WO1991019679A1 - Coagulants based on double-layer hydroxide compounds - Google Patents

Abstract

The invention relates to coagulants for lacquers, waxes and/or coating materials containing double-layer hydroxide compounds, aqueous suspensions containing the coagulants, a process for producing the coagulants and the use of the coagulants and/or of the aqueous suspension. In particular, the invention relates to the use of hydrotalcite, pyroaurite and magaldrate as new coagulants in lacquer-disposal installations.

Description

 Coagulant based on double layer hydroxide compounds

The invention relates to coagulants for lacquers, waxes and / or coating compositions containing double-layer hydroxide compounds, aqueous slurries containing the coagulants, a process for the preparation of the coagulants and the use of the coagulants and / or the aqueous slurry.

When applying lacquers, waxes or similar coating materials containing water-insoluble organic substances to metallic or plastic surfaces, e.g. in the automotive industry, it is not possible to completely apply the paints or coating materials to the parts to be coated. Especially when painting motor vehicle bodies, so-called "overspray" occurs in the paint spray booths, which is removed from the paint spray booths by means of water and rinsed into a so-called "calming basin". In order not on the one hand to disturb the function of the water-carrying pipe, nozzle and sprinkler systems by adhesive paint particles and on the other hand to dispose of the circulating water from the absorbed ingredients, chemicals have to be added to the water to coagulate the substances mentioned. The addition of chemicals was intended to detack the sprayed and water-borne paint particles and to agglomerate them into a disposable coagulate in one operation.

There is a range of neutral and alkaline coagulants for conventional paints, especially those used in the automotive industry Products. In order to achieve coagulation, ie detackification of the paint particles and their agglomeration to form a dispensable coagulate, the water circulating in the paint spray booths and connected lines and assemblies has hitherto been added to powdered or liquid alkaline and neutral products.

The agents known hitherto had a number of disadvantages when used for the coagulation of conventional lacquers: they took a relatively long time to coagulate the lacquer particles and to satisfactorily dispose of the water used to remove excess lacquer mist. In unfavorable cases, defective detackification led to the deposition of paint particles that were sticking together in the entire system area. Many of the coagulants known up to that time contained substances (for example inorganic anions such as chloride or sulfate) which accumulated in the circulating water and had a corrosive effect on the parts of the plant. The frequent bath changes that this forced were increasingly regarded as disadvantageous. Since an extension of the service life of the disposal baths is desirable for water technology reasons, the use of substances which accumulate rapidly in the disposal baths and thus impair the functionality of the system for various reasons is undesirable.

In the processes for the coagulation of paints and coating agents known from the prior art, it largely depended on the existing technical systems whether either a paint coagulating agent was used which floated the coagulate in the calming basin, ie caused it to float, or whether a coagulant through which the coagulate sedimented had to be used. In the former case, the coagulum was skimmed off possible from the water surface, while in the latter case the sedimented coagulates were removed from the pool floor by means of a scraper belt. However, paint disposal lines were increasingly used in which it was necessary to keep the detackified and coagulated paint particles in a uniform dispersion. Depending on the paint quality and type of paint, it was necessary to influence the specific behavior of the paint particles in individual cases by more strongly sedimenting paints that tended to float, so that a uniform dispersion could be obtained, or by causing paints that tended to sediment. float more strongly and thus also remain in dispersion. (J. Geke in Surface + JOT, U_ 1986, pp. 43 to 46).

Frequently used agents, which previously contributed to satisfactory paint coagulation in such systems, contained layered silicates which were introduced into the supply lines to the spray booths. EP-A 0 193 668 discloses the use of Hectoriteπ in connection with defoamers for detackifying and clarifying waste water containing overspray. For example, paint adsorption was able to be carried out on the surface of bentonites, thus ensuring that the paint particles were detached.

DE-PS 3421 289 discloses agents for detackifying and coagulating synthetic resin lacquer components in wet separators of spray painting systems which contain 5 to 20% by weight of a wax, 10 to 30% by weight of an alkanolamine, 0.5 to 5% by weight .-% contain a defoamer and water. Although these agents represent an advance over the prior art described above, they have not been able to disperse paints which are difficult to detack, such as so-called "high-solid paints" with a "high solids content" or polyurethane stone chip protection primer filler paints hold and thus enable continuous coagulum withdrawal. They also contain alkanolamines, the use of which is not desirable due to the known disadvantages associated therewith.

