Lignocellulosic biomass is the potential resource for production of raw materials and can be easily supplemented through reforestation. Conventionally, biochar is produced by slow pyrolysis and directly used in energy industries. However, current processes of pyrolysis are inefficient. Biochar, produced from slight pyrolysis “torrefaction”, has less volume and is cost effective in its transportation to power plant for pulverizer. The purpose of this study was to develop a coupled heat and mass transfer model ,including chemical kinetics. After that, the measurements of mass change during torrefaction of Cryptomeria japonica were compared with the simulation results. Simulation results shows that hemicellulose is the main reactant of the torrefaction. After the sample was heated for 3600s at 250℃, concentration of hemicellulose was reduced to nearly zero. After heating sample for 2000s at 270℃,and 1000s at 290℃, hemicellulose was completely reacted. However, concentration of cellulose and lignin changed slightly at 250℃, the change was significant when temperature was over 270℃. These findings indicate that hemicellulose is the main reactant of the torrefaction. After heating for 3600s, experimental results showed that yields of biochar at 250℃,270℃ and 290℃ were 77%, 69% and 65%. The model was successfully constructed with relative error 5% between the experiment and simulation. Additionally, the percentage curves of hemicellulose, cellulose, and lignin showed a correct approach with that of chemical analysis of the heated sample.