What is the potential for utilizing the resources in sludge?

The successful strategy for water protection by biological wastewater treatment results in a sludge production of about 20 to 40 kg dry matter per population equivalent and year. In the context of regional material fluxes, sewage sludge has a low resource potential and a low pollution potential desp...

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Veröffentlicht in:	Water science and technology 2004-01, Vol.49 (10), p.1-10
1. Verfasser:	Kroiss, H
Format:	Artikel
Sprache:	eng
Schlagworte:	Agriculture Agronomy Biological effects Biological wastewater treatment Conservation of Natural Resources - economics Dry matter Environmental Pollution - prevention & control Farmers Farms Fertilizers Fluxes Food consumption Food processing industry Hygiene Mass flow Mineral fertilizers Nutrients Phosphorus Plant reliability Political science Psychology Quality assurance Risk Assessment Sewage - chemistry Sewage sludge Sludge Sociology Unions Waste Disposal, Fluid - economics Waste Disposal, Fluid - methods Wastewater treatment Water pollution Water protection
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description	The successful strategy for water protection by biological wastewater treatment results in a sludge production of about 20 to 40 kg dry matter per population equivalent and year. In the context of regional material fluxes, sewage sludge has a low resource potential and a low pollution potential despite the fact that it can be characterised as a sink, concentrating wastewater compounds. The mass flow of nutrients (N, P) in the sewage sludge is comparatively small as compared to the losses of nutrients in agriculture. The most valuable element in the sludge is phosphorus, as the availability of phosphorus for the production of low-cost mineral fertiliser is limited. The most economical means of P-recycling is agricultural sludge application, which can also be seen as the option with the lowest loss of all valuable compounds of the sludge, and the lowest increase of entropy. The reliability of this disposal route for the treatment plant operator depends on several major pre-requisites: * reliability in regard to hygiene * reliability in regard to long-term soil protection public acceptance (politicians, media) * acceptance by all parties involved in sludge application and its consequences (farmers, farmer unions, land owners, food industry, food trade, retailers, consumers, consumer associations, NGOs, etc.) Only the first two prerequisites can be based on scientific research and risk assessment. As a consequence, only for these two aspects can quality criteria and adequate procedures be developed and introduced into a legal framework and quality assurance procedures. The latter two pre-requisites must be addressed in terms of sociology, psychology and political science and have a strong educational aspect.
doi_str_mv	10.2166/wst.2004.0595
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source	MEDLINE; EZB-FREE-00999 freely available EZB journals
subjects	Agriculture Agronomy Biological effects Biological wastewater treatment Conservation of Natural Resources - economics Dry matter Environmental Pollution - prevention & control Farmers Farms Fertilizers Fluxes Food consumption Food processing industry Hygiene Mass flow Mineral fertilizers Nutrients Phosphorus Plant reliability Political science Psychology Quality assurance Risk Assessment Sewage - chemistry Sewage sludge Sludge Sociology Unions Waste Disposal, Fluid - economics Waste Disposal, Fluid - methods Wastewater treatment Water pollution Water protection
title	What is the potential for utilizing the resources in sludge?
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