy, An Int. J., 1(1), 3 (2001).
I. Dincer, Energy Policy, 30(2), 137 (2002).
I. Dincer and M. A. Rosen, Exergy: Energy, environment and sustainable development, Amsterdam: Elsevier (2007).
I. Dincer, M. M. Hussain and I. Al-Zaharnah, Energy Policy, 32(14), 1615 (2004).
W. L. Luyben, B. D. Tyreus and M. L. Luyben., Plantwide process control, New York: McGraw-Hill (1998).
M. T. Munir, W. Yu and B. R. Young, Determination of Plant-wide Control Loop Configuration and Eco-Efficiency, G. P. Rangaiah and V. Kariwala (Eds.), in Plantwide Control: Recent Developments and Applications, John Wiley & Sons, ISBN:9780470980149 (2012).
J.M. Montelongo-Luna, W.Y. Svrcek and B. R. Young, The Relative Exergy Array — A tool for integrated process design and control in Chemeca 20092009: Perth, Australia.
J.M. Montelongo-Luna, W.Y. Svrcek and B. R. Young, The Canadian J. Chem. Eng., 89(3), 545 (2010).
M. T. Munir, W. Yu and B. R. Young, Control loop configuration and eco-efficiency, in FOCAPO/CPC-VIII2012: Savannah, Georgia, USA.
M.T. Munir, J. J. Chen and B. R. Young, A computer program to calculate the stream exergy using the visual basic graphical interface, in Chemeca2010: Adelaide, Australia.
M.T. Munir, W. Yu and B. R. Young, Chem. Eng. Res. Design, 90(1), 110 (2012).
A. Papadourakis, M. F. Doherty and J.M. Douglas, Ind. Eng. Chem. Res., 26(6), 1259 (1987).
E. Bristol, Automatic Control, IEEE Transactions on, 11(1), 133 (1966).
S. Skogestad, P. Lundström and E.W. Jacobsen, AIChE J., 36(5), 753 (1990).
M. F. Witcher and T. J. McAvoy, ISA Trans., l6(3), 35 (1977).
A. Fatehi and A. Shariati, Automatic pairing of MIMO plants using normalized RGA, in Mediterranean conference on control and automation2007: Athens Greece.
A. Niederlinski, Automatica, 7(6), 691 (1971).
Z.-X. Zhu and A. Jutan, Chem. Eng. Communications, 121(1), 235 (1993).
T. J. McAvoy, Interaction analysis: Principles and applications. Research Triangle Park, NC: Instrument Society of America (1983).
B. A. Ogunnaike and W. H. Ray, Process dynamics, modelling and control, Oxford University Press (1994).
J. Goldberg and M.C. Potter, Differential equations a systems approach, New Jersey: Prentice-Hall (1998).
K. G. Denbigh, Chem. Eng. Sci., 6(1), 1 (1956).
T. J. Kotas, The exergy method of thermal plant analysis, London: Butterworths. Medium: X; Size: Pages: 344 (1985).
J. M. Smith, H.C.V. Ness and M. M. Abbott, Introduction to chemical engineering thermodynamics, New York: McGraw-Hill (2005).
R. Smith, Chemical process design and integration, Chichester, England: John Wiley & Sons, Ltd. (2005).
A. P. Hinderink, F. P. J. M. Kerkhof, A. B. K. Lie, J. De Swaan Arons and H. J. Van Der Kooi, Chem. Eng. Sci., 51(20), 4693 (1996).
J. Szargut, D. R. Morris and F. R. Steward, Energy analysis of thermal, chemical, and metallurgical processes, Medium: X; Size: Pages: 332 (1988).
W. D. Seider, J. D. Seader and D. R. Lewin., Product and process design principles: Synthesis, analysis, and evaluation, 2nd Ed., New York: John Wiley (2004).
J.M. Montelongo-Luna, J.M., Process design and control for ecoefficiency, in Chemical and Petroleum Engineering2010, University of Calgary: Calgary, Alberta.
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Munir, M.T., Yu, W. & Young, B.P. Eco-efficiency and control loop configuration for recycle systems. Korean J. Chem. Eng. 30, 997–1007 (2013). https://doi.org/10.1007/s11814-013-0005-z
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DOI: https://doi.org/10.1007/s11814-013-0005-z