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Batch Reactor Pyrolysis of Stabilized Sewage Sludge: Product Analysis and Sulphur Balance.

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    0501328 - ÚCHP 2019 RIV GB eng C - Conference Paper (international conference)
    Moško, Jaroslav - Pohořelý, Michael - Skoblia, S. - Beňo, Z. - Bičáková, Olga - Václavková, Šárka - Šyc, Michal - Svoboda, Karel
    Batch Reactor Pyrolysis of Stabilized Sewage Sludge: Product Analysis and Sulphur Balance.
    Wit Transactions on Ecology and the Environment. Vol. 231. Southampton: WIT Press, 2019, s. 357-365. ISBN N. E-ISSN 1743-3541.
    [International Conference on Waste Management and the Environment /9./. Seville (ES), 17.09.2018-19.09.2018]
    R&D Projects: GA TA ČR(CZ) TH03020119; GA MZe(CZ) QK1820175
    Grant - others:AV ČR(CZ) StrategieAV21/3
    Program: StrategieAV
    Institutional support: RVO:67985858 ; RVO:67985891
    Keywords : sewage sludge * sludge-derived biochar * pyrolysis * mass balance
    OECD category: Energy and fuels; Bioproducts (products that are manufactured using biological material as feedstock) biomaterials, bioplastics, biofuels, bioderived bulk and fine chemicals, bio-derived novel materials (USMH-B)

    Prior to sewage sludge application to agricultural soil, the sludge should be treated appropriately to suppress its negative features like content of microorganic pollutants or leaching heavy metals. Pyrolysis has been investigated as one way of producing sewage sludge-derived biochar (solid pyrolysis residue) which is stable and less toxic than sewage sludge. A significant amount of heat must be provided to the pyrolysis process due to its endothermic character. To make the process economically and energy efficient, the necessary heat can be obtained by the combustion of primary pyrolysis products (pyrolysis oil and gas), however in the case of sewage sludge, attention must be paid to the resulting gaseous pollutants due to high nitrogen and sulphur content. Slow pyrolysis of stabilized sewage sludge in inert helium atmosphere was performed at temperatures 400–800°C in order to examine the influence of pyrolysis temperature on the properties of pyrolysis products and sulphur
    distribution amongst these products. Pyrolysis at higher temperatures resulted in lesser biochar yield and promoted gas yield. At temperatures of 500°C and higher, over 50% of energy bound in the input sewage sludge was transformed to liquid and gas products. Finally, the effect of pyrolysis temperature on sulphur distribution amongst pyrolysis products was only marginal.
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