FI97276B - Method for the disposal of halogenated aryl compounds - Google Patents

Abstract

A process for the destruction of halogenated products and more particularly of chlorinated aromatic products or of oils containing these products, for example unchlorinated dielectric fluids contaminated with PCBs. The process is characterised in that these products are subjected to the action of an alcoholate and preferably sodium methylate at a temperature of between 250 and 290 DEG C.

Description

97276

A method for disposing of halogenated aryl compounds

The present invention relates to a chemical process for the disposal of organic halogen-containing aryl compounds and in particular aromatic chlorine compounds, such as, for example, PCBs (polychlorinated biphenyls), which may include non-chlorinated organic compounds.

The prior art has already proposed the removal of PCBs contained in transformer die-electric oils or lubricating oils by methanol extraction (U.S. Patent 4,387,018). The methanol is then separated from the PCB by distillation and then returned to the cycle. With this method it is possible to reduce 70% of the amount of PCBs. EP 99951 proposes the treatment of similar compounds with sodium dispersed into particles larger than 10 μm. EP patent application 107 404 describes the treatment of transformer oil containing 652 ppm PCB with sodium salts of polyethylene glycol. The downside of these methods is the necessary separations and re-cycle returns or sodium treatment. EP patent application 21294 discloses the disposal of dioxins, in particular chlorinated anisols, containing 39.7 ppm of 2,3,7,8-tetrachlorodibenzo-p-dioxin by reacting these compounds under pressure with sodium methylate in methanol at a temperature of 160 ° C. ° C. In addition to this, in an article by Gyula Pfeifer and Terez Flora in the Hungarian magazine MAGY. KEM. FOLYOIRAT 71 (8), 343346 (1965) discloses that sodium methylate can begin to decompose between 120-140 ° C. A much simpler and very effective method has now been invented.

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The present invention relates to a process for the disposal of halogenated aryl compounds, characterized in that a) these compounds are contacted with at least one anhydrous powdered metal alcoholate for a necessary time to convert organic halogen compounds into inorganic halides, b) the amount of the alcoholate is halogen-based c) the alcoholate is selected from sodium, lithium or potassium methylate, ethylate, propylate or isopropylate, d) the temperature is above 220 ° C, and e) the non-halogenated organic product is taken recovered by distillation.

The invention is particularly useful for compounds containing aryl carbon atoms substituted by chlorine and / or bromine. This group includes, for example, chlorinated or brominated dioxins, chlorinated or brominated dibenzofurans, (polychloro) diphenyls, (polybromo) diphenyls, (polybromine) diphenyl ethers, (polychloro) diphenyl ethers.

These compounds may be pure or in admixture with each other or with organic non-halogenated compounds such as polyarylalkanes or mineral oils.

Although the invention makes it possible to dispose of any halogenated aryl compound, it is preferably used to dispose of compounds containing less than 1% by weight of halogen and preferably less than 1000 ppm.

Sodium methylate is preferably used.

The alcoholate is preferably added to the halogen-containing compounds or to a mixture containing the halogenated compounds. Sto-3 97276 cymometrically corresponds to one group of alcoholates per halogen atom which must be removed, but an excess of alcoholate relative to this etiometric amount is used. Very good de-halogenation is obtained by using a 5-10 times excess over the etiometric amount. For example, if the mixture contains PCBs in an amount of 100 ppm expressed as chlorine, sodium methylate is used in an amount of 0.14 X.

It would not be excluded from the scope of the invention if another compound which can convert organic chlorine to an inorganic chloride, such as sodium carbonate or another alkaline substance, is added with the alcoholate.

The contacting of the organic halogen-containing compounds with the alcoholate is preferably carried out by stirring, for example, in a stirred reactor or a column equipped with stages or any other. , in a device in which it is possible to mix sufficiently so that the alcoholate is well dispersed and in contact with the halogenated compounds for a sufficient time to dispose of them. The reaction can be carried out continuously or not - .. * · * continuously. The kinetics of the reaction increase with increasing temperature.

