FR2721919A1 - PROCESS AND PLANT FOR RECOVERING BROMINE FROM A LIQUID EFFLUENT - Google Patents

Abstract

Process and installation for recovering bromine in a liquid effluent, by combustion at high temperature under pressure of the liquid effluent in a combustion chamber (10), maturation of the combustion gases at medium temperature in a chamber (20), hetero distillation - azeotropic gas in a distillation column (26), with condensation in (36, 38) of the water-bromine gas mixture resulting from the distillation and separation of the bromine in a settling tank by demixing the water and the bromine at a temperature of the order of 5 ° C., the liquid bromine obtained being subjected to a further distillation in a column (48) in order to be purified to 99.9%.

Description

PROCESS AND PLANT FOR RECOVERING BROMINE

IN A LIQUID EFFLUENT

  The invention relates to a method and an installation for recovering bromine in a liquid effluent. Currently, liquids with a high bromine content, which are wastes from certain chemical industries, are destroyed by incineration in special plants, which has the disadvantage of being expensive and generating secondary wastes which then have to be

Discard.

  The subject of the invention is a method and an installation for incinerating liquid effluents containing bromine, this method and this installation being such that they make it possible to recover practically pure and directly reusable bromine, that they require an investment capable of to be amortized quickly, and they only produce relatively large quantities

low secondary waste.

  To this end, it proposes a process for recovering bromine contained in a liquid effluent, characterized in that it is carried out under pressure and consists in: - incinerating the liquid effluent using pure oxygen as oxidizer, - cooling the combustion gases by dilution with water, subject the cooled gases to a hetero-azeotropic distillation consisting in obtaining a water-bromine gas mixture, in condensing it and in separating the bromine by decanting the mixture into the liquid phase at a determined temperature get bromine with a

  high degree of purity, greater than 99.9%.

  The invention thus makes it possible to recover approximately 80% of the bromine contained in a liquid effluent instead of destroying it, which results on the one hand by a rapid amortization of the investments necessary for the execution of this process and on the other hand by greatly reducing the amount of secondary waste

must then dispose.

  In addition, carrying out the process under pressure promotes the treatment of combustion gases and the recovery of bromine in these gases, and reduces

  considerably the volume of gases to be treated.

  In the aforementioned heterozeotropic distillation, the bromine in the liquid phase separated by decantation is subjected to a new distillation for elimination of traces.

of water.

  The liquid residue from the distillation is partly resubmitted in the aforementioned incineration step, and the rest of this liquid residue is neutralized by treatment with sodium hydroxide. The invention also provides an installation for recovering bromine in a liquid effluent, characterized in that it is designed to operate under pressure and in that it comprises: - a chamber for rapid combustion of the liquid effluent at high temperature in a pure oxygen atmosphere, means for diluting and rapidly cooling the combustion gases with water, and a chamber for maturing the combustion gases at medium temperature, - means for hetero-azeotropic distillation of the cooled combustion gases , comprising at least one distillation column associated with means for condensing the gas mixture leaving this column and with means for separating the bromine by decantation at

  determined temperature of the condensed mixture.

  Advantageously, these means comprise a second distillation column, which is supplied by the "bromine" outlet of the separation means by decantation and which provides substantially pure bromine and a gaseous mixture.

  referred to the aforementioned means of condensation.

  Such an installation is designed to operate at a pressure of 5 to 20 bars, preferably 8 to 10

bars, and can therefore be compact.

  It can have for example (without this indication being limiting) a treatment capacity of the order of kg of liquid effluent per hour, or approximately 600 tonnes per year, which allows the recovery of approximately tonnes of bromine per year for an effluent containing approximately 40% of bromine, so that the investment necessary for the implementation of the invention can be

amortized in less than three years.

  The invention will be better understood and other characteristics, details and advantages thereof will appear more clearly on reading the

  description which follows, given by way of example in

  reference to the accompanying drawing, which is a schematic view

  of an installation according to the invention.

  This installation essentially comprises a combustion chamber under pressure of a liquid effluent 12 with a high bromine content (for example of the order of 50% by weight) which is fed continuously to the combustion chamber 10 with a continuous flow 14 pressurized oxygen serving as oxidizer. A supply 16 of a fuel such as fuel oil is provided for starting

of the installation.

  Typically, the internal pressure in the combustion chamber and in the rest of the installation is preferably of the order of 8 to 10 bars, the combustion temperature of the liquid effluent being between 2,000 and 2,500 K degrees to obtain very quickly the thermodynamic balance at the end of combustion and being able to contain the gases in reaction in a

small dimension.

  A flow 18 of water in liquid phase at ambient temperature is brought inside the combustion chamber 10 to cool the walls of the latter. A small part of this water flow is used to maintain the gases at the desired temperature of 2,000 to 2,500 K. Most of the water is injected very quickly at the entrance to a maturation chamber 20, arranged immediately downstream of the combustion chamber 10, to bring the gases to a temperature of the order of 430 C, without modifying their chemical composition at the end of combustion at high temperature (2,000 to 2,500 K). A temperature of 400 to 600 ° C. and a residence time in chamber 20 of the order of 0.1 to 10 s under a pressure of to 20 bars are conditions which make it possible to maximize the formation of bromine (Br2) to the detriment bromine hydride (HBr) and thereby increase the bromine recovery yield. Preferably, the values of 400 to 450 C, 0.5 to 2 s and 8 to 10 bars will be chosen, which allow reaching more than 80% of

  conversion of bromine to Br2 (diatomic bromine).

