Mechanistic insight into the effect of hydrothermal treatment of sewage sludge on subsequent pyrolysis: Evolution of volatile and their interaction with pyrolysis kinetic and products compositions

Hydrothermal treatment (HT) is an effective thermochemical pretreatment process for improving the pyrolysis behavior and quality of products. This study systematically investigated the relationship between the compositions and structures of hydrothermally treated sewage sludge (SS) (120-260 degrees C) and the characteristics of the subsequent pyrolysis. The results indicated that, in the solubilization and hydrolyzation stage (120-160 degrees C), the hydrolyzation of thermally stable polymeric substances in the SS reduced the activation energy of pyrolysis reaction and facilitated the formation of aliphatic hydrocarbons and acids/esters in the bio-oil. Moreover, the solubilization and deamination of proteinaceous substrates during HT reduced the content of nitrogen- and sulfur-containing compounds in bio-oil and non-condensable gases. In the carbonization stage (180-260 degrees C), the activation energy of the HT-sludge pyrolysis reaction increased with the formation of aromatic structures. Furthermore, odxygen- and nitrogen-containing aryl compounds formed from the repolymerization of soluble intermediates were converted into acids/esters and amine/amide in the primary bio-oil during pyrolysis (450 degrees C). With increasing pyrolysis temperature, deamination and decarboxylation of amides and acids/esters in the primary bio-oil increasingly occurred, resulting in the release of NH3 and CO2.

Automated summary

Hydrothermal treatment (HT) improves the pyrolysis of sewage sludge by reducing the activation energy and facilitating the formation of hydrocarbons and acids/esters. HT also reduces the nitrogen- and sulfur-containing compounds in bio-oil and non-condensable gases. The pyrolysis of HT-sludge results in the formation of aromatic structures and the conversion of oxygen- and nitrogen-containing compounds into acids/esters and amine/amide.