Indian Patents. 207682:RECOVERY OF HIGHLY FLUORINATED CARBOXYLIC ACIDS FROM THE GAS PHASE

Title of Invention	RECOVERY OF HIGHLY FLUORINATED CARBOXYLIC ACIDS FROM THE GAS PHASE
Abstract	The process for the recovery of highly fluorinated carboxylic acids from off-gas streams, in which the off- gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the salt of the highly fluorinated carboxylic acid settles out as a separate phase, proceeds particularly advantageously when the alkaline washing solution is a potassium carbonate solution.

Full Text	German Patent 195 27 276 (Patent Specification published on 08.08.1996) relates to a process for the recovery of highly fluorinated carboxylic acids from off-gas streams, wherein the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the salt of the highly fluorinated carboxylic acid settles out as a separate phase. As a further development of this inventive conception, it has now been found that the alkaline washing solution used is advantageously a potassium carbonate solution. The invention thus relates to a process for the recovery of highly fluorinated carboxylic acids from off-gas streams, in which the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the salt of the highly fluorinated carboxylic acid settles out as a separate phase, wherein the alkaline washing solution used is a potassium carbonate solution. When the alkaline washing solution in the process of German Patent 195 27 276 is an alkali metal hydroxide solution, the corresponding carbonate is formed if the off-gas stream to be purified contains carbon dioxide. It has now been found that, when using sodium hydroxide solution, this sodium carbonate leads to encrustation in the scrubbing column. This formation of carbonate is furthermore associated with an undesirable consumption of sodium hydroxide. The use of potassium carbonate as the alkaline agent avoids these disadvantages. If sodium carbonate is used instead of potassium carbonate, no sodium hydroxide is consumed but there is a considerable increase in encrustation. Moreover, sodium carbonate has a less favorable solubility behavior. This is shown by the fact that the cooling of sodium carbonate solutions of the density required for the process results in precipitation due to supersatur-ation. This is not the case with potassium carbonate, so it is not necessary to heat pipelines and vessels. It has further been found that when potassium carbonate is used as the alkaline agent, the potassium salt of the highly fluorinated carboxylic acid is deposited in a form which is easier to filter off than when potassium hydroxide solution is used. This is coupled with the abovementioned advantage that when potassium carbonate is used, there is no consumption of alkaline agent by absorbed carbon dioxide. The density of the alkaline washing solution is advantageously 1.2 to 1.4 g/cm3. Reference is made to German Patent 195 27 276 for further details. The invention will now be illustrated further by means of the following example. Example 4 00 Nm3/h of off-gas from a process for drying powdered fluorinated polymer, at a temperature of 171°C, are introduced into a commercially available scrubbing column of length 2000 mm and internal diameter 250 mm. The off-gas contains 750 mg/Nm3 of perfluorooctanoic acid, corresponding to 300 g/h. Circa 20 kg/h of water are additionally conveyed with the off-gas from the dryer into the scrubbing process. The pressure in the scrubbing column is circa 1 bar absolute. 10 m3/h of an alkaline washing liquor, consisting essentially of aqueous potassium carbonate solution of density 1.30 g/cm3, at a temperature of 45°C, are introduced into the scrubber via a nozzle. The purified off-gas stream of 400 Nm3/h, now containing only 0.8 mg/Nm3 of perfluorooctanoic acid, corresponding to 0.32 g/h, escapes from the lower section of the scrubbing column. Water vapor, corresponding to the water partial pressure, is additionally present at the temperature of circa 45°C prevailing in the scrubber. The scrubber is operated in co-current. The alkaline washing medium and the potassium salt of perfluorooctanoic acid which is formed flow out of the column directly into a separating vessel of volume 0.4 m3, where the potassium salt of perfluorooctanoic acid, which is insoluble in the alkaline washing solution, floats to the top as a pulpy layer. The alkaline washing solution, which now contains practically no potassium salt of perfluorooctanoic acid, is withdrawn from the bottom of the separating vessel and pumped back into the scrubbing column. The concentration of dissolved potassium salt of perfluorooctanoic acid in the washing medium is about 170 mg/1. The density of the washing liquor is maintained at the desired value of about 1.30 g/cm3 by the addition of potassium carbonate. The potassium salt of perf luorooctanoic acid which has separated out as a pulpy layer runs off into a tank through an overflow on the separating vessel, together with some washing medium. The discharge process is aided by a very slow stirrer immersed directly in the upper layer. In the separating vessel, the separation of the washing solution and the potassium perfluorooctanoate foam formed is very good. After standing for several hours, a further two phases separate out in the tank: a lower phase consisting essentially of excess washing liquor, and a pulpy upper phase. The lower phase is separated off and recycled into the washing process. The pulpy upper phase contains 3 6% by weight of potassium perfluorooctanoate. The concentrate obtained in this way is subjected to further working-up to give pure 100% by weight perfluorooctanoic acid. It may be mentioned that although the concentrate obtained in this way is a stirrable and pumpable mixture, it does not constitute a stable solution of the potassium salt of perfluorooctanoic acid. To obtain a stable solution, it would be necessary to add even more water. However, this is not absolutely necessary for further working-up. Because the lower phase which has been separated off is recycled into the washing process as described, no perfluorooctanoic acid is lost. There is no observable impairment of the washing process due to encrustation in the column after several weeks of operation. Patent Claim I. A process for the recovery of highly fluorinated carboxylic acids from off-gas streams, in which the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the :;salt of the highly fluorinated carboxylic acid settles out as a separate phase, wherein the alkaline washing solution used is a potassium carbonate solution.

