浸没燃烧一体化原油精馏塔的设计

A. Mamudu, E. Okonkwo, S. I. Okocha, E. Okoro, F. Elehinafe, K. Igwilo
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引用次数: 5

摘要

一般来说,石油精炼厂是利用物理分离和化学转化过程将未加工的原油转化或提炼成更有用的产品。虽然,不同的精炼装置是物理分离类别的子集。常减压蒸馏装置似乎更为突出。通常情况下,由于焦炭形成、管道堵塞、热裂和炉膛张力等原因,粗常压渣油不能在常压条件下进一步加热。因此需要一个真空精馏塔。因此,本研究的重点是限制,“过度紧张的炉提供必要的热量”和“不依赖额外的再锅炉,因为它只是作为一个热交换器”。因此,设计了一个容量为每天10,000桶的综合蒸馏塔,用于同时生产所有馏分。这是通过在塔的汽提段引入浸入式燃烧区来实现的,石脑油被用作燃料来源。还使用Autodesk发明软件和有限元分析工具对该方法进行了验证,以评估热分析和计算流体分析的影响。总体而言,所有衍生蒸馏产品都符合美国检验和材料协会标准表6。
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The Design of an Integrated Crude Oil Distillation Column with Submerged Combustion Technology
Generally, Petroleum refineries are put in place to convert or refine unprocessed crude oil into more useful products using both physical separation and chemical conversion processes. Albeit, different refining unit are subsets of the physical separation category. The atmospheric and vacuum distillation unit seems to be more prominent. Conventionally, the crude atmospheric residue cannot be further heated in an atmospheric condition due to: coke formation, pipes plugging, thermal cracking and straining of the furnace. A vacuum distillation column is therefore required. This study, therefore, focuses on the limitations, “over straining of the furnace to provide the necessary heat” and “non-reliance on the additional re-boiler since it only acts as a heat exchanger”. An integrated distillation column with a capacity of 10,000 barrel per day was therefore designed for the concurrent production of all distillate cuts. This was achieved through the introduction of a submerged combustion zone at the stripping section of the column where Naphtha was utilized as the source of fuel. Verification of this approach was also conducted using Autodesk invention software and a finite element analysis tool to evaluate both thermal and computational fluid analysis impact. Overall, all derived distilled products met the American Society for Testing and Material Standard Table 6.
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