DD294187A5 - METHOD FOR WET CLEANING OF FLUOROUS EXHAUST GASES - Google Patents

Abstract

The invention relates to a process for Naszreinigung fluorine-containing exhaust gases while obtaining alkali fluorides with a Alkalihydroxidloesung as an absorbent and reactants. The fluorine-containing crude gas is purified in a Naszreinigungsstufe, wherein a maximum of 3% Alkalihydroxidloesung is injected into the Nachreinigungsteil and is reacted in the pre-cleaning part at a p H value of 5 to 8 completely to the corresponding alkali metal fluorides. The resulting undersaturated Alkalifluoridloesung is sprayed in an upstream drying step and dried by the one-off heisze fluorine-containing raw gas. The raw gas laden with steam and pre-cooled is subsequently conveyed to the wet cleaning stage and the resulting anhydrous alkali fluoride is discharged from the dryer. figure

Description

For this 1 page drawings

Field of application of the invention The invention relates to a method for wet cleaning fluorine-containing exhaust gases with simultaneous production of alkali metal fluorides

an alkali hydroxide solution as an absorbent and reactant.

The process can be used without additional measures wherever there are hot fluorine-containing waste gases, such as

z. B. in melting processes of the enamel, metallurgical, building materials · and glass industry. These fluorine-containing exhaust gases contain mainly

Hydrogen fluoride and in small proportions of silicon tetrafluoride as pollutant components. This at this Wet cleaning process as a recycled product recovered dry alkali fluoride such. As NaF, KF, can be used as a flux for Melting processes in the producer or other industries are reinstated. The existing waste heat out

the melting processes are used.

As an input product waste liquor, such as. As dilute NaOH or KOH solution can be used. Characteristic of the known technical solutions

It is known to absorb fluorine-containing exhaust gases with water, wherein, depending on the type of fluorine compound, the corresponding acid is formed. Thus, processes for the absorption of predominantly SiF ₄ -containing exhaust gases, as z. B. in the fertilizer industry, known (DD-PS 67408). Here, usable with one or two-stage wet cleaning process usable concentrated hydrofluoric acid.

For predominantly HF-containing exhaust gases, such as in the enamel, metallurgical and building materials industry anfaiiö.i, however, can be generated in most cases because of the unfavorable partial pressure conditions only a dilute hydrofluoric acid, which can be used either for adjusting concentrated acid kar '.i or a separate neutralization with lime, wöbe! CaF _{2 is produced} as a waste product.

Direct wet cleaning with milk of lime causes problems with solid particles, since the CaF ₂ produced during absorption is insoluble in water and causes blockages in narrow cross sections. The adsorption with dry lime leads to a discontinuous operation and thus to variations in the adsorption and fluorine emission, also the adsorption at intervals of formed CaF _{2 are} to be disposed of and recycle with lime. Thus, wet cleaning processes have been developed for HF removal from industrial waste gases, which work with NaOH solutions as absorption and crystallization agents (DD-PS 127 548).

These processes work with a closed-loop absorption and crystallization stage followed by a drying stage for the crystallizate. However, these processes have the disadvantage that they work closely to the solubility limit and, in the case of severe operational fluctuations or operating errors, irreversible blockages with NaF crystals occur, and, moreover, feeding the crystallizate to the downstream drying causes difficulties.

Object of the invention

Zie! The object of the invention is to eliminate the difficulties in carrying out the process with a slightly undersaturated fluoride solution and to find a process which leads, with little effort and waste, both to a purified tail gas and to a usable by-product.

Explanation of the essence of the invention

The object of the invention is to achieve through a recycling process using existing in the fluorine-containing exhaust gases from heat processes with little and simple process steps to usable dried alkali fluorides and to obtain a pure end gas by störungsunanfällige effective wet cleaning without a waste product.

According to the invention, this object is achieved in that the fluorine compounds are absorbed in the raw gas in Nachreinigungsteil a Naßreinigungsstufe with a maximum of 3% Alkalihydroxidlösung and converted to alkali fluorides, the resulting alkaline fluoride solution in Vorreinigungsteil this wet cleaning stage by intensive backmixing by means of circulation mode of the absorbent completely reacting a salt solution with the corresponding alkali metal fluorides, that in the bottom of this Vorreinigungsteil a constant pH between 5 and 8 is set via the Alkalizuführung that the salt solution thus produced is dried in an upstream drying stage in countercurrent to the hot fluorine-containing raw gases by spraying, anhydrous alkali fluorides are formed, and that the thus cooled ur.d loaded with steam Rongas is promoted to the wet cleaning stage.