::: Can be used at temperatures between 220-300 C, but • · o it is considered best to work with a temperature of 1 i 1 at 250-290 C.

• s

Depending on the physical properties of the compounds (vapor pressure), work is carried out at atmospheric pressure or higher. The duration of the reaction depends on the amounts of the organic halogen compound, the temperature, the amount of the alcoholate, the mixing conditions to obtain good contact between the reactants; it is usually from 30 minutes to 10 • · hours.

The invention is particularly useful for the disposal of halogen-containing aryl compounds present in a mixture such as a non-halogenated dielectric liquid or an inorganic oil containing i 4 97276 PCBs. . This compound, which contains PCBs or other chlorine-containing substances, is subjected to the process according to the invention, after which the inorganic halogenated compounds are separated from the other substances, for example by distillation. In this way, a mineral oil or a dielectric liquid free of organic chlorine is obtained.

Excess alcoholate is used to ensure complete dehalogenation. When a dielectric liquid containing some hundreds of ppm of aromatic chlorine-containing compounds is treated, a dielectric liquid, NaCl, conversion products of aromatic chlorine-containing compounds and a residue of unreacted alcoholate are obtained after completion of the reaction. This mixture is very easily distilled to recover a pure dielectric liquid that no longer contains aromatic chlorine. When the alcoholate used is sodium methylate, it is wisest to have a vio in the distillation apparatus. . the storage time does not exceed 12 hours at 295 C to avoid decomposition of the methylate • · e ’**. *.

The process according to the invention can also be used as a complementary ground process by means of sodium carbonate. Sodium carbonate is very easy to handle, but it does not::: remove non-aliphatic halogens and the most labile aryl halogens.

The process according to the invention makes it possible to obtain a substance with an aryl halogen content of less than 10 ppm. This men- • · · I! The advantage of the system is that, although it is directed to compounds • i * • · · whose halogen atoms are only slightly reactive, there is no need for I I Vita solvents; so it is enough to add alcoholate ··· ....

:; for example, oil containing PCBs without • · e | it is not necessary to add a corresponding alcohol in addition to the alcoholate as described in EP patent application 21294. The method does not need to: after completion of the fine treatment before the recovery of the compounds from which the aryl halogens have been removed, the excess alcoholate, in particular sodium methylate, is removed beforehand.

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Another advantage of the invention is that the by-products formed, such as NaCl, alcoholate-modified aryl halogen compounds and the residue of unreacted alcoholate, can be disposed of gently by incineration without generating toxic substances.

The following examples illustrate the invention without limiting it.

Example 1

Take 1000 g of dibenzyltoluene (DBT) containing 300 ppm of aromatic chlorine in the form of monochlorobenzyltoluene. This mixture is placed in a reactor equipped with a rotary stirrer, a vertical condenser and a nitrogen jet. After a gas purge for 15 minutes, one% by weight (i.e. 10 g) of sodium methylate is added with a stream of nitrogen at 100 ° C. The medium is started to reflux at 285 ° C with stirring and purging with a stream of nitrogen for three hours. Ai-. . they are then distilled by progressively adjusting the vacuum to 2 mm • · · o

Hg until. so as not to exceed 300 C at the bottom. The resulting road • · · ··· · has a total aromatic chlorine content of 3 ppm.

M »• · • · ··· .. *; * For comparison, the same substance containing the same chlorine compounds is treated with sodium carbonate to give a substance with a total aromatic chlorine content of about 100 ° C. ppm.

Example 2_ .. DBT is treated as in Example 1, but using e e · ** NaOCoHg, KOCH3, KOC2H5, NaOCIKCH2 ^ under the conditions of Example 1.

