The performance of a novel ultrasonic flatbed reactor for sewage sludge pre-treatment was assessed for three different waste activated sludges. The study systematically investigated the impact of specific energy input (200 - 3,000 kJ/kgTS) on the degree of disintegration (DDCOD, i.e. ratio between ultrasonically and maximum chemically solubilized COD) and methane production enhancement. Relationship between DDCOD and energy input was linear, for all sludges tested. Methane yields were significantly increased for both low (200 kJ/kgTS) and high (2,000 - 3,000 kJ/kgTS) energy inputs, while intermediate inputs (400 - 1,000 kJ/kgTS) showed no significant improvement. High inputs additionally accelerated reaction kinetics, but were limited to similar gains as low inputs (max. 12%), despite the considerably higher DDCOD values. Energy balance was only positive for 200 kJ/kgTS-treatments, with a maximum energy recovery of 122%. Results suggest that floc deagglomeration rather than cell lysis (DDCOD=1% - 5% at 200 kJ/kgTS) is the key principle of energy-positive sludge sonication.
Keywords: Degree of disintegration; Energy self-sufficiency; Low energy input treatment; Specific methane yield; Ultrasonic flatbed reactor.
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