Furthermore, it has been found that the concentration of the supplied alkali metal hydroxide solution is adjusted in the post-cleaning part of the wet cleaning stage by spraying water and concentrated solution that for the purpose of setting a constant pH alkali hydroxide solution is fed directly to the absorbent circuit of the pre-cleaning part, that the pre-cleaning part of the wet cleaning stage in several sections with is subdivided into different levels of liquid loading with separate absorption of the absorbent, that the water supply is set in the wet cleaning stage that the dew point of the raw gas is not exceeded after the drying step, that the water supply is controlled by a density measurement of the salt solution, that a partial stream of the raw gas branched off before the spray dryer and after the spray dryer is fed again.

The main advantage of the process according to the invention over the known state of the art lies in the simple and manageable process control, only two main process steps, namely drying and wet cleaning, are required in order to obtain both a purified final gas and a recoverable dried alkali fluoride. Further advantages are the use of the heat content of the hot raw gases for drying and the utilization of waste eyes as an absorbent and reactant.

embodiment

10000 m ³ i. N./h fluorine-containing raw gas are conveyed from drum furnaces of an enamel frit melt with a temperature of 25O ⁰ C via the crude gas line 1 in the spray dryer 2. This raw gas contains 10kg / h hydrogen fluoride and a

Residual dust content of 0.2 kg / h. At the same time, 3525kg / h of undersaturated sodium fluoride solution containing

4 mass fractions in% NaF promoted by the pump 14 in the dryer and sprayed.

In this case, 504 kg / h of water are evaporated and the resulting 21 kg / h of dried NaF crystals are over a

suitable discharge unit at 4 out of the dryer.

The loaded with water vapor and cooled to 97 ⁰ C fluorine-containing raw gas is through the gas line 5 in the wet scrubber β

directed. The raw gas temperature is above the dew point, so that in the gas line to no condensate or

Acid attack is coming. The gas first flows through the pre-cleaning part in countercurrent to about 11 mVh NaF solution, the Part is conveyed by means of centrifugal pump 8 via the pipe 9 in the circuit, with an intensive pre-cleaning of HF-containing gas and a good liquid mixing at a mean residence time of 7 min. Takes place.

In this Vorreinigungs- and mixing process, the gas is saturated with water vapor, and it sets a liquid temperature of 47 ⁰ C.

The pH in the pre-purification stage 7 is constantly controlled to pH 7 via the supply of fresh NaOH solution. At the head of the wet scrubber, 13785 kg / h of NaOH solution with a content of 2.55% by weight in% NaOH are thus injected via the feed line. This injected NaOH solution flows countercurrently to the pre-cleaned HF-containing exhaust gas, the Nachreinigungsstufe 10 and vermiscnt in the pre-cleaning stage with the NaF solution. The thus purified tail gas passes with an HF content of less than 5 mg / m ³ via the mist eliminator 11 in the exhaust pipe 12 and is emitted at a prescribed Schlothöhe.

Claims (8)

1. A process for wet cleaning fluorine-containing exhaust gases with simultaneous production of alkali metal fluorides with an alkaline solution as an absorbent and reactants, characterized in that the fluorine compounds are absorbed in the raw gas in Nachreinigungsteil a Naßreinigungsstufe with a maximum of 3% Alkalihydroxidlösung and converted to alkali metal fluorides that the case resulting alkaline fluoride solution in Vorreinigungsteil this wet cleaning stage by intensive backmixing by means of circulation mode of the absorbent completely converts to a saline solution with the corresponding alkali metal fluorides in the bottom of this Vorreinigungsteiles a constant pH between 5 and 8 is adjusted via the alkali feed that the salt solution thus produced is dried in a preceding drying stage in countercurrent to the hot fluorine-containing raw gases by spraying to form anhydrous alkali metal fluorides, and that the au f this way cooled and loaded with steam raw gas is fed into the wet cleaning stage. 2. The method according to claim 1, characterized in that the concentration of the zugoführt Alkalihydroxidlösung is adjusted in the post-purification part of the wet cleaning stage by spraying water and concentrated solution. 3. The method according to claim 1 and 2, characterized in that for the purpose of setting a constant pH alkali hydroxide solution is fed directly to the absorbent circuit of the pre-cleaning part. 4. The method according to claim 1 to 3, characterized in that the pre-cleaning part of the wet cleaning stage is subdivided into several sections with different liquid load with separate absorption medium supply. 5. The method according to claim 1 to 4, characterized in that the water supply is set in the wet cleaning stage so that the dew point of the raw gas is not exceeded after the drying step. 6. The method according to claim 1 to 5, characterized in that the average residence time of the absorbent in the bottom of the wet cleaning stage is between 5 and 10 min. 7. The method according to claim 1 to 6, characterized in that the water supply is controlled by a density measurement of the salt solution. 8. The method according to claim 1 to 7, characterized in that a partial stream of the raw gas branched off before the spray dryer and fed back to the spray dryer.