Combustion Characteristics, Kinetics, and Thermodynamics of Pine Wood Through Thermogravimetric Analysis

The thermal conversion of woody biomass is increasingly critical for the development of the energy processing technologies and fire safety engineering. The combustion characteristics, kinetics, and thermodynamics of pine wood were characterized through a thermogravimetric analyzer in the air atmosphere. There were two apparent peaks in the derivative TG curves for pine wood. The combustion process of pine wood was divided into two stages. Therein, the first stage occurring in the conversion degree range of 0-0.6 may be considered a one-step reaction. It was easier for pine wood to decompose under air than under nitrogen. Moreover, the first stage of pine wood combustion may be characterized by the diffusion model g(alpha) = [1 - (1 - alpha)(1/3)](2). The kinetic modeling showed a good agreement between the predicted and experimental conversion degree curves. In addition, the high comprehensive combustion index of pine wood at 10 K min(-1) (6.73 x 10(-7) %(2) min(-2) K-3) showed its great potential for bioenergy generation. Besides, both the value of Delta H and Delta S exhibited similar patterns with the activation energy value versus conversion degree, while the Delta G value almost remained at a positive constant with conversion degree. The average Delta H, Delta G, and Delta S value was nearly equal under different heating rates.