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W2283062015 abstract "Energy conversion efficiencies of three pyrolysis reactors (bench-scale auger, batch, and fluidized bed) were investigated using rice straw as the feedstock at a temperature of 500 °C. The highest bio-oil yield of 43% was obtained from the fluidized bed reactor, while the maximum bio-char yield of 48% was obtained from the batch reactor. Similar bio-oil yields were obtained from the auger and batch type reactors. The GCMS and FTIR were used to evaluate the liquid products from all reactors. The best quality bio-oil and bio-char from the batch reactor was determined to have a heating value of 31 MJ/kg and 19 MJ/kg, respectively. The highest alkali mineral was found in the bio-char produced from the auger reactor. The energy conversion efficiencies of the three reactors indicated that the majority of the energy (50–64%) was in the bio-char products from the auger and batch reactors, while the bio-oil from the fluidized bed reactor contained the highest energy (47%). A Sankey diagram has been produced to show the flows of product energy from each pyrolysis process. The result will help determine which conversion process would be optimal for producing specific products of bio-char, bio-oil, and gas depending on the needs." @default.
W2283062015 created "2016-06-24" @default.
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W2283062015 date "2015-12-01" @default.
W2283062015 modified "2023-10-18" @default.
W2283062015 title "Experimental investigation of pyrolysis of rice straw using bench-scale auger, batch and fluidized bed reactors" @default.
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W2283062015 cites W1644238398 @default.
W2283062015 cites W1964235881 @default.
W2283062015 cites W1968177263 @default.
W2283062015 cites W1973334650 @default.
W2283062015 cites W1973982799 @default.
W2283062015 cites W1981464036 @default.
W2283062015 cites W1985368183 @default.
W2283062015 cites W1986669412 @default.
W2283062015 cites W1987651393 @default.
W2283062015 cites W1987949369 @default.
W2283062015 cites W1998289285 @default.
W2283062015 cites W1998923918 @default.
W2283062015 cites W2002046865 @default.
W2283062015 cites W2002635816 @default.
W2283062015 cites W2003613100 @default.
W2283062015 cites W2005366922 @default.
W2283062015 cites W2005634799 @default.
W2283062015 cites W2014053414 @default.
W2283062015 cites W2021916337 @default.
W2283062015 cites W2021972903 @default.
W2283062015 cites W2022029535 @default.
W2283062015 cites W2024814920 @default.
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W2283062015 cites W2030025157 @default.
W2283062015 cites W2032451665 @default.
W2283062015 cites W2037878883 @default.
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W2283062015 cites W2049572203 @default.
W2283062015 cites W2052346332 @default.
W2283062015 cites W2053814173 @default.
W2283062015 cites W2055748013 @default.
W2283062015 cites W2069976588 @default.
W2283062015 cites W2074278999 @default.
W2283062015 cites W2074968070 @default.
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W2283062015 doi "https://doi.org/10.1016/j.energy.2015.10.028" @default.
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