Corn (maize) is an important crop w

Corn (maize) is an important crop with its annual production being the top among all agricultural grains in the world. The amount of its byproducts such as corn straw and corncob is enormous. More than 1.3 billon tons byproducts generated each year in North America (Kim and Dale, 2004). The LHV of corncob is about 4400kcal/kg, which is similar to corn stern and leaf. However, its fertilizing value is less than one-tenth of that of corn stern or leaf (Avila-Segura et al., 2011). Therefore, corncob is suitable for
burning as a fuel instead of serving as a fertilizer. Due to the abundant supply of corncob in the world, a lot of research attention is focused on the new techniques of converting corncob to biomass energy forms. Tippayawong et al. (2006) used the heat from corncob combustion in a 1.0 m ID 2.0 m in height combustor for tobacco drying. The temperature stability in this corncob combustion proved that corncob is suitable for replacing wood as an alternative fuel.
FBC is recognized as one of many viable technologies in dealing with corncob combustion (Lin et al., 1995; Shafey and Taha, 1992). FBC has the potential for cleaner combustion because of its lower operation temperature (700–900 C), which significantly reduces the formation of thermal NOx and prompt NOx (Leckner and Karlsson, 1993; Werther et al., 2000). In previous studies, many experimental investigations were carried out to understand the formation and reduction mechanism of pollutant emission produced by corncob combustion in FBC. Youssef et al. (2009) studied the corncob combustion in a 0.145m ID 2.0 m in height CFB. The results showed that the lowest emissions of the CO and NOx occurred when the excess air ratio is 24%. Butuk and Morey (1987) evaluated the thermal efficiency of a combustion system using corncob. However, few studies focused on the NOx lowering techniques by using staged combustion and FGR.
Meanwhile, some fossil fuels, such as lignite and anthracite were mixed with corncob in some combustion research works. The co-combustion characteristics in the fluidized-beds were also investigated (Lin et al., 2010; Trif-Tordai et al., 2010). The results


showed that co-combustion of corncob and coal could significantly reduce the NOx emission. The alkali metal elements such as K, Na, andCaofcorncobhavegooddesulfurizationeffectandthisreduces the SO2 emission significantly. Moreover, because corncob has higher volatile ratio than coal, the volatile of corncob releases rapidly and combusts in the freeboard, leading to higher freeboard temperatures. However, due to the insufficient combustion time
of volatile, the CO emission concentration increases with the ratio of corncob in the mixture. Corner tangential firing technology is originally applied in the pulverizedcoal-fired boiler. From the previous studies on the corncob combustion in fluidized-bed combustors, the volatile released from corncob is carried up from the bed zone and combusts in the freeboard. In addition, due to the lower solid voidage in the

freeboard, the efficiency of heat transfer and mass transfer is lower (Bai et al., 1996), which militates against complete combustion of corncob(Linetal.,1995).Therefore,VFBCwasestablishedtocreate a vortex-generating system by injecting the secondary air tangentially into the freeboard to increase the combustion intensity and the turndown capability. This system improved the combustion performance of fluidized-bed combustors (Chakritthakul and Kuprianov, 2011; Chyang et al., 2008; Qian et al., 2009, 2011). The mechanisms of CO/NO formation and reduction of corncob combustion in VFBC are complex. It is difficult to explain the NO emission variations for different operation conditions (Permchart and Kouprianov, 2004; Qian et al., 2011). In this paper, we employed three combustion modes including direct combustion, staged combustion and FGR combustion, and investigated their combustion and pollutant emission characteristics. In addition, the effects of combustion fractions, bed temperature on the CO andNOemissionswereinvestigated.Resultsfromthisstudywould be helpful in the development of more comprehensive physical models for fluidized-bed combustion systems and setting operational parameters in practical applications.