Full Text

German Patent 195 27 276 (Patent Specification published on 08.08.1996) relates to a process for the recovery of highly fluorinated carboxylic acids from off-gas streams, wherein the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the salt of the highly fluorinated carboxylic acid settles out as a separate phase.
As a further development of this inventive conception, it has now been found that the alkaline washing solution used is advantageously a potassium carbonate solution. The invention thus relates to a process for the recovery of highly fluorinated carboxylic acids from off-gas streams, in which the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the salt of the highly fluorinated carboxylic acid settles out as a separate phase, wherein the alkaline washing solution used is a potassium carbonate solution.
When the alkaline washing solution in the process of German Patent 195 27 276 is an alkali metal hydroxide solution, the corresponding carbonate is formed if the off-gas stream to be purified contains carbon dioxide. It has now been found that, when using sodium hydroxide solution, this sodium carbonate leads to encrustation in the scrubbing column. This formation of carbonate is furthermore associated with an undesirable consumption of

sodium hydroxide. The use of potassium carbonate as the alkaline agent avoids these disadvantages.
If sodium carbonate is used instead of potassium carbonate, no sodium hydroxide is consumed but there is a considerable increase in encrustation. Moreover, sodium carbonate has a less favorable solubility behavior. This is shown by the fact that the cooling of sodium carbonate solutions of the density required for the process results in precipitation due to supersatur-ation. This is not the case with potassium carbonate, so it is not necessary to heat pipelines and vessels.
It has further been found that when potassium carbonate is used as the alkaline agent, the potassium salt of the highly fluorinated carboxylic acid is deposited in a form which is easier to filter off than when potassium hydroxide solution is used. This is coupled with the abovementioned advantage that when potassium carbonate is used, there is no consumption of alkaline agent by absorbed carbon dioxide.
The density of the alkaline washing solution is advantageously 1.2 to 1.4 g/cm3.
Reference is made to German Patent 195 27 276 for further details.
The invention will now be illustrated further by means of the following example.

