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Performance Analysis of Supercritical Coal Fired Power Plant Using gCCS Simulator
Tefera Zelalem Tumsa,Tae-Young Mun,Uendo Lee,Won Yang 한국연소학회 2014 KOSCOSYMPOSIUM논문집 Vol.2014 No.11
Capturing the carbon dioxide emitted from coal-fired power plants will be necessary if targeted reduction in carbon emissions is to be achieved. Modelling and simulation are the base for optimal operation and control in thermal power plant and also play an important role in energy savings. This study aims to analyze the performance of supercritical coal fired power plant through steady and dynamic simulation using a commercial software gCCS. A whole power plant has been modeled and validated with design data of 500 MWe power plant, base and part load operations of the plant were also evaluated, consequently it had been proven that the simulated result had a good agreement with actual operating data. In addition, the effect of co-firng on the plant efficiency and flue gases were investigated using gCCS simulator.
Mun, Tae-Young,Tumsa, Tefera Zelalem,Lee, Uendo,Yang, Won Elsevier 2016 ENERGY Vol.115 No.1
<P><B>Abstract</B></P> <P>Recently in Korea, the co-firing of biomass in existing pulverized coal power plants has become an important mean to comply with the nation's renewable portfolio standard (RPS). This study investigated boiler efficiency, net plant efficiency, and combustion characteristics from co-firing various biomasses along with two coal blends and the combustion of low rank coals through process simulation based on an existing 500 MWe coal fired power plant using a commercial process simulator (gCCS). Five sources of biomass - wood pellet, empty fruit bunch pellet, palm kernel shell, walnut shell, and torrefied biomass were selected as renewable fuels for co-firing. In addition, hardgrove grindability index tests were conducted for a blend of coal (90%) and each selected biomass (10%) based on thermal share input to investigate the milling power consumption of each blended fuel for a more rigorous simulation. The results show quantitatively that when biomass is co-fired the plant efficiency is decreased due to its lower heating value and more power consumption in mills. The plant efficiency of torrefied biomass co-firing was the highest among all biomass co-firing and combustion of low rank coals due to higher energy density and enhanced grindability of torrefied biomass after torrefaction.</P> <P><B>Highlights</B></P> <P> <UL> <LI> Process simulation for co-firing of various biomasses was performed. </LI> <LI> HGI tests for fuel blends were conducted to predict milling power consumptions. </LI> <LI> Net plant and boiler efficiency were investigated and quantitatively analyzed. </LI> <LI> Grindability and heating value of the fuels mainly affected to the efficiencies. </LI> </UL> </P>
미분탄화력발전에서의 바이오매스 혼소 시 플랜트 성능특성 평가
문태영(Tae-Young Mun),Zelalem Tumsa Tefera,이은도(Uendo Lee),이정우(Jeung Woo Lee),양원(Won Yang) 한국연소학회 2014 한국연소학회지 Vol.19 No.3
The aims of this research were to evaluate effects of biomass co-firing to pulverized coal power plants and the variation of co-firing ratios on the plant efficiency related to power consumption of auxiliary system and flue gas characteristics such as production and component by process simulation based on the existing pulverized coal power plant. In this study, four kinds of biomass are selected as renewable fuel candidates for co-firing: wood pellet(WP), palm kernel shell(PKS), empty fruit bunch(EFB) and walnut shell(WS). Process simulation for various biomass fuels and co-firing ratios was performed using a commercial software. Gas side including combustion system and flue gas treatment system was considering with combination of water and steam side which contains turbines, condenser, feed water heaters and pumps. As a result, walnut shell might be the most suitable as co-firing fuel among four biomass since when 10% of walnut shell was co-fired with 90% of coal on thermal basis, flue gas production and power consumption of auxiliary systems were the smallest than those of other biomass co-firing while net plant efficiency was relatively higher than those of other biomass co-firing. However, with increasing walnut shell co-firing ratios, boiler efficiency and net plant efficiency were expected to decrease rather than coal combustion without biomass co-firing.