Modelling, Sensitivity and Exergy Analysis of Triple-Pressure Heat Recovery Steam Generator
Yıl 2020,
Cilt: 8 Sayı: 2, 106 - 114, 21.12.2020
Suha Orçun Mert
,
F. Zehra Özçelik
,
Ceyda Kök
Öz
Combined with the increasing demand for environmental pollution and electrical energy, combined cycle power plant power plants are increasingly important. It is necessary to increase the performance of power plants, reduce carbon emissions and increase energy production. Any change to the heat recovery steam generator design is an important component of the combined cycle power plant, as it directly affects the performance of the combined cycle power plant. This study describes the modeling, sensitivity and exergy analysis of a HRSG in a combined cycle power plant. Three-pressure HRSG was modeled with the Aspen Plus simulation program and sensitivity analysis was performed. At the same time, energy and exergy analyzes were made for each component in the combined cycle power plant.
Kaynakça
- Kole A., "A review and study on advanced control and automation functions and future control for a modern combined cycle power plant", 2016 International Conference on Intelligent Control, Power and Instrumentation, (2017), 215-220.
- Rackley S.A., "Carbon capture from power generation. In: Carbon Capture and Storage" (2017).
- Nadir M., Ghenaiet A., "Thermodynamic optimization of several (heat recovery steam generator) HRSG configurations for a range of exhaust gas temperatures" Energy, (2015),685-695.
- Dumont M.N., Heyen G., "Mathematical modelling and design of an advanced once-through heat recovery steam generator", Computers and Chemical Engineering, (2004),651-660.
- Feng H., Zhong W., Wu Y., Tong S., "Thermodynamic performance analysis and algorithm model of multi-pressure heat recovery steam generators (HRSG) based on heat exchangers layout", Energy Convers Manag, (2014), 282-289.
- Durán M.D., Valdés M., Rovira A., Rincón E., "A methodology for the geometric design of heat recovery steam generators applying genetic algorithm". Appl Therm Eng, (2013),77-83.
- Naemi S., Saffar A.M., Behboodi K.S., Mansoori Z., "Optimum design of dual pressure heat recovery steam generator using non-dimensional parameters based on thermodynamic and thermoeconomic approaches" Appl Therm Eng, (2013), 371-384.
- Mohammadi K.A., Joda F., Bozorgmehry R., "Exergic, economic and environmental impacts of natural gas and diesel in operation of combined cycle power plants", Energy Convers Manag, (2016), 103-112.
- Manassaldi J.I., Arias A.M., Scenna N.J., Mussati M.C., Mussati S.F., "A discrete and continuous mathematical model for the optimal synthesis and design of dual pressure heat recovery steam generators coupled to two steam turbines", Energy, (2016), 807-823.
- Martelli E., Elsido C., Mian A., Marechal F., "MINLP model and two-stage algorithm for the simultaneous synthesis of heat exchanger networks, utility systems and heat recovery cycles", Comput Chem Eng, (2017), 663-689.
- Pelster S., Favrat D., Von M.R. "The thermoeconomic and environomic modeling and optimization of the synthesis, design, and operation of combined cycles with advanced options", J Eng Gas Turbines Power, (2001),717-726.
- Srinivas T., Gupta A., Reddy B. V., "Thermodynamic modeling and optimization of multi-pressure heat recovery steam generator in combined power cycle" J Sci Ind Res, (2008).
- Hajabdollahi H., Ahmadi P., Dincer I., "An Exergy-based multi-objective optimization of a heat recovery steam generator (HRSG) in a combined cycle power plant (CCPP) using evolutionary algorithm" Int J Green Energy, (2011), 44-64.
- Alus M., Petrović M .V., "Optimization of the triple-pressure combined cycle power plant",Therm Sci, (2012),901-914.
- Alobaid F., Karner K., Belz J., Epple B., Kim H.G., "Numerical and experimental study of a heat recovery steam generator during start-up procedure", Energy, (2014), 1057-1070.
- Ali M.S., Shafique Q.N., Kumar D., Kumar S., Kumar S., "Energy and exergy analysis of a 747-MW combined cycle power plant Guddu", Int J Ambient Energy, (2018),1-10.
- Moosazadeh S.A., Mafi M., Kaabi N.A., Salehi G., Torabi A. M. "A new method to boost performance of heat recovery steam generators by integrating pinch and exergy analyses" Adv Mech Eng, (2018).
- Boyaghchi F.A., Molaie H., "Sensitivity analysis of exergy destruction in a real combined cycle power plant based on advanced exergy method" Energy Convers Manag. (2015),374-386.
- Sabia G., Heinze C., Alobaid F., Martelli E., Epple B., "ASPEN dynamics simulation for combined cycle power plant – Validation with hot start-up measurement" Energy, (2019).
- Kakaras E., Doukelis A., Leithner R., Aronis N., "Combined cycle power plant with integrated low temperature heat (LOTHECO)", Applied Thermal Engineering, (2004),1677-1686.
