The Experts below are selected from a list of 327 Experts worldwide ranked by ideXlab platform
Chun-zhu Li - One of the best experts on this subject based on the ideXlab platform.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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production and Fuel Properties of fast pyrolysis oil bio diesel blends
Fuel Processing Technology, 2010Co-Authors: Chun-zhu Li, Xiao Shan Wang, Jun Shen, Manuel GarciaperezAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported. © 2009 Elsevier B.V. All rights reserved.
Jun Shen - One of the best experts on this subject based on the ideXlab platform.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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production and Fuel Properties of fast pyrolysis oil bio diesel blends
Fuel Processing Technology, 2010Co-Authors: Chun-zhu Li, Xiao Shan Wang, Jun Shen, Manuel GarciaperezAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported. © 2009 Elsevier B.V. All rights reserved.
Xiao Shan Wang - One of the best experts on this subject based on the ideXlab platform.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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production and Fuel Properties of fast pyrolysis oil bio diesel blends
Fuel Processing Technology, 2010Co-Authors: Chun-zhu Li, Xiao Shan Wang, Jun Shen, Manuel GarciaperezAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
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Production and Fuel Properties of fast pyrolysis oil/bio-diesel blends
Fuel Processing Technology, 2010Co-Authors: Manuel Garcia-perez, Xiao Shan Wang, Jun Shen, Chun-zhu LiAbstract:This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported. © 2009 Elsevier B.V. All rights reserved.
Manuel Garciaperez - One of the best experts on this subject based on the ideXlab platform.
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production and Fuel Properties of fast pyrolysis oil bio diesel blends
Fuel Processing Technology, 2010Co-Authors: Chun-zhu Li, Xiao Shan Wang, Jun Shen, Manuel GarciaperezAbstract:Abstract This paper describes the production and Fuel Properties of fast pyrolysis oil/bio-diesel blends. The bio-oils used in this study were produced from the fast pyrolysis of woody biomasses, oil mallee and pine. The bio-diesel employed was derived from canola vegetable oil. The conditions used to prepare the bio-oil/bio-diesel blends, as well as some of the Fuel Properties of the resulting bio-diesel rich phase, are reported. The experimental results show that the solubility of fast pyrolysis oils in bio-diesel is not as high as was previously reported for decanted oils obtained by Auger pyrolysis. The carboxylic acids, mono-phenols, furans and lignin derived oligomers were the compounds most soluble in bio-diesel, while the sugars, on the other hand, showed poor solubility. Although the presence of phenols enhances the oxidation stability of the bio-diesel rich phases, other Fuel Properties deteriorate. For example, the content of solid residues increased primarily because of the solubilisation of lignin derived oligomers, which were quantified by UV-fluorescence. Concentrations as high as 3.5 mass % of these compounds were observed in the bio-diesel rich phase. The solubility of bio-oil in bio-diesel was enhanced by using ethyl acetate/bio-diesel blends. Some Fuel Properties of the bio-diesel rich phase, after the removal of ethyl acetate, are reported.
Kaustubha Mohanty - One of the best experts on this subject based on the ideXlab platform.
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Effect of catalytic vapour cracking on Fuel Properties and composition of castor seed pyrolytic oil
Journal of Analytical and Applied Pyrolysis, 2016Co-Authors: Mithelesh Koul, Krushna Prasad Shadangi, Kaustubha MohantyAbstract:Abstract In this work, catalytic upgrading was carried out to enhance the yield and quality of castor seed pyrolytic oil. The influence of catalytic vapour cracking of castor seed was performed over Kaolin, CaO and ZnO catalysts at various weight percentage of loading. This study confirmed that the yield varied with catalyst type and its amount of loading. The maximum pyrolysis yield of oil was obtained about 66.4 wt.%, 64.9 wt.% and 65.8 wt.% at 15 wt.% CaO and Kaolin and 10 wt.% ZnO respectively. The effect of catalyst on Fuel Properties were studied at that catalyst loading where the yield of pyrolytic liquid was higher. The Fuel Properties of castor seed thermal and catalytic pyrolytic oil were compared. The cracking of castor seed pyrolytic vapour over the bed of catalysts proved to enhance the Fuel Properties of pyrolytic oil for all catalysts. In comparison with ZnO, CaO and Kaolin found to have significant effect on enhancing the Fuel Properties in terms of viscosity, pH, calorific value and pour point. It was observed that in catalytic pyrolytic oil the number of acidic groups significantly reduced as they got converted to esters compared to thermal pyrolytic oil. The increase in the formation of nitriles and aromatics content in the catalytic pyrolytic oil was also noticed which were comparatively less in the thermal pyrolytic oil.
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Comparison of yield and Fuel Properties of thermal and catalytic Mahua seed pyrolytic oil
Fuel, 2014Co-Authors: Krushna Prasad Shadangi, Kaustubha MohantyAbstract:In this work, the production and evaluation of Fuel Properties of pyrolytic oil from one non-edible oil seed Mahua was reported. Both thermal and catalytic pyrolysis using CaO was carried out. The aim of the study was to detect the optimum temperature to produce maximum pyrolytic oil and to increase the quality of oil using catalyst. It was observed that thermal pyrolysis of Mahua seed at 525 C produced maximum yield of liquid. Hence the influence of catalyst was examined at the optimum temperature (525 C) on liquid yield and its Properties. The catalytic effect of CaO, on Mahua seed pyrolysis at a feed to catalyst ratio of 2:1, 4:1 and 8:1 was studied. The pyrolytic liquid collected was separated into two phases. The top phase (organic) was considered as oil phase where as the bottom phase as aqueous. Maximum yield of 40.71 wt.% of oil with better Fuel Properties was obtained as Mahua seed pyrolyzed in the presence of CaO at the ratio of 2:1. The result confirmed that catalyst (CaO) not only increased the heating value (41-43.15 MJ kg-1), viscosity (0.033-0.018 Pa s) and cold flow Properties but also altered the pH (4.86-8.58) significantly when compared with thermal pyrolysis. © 2013 Elsevier Ltd. All rights reserved.
