Optimizing supply airflow and its distribution between primary and secondary air in a forced-draft biomass pellet stove

Abstract

Forced-draft biomass stoves improve the pollutant emission performance of biomass combustion. The parameters of supply airflow and its distribution between primary air (PA) and secondary air (SA) have a significant effect on the performance of this stove type. In this study, we designed an air supply control system to accurately quantify the airflow rates, and monitored the dynamic emissions of focused pollutant species including carbon monoxide (CO), nitrogen oxides (NOx), particulate matter (PM2.5), and the fuel burning rate. The tested stove had a combustion structure typical of many popular stoves, and wood pellets were the burning fuel. Three total airflow rates (92 L/min, 184 L/min, and 276 L/min) were selected, and six distributions between PA and SA (PA:SA) for each airflow rate were tested, which included 10:0 (full PA), 8:2, 6:4, 5:5, 4:6, and 2:8. The results showed that the test duration, burning rate, and pollutant (CO, NOx, and PM2.5) emission performances of different airflows or distributions varied. Overall, when the PA and SA distribution mode was determined, the total airflow rate of 184 L/min was the optimal supply airflow rate. Under the same total airflow rate, the burning and emission performances were better when the primary and secondary airflows were similar, namely from 4:6 to 6:4. This study provided core information about stove air supply and distribution, which is essential to quantitatively determine the stove air supply mode to significantly improve stove performances.