High-temperature catalytic pyrolysis of radiata pine for production of high-value products

In this study, high-temperature catalytic pyrolysis of radiata pine was investigated for the production of high-value gas products. Pyrolysis experiments were conducted in a fluidized bed reactor at temperatures of 600 to 850 degrees C. The effect of temperature and the addition of titanomagnetite as the catalyst was evaluated based on product distribution, gas composition, gas properties, and tar composition. The results show that with titanomagnetite, the maximum gas yield of 72.9% was achieved at 850 degrees C, which is higher than that of the non-catalytic pyrolysis at the same temperature. The main gas species in the gas product from the catalytic pyrolysis at 850 degrees C include hydrogen (12.8 vol%), carbon monoxide (37.6 vol%), carbon dioxide (35.8 vol%), methane (5.8 vol%), and ethylene (5.8 vol%). Also, with titanomagnetite, the maximum lower heating value of 23.0 MJ/Nm(3) for the product gas was achieved at 800 degrees C, and the maximum value for hydrogen to carbon monoxide (0.34) was found at 850 degrees C. Titanomagnetite promoted the formation of oxygenated hydrocarbons such as acids, esters, and phenols in tar, but at 850 degrees C, the tars from both catalytic and non-catalytic pyrolysis were rich in naphthalenes (more than 40%). H-2-reduced titanomagnetite performed equally as the unreduced titanomagnetite with respect to gas yield, but the hydrogen and ethylene contents in the gas from the pyrolysis at 850 degrees C were 21.5 and 21.8 vol%, respectively. At this temperature, the lower heating value of the gas from the catalytic pyrolysis with the H-2-reduced titanomagnetite was 17.4 MJ/Nm(3), and the hydrogen to carbon monoxide ratio was 2.6.

Automated summary

This study investigated the high-temperature catalytic pyrolysis of radiata pine for the production of high-value gas products. The results show that the addition of titanomagnetite as a catalyst can increase gas yield and lower heating value, as well as promote the formation of oxygenated compounds in tar.