  The maturation chamber 20 is followed by a gas-solid separator 22, constituted for example by ceramic dedusting filters, making it possible to separate the gases and the combustion ashes. The temperature inside the separator 22 is identical to that of the

room 20.

  The gases leaving the separator 22 are then brought to a heat exchanger 24, of the water circulation type, or they are cooled to a temperature of the order of 180 to 220 degrees C. Another possibility is to replace the elements 22 and 24 by a chamber 23 for dilution by a water flow 25 which will bring the gases to the same temperature from 180 'to 220' C. This temperature, preferably from 'C under 10 bars, is chosen to limit the problems corrosion by acidic liquids in the

  hetero-azeotropic distillation while remaining

  above the dew point temperature of the water-bromine mixture at

  the entry of the distillation means.

  The outlet of the exchanger 24 or of the chamber 23 is connected to an inlet of a hetero-azeotropic distillation column 26, an upper outlet 28 of which makes it possible to obtain an azeotropic water-bromine mixture in the gas phase and of which a lower outlet 30 is connected on the one hand to an inlet of the combustion chamber 10 or of the maturation chamber 20 for recycling part of the liquid distillation residues and on the other hand to an inlet 32 of the column 26 by means of a boiler 34 comprising heating means, not shown, for example of the electric type. The recycling of the liquid residues to the chamber 10 or the chamber 20 makes it possible to re-transform part of the bromine hydride contained in the liquid into bromine and therefore to increase overall the recovery rate of the bromine. The outlet 28 of the distillation column 26 is connected to condensing means comprising two condensers 36 and 38 connected in series, the first of which is supplied with water at room temperature and the second of which is supplied with glycol water or the like at a temperature lower

  at zero degrees C, for example from -20 degrees C approximately.

  The outlet of the second condenser 38 is connected to a settling tank 40 in which the bromine is separated from the water by demixing at a temperature of the order of 5 degrees C, the settling tank containing an upper layer 42 of a light liquid consisting essentially of water with traces of bromine, and a lower layer 44 of a heavy liquid consisting essentially of bromine with traces of water. The temperature of 5 ° C. and the pressure level of 8 to 10 bars are chosen so as to maximize the bromine condensation and to favor the appearance by demixing of a phase very rich in bromine which it will be easy to purify by distillation for

  achieve at least 99.9% purity.

  The lower part of the settling tank 40 is connected to an inlet 46 of a second distillation column 48, an upper outlet 50 of which is connected with the upper outlet 28 of the first column 26 to the inlet of the first condenser 36 and of which a lower outlet 52 is connected to a boiler 54, a lower outlet 56 of which supplies pure bromine in the liquid phase and an outlet 58 of which is connected to a lower inlet 60 of the column 48. This installation also includes means for treatment and elimination of secondary waste resulting from the recovery of bromine in the liquid effluent 12. These means comprise columns 62 of absorption with activated carbon, which are installed in parallel and fed by a gas outlet 64 from the settling tank 40, the outlets absorption columns 62 being connected by a pressure reducer 66 to rejection means

gas.

  Furthermore, the boiler 34 of the first distillation column 26 comprises a "liquid" outlet 68 which is connected to a neutralization chamber 70 supplied with soda or other basic product from a tank 72, the outlet from the chamber 70 being connected to a regulator 74 comprising a "gas" outlet 76 and an outlet

"liquid" 78.

  Finally, the settling tank 40 comprises an intermediate outlet 80 connected to the distillation column 26 for re-injecting therein the liquid of the layer 42, consisting essentially of water with traces of bromine. The operation of this installation is as follows: a flow rate of liquid 12 highly charged with bromine, for example of the order of 100 kg / h, is brought under a pressure of 8 to 10 bars and at ambient temperature in the combustion chamber 10, with a flow of pure oxygen of the order of 110 kg / h under a pressure of 8 to 10 bars at room temperature to be burned at a temperature of the order of 2,000 to 2,500 K, the gases of combustion being diluted and cooled to a temperature of the order of 430 degrees C by mixing with the water injected and vaporized in the combustion chamber 10 and the combustion chamber

dilution 20.

  The combustion gases are separated from the ashes in the separator 22, then cooled to a temperature of the order of 200 degrees C by the exchanger 24, this temperature of 200 degrees C being higher than the vaporization temperature of the water under a pressure of

bars.

  In the variant described above, the gases are cooled by dilution with water in chamber 23, the ashes being recovered at the bottom of the column 26 by

  solid / liquid separation on outlet 30.

  The gas mixture supplied to the first distillation column 26 comprises an azeotropic water-bromine mixture, which has the same composition in liquid phase and in vapor phase and which cannot be separated.

constituents by distillation.

