On August 7,2015 the project"Development of package technology for producing biodiesel from microalgae",which was jointly undertaken by the SINOPEC Research Institute of Petroleum Processing(RIPP),the Fushun Resea...On August 7,2015 the project"Development of package technology for producing biodiesel from microalgae",which was jointly undertaken by the SINOPEC Research Institute of Petroleum Processing(RIPP),the Fushun Research Institute of Petroleum and Petrochemicals(FRIPP).展开更多
The hydrolysate of waste sludge was used as the feedstock of biodiesel production,and its technological feasibility was investigated.Waste sludge,collected from No.3 Municipal Wastewater Treatment Plant of Xi’an,was ...The hydrolysate of waste sludge was used as the feedstock of biodiesel production,and its technological feasibility was investigated.Waste sludge,collected from No.3 Municipal Wastewater Treatment Plant of Xi’an,was hydrolyzed in two parallel reactors firstly.Yeast was added into one reactor for bioaugmentation,and the other reactor without yeast was used as a control.Then an acid-catalyzed in situ esterification process was carried out to convert the hydrolysate to biodiesel.The results of hydrolysis showed that the reactor bioaugmented with yeast could promote hydrolysis compared with the control one because of an obvious variance in total suspended solid(TSS),volatile suspended solid(VSS)and soluble chemical oxygen demand(SCOD).Furthermore,gas chromatography(GC)analysis exhibited that the total volatile fatty acid(VFA)was low in the hydrolysate of bioaugmentation reactor;however,its yield of the fatty acid methyl esters(FAMEs)by in situ esterification was obviously higher when compared with the control one.Therefore,it may be inferred that the hydrolysate of bioaugmentation was mainly inclined to longer-chain fatty acid rather than to VFA.Anyway,an FAMEs yield of 9.24%(wt%)from dried sludge was attained after the 12-d bioaugmentation hydrolysis and succedent esterification.This value was not only higher than that of the control one but also higher than that reported in previous literature.The above results illuminated that it was feasible to produce biodiesel from the bioaugmented hydrolysate of waste sludge.展开更多
Biodiesel (fatty acid methyl ester) has been identified as a non-toxic biodegradable alternative fuel that is obtained from renewable sources. Over the last decade, there has been increasing interest in producing bi...Biodiesel (fatty acid methyl ester) has been identified as a non-toxic biodegradable alternative fuel that is obtained from renewable sources. Over the last decade, there has been increasing interest in producing biodiesel from conventional sources such as soybean, canola, sunflower, and coconut oils. Current efforts are directed towards the development of new non-edible resources. Among these Jatropha Curcas comes at the forefront. In Egypt, Jatropha Curcas has grown successfully using primary treated wastewater. Also, extensive R&D efforts identified the optimum conditions for the various processing stages namely crushing, extraction, transesterification and purification. Based on the research findings, the techno-economic appraisal of biodiesel production from Jatropha Curcas is conducted. Two nominal capacities namely 8,000 and 50,000 metric tons/yr have been proposed. Several scenarios have been formulated to take into consideration varying productivity (3.4 to 5.8 ton fruits per 4,000 m^2 (acre)) and varying recovery rates of oil from seeds. Economic indicators including capital and production costs for the various processing stages and revenues according to current prices of oil and cake have been obtained. The price of biodiesel that provides a simple rate of return (SRR) on investments of 10% was in the range of $0.3-0.7/liter for the different assumed scenarios which is lower than the prevailing price of biodiesel (about $1/liter) in the US. Thus, in view of experimental results and economic assumptions, there are positive prospects for the production of biodiesel from Jatropha Curcas under Egyptian conditions.展开更多
文摘On August 7,2015 the project"Development of package technology for producing biodiesel from microalgae",which was jointly undertaken by the SINOPEC Research Institute of Petroleum Processing(RIPP),the Fushun Research Institute of Petroleum and Petrochemicals(FRIPP).
基金Supported by Excellent Project from Shaanxi Administration of Foreign Expert Affairs in 2011International Cooperation Project of Shaanxi Province(No.2011KW-34)
文摘The hydrolysate of waste sludge was used as the feedstock of biodiesel production,and its technological feasibility was investigated.Waste sludge,collected from No.3 Municipal Wastewater Treatment Plant of Xi’an,was hydrolyzed in two parallel reactors firstly.Yeast was added into one reactor for bioaugmentation,and the other reactor without yeast was used as a control.Then an acid-catalyzed in situ esterification process was carried out to convert the hydrolysate to biodiesel.The results of hydrolysis showed that the reactor bioaugmented with yeast could promote hydrolysis compared with the control one because of an obvious variance in total suspended solid(TSS),volatile suspended solid(VSS)and soluble chemical oxygen demand(SCOD).Furthermore,gas chromatography(GC)analysis exhibited that the total volatile fatty acid(VFA)was low in the hydrolysate of bioaugmentation reactor;however,its yield of the fatty acid methyl esters(FAMEs)by in situ esterification was obviously higher when compared with the control one.Therefore,it may be inferred that the hydrolysate of bioaugmentation was mainly inclined to longer-chain fatty acid rather than to VFA.Anyway,an FAMEs yield of 9.24%(wt%)from dried sludge was attained after the 12-d bioaugmentation hydrolysis and succedent esterification.This value was not only higher than that of the control one but also higher than that reported in previous literature.The above results illuminated that it was feasible to produce biodiesel from the bioaugmented hydrolysate of waste sludge.
文摘Biodiesel (fatty acid methyl ester) has been identified as a non-toxic biodegradable alternative fuel that is obtained from renewable sources. Over the last decade, there has been increasing interest in producing biodiesel from conventional sources such as soybean, canola, sunflower, and coconut oils. Current efforts are directed towards the development of new non-edible resources. Among these Jatropha Curcas comes at the forefront. In Egypt, Jatropha Curcas has grown successfully using primary treated wastewater. Also, extensive R&D efforts identified the optimum conditions for the various processing stages namely crushing, extraction, transesterification and purification. Based on the research findings, the techno-economic appraisal of biodiesel production from Jatropha Curcas is conducted. Two nominal capacities namely 8,000 and 50,000 metric tons/yr have been proposed. Several scenarios have been formulated to take into consideration varying productivity (3.4 to 5.8 ton fruits per 4,000 m^2 (acre)) and varying recovery rates of oil from seeds. Economic indicators including capital and production costs for the various processing stages and revenues according to current prices of oil and cake have been obtained. The price of biodiesel that provides a simple rate of return (SRR) on investments of 10% was in the range of $0.3-0.7/liter for the different assumed scenarios which is lower than the prevailing price of biodiesel (about $1/liter) in the US. Thus, in view of experimental results and economic assumptions, there are positive prospects for the production of biodiesel from Jatropha Curcas under Egyptian conditions.