基于na -膨润土和NTT土灰岩的棕榈油热裂解转化为燃料生物汽油

Daniel Silalahi, M. Supeno, M. Taufik
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引用次数: 0

摘要

采用膨润土和石灰石基催化剂对催化棕榈油进行皂化预处理,将其裂解为碳氢燃料。采用钠基膨润土和石灰石NTT作为催化剂,采用XRF、XRD和SEM对催化剂进行了分析。对CPO进行皂化预处理,以促进催化剂催化裂化过程。然后用DSC分析肥皂和甘油混合物形式的皂化产物,以确定降解温度。催化裂化分两个阶段进行,第一阶段采用不锈钢反应器,在250 ~ 350℃的温度下加氢裂化,为Fe / Cr催化剂的来源,所得馏出物再采用na -膨润土催化剂和TKNTT催化剂裂化。得到的燃料是一种碳氢化合物燃料,从FT-IR结果证实,表明存在长链碳氢化合物。这一数据也得到了GC-MS分析结果的支持,GC-MS分析结果表明,生产的燃料馏分主要是生物汽油。其中,使用na -膨润土催化剂裂解,生物汽油馏分为61.36%,生物柴油馏分为38.63%,生物汽油馏分为88.88%,生物柴油馏分为11.11%。经分析的烃类燃料的特性表明,燃烧热值为6101 cal/g(用弹式量热计测定),十六烷指数为62(用CCI测定)。根据SNI标准,这两种碳氢化合物燃料都满足生物汽油燃料必须具备的物理要求。
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Conversion of Palm Oil (CPO) into Fuel Biogasoline through Thermal Cracking Using a Catalyst Based Na-Bentonite and Limestone of Soil Limestone NTT
Cracking catalytic palm oil (CPO) into hydrocarbon fuel by saponification pretreatment has been carried out with bentonite and limestone-based catalysts. The catalysts used were Na-bentonite and Limestone NTT which were first analyzed using XRF, XRD, and SEM. Saponification pretreatment was carried out on CPO to facilitate the cracking process using a catalyst. The saponification product in the form of a mixture of soap and glycerol was then analyzed by DSC to determine the degradation temperature. Catalytic cracking is carried out in two stages, namely, the first stage hydrocracking at a temperature of 250-350°C using a stainless steel reactor is the source of catalyst Fe / Cr. The resulting distillate was then cracked again using a Na-bentonite catalyst and a TKNTT catalyst. The resulting fuel is a hydrocarbon fuel which is confirmed from the FT-IR results which indicate the presence of long-chain hydrocarbon compounds. This data is also supported by the results of the GC-MS analysis which shows that the fuel fraction produced is mostly biogasoline. Where cracking using a Na-bentonite catalyst produces a biogasoline fraction of 61.36% and a biodiesel fraction of 38.63%, THAT produces a biogasoline fraction of 88.88% and a biodiesel fraction of 11.11%. The characteristics of the hydrocarbon fuels that have been analyzed show that the calorific value of combustion is 6101 cal/g which is determined using a bomb calorimeter, and the cetane index is 62 which is analyzed using CCI. Both types of hydrocarbon fuels have met the physical requirements that must be possessed by biogasoline fuel based on SNI standards.
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