Res. Agr. Eng., 2015, 61(1):21-28 | DOI: 10.17221/59/2013-RAE

Hydrothermal carbonization of stabilized sludge and meat and bone mealOriginal Paper

J. Malaȇk, T. Dlabaja
Department of Technological Equipment of Buildings, Faculty of Engineering, Czech University of Life Sciences Prague, Prague, Czech Republic

Hydrothermal carbonization is one of suitable methods for energy recovery of sewage sludge and meat and bone meal. The task of the article is to determine appropriate hydrothermal carbonization process conditions and their impact on the quality of the final product - so called biochar or hydrochar. Parameters of the two main phases - initiation and polymerization - were monitored. The basic fuel properties of the final solid products of hydrothermal carbonization were determined. To produce biochar by hydrothermal carbonization, multifunctional pressure vessel with accessories was used - a batch reactor BR-300. Process parameters of hydrothermal carbonization confirm the effect of increasing temperature to increase the lower heating value (LHV). Neither calorific values of meat and bone meal (17.22 MJ/kg), nor calorific values of digested stabilized sludge (12.14 MJ/kg) showed a significant increase after undergoing processing. The effect of reaction temperature on the LHV of the final product is significantly higher than that of residence time. The results show that the main factor affecting LHV of the fuel sample is the final amount of ash. Unlike the meat and bone the hydrothermal carbonization of the stabilized wastewater sludge is one of the effective processing methods for subsequent energy use.

Keywords: biochar; hydrochar; wet pyrolysis; biomass; heating value; stoichiometry

Published: March 31, 2015  Show citation

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Mala»ák J, Dlabaja T. Hydrothermal carbonization of stabilized sludge and meat and bone meal. Res. Agr. Eng. 2015;61(1):21-28. doi: 10.17221/59/2013-RAE.
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    References

    1. Antonietti M., Titirici M.M. (2010): Coal from carbohydrates: The "chimie douce" of karbon. Comptes Rendus Chimie, 13: 167-173. Go to original source...
    2. CZSO (2012): Sewage sludge. Czech Statistical Office. Available at http://www.czso.cz/csu/2012edicniplan.nsf/engt/F3001D390E/$File/w20031211.pdf
    3. Funke A., Ziegler F. (2011): Heat of reaction measurements for hydrothermal carbonization of biomass. Bioresource Technology, 102: 7595-7598. Go to original source... Go to PubMed...
    4. González I.O., Pastor R.P., Hervás J.S. (2012): Sampling of tar from sewage sludge gasification using solid phase adsorption. Analytical and Bioanalytical Chemistry, 403: 2039-2046. Go to original source... Go to PubMed...
    5. Gürdíl G., Mala»ák J., Selví K., Pinar Y. (2009): Biomass utilization for thermal energy. AMA, Agricultural Mechanization in Asia, Africa and Latin America, 2: 80-85.
    6. Hartman M., Svoboda K., Pohoøelý M., Trnka O. (2005): Combustion of dried sewage sludge in a fluidized-bed reactor. Industrial and Engineering Chemistry Research, 44: 3432-3441. Go to original source...
    7. Hartman M., Svoboda K., Veselý V., Trnka O., Chour J. (2003): Sewage sludge thermal processing. Chemické Listy, 97: 976-982.
    8. He C.H., Giannis A., Wang J.Y. (2013): Conversion of sewage sludge to clean solid fuel using hydrothermal carbonization: Hydrochar fuel characteristics and combustion behavior, Applied Energy, 111: 257-266. Go to original source...
    9. Judex J.W., Gaiffi M., Burgbacher H.C. (2012): Gasification of dried sewage sludge: Status of the demonstration and the pilot plant. Waste Management, 32: 719-723. Go to original source... Go to PubMed...
    10. Kobayashi N., Nomura S., Fujimura Y., Tsuboi H., Kimoto T., Itaya Y. (2011): Effect of hydrothermal condition on the characteristics of sludge. Kagaku Kogaku Ronbunshu, 37: 460-467. Go to original source...
    11. Malaȇk J., Passian L. (2011): Heat-emission analysis of small combustion equipments for biomass. Research in Agricultural Engineering, 57: 37-50. Go to original source...
    12. Rillig M.C., Wagner M., Salem M., Antunes P.M., Georgie C., Ramke H.G., Titirici M.M., Antonietti M. (2010): Material derived from hydrothermal carbonization: Effects on plant growth and arbuscular mykorrhiza. Applied Soil Ecology, 45: 238-242. Go to original source...
    13. Seggiani M., Vitolo S., Puccini M., Belini A. (2012): Cogasification of sewage sludge in an updraft gasifier. Fuel, 93: 486-491. Go to original source...
    14. Titirici M.M., Antonietti M. (2010): Chemistry and materials options of sustainable carbon materials made by hydrothermal carbonization. Chemical Society Reviews, 39: 103-116. Go to original source... Go to PubMed...
    15. Werthera J., Obadav T. (1999): Sewage sludge combustion. Progress in Energy and Combustion Science, 25: 55-116. Go to original source...
    16. Zhai Y., Peng W., Zeng G., Fu Z., Lan, Y., Chen H., Wang C., Fan X. (2012): Pyrolysis characteristics and kinetics of sewage sludge for different sizes and heating rates. Journal of Thermal Analysis and Calorimetry, 107: 1015-1022. Go to original source...
    17. Zili J., Dawei M., Hongyan M., Yoshikawa K. (2010): Study on the hydrothermal drying technology of sewage sludge. Science China Technological Sciences, 53: 160-163. Go to original source...

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