The object of the present invention was to provide coagulants for paints and bleaching agents which remedy the disadvantages of the prior art mentioned. In particular, the new coagulants should not only enable the paints and coating compositions to be detackified well to form agglomerates, but should also promote good discharge of the agglomerates formed by keeping the solids evenly in the dispersion. This was intended to ensure continuous removal of the coagulates from the circulating water without settling in critical system parts, both in the above-mentioned systems with continuous coagulum removal and in conventional flotation or sedimentation systems.

In a first embodiment, the invention relates to coagulants for lacquers, waxes and / or coating compositions containing double-layer hydroxide compounds of the general formula (I)

[MII ₁ _ _X MΠI _X ( ₀ H) ₂ ] A _X. mH ₂ 0,

in which

M ¹¹ for at least one divalent metal cation, Vm for at least one trivalent metal cation, A for the equivalent of an anion of a mono- or polybasic

Acid,

1/6 <x <1/2 and

0 <m <1. These so-called "double vision hydroxides" are known in the literature, for example from R. Allmann, Chimia 24 (1977), page 99. Chemically they are mixed basic hydroxy salts of divalent and trivalent metal cations.

Due to the different compositions, also with regard to the water content, line broadening and shifting can be explained in the X-ray diffraction diagram. Natural and synthetic double-layer hydroxides continuously release water when heated or calcined. The water of crystallization is completely removed at 200 ° C., higher temperatures lead to the elimination of water from the hydroxide structure and of carbon dioxide from the carbonate contained as the usual anion. The structures of the double-layer hydroxides are broken down in this process.

In a preferred embodiment of the present invention, the coagulants are characterized in that the anion A of the formula (I) is selected from carbonate, sulfate, chloride, Ni¬ trate and phosphate ions. Because of the extraordinarily large distribution of carbonate ions, even with naturally occurring double-layer hydroxides, carbonate ions are particularly preferred.

In principle, there are no restrictions in the choice of the divalent and trivalent metal cations, but the divalent metal cation of the formula (I) is preferably selected from

Magnesium, calcium, manganese, zinc and copper. The trivalent metal cation of the formula (I) is preferably selected from iron and aluminum. If - in connection with the explanation of the general formula (I) - there is talk of at least one divalent and trivalent metal cation, this means that in such double-layer hydroxide compounds if necessary, several divalent or trivalent metal cations can be present side by side.

A prototype of preferred cationic double layer hydroxide compounds is the mineral hydrotalcite, which has the following ideal formula:

[Mg ₆ Al ₂ (0H) ₁₆ ] CO 3 x 4 H ₂ 0

The above ideal formula corresponds to the general formula (I), provided that the ideal formula is normalized to "(0H)", i.e. all indices are divided by the number 8.

Hydrotalcite is structurally derived from brucite [Mg (0H) ₂ ]. Brucite crystallizes in a layer structure with the metal ions in octahedral gaps between two layers of densely packed hydroxide ions, but only every second layer of the octahedral gaps is occupied. In hydrotalcite, the layer package receives a positive charge in that some magnesium ions are substituted by aluminum ions. This positive charge is compensated for by anions which are located in the interlayers together with crystal water.

The layer structure is clear from X-ray diffraction diagrams, which can also be used for characterization (JCPDS file: 22-700).

Synthetically produced hydrotalcites are generally known, among others they are described in DE-OS 15 92 126, DE-PS 33 06 822, DE-OS 3346 943 and EP-A 0 207811. EP-A 0 207811 describes a particularly finely divided product described that arises during a Conti precipitation (flash precipitation) when one looks at the starting solutions (Metal salt solution and alkaline carbonate solution) can flow together continuously, then filtered, washed and the product left in the moist state.

Further examples are the pyroaurite with the formula: [Mg6Fe ₂ (0H) i6] C03 x 4.5 H 0, magaldrate with the approximate formula [MgιoAl5 (OH) ₃₀ ] (S0 ₄ ) ₂ (OH) x H ₂ 0 and [Zn ₆ Al ₂ (0H) ι ₆ ] C0 ₃ xm H ₂ 0.

