Experimental study of gliding arc plasma-assisted combustion in a blast furnace gas fuel model combustor: Flame structures, extinction limits and combustion stability

As an essential by-product of the iron and steel enterprises, blast furnace gas fuel is used as an alternative fuel for gas turbine combustion to increase economic effect. However, the less combustible components and low heat value of BFG fuel make the combustion in combustor very challenging. In this paper, a gliding arc plasma was employed to assist the blast furnace gas /air combustion with different equivalence ratio. Flame chemiluminescence, the pressure and heat release rate pulsation were recorded simultaneously for showing the flame characteristics of blast furnace gas. The experimental result demonstrates that there are six flame structures in the combustion process of blast furnace gas fuel: A stable flame with short U-shaped (SS-Flame), a vertical oscillating flame (VO-Flame), a stable flame with long U-shaped (SL-Flame), a special gourd-shaped flame (SG Flame), a lifted flame (L-Flame) and a continuous extinct flame (CE-Flame). According to characteristics of flame structures before flameout, all cases can be divided into three types of extinction modes: I: Direct extinction, II: Oscillation extinction, III: Lifted extinction. The equivalence ratio of extinction limits at the low volume flow rate of air is more likely to be extended by gliding arc plasma than those at the high volume flow rate of air. The pressure and heat release rate pulsation experiment result shows that the violent oscillation of the heat release can be one of the prediction indexes of the flameout of blast furnace gas fuel. In all cases, the pressure pulsation of blast furnace gas fuel combustion is & PLUSMN; 10 Pa, and there is no obvious dominant frequency of heat release pulsation. The amplitude of heat release rate decreases from 0.04 V to 0.01 V with gliding arc plasma addition at phi = 0.7 (E-1 case). Meanwhile, the flame structure of blast furnace gas fuel changes from VO-Flame to SS-Flame due to the gliding arc anchoring the flame root.

Automated summary

In this study, the flame characteristics and extinction modes of blast furnace gas combustion were investigated using gliding arc plasma assistance. The results demonstrate that gliding arc plasma can extend the extinction limits of blast furnace gas at low air volume flow rates, and the oscillations of heat release rate can be used as a predictive indicator for flameout.