Reducing high-temperature corrosion on high- alloyed stainless steel superheaters by co-combustion of municipal sewage sludge in a fluidised bed boiler
Artikel i vetenskaplig tidskrift, 2015

One way of mitigating alkali chloride induced corrosion in biomass and waste-fired boilers is by using additives or by co-combustion and thereby decreasing the corrosiveness of the flue gas and deposits. The effect of co-firing digested sewage sludge with a mixture of biomass and waste (78% bark pellets + 22% Solid Recovered Fuel, denoted "SRF'') was investigated in a 12 MW circulating fluidised bed (CFB) boiler. The initial corrosion attack of the stainless steel 304L at 600 degrees C (material temperature) was investigated during 24 h exposures. The exposures were carried out in the flue gas environment from three fuel-mixes: SRF, MSS1- low (SRF with municipal sewage sludge, low dosage) and MSS2- high (SRF with municipal sewage sludge, high dosage). The results showed that the most severe corrosion attack on 304L occurred without sewage sludge in the SRF exposure. This attack was characterised by a corrosion product layer up to 100 mu m in thickness and signs of internal corrosion of the steel. The deposit in the SRF case was dominated by alkali chlorides. The exposures with co- combustion of sewage sludge, MSS1-low and MSS2- high, showed a significant decrease in corrosion. The steel sample of 304L performed especially well in the latter case when it was protected by a thin oxide of less than 0.3 mu m in thickness. This deposit was dominated by sulphate- and phosphate- containing compounds but traces of aluminium silicate compounds where also found. Furthermore, the concentration of alkali chlorides was low. Thus, the initial corrosion attack was greatly reduced by co- combustion of digested sewage sludge with SRF.

Municipal sewage sludge

Alkali chlorides



Fluidised bed boiler


Sofia Karlsson

Chalmers, Kemi och kemiteknik, Energi och material

Lars-Erik Åmand

Chalmers, Energi och miljö, Industriella energisystem och tekniker

Jesper Liske

Chalmers, Kemi och kemiteknik, Energi och material


0016-2361 (ISSN)

Vol. 139 482-493






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