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Clean Technologies and Environmental Policy
Erschienen in: Clean Technologies and Environmental Policy 4/2013

01.08.2013 | Original Paper

Multi-objective optimization of steam power plants for sustainable generation of electricity

verfasst von: César G. Gutiérrez-Arriaga, Medardo Serna-González, José María Ponce-Ortega, Mahmoud M. El-Halwagi

Erschienen in: Clean Technologies and Environmental Policy | Ausgabe 4/2013

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Abstract

A unified framework that combines process simulation and multi-objective optimization is presented to simultaneously maximize the annual profit, while minimizing environmental impact (i.e., greenhouse gas emissions) of steam power plants with fixed flowsheet structures. The proposed methodology includes the selection of suitable primary energy sources (i.e., fossil fuels, biomass, biofuels, and solar energy) for sustainable electricity generation. For solving the problem of optimal selection of energy sources, a linear model is developed and included within a highly nonlinear simulation model for the parameter optimization of steam power plants that is solved by using genetic algorithms. This approach is robust and avoids making discrete decisions. Life cycle assessment technique is used to quantify the greenhouse gas emissions resulting from different combinations of energy sources and operating conditions of the power plants. The thermodynamic properties for liquid water and steam are calculated rigorously using the IAPWS-IF 97 formulation. An example problem of an advanced regenerative-reheat steam power plant is presented to illustrate the proposed method, which provides the Pareto optimal solutions, the types and amounts of primary energy sources as well as the optimal values of the operating conditions of the plant that simultaneously maximize the profit while minimizing environmental impact.
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Literatur
Al-Azri N, Al-Thibaiti M, El-Halwagi MM (2009) An algorithmic approach to the optimization of process cogeneration. Clean Technol Environ Policy 11:329–338CrossRef
Azapagic A, Clift R (1999) Application of life cycle assessment to process optimization. Comput Chem Eng 23:1509–1526CrossRef
Bamufleh HS, Ponce-Ortega JM, El-Halwagi MM (2012) Multi-objective optimization of process cogeneration systems with economic, environmental, and social tradeoffs. Clean Technol Environ Policy. doi:10.​1007/​s10098-012-0497-y
Bejan A, Tsatsaronis G, Moran MJ (1996) Thermal design and optimization. Wiley-Interscience, New York
Brunet R, Kumar KS, Guillen-Gosalbez G, Jimenez L (2011) Integrating process simulation, multi-objective optimization and LCA for the development of sustainable processes: application to biotechnological plants. Comput Aided Chem Eng 29:1271–1275CrossRef
Bruno JC, Fernandez F, Castells F, Grossmann IE (1998) A rigorous MINLP model for the optimal synthesis and operation of utility plants. Chem Eng Res Des 76:246–258CrossRef
Cengel YA, Boles MA (1994) Thermodynamics: an engineering approach. McGraw-Hill Higher Education, New York
Chouinard-Dussault P, Bradt L, Ponce-Ortega JM, El-Halwagi MM (2010) Incorporation of process integration into life cycle analysis for the production of biofuels. Clean Technol Environ Policy 13:673–685CrossRef
Ciric AR, Huchette SG (1993) Multiobjective optimization approach to sensitivity analysis: waste treatment costs in discrete process synthesis and optimization problems. Ind Eng Chem Res 32:2636–2646CrossRef
Cristóbal J, Guillén-Gosálbez G, Jiménez L, Irabien A (2011) Multi-objective optimization of the electricity production from coal burning. Comput Aided Chem Eng 29:1814–1818CrossRef
Dantus MM, High KA (1999) Evaluation of waste minimization alternatives under uncertainty: a multiobjective optimization approach. Comput Chem Eng 23:1493–1508CrossRef
Diwekar UM (2003) Introduction to applied optimization. Kluwer Academic Publishers, DordrechtCrossRef
El-Halwagi MM (2012) Sustainable design through process integration: fundamentals and application to industrial pollution prevention, resource conservation, and profitability enhancement. Butterworth-Heinemann, London
Eliceche AM, Corvalán SM, Martinez P (2007) Environmental life cycle impact as a tool for process optimization of a utility plant. Comput Chem Eng 31:648–656CrossRef
El-Wakil MM (1984) Power plant technology. McGraw-Hill, New York
Farhad S, Saffar-Avval M, Younessi-Sinaki M (2008) Efficient design of feedwater heater network in steam power plants using pinch technology and energy analysis. Int J Energy Res 32:1–11CrossRef
Finnveden G, Nilsson M, Johansson J, Persson A, Moberg A, Carlsson T (2003) Strategic environmental assessment methodologies—applications within the energy sector. Environ Impact Assess 23:91–123CrossRef
Fu Y, Diwekar UM (2004) Cost effective environmental control technology for utilities. Adv Environ Res 8:173–196CrossRef
Goldberg DE (1989) Genetic algorithms in search, optimization, and machine learning. Addison-Wesley, Reading
Guinée JB, Heijungs R, Udo de Haes HA, Huppes G (1993a) Quantitative life cycle assessment of products: 2. Classification, valuation and improvement analysis. J Clean Prod 1:81–91CrossRef
Guinée JB, Udo de Haes HA, Huppes G (1993b) Quantitative life cycle assessment of products: 1: goal definition and inventory. J Clean Prod 1:3–13CrossRef
