DE3048649A1 - Hydrocarbon, esp. halo-hydrocarbon recovery from activated charcoal - by hot desorption, removal and condensation, reducing energy consumption - Google Patents

Abstract

Recovery of (halo)hydrocarbons (I) adsorbed on activated charcoal (II) is effected by heating to a temp. below that at which (I) starts to decompose but above its b.pt., removing the desorbed gaseous (I) and cooling it to a temp. below its b.pt. A hot gas (air) is used for desorption, then cooled to a temp. below the b.pt. (but above the m.pt.) of (I), so that (I) condenses, and is recycled, opt. after reheating. The gas is passed through (II) in countercurrent to the adsorption at a rate of over 10 cm/s. It can be compressed before passing through (I) and expanded before or during cooling. (II) can also be heated by radiant heat and (I) discharged downwards (by forced flow) and cooled. The energy consumption of the process is reduced considerably.

Description

Process for the recovery of activated carbon

adsorbed hydrocarbons The invention relates to a method for the recovery of hydrocarbons adsorbed in activated carbon, in particular of halogenated hydrocarbons.

Among the aforementioned hydrocarbons are primarily chlorinated and / or fluorinated, such as trichlorethylene, perchlorethylene, 1,1,1-trichloroethane, methylene chloride and freon.

When working with such hydrocarbons, there will be exhaust air To get rid of the chlorinated hydrocarbons, activated carbon adsorber systems are used. These serve on the one hand to keep the air clean, but on the other hand also to keep the air clean Recovery of hydrocarbons. The one enriched with chlorinated hydrocarbons Air is forced through a layer of granulated activated carbon. the Activated carbon absorbs the hydrocarbons. This process is called adsorption designated.

To separate the hydrocarbon from the activated carbon, it becomes more saturated or superheated steam passed through the activated carbon. This process is called one desorbtion.

The resulting azeotropic water vapor-hydrocarbon vapor mixture is condensed and finally converted into hydrocarbon and in a water separator Water separated. The recovered hydrocarbon is then again usable.

This recovery process is extremely energy-intensive. The for The amount of water vapor required for desorption depends on the adzotropic mixture the respective hydrocarbon forms with water. For example, for desorption of 1 kg of trichlorethylene requires about 2.5 kg of steam, which means a heat consumption of Corresponds to 1400 Kcal. This is particularly the recovery of methylene chloride and freon problematic because of overheating. This is also true in other respects for trichloroethane, which in the above-described recovery is partly decomposed by hydrolysis and flushing out of the water-soluble stabilizer.

Another disadvantage is that after the recovery of the hydrocarbons By removing the activated charcoal, air is finally dried using waiting air and then dried must be blown cold.

The task is the process of recovering by activated carbon to form adsorbed hydrocarbons in such a way that the energy expenditure is substantial is decreased.

This object is achieved with the features of claim 1. Advantageous Refinements can be found in the subclaims.

The DE-GM 75 41 681 is a device for processing activated carbon removable, which consists of a container that receives the activated carbon and in its Bottom separately loadable nozzles for a washing liquid and for hot air arranged are. However, the washing liquid is decisive for desorbing. Upper a recovery of hydrocarbons is not stated here.

DE-AS 22 42 164 is a method for regenerating loaded Activated charcoal can be removed, in which a solvent through the loaded activated charcoal is directed. These are organic, dipolar, protofil solvents. For removing residual amounts of solvent remaining on the activated carbon more than 2000 nitrogen gas is passed through the activated carbon. The recovery of the solvent used from collected extracts is carried out by rectification.

The decisive factor here, however, is that this is a method for Regeneration of activated carbon by means of a solvent is the last one Process step the solvent is driven off by hot nitrogen gas, but not a process for recovering adsorbed by activated carbon Hydrocarbons.