In addition, the agents according to the invention for the coagulation of lacquers, waxes and / or coating agents may optionally also contain one or more active substances and / or auxiliaries known per se from the prior art for coagulation and / or confectioning, in particular flocculation aids, defoamers Contain corrosion inhibitors, hardness formers, waxes and / or biocides. These must be such that they do not interact with the previously mentioned components in a way that adversely affects the coagulation result. Examples include cyanamides and / or dicyandiamide and / or calcium cyanamide. These compounds are known from DE-OS 3412763.1 for use in coating coagulation. Other components can be calcium and / or aluminum and / or magnesium compounds. In addition, flocculants such as Polyethyleni ine and / or Polyacryla ide can be added. Their molecular masses are preferably in the range from about 5 × 10 ⁴ to 5 × 10 7 D. Waxes, such as are described, for example, in DE-PS 27 58873 or DE-PS 34 21 289, can be used as further active ingredients which may be added.

Special requirements, such as B. the setting of a certain pH value or the antimicrobial treatment of the coagulation agents can be taken into account in that the agents contain special additives. For example, boric acid, the has antimicrobial effect and may also contribute to pH adjustment, as well as biocides, e.g. B. formaldehyde, isothiazolines and their derivatives and pyridine-N-oxide and its derivatives. Phosphoric acid, organic acids such as citric acid and other non-corrosive acids or their acid salts may also be used to adjust the pH. Corrosion inhibitors and defoamers are also possible as further possible constituents of the coagulants according to the invention. In addition to the agents known for this purpose from the prior art, the product Dehydran ^R F (from Henkel KGaA) has proven itself as a defoamer.

If a special type of lacquer disposal system requires sedimentation of the coagulum, then known sedimentation aids can be added to the coagulants according to the invention.

The invention also includes aqueous slurries of the coagulants mentioned. In preferred embodiments, these slurries contain 2 to 30% by weight of coagulants and, if appropriate, of the other active substances and / or auxiliaries mentioned above. The rest of it then consists of water. The formulation of the coagulants according to the invention as aqueous slurries has the advantage that the double-layer hydroxide compounds are already in the dispersed state immediately before use in the coagulation and their detackifying and coagulating effect immediately after addition to the circulating water and / or settling basin can unfold. Of course, however, it is also possible to transport the coagulants in solid form to the place of use, then convert them into a slurry by simply dissolving or suspending them in the desired amount of water, and then transferring them to the slurry U! Water up or watch the calming pool. The addition is advantageously carried out at a point with strong turbulence of the circulating water when the pump is running or using a conventional stirrer in order to ensure rapid distribution.

For the purposes of the present invention, preference is given to using particularly finely divided (flash-precipitated) products. In particular, hydrotalcite and pyroaurite products are stirred with a fast stirrer at 10,000 to 15,000 revolutions / min and added to the paint suspension. In both samples, coarsely disperse, slowly sedimenting flocculations with clear to slightly cloudy solutions are generally observed. By entering small air bubbles, e.g. stirring with the ultra-stirrer results in rapid flotation of the entire solid content. The solutions thus obtained are usually clear and colorless. Post-treatment with one of the above-mentioned flocculation aids can generally be dispensed with when using flash-precipitated products.

Another embodiment of the present invention is the "in situ" precipitation of double-sighted hydroxide compounds in the presence of paints, waxes and / or coating agents. Here, a water-soluble salt of the divalent metal cations is reacted with hydroxyl complexes of trivalent metal cations. So that salting-up of the bath liquid is kept as low as possible, the production of hydrotalcite is preferably carried out by reaction of soluble magnesium salts and aluminate lye.

After addition and dissolution of, for example, the magnesium salts such as magnesium nitrate, the ^" aluminate solution ^" can be metered in. After the stoichiometric addition has ended, the mixture is left to stir for some time, after which a medium-disperse precipitate with a a clear and colorless solution. The pH of the aqueous phase is preferably in the range from 8 to 9. If solutions are still cloudy, a further treatment with one of the abovementioned flocculants may be necessary.

The same coagulation results can be obtained if the lacquer is metered into a suspension of the double-layer hydroxide compounds, as is practiced in principle in overspray coagulation.

The coagulants according to the invention or their aqueous slurries (slurries) are used for the coagulation of paints, waxes and / or coating agents in circulating water and sedimentation tanks in paint disposal systems. The aqueous slurries according to the invention preferably contain the coagulants in an amount of 2 to 30% by weight. They are continuously mixed with the circulating water and / or the settling basin of the plants by means of known, suitable metering devices, for which the aqueous slurries described are particularly suitable. It is also possible to add the agents discontinuously, for example once or several times a day. In a preferred mode of use, the amounts used are such that the amount of coagulant is in the range from 1 to 100% by weight, preferably 2 to 10% by weight, based on the paint overspray. This can be achieved, for example, with a basic approach of 0.1 to 0.3% based on the total amount of circulating water.

