Biomethanol production and CO2 emission reduction from forage grasses, trees, and crop residues

With a wide array of potentially renewable energy resources, the concept and proposed benefits evolving from the use of biofuels are inspiring. Recently, a new approach for gasification of biomass by partial oxidation and subsequent biomethanol production has been developed and is being evaluated at...

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Published inJARQ. Japan agricultural research quarterly Vol. 41; no. 2
Main Authors Nakagawa, H.(National Inst. of Livestock and Grassland Science, Nasushiobara, Tochigi (Japan). Nasu Research Station), Harada, T, Ichinose, T, Takeno, K, Matsumoto, S, Kobayashi, M, Sakai, M
Format Journal Article
LanguageEnglish
Published 2007
Subjects
AGRICULTURAL WASTES
BIOCARBURANT
BIOCARBURANTE
BIOFUELS
BIOMASA
BIOMASS
BIOMASSE
CONTENIDO DE HUMEDAD
DECHET AGRICOLE
DESECHOS AGRICOLAS
FERMENTACION METANICA
FERMENTATION METHANIQUE
FORAGE
FORRAJES
FOURRAGE
GASIFICACION
GASIFICATION
GAZEIFICATION
METHANE FERMENTATION
MOISTURE CONTENT
PRODUCTOS DE LA MADERA
PRODUIT DERIVE DU BOIS
TENEUR EN EAU
WOOD PRODUCTS
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Summary:With a wide array of potentially renewable energy resources, the concept and proposed benefits evolving from the use of biofuels are inspiring. Recently, a new approach for gasification of biomass by partial oxidation and subsequent biomethanol production has been developed and is being evaluated at the 'Norin Green No.1 (renamed as Norin Biomass No.1)' test plant in Nagasaki, Japan. To determine a useful protocol for producing biomethanol, various kinds of biomass resources, such as sawdust and bark of Japanese cedar, chipped Japanese larch, bamboo, salix, cut waste wood from demolition sites, sorghum, and bran straw, and husks of rice were evaluated for their biofuel-use characteristics. From this analysis, lignocellulosic resources (wood materials) and rice bran were estimated to produce a high methanol yield (55% by weight), whereas rice straw and husks were estimated to produce lower methanol yield of 36% and 39%, respectively. On the basis of the data obtained from the test plant, the net heat yield by the methanol production of a full-scale commercial plant was estimated to be ca. 40%. Each of these products is a clean material, readily obtained and highly useful for biomethanol production. Developing nations interested in constructing a national energy policy should focus upon the establishment of a biofuel-based economy. Recycling of agricultural and forest industry by-products has been previously shown to reduce the demand for fossil fuels and provides a more ecologically friendly energy resource. Our research suggests that additional sources of biomethanol production could be developed through the utilization of cellulosic and lignocellulosic raw materials.
Bibliography:Q60
2007006905
J15
ISSN:0021-3551
DOI:10.6090/jarq.41.173