Two methods according to the invention are explained in more detail below: Activated carbon, which with trichlorethylene, perchlorethylene 1,1,1-trichorathan or is loaded with methylene chloride, is in countercurrent to the loading direction of hot air flows through. In the case of trichlorethylene, this hot air has a temperature of below 120 0C 'in the case of perchlorethylene a temperature of below 0 150 0 and in the case of trichloroethane, 16,000. This air can be compared to the Atmospheric pressure have an overpressure. The activated carbon is released at a speed of more than 10 cm / sec., preferably at a speed of 20 to 60 cm / sec. flows through. When and especially after the activated carbon is heated to the aforementioned Temperatures, the air is loaded with the aforementioned hydrocarbons.

Optimal efficiency is achieved when initially the the air flowing out of the activated carbon is almost saturated.

Then the air is below the boiling point of the respective hydrocarbon cooled down. The deeper the cooling, the better the hydrocarbons condense from the air. After the air has cooled and the hydrocarbons have condensed the air should be largely free of hydrocarbons. It is therefore possible to strive for a thawing of the hydrocarbons from the air. This is supported Thaw if immediately before or after cooling the air previously compressed Air can expand.

r; in cooling to the solidification point of the respective hydrocarbon should be avoided, however, as this reduces the efficiency of the refrigeration system to be used and on the other hand the outflow of the recovered hydrocarbons would not suffer more is guaranteed.

After cooling down, the air is heated again and if necessary.

once the compression has taken place, it is again passed through the activated carbon.

This cycle is carried out until the activated carbon outflowing hot air is largely unsaturated. After that, the air continues to flow in Cycle performed, but not heated again after cooling, so that the Activated carbon is now traversed by cool air.

The procedure can also be carried out as follows: The in one Air, preferably in a closed vessel, is raised by radiant heat heated to a temperature that is only slightly below that at which the adsorbed hydrocarbon begins to decompose. The hydrocarbon desorbs here in gaseous form from the activated carbon, is sucked off by it and then lowered to a temperature well below the boiling point of the hydrocarbon. As a result, it condenses and is thus recovered. There to the cooling station if there is a negative pressure as a result of the condensation taking place there, beer is thrown through the removal of the hydrocarbon from the activated carbon promotes or takes place alone through this underpressure

Claims (11)

Claims 1.) Process for the recovery of adsorbed in activated carbon ~ Hydrocarbons, especially halogenated hydrocarbons, thereby it is indicated that the activated carbon is heated to a temperature which is below that at which the hydrocarbon begins to decompose, which, however, is above its boiling point, and which is desorbed from the activated carbon in the process gaseous hydrocarbons are then carried away from the activated carbon and on is cooled to a temperature below the boiling point of the hydrocarbon. 2. The method according to claim 1, characterized in 9 e k e n n z e i c h n e t, that a hot gas is passed through the activated carbon, the temperature of which is below that at which the hydrocarbon begins to decompose, the gas afterwards cooled below the boiling point of the hydrocarbon and here the hydrocarbon is condensed and then the circulated gas is reheated. 3. The method according to claim 1 or 2, dadtirch g e k e n n -z e i c h n e t that the cooling of the gas or the gaseous hydrocarbon on a temperature takes place which is above the freezing point of the hydrocarbon. 4. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that at the end of the recovery the circulated gas without heating the activated carbon is passed. 5. The method according to any one of claims 2 to 4, characterized g e k e n It should be noted that the gas is air. 6. The method according to any one of claims 2 to 5, characterized g e k e n It is noted that the hot gas is countercurrent to the direction of flow the adsorption is passed through the activated carbon. 7. The method according to any one of claims 1 to 5, characterized g e k e n It is not noted that the gas is moving at a speed of more than 10 cm / sec. is passed through the activated carbon. 8. The method according to any one of claims 2 to 7, characterized g e k e n It should be noted that the gas is compressed before it is passed through the activated carbon and expands before or during cooling. 9. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t that the activated carbon is heated by radiant heat. 10. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t that the gaseous hydrocarbon is carried away downwards from the activated carbon and is cooled. 11. The method according to claim 10, characterized in that g e k e n n -z e i c h n e t that the removal of the gaseous hydrocarbon by means of a forced flow he follows.