优化HDT条件降低环烷基基础油中Pca含量

IF 0.5 4区工程技术 Q4 ENERGY & FUELS

Ct&f-Ciencia Tecnologia Y Futuro Pub Date : 2010-06-30 DOI:10.29047/01225383.443

Maria Elizabeth Gómez, Liliana Santos, Néstor Tapias, Clemencia Vargas, J. Lizcano

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引用次数: 5

摘要

多环芳烃(Polycyclic Aromatics, PCA)是一种含有三个或三个以上芳香环的芳烃及其相关的硫、氮化合物，被认为是有毒化合物。PCA控制是一项复杂的任务，因为基础油的生产涉及不同的过程，有许多变量，如压力、温度、原料质量、催化剂等。研究了以加氢处理温度为主要变量对环烷基中PCA还原的影响。采用中试装置在不同温度下对某工业装置的两种环烷馏分进行了加氢处理。结果表明:随着加氢处理温度的升高，PCA减小;但在此温度以上存在一个最佳温度，芳香族氢化热力学平衡发生逆转，导致PCA含量增加。这些结果通过在两个工业反应器之间安装氢淬火装置来实现，以保证由于某些反应的放热特性，温度分布始终在最佳操作范围内。

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PCA REDUCTION IN NAPHTHENIC BASE OILS BY OPTIMIZING HDT CONDITIONS

Polycyclic Aromatics (PCA) are aromatic hydrocarbons and related sulphur and nitrogen compounds, containing three or more fused aromatic rings, which are considered as toxic compounds. PCA control is a complex task because the Base Oil production involves different processes with many variables such as pressure, temperature, feedstock quality, catalyst, etc. This study focuses on controlling the hydrotreating temperature as main variable in the reduction of PCA in Naphthenic Bases. Two Naphthenic distillate fractions taken from an industrial plant were hydrotreated in pilot plant at different temperatures. The results show that PCA are reduced as hydrotreating temperature increases; however there is an optimum temperature above it, the thermodynamic equilibrium of aromatic hydrogenation reverses, increasing as a result, the PCA content. These results were implemented in the industrial Unit by installing a hydrogen quench between the two industrial reactors to guarantee that the profile of temperature, due to exothermic character of some reactions, be always in the optimun operating range.

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来源期刊

Ct&f-Ciencia Tecnologia Y Futuro Energy-General Energy

CiteScore

1.50

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The objective of CT&F is to publish the achievements of scientific research and technological developments of Ecopetrol S.A. and the research of other institutions in the field of oil, gas and alternative energy sources. CT&F welcomes original, novel and high-impact contributions from all the fields in the oil and gas industry like: Acquisition and Exploration technologies, Basins characterization and modeling, Petroleum geology, Reservoir modeling, Enhanced Oil Recovery Technologies, Unconventional resources, Petroleum refining, Petrochemistry, Upgrading technologies, Technologies for fuels quality, Process modeling, and optimization, Supply chain optimization, Biofuels, Renewable energies.