• ♦ ·. ***** The results are summarized in a table.

e · ··· • «· •« ·

Example 3 ···. * * A) Treat DBT containing 1000 ppm PCB three

• e e O

l ”· hours at 280 ° C using 1% sodium hydroxide plate. A compound containing less than 15 ppm chlorine is obtained.

6 97276 b) Proceed as in a), but the DBT contains 1000 ppm tetrachlorobenzyltoluene.

The results are summarized in a table.

Example 4 a) A mineral oil containing 1000 ppm PCB is treated for three hours at 280 ° C using 1% CH 3 ONa. A substance containing less than 15 ppm of halogen is obtained.

b) as in a), but the mineral oil contains 1000 ppm octabromide phenyl.

The results are summarized in a table.

Example 5

To a reactor equipped with a rotary stirrer,. . 1600 g is placed on the condenser and the nitrogen jet. DBT and 32 g of sodium methylate. The mass begins to reflux

• I · O

• ** # 1 2 3 290 C and purge with a stream of nitrogen and mix. The flow of nitrogen • · * ··· 1 is then stopped and the radiator outlet joins. ...... ° ••• Insert the water tank. After treatment for 70 hours at 290 C, no gas release is observed. After cooling and filtration: no light compounds are found in the filtrate according to chromatographic analysis, (· · after washing the solid with monochlorobenzene 1, hexam • · · j ^ and drying under air protection (recovered weight). = 95 wt. • ♦ · • · · * .1% of the methylate used), its inf rapunas pektri • · ·! ΦΣ: is exactly the same as sodium methylate.

··· • · • · · ♦ · • · • · • · · ·· • · ·· • · 2 • · 3 7 97276

Table

Halogen content by weight in the treated and treated substance used in the distilled material quality __alcoholate__sa_

Example 2 DBT + 300 ppm chlorine in 1% CgH 2 ONa <15 ppm monochlorobenzyl-0.5% CHgOK <15 ppm in toluene form 0.5% CgH 2 OKa <15 ppm 0.5 * (CH 3) 2 CHONa 37 ppm

Example 3

BT 100 + 1000 ppm PCB

(6.5 chlorine) 1% CHgONa <15 ppm. . BT 100 + 1000 ppm tet- 1% CHgONa <15 ppm • · · ** ’# * rachlorobenzene 1 itolu- • * * ··· · enenia • ·· • · • * • * · ·» ·

Example 4 • ·

Mineral oil + 1% CHgONa <15 ppm::; 1000 ppm PCB (6.5 1% CHgONa <15 ppm chlorine) (*) Mineral oil + 1000 ppm octa-bromodiphenyl (**) • · • · · • * · ** (*) The distillation residue contains 580 ppm chlorine chloride in the form • · ·, the amount of oil used.

::: (**) Distillation in the residue contains 846 ppm of bromine in the form of bromide; ***; the amount of oil used.

* · · • · • · • e • · · • · • · · · · ·

Claims (6)

A process for the destruction of halogenated aryl products present in a non-halogenated organic product, such as a polyarylalkane or mineral oil, characterized in that a) these products are contacted with at least one anhydrous alkali metal alcoholate in the form of a powder or powder. for a period of time required to convert the organic halogen compounds into inorganic halogen compounds, b) the quantity of alcoholate exceeds the stoichiometric ratio based on the quantity of halogen; d) the temperature exceeds 220 ° C, and e) the non-halogenated organic product is recovered by distillation. 2. A process according to claim 1, characterized in that the halogenated aryl products are products containing aryl carbon substituted by chlorine and / or bromine. 3. A process according to claim 2, characterized in that the products containing aryl carbon are benzyltoluenes or triphenylmethanes or higher homologues thereof. *; A process according to claim 2, characterized in that the products containing aryl carbon are PCBs or dioxins or dibenzofurans. Process according to any of claims 1-4, characterized in that the temperature is poured between 220 and 300 ° C and preferably between 250 and 290 ° C. Process according to any of claims 1-5, characterized in that the alcoholate is preferably sodium methylate.