- Balaman Ş.Y., "Uncertainty Issues in Biomass-Based Production Chains", Decision-Making for Biomass-Based Production Chains, (2019),77-112.
- Bassily A.M., "Modeling, numerical optimization, and irreversibility reduction of a triple-pressure reheat combined cycle", Energy, (2007),778-794.
Yıl 2020,
Cilt: 8 Sayı: 2, 106 - 114, 21.12.2020
Suha Orçun Mert
,
F. Zehra Özçelik
,
Ceyda Kök
Kaynakça
- Kole A., "A review and study on advanced control and automation functions and future control for a modern combined cycle power plant", 2016 International Conference on Intelligent Control, Power and Instrumentation, (2017), 215-220.
- Rackley S.A., "Carbon capture from power generation. In: Carbon Capture and Storage" (2017).
- Nadir M., Ghenaiet A., "Thermodynamic optimization of several (heat recovery steam generator) HRSG configurations for a range of exhaust gas temperatures" Energy, (2015),685-695.
- Dumont M.N., Heyen G., "Mathematical modelling and design of an advanced once-through heat recovery steam generator", Computers and Chemical Engineering, (2004),651-660.
- Feng H., Zhong W., Wu Y., Tong S., "Thermodynamic performance analysis and algorithm model of multi-pressure heat recovery steam generators (HRSG) based on heat exchangers layout", Energy Convers Manag, (2014), 282-289.
- Durán M.D., Valdés M., Rovira A., Rincón E., "A methodology for the geometric design of heat recovery steam generators applying genetic algorithm". Appl Therm Eng, (2013),77-83.
- Naemi S., Saffar A.M., Behboodi K.S., Mansoori Z., "Optimum design of dual pressure heat recovery steam generator using non-dimensional parameters based on thermodynamic and thermoeconomic approaches" Appl Therm Eng, (2013), 371-384.
- Mohammadi K.A., Joda F., Bozorgmehry R., "Exergic, economic and environmental impacts of natural gas and diesel in operation of combined cycle power plants", Energy Convers Manag, (2016), 103-112.
- Manassaldi J.I., Arias A.M., Scenna N.J., Mussati M.C., Mussati S.F., "A discrete and continuous mathematical model for the optimal synthesis and design of dual pressure heat recovery steam generators coupled to two steam turbines", Energy, (2016), 807-823.
- Martelli E., Elsido C., Mian A., Marechal F., "MINLP model and two-stage algorithm for the simultaneous synthesis of heat exchanger networks, utility systems and heat recovery cycles", Comput Chem Eng, (2017), 663-689.
- Pelster S., Favrat D., Von M.R. "The thermoeconomic and environomic modeling and optimization of the synthesis, design, and operation of combined cycles with advanced options", J Eng Gas Turbines Power, (2001),717-726.
- Srinivas T., Gupta A., Reddy B. V., "Thermodynamic modeling and optimization of multi-pressure heat recovery steam generator in combined power cycle" J Sci Ind Res, (2008).
- Hajabdollahi H., Ahmadi P., Dincer I., "An Exergy-based multi-objective optimization of a heat recovery steam generator (HRSG) in a combined cycle power plant (CCPP) using evolutionary algorithm" Int J Green Energy, (2011), 44-64.
- Alus M., Petrović M .V., "Optimization of the triple-pressure combined cycle power plant",Therm Sci, (2012),901-914.
- Alobaid F., Karner K., Belz J., Epple B., Kim H.G., "Numerical and experimental study of a heat recovery steam generator during start-up procedure", Energy, (2014), 1057-1070.
- Ali M.S., Shafique Q.N., Kumar D., Kumar S., Kumar S., "Energy and exergy analysis of a 747-MW combined cycle power plant Guddu", Int J Ambient Energy, (2018),1-10.
- Moosazadeh S.A., Mafi M., Kaabi N.A., Salehi G., Torabi A. M. "A new method to boost performance of heat recovery steam generators by integrating pinch and exergy analyses" Adv Mech Eng, (2018).
- Boyaghchi F.A., Molaie H., "Sensitivity analysis of exergy destruction in a real combined cycle power plant based on advanced exergy method" Energy Convers Manag. (2015),374-386.
- Sabia G., Heinze C., Alobaid F., Martelli E., Epple B., "ASPEN dynamics simulation for combined cycle power plant – Validation with hot start-up measurement" Energy, (2019).
- Kakaras E., Doukelis A., Leithner R., Aronis N., "Combined cycle power plant with integrated low temperature heat (LOTHECO)", Applied Thermal Engineering, (2004),1677-1686.
- Balaman Ş.Y., "Uncertainty Issues in Biomass-Based Production Chains", Decision-Making for Biomass-Based Production Chains, (2019),77-112.
- Bassily A.M., "Modeling, numerical optimization, and irreversibility reduction of a triple-pressure reheat combined cycle", Energy, (2007),778-794.