Food waste hydrogen

Fermentative hydrogen production from food waste... [Pg.149]

Han, S.-K., Shin, H.-S. 2004. Biohydrogen production by anaerobic fermentation of food waste. Int J Hydrogen Energy 29 569-577. [Pg.41]

Shin, H. S., Youn, J. H., and Kim, S. H. 2004. Hydrogen production from food waste in anaerobic mesophilic and thermophilic acidogenesis. Int. J. Hydrogen Energy, 29, 1355-1363. [Pg.285]

Photo-biological Hydrogen Production from Food Waste... [Pg.47]

Fish raw material is primarily the whole fish, although fish oil is also extracted from the waste material from fish markets and canning factories. The enzymic breakdown of fish tissue is even more rapid than from the viscera of animals and has more pronounced effects on the oil and its downstream processing. Fish oils are highly unsaturated and are therefore more liable to oxidative breakdown. Virtually all fish oil for human food is hydrogenated and therefore it is particularly important that oxidation products and sulphur compounds, both of which are hydrogenation catalyst poisons. [Pg.183]

Over the last years food wastes have earned an increasing attention as feedstock for hydrogen production they include kitchen refuse, municipal wastes (a part of), food industry co-products (oil mill, cheese whey) and starch manufacturing wastes. Food wastes show high energy content (85—95% of volatile solids and 75—85% moisture) and high biodegradability, which favours microbial anaerobic development. [Pg.272]

Hydrogen and methane production from food waste 20.4.3.1 Hydrogen production... [Pg.633]

Chu, C.F., Xu, K.Q., Li, Y.Y., Inamori, Y., 2012. Hydrogen and methane potential based on the nature of food waste materials in a two-stage thermophilic fermentation process. International Journal of Hydrogen Energy 37 (14), 10611—10618. [Pg.646]

Han, S.K., Shin, H.S., 2004b. Performance of an innovative two-stage process converting food waste to hydrogen and methane. Journal of the Air Waste Management Association... [Pg.647]

Kim, D.H., Kim, M.S., 2013. Development of a novel three-stage fermentation system converting food waste to hydrogen and methane. Bioresource Technology 127, 267—274. [Pg.648]

Kim, S.H., Shin, H.S., 2008. Effects of base-pretreatment on continuous enriched culture for hydrogen production from food waste. International Journal of Hydrogen Energy 33 (19), 5266-5274. [Pg.648]

Kim, D.-H., Kim, S.-H., Kim, K.Y., Shin, H.-S., 2010. Experience of a pilot-scale hydrogen-producing anaerobic sequencing batch reactor (ASBR) treating food waste. International Journal of Hydrogen Energy 35 (4), 1590—1594. [Pg.648]

Kim, S.-H., Cheon, H.C., Lee, C.Y., 2012b. Enhancement of hydrogen production by recycling of methanogenic effiuent in two-phase fermentation of food waste. International Journal of Hydrogen Energy 37 (18), 13777—13782. [Pg.648]

Lee, Y.W., Chung, J., 2010. Bioproduction of hydrogen from food waste by phot-scale combined hydrogen/methane fermentation. International Jomnal of Hydrogen Energy 35 (21),... [Pg.649]

Liu, X.Y., Li, R.Y., Ji, M., Han, L., 2013. Hydrogen and methane production by co-digestion of waste activated sludge and food waste in the two-stage fermentation process substrate conversion and energy yield. Bioresource Technology 146, 317—323. [Pg.650]

Nathao, C., Sirisukpoka, U., Pisutpaisal, N., 2013. Production of hydrogen and methane by one and two stage fermentation of food waste. International Journal of Hydrogen Energy 38 (35), 15764-15769. [Pg.650]

Tawfik, A., El-Qelish, M., 2012. Continuous hydrogen production ftom co-digestion of municipal food waste and kitchen wastewater in mesophilic anaerohic hafQed reactor. Bioresource Technology 114, 270—274. [Pg.652]

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