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Process for extracting C4-C6 normal paraffins and coproducing isopentane and heterogeneous hexane cooperatively produced from light naphtha

A technology for n-alkane and light naphtha, which is applied in the petroleum industry, hydrocarbon oil treatment, adsorption purification/separation, etc. The effect of high separation, reduced energy consumption, and accelerated desorption rate

Inactive Publication Date: 2013-08-21
NANJING UNIV OF TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0006] CN101148390A and CN101134703A are all inventions of this laboratory. Since the use of inert gas desorption requires subsequent condensation temperature to be below zero, high condensation pressure is required, and energy consumption and equipment investment are relatively large
However, the combined desorption process using high-carbon C4-C6 normal alkanes in the gas phase as a desorbent and isoparaffins as a regenerating agent has not been reported, and the process can co-produce high-purity isopentane and isohexane as required, reducing energy consumption. greatly reduced, so on the basis of laboratory research, the invention of the process

Method used

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  • Process for extracting C4-C6 normal paraffins and coproducing isopentane and heterogeneous hexane cooperatively produced from light naphtha
  • Process for extracting C4-C6 normal paraffins and coproducing isopentane and heterogeneous hexane cooperatively produced from light naphtha
  • Process for extracting C4-C6 normal paraffins and coproducing isopentane and heterogeneous hexane cooperatively produced from light naphtha

Examples

Experimental program
Comparison scheme
Effect test

Embodiment example 1

[0025] Implementation Case 1: A petrochemical enterprise hydrocracked light naphtha as raw material, and the main composition of light naphtha is shown in Table 1:

[0026] Table 1 Composition of Light Naphtha

[0027]

[0028]

[0029] Table 2 shows the time distribution of the PSA cycles in the four towers: one PSA cycle is 24 minutes, and the specific time distribution for each stage is shown in Table 2.

[0030] Table 2 Four-tower pressure swing adsorption cycle schedule

[0031]

[0032] [Note]: A-adsorption, ED-average pressure drop, R-displacement, V-desorption, ER-average pressure rise, H-regeneration

[0033] Separation of normal paraffins in light naphtha based on pressure swing adsorption process figure 1 , Adsorption: V3 storage tank light naphtha raw material, through the advection pump P3 into the vaporization chamber E3, gasification at 150 ℃ and 0.4MPa (gauge pressure), the gasified light naphtha enters T1 through pipeline 1; Pressure drop, after th...

Embodiment example 2

[0039] Implementation case 2: Separation of catalytic cracking naphtha in a petrochemical enterprise. Process flow is similar to example 1.

[0040] The adsorption temperature is 450°C, the adsorption pressure is 3MPa (gauge pressure), the desorption temperature is 450°C, the desorption pressure is 1MPa (gauge pressure), and the desorption space velocity is 2000h -1 , the regeneration temperature is 450°C, the regeneration pressure is 2MPa (gauge pressure), the regeneration space velocity is 2000h-1, the desorbent is a mixed component of n-heptane and n-hexane, and after the desorption is completed, C4-C6 isomeric alkanes are used to desorb the bed regeneration. The number of effective plates of the rectification towers T5, T6 and T7 is 120, 120 and 150 respectively, and the final product purity is shown in Table 4.

[0041] The purity of each component after table 4 rectification

[0042]

Embodiment example 3

[0043] Implementation case 3: Using a factory reformed topping oil as raw material, the composition of the raw material is shown in Table 5.

[0044] Table 5 Composition of reformed top oil

[0045]

[0046]

[0047] The four-tower pressure swing adsorption separation process is still used, and the adsorption process is similar. During desorption, n-octane with stronger adsorption force is used as the desorption agent, and the desorption rate and desorption effect of the gas phase and the liquid phase are compared. Bed regeneration uses isopentane as regenerant.

[0048] When the desorbent with the same liquid phase flow rate is used for desorption, the gas phase desorption after gasification and the direct liquid phase desorption rate are compared for example Figure 4 shown, from Figure 4 It can be seen that the gas phase desorption rate is significantly greater than the liquid phase desorption rate, and the maximum desorption rate is reached within 5 minutes, while...

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Abstract

The invention relates to a chemical separation process and in particular relates to a process for extracting C4-C6 normal paraffins and coproducing isopentane and heterogeneous hexane from light naphtha. A multi-tower variable pressure adsorption and distillation separation coupling process is adopted by the invention. The process comprises the following steps of: introducing mixed gaseous C4-C6 normal paraffins and isohydrocarbons serving as raw materials into an adsorption tower for adsorption and separation; desorbing a bed by taking gaseous C7-C9 normal paraffins as a desorption reagent after the adsorption ends; introducing the desorbed material into a rectifying tower to separate out the product C4-C6 normal paraffins and the desorption reagent C7-C9 normal paraffins; recycling the desorption reagent; then regenerating the adsorption tower which absorbs the C7-C9 normal paraffins by using the un-adsorbed C4-C6 isohydrocarbons; and rectifying and separating the regenerated material twice to obtain high-purity desorption reagent C7-C9 normal paraffins, high-purity isopentane and high-purity heterogeneous hexane. By adopting the process disclosed by the invention, normal paraffins and isohydrocarbons can be effectively separated; the adsorbent is easy to regenerate; the process flow is simple and economic benefit is high; and the energy consumption in the process disclosed by the invention is greatly reduced in comparison with the energy consumption in other desorption processes.

Description

Technical field: [0001] The invention relates to a chemical separation process, in particular to a process for extracting C4-C6 normal alkanes in light naphtha and co-producing isopentane and isohexane. Background technique: [0002] Light naphtha is one of the products of hydrocracking in the aromatics complex. Since most hydrogen production units use natural gas to produce hydrogen, light naphtha is mainly used as raw material for cracking ethylene production and gasoline blending material. Because the isoparaffins in the naphtha are too high, it is not suitable as a raw material for steam cracking to produce ethylene; as a gasoline blending material, because of its high content of n-paraffins, it affects the octane number of oil products. Therefore, the rational separation of n-isoparaffins in light naphtha is of great significance for improving the comprehensive utilization value of light naphtha, integrating optimized light naphtha resources, and increasing the economic...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C10G53/00C07C9/18C07C9/15C07C7/12C07C7/04
Inventor 崔群王海燕殷飞戚龙浩
Owner NANJING UNIV OF TECH
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