Chemical effects of CO2 addition to oxidizer and fuel streams on flame structure in H2-O2 counterflow diffusion flames

Kim

et al. 2004

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SUMMARYA numerical study has been conducted to clearly grasp the impact of chemical effects caused by added CO 2 and of flame location on flame structure and NO emission behaviour. Flame location affects the major source reaction of CO formation, CO 2 +H ! CO+OH and the H-removal reaction, CH 4 +H ! CH 3 +H 2 . It is, as a result, seen that the reduction of maximum flame temperature due to chemical effects for fuel-side dilution is mainly caused by the competition of the principal chain branching reaction with the reaction, CH 4 +H ! CH 3 +H 2 , while that for fuel-side dilution is attributed to the competition of the principal chain branching reaction with the reaction, CO 2 +H ! CO+OH.The importance of the NNH mechanism for NO production, where the reaction pathway is NNH ! NH ! HNO, is recognized. In C-related reactions most of NO is the direct outcome of (R171) and the contribution of (R171) becomes more and more important with increasing amount of added CO 2 as much as the reaction step (R171) competes with the key reaction of thermal mechanism, (R237), for N atom. This indicates a possibility that NO emission in hydrogen flames diluted with CO 2 shows less dependent behaviour upon flame temperature.

Section: Introductionmentioning

confidence: 96%

Evaluation of chemical effects of added CO2 according flame location

Kim

et al. 2004

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“…showing a well-known C-curve. The decrease of maximum flame temperature at low global strain rates is due to flame radiation (Park et al, 2003;2005;Ju et al, 1997). It is also shown that the global strain rate at the maximum of maximum flame temperature shifts to lower one as X CH 4 decreases.…”

Section: Numerical Strategies and Methodsmentioning

confidence: 89%

“…The increase of the forward reaction rate is relevant to the remarkable formation of H atom, despite of the decrease of methane mole fraction. It has been also well known that the populations of the chain carrier radicals (H, O, and OH) increase with the increase of strain rate (Park et al, 2003). Figure 5 shows the variation of maximum (a) CO and (b) CO 2 mole fractions with global strain rate for various blended fuels with hydrogen and methane.…”

mentioning

confidence: 95%

Hydrogen utilization as a fuel: hydrogen-blending effects in flame structure and NO emission behaviour of CH4–air flame

et al. 2007

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SUMMARYHydrogen-blending effects in flame structure and NO emission behaviour are numerically studied with detailed chemistry in methane-air counterflow diffusion flames. The composition of fuel is systematically changed from pure methane to the blending fuel of methane-hydrogen through H 2 molar addition up to 30%. Flame structure, which can be described representatively as a fuel consumption layer and a H 2 -CO consumption layer, is shown to be changed considerably in hydrogen-blending methane flames, compared to pure methane flames. The differences are displayed through maximum flame temperature, the overlap of fuel and oxygen, and the behaviours of the production rates of major species. Hydrogen-blending into hydrocarbon fuel can be a promising technology to reduce both the CO and CO 2 emissions supposing that NO x emission should be reduced through some technologies in industrial burners. These drastic changes of flame structure affect NO emission behaviour considerably. The changes of thermal NO and prompt NO are also provided according to hydrogen-blending. Importantly contributing reaction steps to prompt NO are addressed in pure methane and hydrogen-blending methane flames.

“…Subsequently the existence of hydrocarbon products inhibits chain branching since the rate of the major chain branching reaction, H+O 2 =O+OH, is much less than the rate of reaction between H atoms and hydrocarbons, so that the major chain branching reaction, H+O 2 =O+OH, is prohibited. Recent researches on the chemical effects of carbon dioxide addition to both the fuel-and the oxidizer-sides of a diffusion flame (Liu et al, 2001;Park et al, 2003) displayed that the reaction CO 2 +H->CO+OH was found to be the major starting point of the chemical effects of added CO 2 , and the chemical effects of added CO 2 were also seen to suppress NO x formation. Park et al, (2003) also recognized that the reason why flame temperatures with CO 2 addition to the fuel-side were lower compared with those with CO 2 addition to the oxidizer-side was closely associated with a characterized strain rate, and the chemical effects were much more prevailing with CO 2 addition to the oxidizer-side.…”

Section: Introductionmentioning

confidence: 95%

Comparative study of flame structures and NOx emission characteristics in fuel injection recirculation and fuel gas recirculation combustion system

Chung

et al. 2004

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SUMMARYA numerical study with momentum-balanced boundary conditions has been conducted to grasp the chemical effects of added CO 2 to fuel-and oxidizer-sides on flame structure and NO emission behaviour in H 2 -O 2 diffusion flames with varying flame location. A reaction mechanism is proposed to show better agreements with experimental results in CO 2 -added hydrogen flames.Oxidizer-side dilution results in significantly higher flame temperatures and NO emission. Flame location is dramatically changed due to high diffusivity of hydrogen according to variation of the composition of fuel-and oxidizer-sides. This affects flame structure and NO emission considerably especially the chemical effects of added CO 2 . The present work also displays separately thermal contribution and prompt NO emission due to the chemical effects caused by thermal dissociation of added CO 2 in NO emission behaviour. It is found that flame temperature and the flame location affect the contribution of thermal and prompt NO due to chemical effects considerably in NO emission behaviour.