Example
4 00 Nm3/h of off-gas from a process for drying powdered fluorinated polymer, at a temperature of 171°C, are introduced into a commercially available scrubbing column of length 2000 mm and internal diameter 250 mm. The off-gas contains 750 mg/Nm3 of perfluorooctanoic acid, corresponding to 300 g/h. Circa 20 kg/h of water are additionally conveyed with the off-gas from the dryer into the scrubbing process. The pressure in the scrubbing column is circa 1 bar absolute.
10 m3/h of an alkaline washing liquor, consisting essentially of aqueous potassium carbonate solution of density 1.30 g/cm3, at a temperature of 45°C, are introduced into the scrubber via a nozzle. The purified off-gas stream of 400 Nm3/h, now containing only 0.8 mg/Nm3 of perfluorooctanoic acid, corresponding to 0.32 g/h, escapes from the lower section of the scrubbing column. Water vapor, corresponding to the water partial pressure, is additionally present at the temperature of circa 45°C prevailing in the scrubber.
The scrubber is operated in co-current. The alkaline washing medium and the potassium salt of perfluorooctanoic acid which is formed flow out of the column directly into a separating vessel of volume 0.4 m3, where the potassium salt of perfluorooctanoic acid, which is insoluble in the alkaline washing solution, floats to the top as a pulpy layer. The alkaline washing solution, which now contains practically no potassium salt of perfluorooctanoic acid, is withdrawn from the bottom of the separating vessel and pumped back into the scrubbing column. The concentration of dissolved potassium salt of perfluorooctanoic acid in the washing medium is about 170 mg/1. The density of the washing liquor is maintained at the desired value of about 1.30 g/cm3 by the addition of potassium carbonate. The potassium salt of perf luorooctanoic acid which has separated out as a pulpy

layer runs off into a tank through an overflow on the separating vessel, together with some washing medium. The discharge process is aided by a very slow stirrer immersed directly in the upper layer. In the separating vessel, the separation of the washing solution and the potassium perfluorooctanoate foam formed is very good.
After standing for several hours, a further two phases separate out in the tank: a lower phase consisting essentially of excess washing liquor, and a pulpy upper phase. The lower phase is separated off and recycled into the washing process.
The pulpy upper phase contains 3 6% by weight of potassium perfluorooctanoate.
The concentrate obtained in this way is subjected to further working-up to give pure 100% by weight perfluorooctanoic acid.
It may be mentioned that although the concentrate obtained in this way is a stirrable and pumpable mixture, it does not constitute a stable solution of the potassium salt of perfluorooctanoic acid. To obtain a stable solution, it would be necessary to add even more water. However, this is not absolutely necessary for further working-up.
Because the lower phase which has been separated off is recycled into the washing process as described, no perfluorooctanoic acid is lost. There is no observable impairment of the washing process due to encrustation in the column after several weeks of operation.

Patent Claim
I. A process for the recovery of highly fluorinated carboxylic acids from off-gas streams, in which the off-gas is brought into contact with an alkaline washing solution of density >1.15 g/cm3 so that the :;salt of the highly fluorinated carboxylic acid settles out as a separate phase, wherein the alkaline washing solution used is a potassium carbonate solution.

Documents:

1746-mas-1997- abstract.pdf

1746-mas-1997- assignment.pdf

1746-mas-1997- claims duplicate.pdf

1746-mas-1997- claims original.pdf

1746-mas-1997- correspondence others.pdf

1746-mas-1997- correspondence po.pdf

1746-mas-1997- description complete duplicate.pdf

1746-mas-1997- description complete original.pdf

1746-mas-1997- form 1.pdf

1746-mas-1997- form 26.pdf

1746-mas-1997- form 3.pdf

1746-mas-1997- form 4.pdf

1746-mas-1997- pct.pdf

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Patent Number

207682

Indian Patent Application Number

1746/MAS/1997

PG Journal Number

26/2007

Publication Date

29-Jun-2007

Grant Date

20-Jun-2007

Date of Filing

05-Aug-1997

Name of Patentee

DYNEON GMBH

Applicant Address

D-84504 BURGKIRCHEN.

Inventors:

#	Inventor's Name	Inventor's Address
1	DYNEON GMBH	D-84504 BURGKIRCHEN.

PCT International Classification Number

C11B13/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	196 31 406.2	1996-08-05	Germany