Evaluation of Properties of Pellets Made of Swine Manure

BAPPAH, M. – BRADNA, J. – VELEBIL, J. – MALAŤÁK, J. 2019. The potential of energy recovery from by-products of small agricultural farms in Nigeria. In Agronomy Research, vol. 17, no. 6, pp. 2180–2186.Search in Google Scholar

CARROLL, J. P. – FINNAN, J. 2012. Physical and chemical properties of pellets from energy crops and cereal straws. In Biosystem Engineering, vol. 112, no. 2, pp. 151–159.Search in Google Scholar

DUMITRASCU, R. – LUNGULEASA, A. – SPIRCHEZ, C. 2018. Renewable pellets obtained from aspen and birch bark. In BioResources, vol. 13, no. 3, pp. 6985–7001.Search in Google Scholar

GARCÍA-MARAVER, A. – RODRIGUEZ, M. L. – SERRANO-BERNARDO, F. – DIAZ, L. F. – ZAMORANO, M. 2015. Factors affecting the quality of pellets made from residual biomass of olive trees. In Fuel Processing Technology, vol. 129, pp. 1–7.Search in Google Scholar

HUANG, Y. – FINELL, M. – LARSSON, S. – WANG, X. – ZHANG, J. – WEI, R. – LIU, L. 2017. Biofuel pellets made at low moisture content – Influence of water in the binding mechanism of densified biomass. In Biomass and Bioenergy, vol. 98, pp. 8–14.Search in Google Scholar

JANDAČKA, J. – HOLUBČÍK, M. – MALCHO, M. – NOSEK, R. 2013. Modification of wood pellets parameters by using of organic compounds from defibration. In Acta Facultatis Xylologiae Zvolen, vol. 55, no. 2, pp. 105–115. (In Slovak: Modifikácia vlastností drevných peliet aplikáciou koncentrátu organických látok z defibrácie).Search in Google Scholar

JIANG, L. B. – LIANG, J. – YUAN, X. Z. – LI, H. – LI, C. – XIAO, Z. H. – HUANG, H. – WANG, H. – ZENG, G. M. 2014. Co-pelletization of sewage sludge and biomass: The density and hardness of pellet. In Bioresource Technology, vol. 166, pp. 435–443.Search in Google Scholar

JIANG, L. B. – YUAN, X. Z. – LI, H. – CHEN, X. H. – XIAO, Z. H. – LIANG, J. – LENG, L. J. – GUO, Z. – ZENG, G. M. 2016. Co-pelletization of sewage sludge and biomass: Thermogravimetric analysis and ash deposits. In Fuel Processing Technology, vol. 145, pp. 109–115.Search in Google Scholar

KUBÍK, Ľ. – KAŽIMÍROVÁ, V. 2015. Determination of mechanical properties of apple cultivar Golden Delicious. In Journal on Processing and Energy in Agriculture, vol. 19, no. 1, pp. 17–20.Search in Google Scholar

LEE, Y. L. – AHMED, O. H. – WAHID, S. A. – AB AZIZ, Z. F. 2019. Characterization of tablets made from mixture of charred agricultural residues with and without embedded fertilizer. In Acta Technologica Agriculturae, vol. 22, no. 3, pp. 70–74.Search in Google Scholar

MARTÍNEZ-GUIDO, S. I. – RÍOS-BADRÁN, I. M. – GUTIÉRREZ-ANTONIO, C. – PONCE-ORTEGA, J. M. 2019. Strategic planning for the use of waste biomass pellets in Mexican power plants. In Renewable energy, vol. 130, pp. 622–632.Search in Google Scholar

OLOSO, A. O. – CLARKE, B. 1993. Some aspects of strength properties of cashew nuts. In Journal of Agricultural Engineering Research, vol. 55, no. 1, pp. 27–43.Search in Google Scholar

PAMPURO, N. – BAGAGIOLO, G. – PRIARONE, P. C. – CAVALLO, E. 2017. Effects of pelletizing pressure and the addition of woody bulking agents on the physical and mechanical properties of pellets made from composted pig solid fraction. In Powder Technology, vol. 311, pp. 112–119.10.1016/j.powtec.2017.01.092Search in Google Scholar

PAMPURO, N. – FACELLO, A. – CAVALLO, E. 2013. Pressure and specific energy requirements for densification of compost derived from swine solid fraction. In Spanish Journal of Agricultural Research, vol. 11, no. 3, pp. 678–684.Search in Google Scholar

PUROHIT, P. – CHATURVEDI, V. 2018. Biomass pellets for power generation in India: a techno-economic evaluation. In Environmental Science and Pollution Research, vol. 25, no. 29, pp. 29614-29632.Search in Google Scholar

SAID, N. – ABDEL DAIEM, M. M. – GARCÍA-MARAVER, A. – ZAMORANO, M. 2015. Influence of densification parameters on quality properties of rice straw pellets. In Fuel Processing Technology, vol. 138, pp. 56–64.Search in Google Scholar

SPIRCHEZ, C. – LUNGULEASA, A. – GACEU, L. 2019. Researches on grape husk waste obtained from the winery and its use as pellets for combustion. In Wood Research, vol. 64, no. 3, pp. 557–564.Search in Google Scholar

VURSAVUŞ, K. – ÖZGÜVEN, F. 2004. Mechanical behaviour of apricot pit under compression loading. In Journal of Food Engineering, vol. 65, no. 2, pp. 255–261.Search in Google Scholar

ZAFARI, A. – KIANMEHR, M. H. 2012. Effect of temperature, pressure and moisture content on durability of cattle manure pellet in open-end die method. In Journal of Agricultural Science, vol. 4, no. 5, pp. 203–208.Search in Google Scholar

ZAMORANO, M. – POPOV, V. – RODRÍGUES, M. L. – GARCÍAMARAVER, A. 2011. A comparative study of quality properties of pelletized agricultural and forestry lopping residues. In Renewable Energy, vol. 36, pp. 3133–3140.Search in Google Scholar

ZHAI, Y. – WANG, T. – ZHU, Y. – PENG, C. – WANG, B. – LI, X. – LI, C. – ZENG, G. 2018. Production of fuel pellets via hydrothermal carbonization of food waste using molasses as a binder. In Waste Management, vol. 77, pp. 185–194.Search in Google Scholar