SU941342A1 - Process for purifying aliphatic saturated hydrocarbons from mercaptanes and sulphides - Google Patents

Description

(S) METHOD FOR CLEANING ALIPHATIC SATURATED

HYDROCARBONS FROM MERCAPTANS AND SULFIDES

one

The invention relates to methods for purifying petroleum and gas condensate refined products from organic sulfur compounds, in particular to methods for purifying aliphatic saturated hydrocarbons from mercaptans and sulfides, and can be used in the refining and petrochemical industries.

Methods are known for the purification of hydrocarbons from organosulfur compounds by contacting the feedstock with natural adsorbents — zeolites, bauxites, and Cl and 2 clays.

Closest to the invention is a method of purifying aliphatic saturated hydrocarbons from organosulfur compounds, such as sulfides, by adsorbing the latter with natural clay, which uses palyhorskite activated with sulfuric acid 3.

However, the method is not characterized by a high degree of purity;

hydrocarbons from organo-sulfur compounds.

The purpose of the invention is to increase the degree of purification.

This goal is achieved in that according to the method of purification of aliphatic saturated hydrocarbons from mercaptans and sulfides by adsorbing them activated with Q, native clay palygorskite, palygorskite activated with barium chloride and calcined is used. .%. Example 1.8. Loading flask) 5 yards of palygorskite clay from the Cherkassy deposit and an aqueous solution of barium chloride in the ratio of sorbent: solution 1: 6. The activation is carried out at the boiling point of the solution for 2 hours.

20 Then the sorbent is washed from chlorine ions and dried. The resulting sorbent is subjected to heat treatment at 250C. Chemical compositions of the original .palygorskite clay, activated

0.05 n. 0.3 n, and a saturated solution of barium chloride and sulfuric acid are given in table. one.

A flask is charged with 2 g of palygorskite clay, activated with barium chloride and 50 ml of n-g, eksana containing ethyl mercaptan. Purification temperature 200s, atmospheric pressure. The mixture is vigorously stirred and set at a constant temperature. The initial and purified n-hexane is analyzed for the content of mercaptan sulfur by potentiometric titration. The results of the experiment are given in table. 2

Example 2. A flask is charged with 2 g of palygorskite clay, activated. a bath of barium chloride and 50 ml of n-hexane containing dimethyl sulfide. The purification conditions are similar to those of Example 1. The analysis of the initial and purified n-hexane for the content of sulfide sulfur is carried out by the method of potentiometric titration.

The results of the experiment are given in table. 3

Example 3 — A flask is charged with 2 g of palygorskite clay, activated with barium chloride and 50 ml of the Orenburg pentane-hexane fraction.

gas condensate containing mercaptans and sulfides. The conditions for purification and analysis are similar to those of example 1 and 2.

The results of the experiment are given in table. ,

The proposed method allows to significantly increase the degree of purification.

hydrocarbon raw materials from mercaptans and sulfides. The method can be used in the refining and petrochemical industries of the industry for the purification of mercaptans

and liquefied petroleum gas sulfides, a broad fraction of light hydrocarbons, pentane and hexane fractions and other similar products of oil refining and gas condensate. Using the proposed method in the purification processes of these types of hydrocarbon raw materials from mercaptans and sulphides by increasing the degree of purification allows to obtain

significant technical and economic effect. With the annual volume of hydrocarbons to be cleaned in only one unit with a capacity of 100 thousand tons, the economy is not

less than 100 thousand rubles.

clay S, activated 0.05 n. barium chloride solution containing 1.19 May,% barium oxide

Palygorskite clay, activated 0.3 and. barium chloride solution containing 1.75 wt.% barium oxide

Palygorskite clay, activated with a saturated solution of barium chloride, containing 3.85 May of barium oxide

Palygorskite clay, activated with sulfuric acid

Palygorskitova

0,282 clay 0,064

table 2

87.68

4.077 72.00 0.760

90.26

4,200 80,55 0,851

100

4.653 100, 056

86.17

4,009 68,75 0,726

73.76

3,426 57,81 0,610

Palygorskite clay, activated with 0.05 N, barium chloride solution, containing 1.19 May. barium oxides

Palygorskite clay, activated 0.3 n. barium chloride solution containing 1.75 May. ° / barium oxide

Palygorskite clay, activated with a saturated solution of barium chloride, containing 3.85 masa of barium oxide

Palygorskite clay, activated with sulfuric acid

Palygorskitova

0.076 clay 0.030

Table 3

5t, 51

0.68t 9.53

O., 4b8

57.11

0.716 96.39 0.77

57,89

0.726 99.00 0,

53.95

0.676 93.33 0,

52.63

0.660 70.00 0,

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Claims (3)

1. Lobanov G, A. et al. Use of zeolites for refining petroleum 13 2. sixteen products from mercaptans. Sat Properties and chemical transformations of hydrocarbons of Mangyshlak oils. Almaty, Science, 1975, p. 80. 5 2. N.N. etchings, et al., Adsorption and desorption of organosulfur compounds contained in petroleum and petroleum products. Sat Chemistry of organo-sulfur compounds contained in petroleum and petroleum products. M., Higher School, 1972, t. IX, p. ilS . 3. Lobanov G.A. and others. Sorption of sulfides by salt forms of ion exchangers and zeolites from organic solvents. ЖПХ, t. 50, No. 6, 1977, p. 327 (prototype).