The agents for coagulating paints, waxes and coating agents in accordance with the above description show excellent properties when used: for example, the paint particles are not only completely detacked, but also with the circulating water in the form of a readily removable coagulum from the were carried out without disturbing the system parts due to sticking or blockages. The paint particles are kept floating in the dispersion and can thus be easily separated from the circulating water even in continuously operating disposal systems. Even in conventional plants, there are no problems with separating the coagulum. They are just as suitable for use in conventional systems that float or sediment the detackified paint coagulate as in the recently used, continuously operating disposal systems that keep the coagulate in the dispersion and continuously dispose of it. In particular, with the previous methods and agents, paints that are difficult to dispose of, such as high-solid topcoats or PUR stone chip protective primer fillers, can be detacked without any problems and removed from the systems. In addition, there are application-technical advantages in that the agents can be formulated in liquid form, that is to say as aqueous slurries, and are automatically added to the circulating water and calming basin without a premixing system, that is to say with pumps to be continuously monitored and controlled can. There is no odor nuisance due to strong smelling ingredients.

The invention is illustrated by the following examples. Unless otherwise stated, all amounts are given in% by weight, based on the ready-to-use coagulant. Examples:

Two different processes for coating coagulation were investigated. The first method (Examples 1.1 to 6.2) is based on a hydro basecoat. The coagulation experiments were carried out on a 1/2 1 scale. Conditions that were as real as possible were simulated:

The coating of overspray from typical spray booths in the automotive industry is about 25 kg / h. With a working time of 16 hours in 2-shift operation and a working pool capacity of around 60 m ^, a concentration of paint of 6 to 7 g / 1 builds up in the circulating water within one day. A lacquer concentration of 5 g / l was therefore set and used for the subsequent coagulation and precipitation experiments. In the second method, tests were carried out with a 90 1 pilot plant. Different Ford hoe (red and white topcoat, primer and clearcoat) were used.

Example 1.1

According to the first variant, 500 ml of a hydro basecoat suspension with a concentration of 5 g / l in water were reacted with 1 g of commercially available hydrotalcite with stirring and stirred for a further 2 min. A finely dispersed precipitate with a highly cloudy, protruding solution was observed.

A polyurethane / polyester lacquer was used as the hydro base lacquer, which corresponds to the type of binder PU7 PE melamine. This has a solids content of approximately 24% by weight and a binder content of approximately 19.5% by weight. This varnish has a solvent content (Water and mono- and dihydric alcohols) of about 76% by weight.

Example 1.2

According to Example 1.1, 1 g of calcined hydrotalcite (prepared by heating hydrotalcite to 500 ° C. in the course of 2 hours, loss in mass approx. 40% by weight) was used. A medium-sized precipitate with a moderately cloudy, protruding solution was observed.

Example 1.3

According to Example 1.1, 5 g of flash-precipitated hydrotalcite with 20% solids content 1 were used. A coarse reverse flocculation (slowly sedifying) with a slightly cloudy, protruding solution was observed; aftertreatment with an ultra-stirrer (approx. 15000 revolutions / min) resulted in a fast flotation of the solids content and a clear solution.

Example 1.4

According to Example 1.1, 5 g of flash-precipitated pyroaurite with 25% solids content was used. The observations correspond to those of Example 1.3, but a slightly cloudy solution was obtained.

Example 1.5

5.1 g of Mg (N03) ₂ were dissolved in water to give 1 liter of a hydrobase lacquer suspension. 6 H ₂ 0 and stirring with a Hydrotalcite formula equivalent amount of an aluminate solution containing 11.1% Al 03 and 19.1% Na ₂ 0.

A medium-disperse precipitate with a slightly cloudy, protruding solution was obtained.

Example 2.1

According to the first process variant, 500 ml of the hydrobase lacquer suspension according to Example 1.1 with a concentration of 5 g / 1, 1 g of commercially available hydrotalcite and 10 ml of a cationic flocculant were added. Approximately 1 min after the addition of the double layer hydroxide phase, the flocculant was added as a 0.1% solution and stirring was continued for 2 min. The solution above was clear and discolored.

A flocculant used was a polyacrylamide-based one which was commercially available as a 0.1% solution, for example under the designation P-3-ferrocryl 8767 from the applicant.

According to Example 2.1, 500 mg of calcined hydrotalcite and 10 ml of cationic flocculant were used.

