Techno-economic analysis and optimization of the heat recovery of utility boiler flue gas

Coal-fired power plants in China consume nearly half of available coals, and the resulting CO2 emissions cover over 40% of total national emissions. Therefore, reducing the energy expenditure of coal-fired power plants is of great significance to China’s energy security and greenhouse gas reduction programs. For coal-fired power plants, the temperature of a boiler’s exhaust gas reaches 120–150°C or even higher. The thermal energy of boiler’s exhaust accounts for approximately 3–8% of the total energy of fuel input. Given these factors, we conducted a techno-economic analysis and optimization design of the heat recovery system using boiler exhaust gas. This research is conformed to the principles of thermodynamic, heat transfer, and hydrodynamics. Based on the data from an existing 1000MW typical power generation unit in China, four typical flue gas heat recovery schemes are quantitatively analyzed from the thermodynamics perspective. The impacts of flue gas heat recovery on net work output and standard coal consumption rate of various schemes are performed. Furthermore, the transfer area of heat recovery exchanger and the draft fan work increment due to the flue gas pressure drop are analyzed. Finally, a techno-economic analysis of the heat recovery schemes is conducted, and some recommendations on optimization design parameters are proposed, with full consideration of various factors such as the decrease on fuel cost due to energy conservation as well as the investment cost of heat recovery retrofitting. The results revealed that, high-stage steam substitute scheme of flue gas heat recovery in power plant can obtain higher energy-saving effects than that of low-stage steam substitute scheme. And the energy-saving benefit of flue gas heat recovery, especially with high-stage steam substitute scheme, is weakened by large heat exchange areas and flue gas pressure drop caused by lower temperature differentials. Therefore, the techno-economic performance of the flue gas heat recovery in power plant may not always increase with the increment of the recovered heat but have an optimum point.

[1]  Kiyoshi Kawaguchi,et al.  The heat transfer and pressure drop characteristics of finned tube banks in forced convection (comparison of the pressure drop characteristics of spiral fins and serrated fins) , 2004 .

[2]  E Jannelli,et al.  Simulation of the flue gas cleaning system of an RDF incineration power plant. , 2007, Waste management.

[3]  Kwangkook Jeong,et al.  Analytical modeling of water condensation in condensing heat exchanger , 2010 .

[4]  A. Bahadori Estimation of combustion flue gas acid dew point during heat recovery and efficiency gain , 2011 .

[5]  Guolian Hou,et al.  Generalized predictive control applied in waste heat recovery power plants , 2013 .

[6]  R. Velraj,et al.  Experimental investigation on heat recovery from diesel engine exhaust using finned shell and tube heat exchanger and thermal storage system , 2011 .

[7]  Sergio Mussati,et al.  Optimal synthesis and design of Heat Recovery Steam Generation (HRSG) via mathematical programming , 2011 .

[8]  Jonathan Fagerström,et al.  Flue gas purification and heat recovery: A biomass fired boiler supplied with an open absorption system , 2012 .

[9]  Hu Lin,et al.  A comprehensive techno‐economic analysis method for power generation systems with CO2 capture , 2010 .

[10]  Morten Boje Blarke,et al.  Towards an intermittency-friendly energy system: Comparing electric boilers and heat pumps in distributed cogeneration , 2012 .

[11]  Zhao Zhi-jun,et al.  Theoretical Analysis and Engineering Practice of Heat Recovery from Exhaust Gas of Power Boilers , 2009 .

[12]  Luis M. Romeo,et al.  Optimization of boiler cold-end and integration with the steam cycle in supercritical units , 2010 .

[13]  Xiaohui Zhang,et al.  Condensing boiler applications in the process industry , 2012 .

[14]  Ying Wu,et al.  Application of a low pressure economizer for waste heat recovery from the exhaust flue gas in a 600 MW power plant , 2012 .

[15]  R. Williams,et al.  Co-production of hydrogen, electricity and CO2 from coal with commercially ready technology. Part B: Economic analysis , 2005 .

[16]  Dexin Wang,et al.  Coal power plant flue gas waste heat and water recovery , 2012 .

[17]  C. Weierman,et al.  Correlations Ease the Selection of Finned Tubes , 1976 .