Haimes YY, Lasdon LS, Wismer DA (1971) On a bicriterion formulation of the problems of integrated system identification and system optimization. IEEE Trans Syst Man Cybern 1:269–297
Haywood RW (1991) Analysis of engineering cycles. Pergamon Press, Oxford
Hugo A, Pistikopoulos EN (2005) Environmentally conscious long-range planning and design of supply chain networks. J Clean Prod 13:1471–1491CrossRef
IEA (2008) CO2 emissions from fuel combustion: 1971/2006, vol 21. International Energy Agency, Paris, pp 1–530
IEA (2010) World energy outlook, vol 21. International Energy Agency, Paris, pp 1–530
IPCC (2007) Climate Change 2007: The Physical Science Basis Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge
ISO (2006) NF EN ISO 14040:2006-Environmental management-life cycle assessment-principles and framework. AFNOR
Jeswani HK, Gujba H, Azapagic A (2011) Assessing options for electricity generation from biomass on a life cycle basis: environmental and economic evaluation. Waste Biomass Valor 2:33–42CrossRef
Kharchenko NV (1998) Advanced energy systems. Hemisphere Pub, Washington, DC
Kucukvar M, Tatari O (2011) A comprehensive life cycle analysis of cofiring algae in a coal power plant as a solution for achieving sustainable energy. Energy 36:6352–6357CrossRef
Leeper SA (1981) Wet cooling towers: rule-of-thumb design and simulation. EG and G Idaho, Inc., Idaho FallsCrossRef
Liska AJ, Yang HS, Bremer V, Walters DT, Erickson G, Klopfenstein T, Kenney D, Tracy P, Koelsch R, Cassman KG (2009) BESS: Biofuel energy systems simulator; Life cycle energy and emissions analysis model for corn-ethanol biofuel. Vers. 2008.3. 1, www.​bess.​unl.​edu
López-Maldonado LA, Ponce-Ortega JM, Segovia-Hernández JG (2011) Multi-objective synthesis of heat exchanger networks minimizing the total annual cost and the environmental impact. Appl Therm Eng 31:1099–1113CrossRef
Martínez PE, Eliceche AM (2009) Minimization of life cycle CO2 emissions in steam and power plants. Clean Technol Environ Policy 11:49–57CrossRef
Martínez PE, Pasquevich DM, Eliceche AM (2012) Operation of a national electricity network to minimize life cycle greenhouse gas emissions and cost. Int J Hydrogen Energy 37(19):14786–14795
Metz B, Davidson O, de Coninck H, Loos M, Meyer L (2005) IPCC special report on carbon dioxide capture and storage. Cambridge University Press, New York
Mohan T, El-Halwagi MM (2007) An algebraic targeting approach for effective utilization of biomass in combined heat and power systems through process integration. Clean Technol Environ Policy 9:13–25CrossRef
Moran MJ, Shapiro HN (2006) Fundamentals of engineering thermodynamics. Wiley, Chichester
Odeh NA, Cockerill TT (2008) Life cycle GHG assessment of fossil fuel power plants with carbon capture and storage. Energy Policy 36:367–380CrossRef
Peters MS, Timmerhaus KD, West RE (2003) Plant design and economics for chemical engineers. McGraw-Hill Science/Engineering/Math
Ponce-Ortega JM, Mosqueda-Jiménez FW, Serna-González M, Jiménez-Gutiérrez A, El-Halwagi MM (2011a) A property-based approach to the synthesis of material conservation networks with economic and environmental objectives. AIChE J 57(9):2369–2387
Ponce-Ortega JM, Tora EA, González-Campos JB, El-Halwagi MM (2011b) Integration of renewable energy with industrial absorption refrigeration systems: systematic design and operation with technical, economic, and environmental objectives. Ind Eng Chem Res 50(16):9667–9684CrossRef
PRé-Consultants (2000) The Eco-indicator 99. A damage oriented method for life cycle impact assessment. Methodology report and manual for designers. Technical Report, PRé Consultants, Amersfoort, The Netherlands
Salisbury JK (1950) Steam turbines and their cycles. Wiley, New York
Santibañez-Aguilar E, González-Campos B, Ponce-Ortega JM, Serna-González M, El-Halwagi MM (2011) Optimal planning of a biomass conversion system considering economic and environmental aspects. Ind Eng Chem Res 50:8558–8570CrossRef
Smith R (2005) Chemical process design and integration. Wiley, New York
Varun, Bhat IK, Prakash R (2009) LCA of renewable energy for electricity generation systems—a review. Renew Sust Energy Rev 13:1067–1073CrossRef
Wagner W, Kruse A (1998) Properties of water and steam: the industrial standard IAPWS-IF97 for the thermodynamic properties and supplementary equations for other properties: tables based on these equations, Springer-Verlag
Wagner W, Cooper JR, Dittmann A, Kijima J, Krestzschmar HJ, Kruse A, Mares R, Oguchi K, Sato H, Stocker I (2000) The IAPWS industrial formulation 1997 for the thermodynamic properties of water and steam. J Eng Gas Turb Power 122:150CrossRef
Wang M, Wu Y, Elgowainy A (2007) Operating manual for GREET: Version 1.7. Center for Transportation Research, Energy Systems Division, Argonne National Laboratory, Iowa
Weisser D (2007) A guide to life-cycle greenhouse gas (GHG) emissions from electric supply technologies. Energy 32:1543–1559CrossRef
Metadaten
Titel
Multi-objective optimization of steam power plants for sustainable generation of electricity
verfasst von
César G. Gutiérrez-Arriaga
Medardo Serna-González
José María Ponce-Ortega
Mahmoud M. El-Halwagi
Publikationsdatum
01.08.2013
Verlag
Springer Berlin Heidelberg
Erschienen in
Clean Technologies and Environmental Policy / Ausgabe 4/2013
Print ISSN: 1618-954X
Elektronische ISSN: 1618-9558
DOI
https://doi.org/10.1007/s10098-012-0556-4

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