Alternatively, 1 g of calcined hydrotalcite and 5 and 10 ml of cationic flocculant were used.

In addition, reaction was carried out with 2 g of calcined hydrotalcite and 5 ml of the cationic floating aid. In all three cases there were medium to coarse flakes, the protruding solutions were clear and discolored.

Example 2.2

In accordance with Example 2.1, 2.5 g of flash-precipitated hydrotalcite (20% solids content) and 25 ml of cationic flocculation aid were used. Alternatively, 5 g of flash-precipitated hydrotalcite and 10 and 25 ml of cationic flocculation aid were used.

In addition, 10 g of flash-precipitated hydrotalcite and 10 ml of cationic flocculant were used.

In all three of the cases mentioned, medium to coarse-grained precipitation occurred; the protruding solutions were clear and discolored.

Example 2.3

According to Example 2.1, 5 g of flash-precipitated pyroaurite (25% solids content) and 10 ml of flocculant were used.

Here, too, medium to coarse-flocculent precipitation was found, the supernatant solutions were clear and discolored.

Example 2.4

According to Example 2.1, 5.1 g of Mg (N © 3) was dissolved in 1 l of a lacquer suspension in water. 6 H 0 and mixed with stirring with an amount equivalent to the hydrotalcite formula of an aluminate which contained 11.1% Al ₂ 03 and 19.1% Na 0. Subsequently 40 ml of the flocculant were added. The suspension had a pH of 8 to 9.

Here too, medium to coarse-flocculent precipitation was evident; the remaining solutions were clear and discolored.

A corresponding amount of hydrotalcite (X) in g according to the following Table 1 was suspended in 300 ml of water and a certain amount of an undiluted hydro-based lacquer (Y) in g according to Table 1 was added with stirring.

After about 1 min, Z ml of a 0.1% solution of the above-mentioned flocculant were added, the mixture was left to react for a further 2 min and then sedimented.

Table 1

Hydrotalcite (X)

Lacquer (Y) 0.7 0.7 0.7 1.3 1.3

ml flocculant (Z) 3 3 1 6 3 medium

Medium-Ms coarsely dispersed precipitates and slightly cloudy to clear solutions were observed. Example 3.1

2 g of commercially available hydrotalcite were added to 300 ml of a suspension of 1.5 g of the above-mentioned hydro base lacquer with vigorous stirring, and 6 ml of a neutral nonionic flocculant were then added. After stirring for 2 min, the suspension was allowed to sediment. Coarse-flocculated precipitates and almost clear, protruding solutions were obtained. As a neutral flocculant, a polyacrylic based was used which is commercially available as a 0.1% solution, for example under the name P-3-ferrocryl 8740 from the applicant.

Example 3.2

According to Example 3.1, 10 ml of the neutral flocculant was added. Here too, coarse-fluffy precipitates and almost clear, protruding solutions were obtained.

Example 3.3

According to Example 3.1, 5 g of commercially available hydrotalcite and 6 ml of the neutral flocculant were used. A flaky precipitate with a practically clear solution was also observed here.

Example 4.1

According to Example 1.1, 1.25 g of magaldrate was added to 500 ml of the lacquer suspension with a concentration of 5 g / l while stirring. The mixture was stirred for a further 5 min, after which a finely dispersed precipitate was observed in the suspension with a highly cloudy, protruding solution. Example 4.2

According to Example 4.1, 2.5 g of magaldrate were used. A finely dispersed precipitate with cloudy supernatant solution was observed in the suspension.

Example 4.3

When using an amount of calcined magaldrate according to Example 4.1 (produced by heating magaldrate to 500 ° C. over the course of 2 h, loss in mass approx. 35% by weight) to the lacquer suspensions, a medium-disperse precipitate with moderately cloudy, protruding Solution can be observed that had a low opalescence.

Example 4.4

When using 2.5 g of calcined magaldrate according to Example 5.3, a medium-disperse precipitate with moderately cloudy, protruding solution was also observed, which had a low opalescence.

Example 5

According to Example 2.1, magaldrate or calcined magaldrate was added under the abovementioned conditions. After stirring for 5 min, 10 ml of the 0.1% cationic flocculant solution were added. When using 1.25 g of magaldrate, medium-dispersed, -dedicated coagulates with a clear, protruding solution were obtained. When using 2.5 g of magaldrate, a slight clouding of the supernatant solution was observed. In the Using calcined magaldrate gave flaky precipitates, but with strongly cloudy solutions.

