Bioethanol Production from Tea Waste as a Basic Ingredient in Renewable Energy Sources

M. K. Afdhol, H. Lubis, Chalidah Pratiwi Siregar
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引用次数: 10

Abstract

Global demand for energy needs has increased due to the rapid development of the human population, raising the industrial prosperity in developing countries. Primary energy demand is still supplied from fossil fuels, such as oil, coal and natural gas. The utilization of fossil fuels will continuously enhance the effect of greenhouse gases in the atmosphere. On the other hand, the extent of the tea plantation area in Indonesia reached 53,009 Ha, so that it will reproduce a waste too. Thus, spent tea as bioetanol. In addition it contains cellulose fibres are quite high, environmentally friendly and economical. Bioethanol as motor vehicle fuels can reduce the addition of CO2 at atmosphere because the use of biomass for the production and usage of bioethanol can be considered as a closed cycle. According to this principle the buyer of CO2 from fuel combustion bioethanol originating from the CO2-based biomass will be reabsorbed by plants through photosynthesis reactions. As a result of this whole process is not accounted for emissions of CO2 liquid gas a greenhouse gas into the atmosphere. Bioethanol-cellulosa can reduce greenhouse gas emissions amounted to 80%. The process into products bioethanol via hydrolysis, fermentation, distillation and characterization using Gas Chromatography-Mass Spectrometry (GC-MS). Them is the optimal bioethanol levels produced from fermented inoculant 1% amounting to 8.2% and optimal levels of bioethanol produced from hydrolysis of 8% H2SO4 results amounted to 8.2%, thus optimumsitas the ethanol produced from 8% acid and 1% inoculant apply to have levels of ethanol amounted to 8.2%. The product program could be developed into bioethanol solvent to dissolve the oil that is waxy crude oil.
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茶叶废弃物作为可再生能源的基本原料生产生物乙醇
由于人口的快速发展,全球对能源需求增加,提高了发展中国家的工业繁荣。初级能源需求仍然由石油、煤炭和天然气等化石燃料提供。化石燃料的利用将不断增强大气中温室气体的影响。另一方面,印度尼西亚的茶园面积达到53009公顷,因此它也将繁殖废物。因此,用茶作为生物乙醇。此外,它含有相当高的纤维素纤维,环境友好和经济。生物乙醇作为机动车辆燃料可以减少大气中二氧化碳的添加,因为使用生物质生产和使用生物乙醇可以被视为一个封闭的循环。根据这一原理,来自燃料燃烧的CO2的购买者来源于基于CO2的生物质的生物乙醇将通过光合作用反应被植物重新吸收。由于整个过程没有考虑到二氧化碳液体气体的排放,这是一种温室气体进入大气。生物乙醇纤维素可以减少80%的温室气体排放。通过水解、发酵、蒸馏和使用气相色谱-质谱(GC-MS)进行表征来生产生物乙醇的过程。它们是由1%的发酵接种物产生的最佳生物乙醇水平达8.2%和由8%H2SO4水解产生的最佳生命乙醇水平达8.2%,因此,用8%的酸和1%的接种剂生产乙醇的最佳工艺条件是乙醇含量达到8.2%。该产品程序可以开发成生物乙醇溶剂来溶解含蜡原油。
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10
审稿时长
8 weeks
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