Hydrolysis rates, methane production and nitrogen solubilisation of grey waste components during anaerobic degradation

Municipal grey waste (i.e. the remaining fraction in municipal waste management systems in which putrescibles (biowaste) and other recyclables (paper, metals, glass) are source-segregated) was manually sorted into six main fractions on the basis of composition and also separated by sieving (100 mm m...

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Bibliographic Details
Published in:Bioresource technology 2005-03, Vol.96 (4), p.501-508
Main Authors: Jokela, J.P.Y., Vavilin, V.A., Rintala, J.A.
Format: Article
Language:English
Subjects:
Anaerobic Conditions
Anaerobic degradation
Bacteria, Anaerobic - growth & development
Bacteria, Anaerobic - metabolism
Biodegradation, Environmental
Cities
Components
Filtration - methods
Garbage
Grey waste
Hydrolysis
Hydrolysis rate
Kinetics
Landfill
Manufactured Materials - analysis
Manufactured Materials - classification
Methane
Methane - metabolism
Municipal solid waste
Nitrogen
Nitrogen - analysis
Nitrogen - chemistry
Nitrogen - metabolism
Refuse Disposal - methods
Solubilisation
Solubility
Source-segregation
Waste Products - analysis
Waste Products - classification
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Summary:Municipal grey waste (i.e. the remaining fraction in municipal waste management systems in which putrescibles (biowaste) and other recyclables (paper, metals, glass) are source-segregated) was manually sorted into six main fractions on the basis of composition and also separated by sieving (100 mm mesh size) into two fractions, oversized and undersized, respectively. In practice, in waste management plant the oversized fraction is (or will be) used to produce refuse-derived fuel and the undersized landfilled after biological stabilisation. The methane yields and nitrogen solubilisation of the grey waste and the different fractions (all studied samples were first milled to 5 mm particle samples) were determined in a 237-day methane production batch assay and in a water elution test, respectively. The grey waste was found to contained remnants of putrescibles and also a high amount of other biodegradable waste, including packaging, cartons and cardboard, newsprint, textiles and diapers. These waste fractions comprised 41%-w/w of the grey waste and produced 40–210 m 3 methane (total solids (TS)) −1 and less than 0.01 g NH 4-N kg TS −1 added except diapers which produced 9.8 g NH 4-N kg TS −1 added in the batch assays. In the case of the two sieved fractions and on mass bases, most of the methane originated from the oversized fraction, whereas most of the NH 4-N was solublised from the undersized fraction. The first-order kinetic model described rather well the degradation of each grey waste fraction and component, showing the different components to be in the range 0.021–0.058 d −1, which was around one-sixth of the values reported for the source-segregated putrescible fraction of MSW.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2004.03.009