Abstract
Bioethanol synthesis techniques have been studied intensively due to the energy crisis and various environmental concerns. A two-step bioethanol production process was carried out multiple times in an unbaffled agitator tank. The parameters varied, including the fermentation temperature, the pH level, the amount of yeast, and the impeller type. Then, a simulation was used to obtain an image of the agitation behavior inside the agitator tank to compare the velocity profile of each type of impeller design. The impeller with eight blades was found to produce the highest flow velocity: 0.28 m/s. The highest concentration of bioethanol generated from the fermentation was 34 g/L, which was produced by using an eight-blade impeller at 30 °C, a pH level of 5, an agitation speed of 70 rpm, and 2 wt % yeast. The two-blade impeller produced the lowest bioethanol concentration, 18 g/L, under the same conditions. Ethanol concentration was found to peak at 40 °C and a pH level of 5. The geometry of the impeller, the fermentation temperature, and the pH level were each found to have a significant effect on the resulting bioethanol concentration according to the results of an ANOVA test. The amount of yeast had no effect on the fermentation reaction. Finally, the results demonstrated the possibility of using computational fluid dynamic modeling to determine the impeller’s behavior for the development of the bioethanol fermentation process. The simulation and experimental results from this research support the scaling up of a bioethanol production facility.
Highlights
The efficient production method for bio-fuel, such as bioethanol and biodiesel, from sustainable resources is mandatory for humanity today and in the near future [1]
In Thailand, the Ministry of Energy recognized the potential for bioethanol production from various biomass, such as sugar cane and agricultural wastes
Bioethanol is produced by fermentation of reduced sugar in aqueous solution inhabited by saccharomyces cerevisiae yeast, which
Summary
The efficient production method for bio-fuel, such as bioethanol and biodiesel, from sustainable resources is mandatory for humanity today and in the near future [1]. In Thailand, the Ministry of Energy recognized the potential for bioethanol production from various biomass, such as sugar cane and agricultural wastes. Kyoto protocols have been issued as an incentive to establish a production base in Thailand that is capable of generating at least 11.9 million liters of bioethanol daily by the year 2036 according to the Alternative Energy Development Plan [3]. Bioethanol is produced by fermentation of reduced sugar (glucose, xylose, and fructose) in aqueous solution inhabited by saccharomyces cerevisiae yeast, which. Energies 2020, 13, 5457 is the kind of yeast that is used to make bread. In the case of agricultural waste or biomass fermentation it is important for the carbohydrate in these materials to first be broken down to fermentable sugar through a hydrolysis process in acidic solution
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