SU982755A1 - Method of recuperation of organo chlorine substances - Google Patents

Description

one

The invention relates to the chemical industry, as well as to other industries where organochlorine substances are obtained or consumed.

There is a method of recovery of trichlorethylene, dichloroethane and chlorobenzene from the vapor-mixture by adsorption on the active carbon AP-3 1.

However, the use of AP-3 carbon for the recovery of organochlorine substances significantly different in their physicochemical 10 IMC properties leads to a relatively high consumption of the desorbing agent (for example, water vapor) and a decrease in the absorbing capacity of the adsorbent.

A known method for the recovery of volatile solvents with active carbons, in which, depending on the elasticity of the vapor of the solvents, is used COBLES with different B constants in the Dubinin equation 2.

A disadvantage of the known method is the use of industrial active carbons with a relatively low realizable activity as an adsorbent.

The purpose of the invention is to increase the realized activity of coal.

The goal is achieved by the fact that the recovery of organochlorine substances from exhaust gases is carried out by adsorption with active carbon taking into account the vapor pressure of the recovered substances using coal with a bulk density of 350-700 g / dm, while the adsorption of substances with vapor pressure in the range of 0.2 -14.0 mm. Hg Art. lead coal fraction with a bulk density of 350- 420 g / dm, the adsorption of substances with vapor pressure in the range of 14.0-60.0 mm Hg. Art. lead coal fraction with a bulk density of 420-450 g / dm, the adsorption of substances with vapor pressure in the range of 60.0-98.5 mm Hg. Art. lead coal fraction with a bulk density of 450-480 g / dm, the adsorption of substances with vapor pressure in the range of 98.5 - 304.0 mm Hg. Art. lead coal fraction with a bulk of 480-510 g / dm, the adsorption of substances with vapor pressure in the range of 304.0-1012.8 mm Hg. Art. lead coal fraction with a bulk density of 510-540 g / dm, the adsorption of substances with vapor pressure in the range of 1012.8-2528.0 mm Hg. Art. lead coal fraction with a bulk density of 540-570 g / dm, the adsorption of substances with vapor pressure in the range of 2528.0-3736.0 mm Hg. Art. lead coal fraction with a bulk density of 570-700 g / dm. The difference of the proposed method is that active carbon is used with a bulk density of 350-700 g / dm. The absorption of substances with the above vapor pressure is effected by coal fractions with bulk density, indicated above as intervals. Example 1. A steam-air mixture containing organochlorine substances, with an initial concentration of Co from 2 to 50 g / m, was passed through activated carbon by a known and proposed method. For dichloroethane, according to a known method, coal should be taken with a constant B) 0.8-1.2 X 10®, which corresponds to industrial activated carbon AR-B GOST 8703-74 (B, 1.0-10-6, bulk density 585 g / dm) According to the proposed method, a fraction with a bulk density of 450-480 g / dm is recommended for dichloroethane. For chlorobenzene, AR-B {E 1 ,, coal should be taken by a known method (bulk density 570 g / dm). The proposed method recommends a fraction with a density of 350-420 g / dm. Comparative data are given in Table. 1. As follows from the table. 1, the coal activity in the proposed method is 12–17% higher in dichloroethane and 19–59% in chlorobenzene than in the known method. Example 2. A steam-air mixture containing 2 g / m of trichlorobenzene was sent to an adsorber filled with a commercial fraction of separated coal AR-B. The AR-B product fraction with a bulk density of 407 g / dm is assembled by mixing separated coal fractions with a bulk density in the range of 350-420 g / dm. Coal regeneration was carried out with water vapor at 105 ° С. Realized the activity of the fraction of the separated coal was 2.8 mmol / g The activity of the original industrial coal AR-B (GOST 870374) with a bulk density of 570 g / cm is realized under similar conditions to 1.66 mmol / g, i.e., 68.7% less. The results of experimental data obtained in the cycle of adsorption - regeneration of organochlorine substances with their content in the steam-air mixture (Co) from 2 to 50 g / m for each group of organochlorine substances, characterized by numerical values of the elastic vapor range, on the optimal fractions of separated carbon are given in table. 2. As can be seen from the table. 2, the realizable activity of the optimal fraction of the separated coal in pairs of a particular organochlorine substance is higher than the realized activity of the original coal in pairs of the same substance by 10.2-89%. The experimental results show that the use of the proposed method for the recovery of organochlorine substances can increase the actual activity of coal in dichloroethane and chlorobenzene by 12-59% compared to the known method, and by 10.2-89% for a number of substances compared to using the original active carbon AR-B.

Dichloroethane i50- 802.50 2.13 3.18 Chlorobenzene 350-t202.52 2.11 3, 2.83 3.83 Z.Zb 2, 3.79 2.38

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Claims (2)

-CMCM 1. Invention 1. A method for recovering organochlorine substances from waste gases by adsorption with active carbon, taking into account the vapor pressure of the recovered substances, characterized in that the latter is used with a bulk density of 350-700 g / dm in order to increase the realized activity of coal. 2. The method according to claim 1, distinguished (icts. That the adsorption of substances with vapor pressure in the range of 0.2-14.0 mm Hg. Lead coal fraction with a bulk density of 350- 420 g / dm. 3. A method according to claim 1, characterized in that the adsorption of substances with vapor pressure in the range of 14.0-60.0 mm Hg is produced by a coal fraction with a bulk density of 420-450 g / dmz. 4. The method according to claim 1, characterized in that the adsorption of substances with vapor pressure in the range of 60.0-98.5 mm of mercury is effected by a fraction of coal with a bulk density of 450- 480 g / dm 5. The method according to claim 1, characterized in that the adsorption of substances with vapor pressure In the range e 98.5-304.0 mmHg are coal fractions with a bulk density of 480-510 g / dmz. 6. The method according to claim 1, characterized in that the adsorption of substances with vapor pressure in the range 304.0-1012 , 8 mm Hg are coal fraction with a bulk density of 510-540 g / dmz 7. Method according to claim 1, characterized in that the adsorption of substances with vapor pressure in the range of 1012.8-2528.0 mm Hg. lead coal fraction with a bulk density of 540-570 g / dm 8. The method according to claim 1, characterized in that the adsorption of substances with vapor pressure in the range of 2528.0-3736.0 mm Hg. Art. lead coal fraction with a bulk density of 570-700 g / dmz. Sources of information taken into account in the examination 1. "Industrial and sanitary cleaning of gases, 1976, No. 2, p. 18. 2. Carbon adsorbents and their application in industry, Perm, 1969, Part I, p. 26-38.