Example 6.1

According to Example 1.1, 500 g of the paint suspension with a content of 5 g / 1 was 3.4 g of the flash-precipitated Zn / Al product [ZnöAl (0H) i6] CO3. mH ₂ 0 (flash-precipitated laboratory product, solids content 36.4%) and stirred vigorously. Vuminous, slowly sedimenting precipitates with medium-cloudy, supernatant solutions were obtained. Aftertreatment with an ultrasonic stirrer (approx. 15000 revolutions / min) resulted in a fast flotation of the solids content with a medium cloudy solution.

With further addition of flocculants, the coarse disperse precipitation remains. The protruding solutions are slightly clouded or clear.

Example 6.2

Using 6.7 g of the flash-precipitated Zn-Al product according to Example 6.1, the procedure was as in Example 1.1. A voluminous, slowly sedimenting precipitate with a slightly cloudy, protruding solution was obtained. Aftertreatment with an ultra-stirrer resulted in rapid flotation of the solids content with a medium-cloudy solution. When the neutral flocculant was added, the coarsely dispersed precipitates remained. The solution above was clear. Example 7

In the second variant, the implementation with solvent-based paints was examined. The following paint coagulation tests were carried out in a test spray booth (90 l pilot plant). The following composition served as a coagulating agent:

30% hydrotalcite (flash-precipitated hydrotalcite paste, 8%),

2% dicyandiamide,

2% neutral flocculant, 66% water (fully desalinated).

265 g of the batch were stirred for 1 h at 1000 revolutions / min with a propeller stirrer.

With the tested standard varnishes from Ford (Primer Surfacer with a solids content of more than 55% and a solvent mixture, top coat solids with a solids content of more than 50% and a solvent mixture), each of which was sprayed with 70 g the following results:

The topcoat red, topcoat white, primer and the clearcoat could each be detacked, with the precipitation occurring in finely dispersed form. The coagulated products were partly sedimenting and partly floating.

Claims

Patent claims

1. Coagulants for lacquers, waxes and / or coating compositions containing double-layer hydroxide compounds of the general formula (I)

[MII _{1 X} IΠ _X (OH) ₂ ] A _X. mH ₂ 0,

in which

M-- for at least one divalent metal cation, M ¹¹ * for at least one trivalent metal cation, A for the equivalent of an anion of a mono- or polybasic acid,

1/6 <x <1/2 and 0 <m <1.

2. Coagulant according to claim 1, characterized in that the anion A of formula (I) is selected from carbonate, sulfate, chloride, nitrate and phosphate ions.

3. Coagulant according to claim 1, characterized in that the divalent metal cation of formula 1 is selected from magnesium, calcium, manganese, zinc and copper.

4. Coagulant according to claim 1, characterized in that the trivalent metal cation of formula 1 is selected from iron or aluminum. 5. Coagulant according to claim 1, containing one or more compounds of formula (I) selected from hydrotalcite [Mg ₆ Al ₂ (0H) ₁₆ ] C0 _3rd 4 H ₂ 0, pyroaurite [Mg ₆ Fe ₂ (OH) ₁₆ ] CO 3. 4,

5 H ₂ 0, magaldrate [MgιoAl5 (OH) 3i] (Sθ4) ₂ . mH ₂ 0 and [Zn6Al ₂ (0H) i6] CO3. mH ₂ 0.

6. Coagulant according to claims 1 to 5, additionally containing one or more active substances and / or auxiliaries known per se for coagulation or confectioning, in particular flocculants, defoamers, corrosion inhibitors, detackifiers, waxes and / or biocides.

7. coagulant according to claim 6, containing as added active substances and / or auxiliary substances, dicyandiamide, calcium, aluminum and / or magnesium compounds, polyethyleneimines, polyacrylamides and / or acids.

8. Aqueous slurry containing coagulant according to claims 1 to 7 in an amount of 2 to 30 wt .-%.

9. Preparation of the coagulant according to claim 1 by in-situ precipitation of the double-layer hydroxides in the presence of lacquers, waxes and / or coating agents by reacting water-soluble salts of divalent metal cations with hydroxo-complexes of trivalent metal cations.

10. Use of the coagulation agents according to claims 1 to 9 for coagulating paints, waxes and / or coating agents in water and / or treatment pools of paint disposal systems.

11. Use according to claim 10, characterized by a concentration of the coagulant in the range from 1 to 100% by weight, preferably 2 to 10% by weight, based on the paint overspray.