Spectral energy characteristics of radiation in oxy-coal combustion for energy utilization

In this paper, the radiative energy characteristics, especially the spectral distribution characteristics, of the oxy-fuel combustion of pulverized coal are studied from the perspective of radiative energy utilization. Based on a modified tube furnace test platform, the radiative energy flux and spectral distribution of oxy-fuel combustion for three typical Chinese coals under O-2/N-2 and O-2/CO2 atmospheres in the temperature range of 600-1000 degrees C are measured online using radiative heat flux sensors. In particular, the radiative exergy and its spectral distribution characteristics are analyzed based on the second law of thermodynamics. It is found that the intensity of the radiative energy and exergy increase, as does the proportion of spectral radiation below the wavelength of 4.1 mu m, with the increase of the oxygen ratio and combustion temperature under the experimental conditions. In contrast, different atmospheres are found to have little effect on the radiation characteristics. One-dimensional calculation cases of media radiation transfer constructed according to the combustion characteristics can better reveal the proportional characteristics of the spectral radiation. The results provide a reference for research on the cascade conversion and management of photo-thermal energy in fuel combustion.

Automated summary

This paper studies the radiative energy characteristics of oxy-fuel combustion of pulverized coal, focusing on spectral distribution characteristics. Experimental results show that the intensity of radiative energy and exergy increase with oxygen ratio and combustion temperature, while different atmospheres have little effect on radiation characteristics. One-dimensional calculation can better reveal proportional characteristics of spectral radiation.