  The distillation of the combustion gases in the active column therefore makes it possible to recover, at the upper outlet 28 of the column, a water-bromine mixture in the vapor phase and, at the outlet 30 of the column, a liquid consisting in particular of water and hydrobromic acid which is partly returned to the combustion chamber 10 and partly supplied to the boiler 34 one outlet of which feeds the distillation column 26 and another outlet of which supplies the chamber 70 where the acidic liquid is neutralized by soda , before being brought back to atmospheric pressure by the regulator 74 producing steam and a liquid subsequently treated by means

of purification.

  The water-bromine mixture in the vapor phase obtained at the outlet 28 of the first distillation column 26 is condensed by passing through the condensers 36 and 38 and brought to a temperature of the order of 5 degrees C in the settling tank 40, o water and bromine are separated by density difference into an upper layer 42 and a lower layer 44, due to a phenomenon of demixing of bromine and water at the above temperature of 5 degrees C. The lower part the settling tank 40 essentially contains bromine with traces of water, which is brought to the second distillation column 48 to be purified there by vaporization of water at a temperature of the order of 100 degrees C, the bromine pure then passing through the boiler 54 and being recovered at the outlet 56

of it.

  The steam leaving at 50 from the second distillation column 48 is mixed with the steam leaving at 28 from the first distillation column 26 to be condensed again in the condensing means 36,

38.

  The incondensable gases which are in the upper part of the settling tank 40 are brought to one of the two purification columns 62 (which are used alternately), then the purified gases are expanded at 66

  before being released to the atmosphere.

  An installation according to the invention having a treatment capacity of 100 kg / h of liquid loaded with bromine, has a small footprint due to its internal operating pressure, the distillation column 26 having for example a diameter of the order of 30 centimeters for a

height of 2 meters.

  The components of this installation are made for example of tantalum, glass or enamelled steel which resist bromine well, and are designed for a pressure

  operating on the order of ten bars.

Claims (14)

  1. Method for recovering bromine contained in a liquid effluent, characterized in that it is carried out under pressure and consists in: incinerating the liquid effluent using pure oxygen as oxidizer, - cooling the combustion gases by dilution with water, - and subject the cooled gases to a hetero-azeotropic distillation consisting in obtaining a gaseous water-bromine mixture, in condensing it and separating the bromine by decanting the mixture in liquid phase at a determined temperature, to obtain bromine with a degree of purity   high, for example at least 99.9%.   2. Method according to claim 1, characterized in that the bromine in the liquid phase separated by decantation is subjected to a new distillation for elimination of traces of water.   3. Method according to claim 1 or 2, characterized in that the gaseous residues of the above-mentioned condensation are purified by passage over active carbon, expanded and released to the atmosphere.   4. Method according to one of the preceding claims,   characterized in that the liquid residue from the decantation is subjected to the aforementioned hetero-azeotropic distillation.   5. Method according to one of the preceding claims,   characterized in that part of the liquid residue from hetero-azeotropic distillation is resubmitted at the stage above-mentioned incineration.   6. Method according to one of the preceding claims,   characterized in that another part of the liquid residue from hetero-azeotropic distillation is neutralized by treatment with soda.   7. Method according to one of the preceding claims,   characterized in that it is produced at a pressure of   from 5 to 20 bars and preferably from 8 to 10 bars.   8. Installation for recovering bromine in a liquid effluent, characterized in that it is designed to operate under pressure and in that it comprises: - a chamber (10) for rapid combustion of the liquid effluent at high temperature and in a pure oxygen atmosphere, means (18) for diluting and rapidly cooling the combustion gases with water, and a chamber (20) for maturing the combustion gases at medium temperature, - hetero-distillation means azeotropic receiving the cooled combustion gases, comprising at least one distillation column (26) associated with   means (36), (38) for condensing the gas-water mixture   bromine leaving this column (28), and to means (40) for separating the bromine by decantation at temperature determined of the condensed mixture.   9. Installation according to claim 8, characterized in that it comprises a second distillation column (48), supplied by the decantation means (40) in bromine containing traces of water, the second distillation column (48) comprising a lower outlet (52) supplying substantially pure bromine, and an upper outlet (50) connected to the aforementioned means (36), (38) of condensation.   10. Installation according to claim 8 or 9 characterized in that the means of condensation and decantation comprise an outlet (44) of gas connected by purification means (62) and expansion (66) to means of release to the atmosphere.   11. Installation according to one of claims 8 to 10,   characterized in that the settling means (40) comprise an intermediate outlet connected to the   first distillation column (26).   12. Installation according to one of claims 8 to 11,   characterized in that it comprises means (70), (72) for neutralizing, for example with sodium hydroxide, an acidic liquid forming the distillation residue in the first distillation column (26).   13. Installation according to one of claims 8 to 12,   characterized in that the first distillation column (26) comprises a liquid outlet (30) connected to the aforementioned combustion chamber (10), for recycling part of the liquid residue of hetero-azeotropic distillation.   14. Installation according to one of claims 8 to 13,   characterized in that the internal operating pressure is of the order of 5 to 20 bars, of preferably 8 to 10 bars.