Effects of used bed materials on char gasification: Investigating the role of element migration using online alkali measurements

Online alkali measurements using surface ionization are employed to study alkali release during heating of used industrial fluidized bed materials and gasification of biomass-based char and bed material mixtures. The alkali release from the bed materials starts at 820 C and increases with temperature, the time a bed material has experienced in an industrial process, and in the presence of CO2. Online alkali measurement during heating of char mixed with used bed material shows significant alkali uptake by the char. Complementary SEM-EDS studies confirm the alkali results and indicate that other important inorganic elements including Si, Mg, and Ca also migrate from the bed material to the char. The migration of elements initially enhances alkali release and char reactivity, but significantly reduces both during the final stage of the gasification. The observed effects on char gasification become more pronounced with increasing amount of bed material and increasing time the material experienced in an industrial process. The ash-layer on the used bed material is concluded to play an important role as a carrier of alkali and other active components. The char and bed material systems are closely connected under operational conditions, and their material exchange has important implications for the thermal conversion.

Automated summary

Online alkali measurements using surface ionization were conducted to investigate alkali release during heating of industrial fluidized bed materials and gasification of biomass-based char and bed material mixtures. The results indicate that alkali release from the bed materials starts at 820 C and increases with temperature, time, and the presence of CO2. It was also observed that the char absorbs significant amounts of alkali from the used bed material. Furthermore, the migration of other important inorganic elements enhances initial alkali release and char reactivity, but reduces during the final stage of gasification.