A novel sludge pyrolysis and biomass gasification integrated method to enhance hydrogen-rich gas generation

A novel sludge pyrolysis and biomass gasification (SPBG) integrated method is proposed to facilitate the efficient utilization of sludge and biomass. The transformation of gas, especially hydrogen, and the migration of N in SPBG were investigated. The H-2 proportion increased by 6.22 vol% due to the involvement of sludge steam (S-steam) and sludge volatiles (S-volatiles). S-steam was beneficial to gasification, reforming, and the water-gas shift (WGS) reaction of biomass, which was conducive to hydrogen production. Moreover, in the gasification stage, Svolatiles were heated and then cracked to form gases and free radicals. The latter changed the original system to facilitate dehydrogenization with condensation and the formation of new functional groups. In the range of 30-70%, when the moisture content of the wet sludge was 50%, a relatively higher amount of H-2 and a higher calorific value were obtained. To further enhance hydrogen production, a modified calcium-based additive (MCA) was added. At 800?degrees C, the addition of MCA promoted steam reforming and the WGS reaction, resulting in a higher H-2 concentration of 268.31 mL/g (based on dehydrated feeding including sludge volatiles and biomass). Nitrogen-containing functional groups such as amines, N-PAH, and nitriles from tar also decreased after the addition of MCA.

Automated summary

The novel sludge pyrolysis and biomass gasification integrated method aims at efficient utilization of sludge and biomass, with an increase in hydrogen production by 6.22 vol% through the involvement of sludge steam and sludge volatiles. Addition of a modified calcium-based additive enhances hydrogen production and decreases nitrogen-containing functional groups in tar.