Rice husks are pyrolyzed in a fluidized bed reactor using alumina as the bed material. At the nitrogen velocity of 0.42 m/s and pressure of 1.5 atm, and the oven temperature of 670°C, we evaluate the effects of the biomass feeding rate, F, and the bed height/diameter ratio, H/D, on the pyrolysis performances. We monitor the product yield, composition and high heating value, and the reactor temperature variation at For5 g/min, 10 g/min, or 15 g/min with H/D ratio of 1, 0.75, or 0.5. The heat of reaction and the bed overall heat transfer coefficient are also analyzed based on the energy balance equations.The yield and high heating value of bio-oil increase with the F increasing. When F=15 g/min and H/D ratio=1, the bio-oil yield is the highest 41%. When F decreases, the retention time of pyrolyzed gas increases, which increases the possibility of the secondary pyrolysis reaction, and hence the overall exothermic heat of reaction increases. When F=5 g/min and H/D ratio=1, the overall exothermic heat of reaction is the highest 3.9 MJ/kg. Comparing to F, H/D ratio has less influence on the product yield, high heating value and the reaction heat. F and H/D ratio affect the reactor temperature through the bed overall heat transfer coefficient, thereby affecting the distribution and composition of products. Before the biomass feeding, the fluidized bed temperature and the bed overall heat transfer coefficient increase with the increasing of H/D ratio. After the biomass feeding, the bed overall heat transfer coefficient decreases due to the presence of rice husk and char with poor heat conductivity. When F=5 g/min and H/D ratio=0.75, the bed overall heat transfer coefficient decreases the least as 25% decreasing after the biomass feeding. When F=15 g/min and H/D ratio=0.5, the bed overall heat transfer coefficient decreases the most as 66% decreasing after the biomass feeding.