EP1590409A1

EP1590409A1 - Synthetic binding agent for producing powder paints, powder paints containing this agent, and coats and coatings produced therewith

Info

Publication number: EP1590409A1
Application number: EP04702607A
Authority: EP
Inventors: Gerhard Reich
Original assignee: Tigerwerk Lack- U Farbenfabrik & Co Kg GmbH
Current assignee: Tigerwerk Lack- U Farbenfabrik & Co Kg GmbH
Priority date: 2003-01-24
Filing date: 2004-01-16
Publication date: 2005-11-02
Also published as: AT412555B; WO2004065499A1; US20060183838A1; ATA972003A

Abstract

The invention relates to a synthetic binding agent for producing powder paints, which is mixed with pyrogenic oxides of silicon, aluminum or of titanium, preferably pyrogenic silicic acid, or mixtures thereof with primary particle sizes ranging from 5 to 65 nm. The invention also relates to powder paints containing said synthetic binding agent and to coats and coatings produced therewith.

Description

Plastic binders for the production of powder coatings, powder coatings containing them and coatings and coatings produced therewith

The invention relates to a plastic binder for the production of powder coatings, powder coatings containing them and coatings and coatings produced therewith.

Powder coatings have long been highly valued as a coating agent. Above all, the lack of solvents is extremely beneficial, both ecologically and economically.

According to common practice, plastic binders, which together have the potential for a subsequent curing reaction under the addition of heat or radiation, are intimately mixed together with optionally further substances such as pigments, fillers and additives in fine particles and then mixed in an extruder with heating to form a homogeneous plastic mass. This mass is cooled, broken, ground and sieved and then represents the powder coating.

A peculiarity in the production of powder coatings according to this mostly used extrusion process is the fact that this process is a continuous one, in which the dry mixture previously intimately pre-mixed as a batch, but which still constitutes a discontinuity at this point, ideally after passing through the extruder to represent a perfectly homogeneous mass through and through.

It is obvious that the above requirement for perfect homogeneity conflicts with the desire for the highest possible economic efficiency of the process. Nevertheless, it is - inevitable - state of the art that some. Powder coating formulation after a first extrusion due to technical and / or aesthetic deficiencies after appropriate nipping of the first extrudate has to be passed through the extruder again. In addition to economic disadvantages, multiple extrusion also has technical disadvantages. The danger of inadvertent contamination of the powder coating material by components that are not part of the formulation - recognizable for example Crater - grows with the scale of the process steps required. In addition, in the case of heat-curing formulations, there is the possibility of a partial nor reaction during the extrusion step. In such cases, multiple extrusions can of course lead to an increased nor reaction of the binding agent partners, which - in addition to more difficult to grind - is a reduction in quality. Properties such as the course of the powder coating and its ability to wet the substrate are usually reduced. If one assumes that difficulties in getting the powder coating materials to be technically and aesthetically completely satisfactory in just one extrusion step of the powder coatings are related, among other things, to a possibly too low system viscosity of the mixture in the extrader, then the use of offers to increase the system viscosity finely divided fillers based on the pyrogenic oxides of silicon, but also aluminum or titanium with particle sizes far below the μm range.

Examples of plastic binders in question here are synthetic resins such as polyester, poly (meth) acrylate, epoxy resins or mixtures thereof and - commonly referred to as hardeners - plastic binders such as β-hydroxyalkylamides, triglycidyl isocyanate, diglycidyl terephthalate, triglycidyl trimellitate, isocyanate adducts or mixtures thereof. Among the synthetic resin binders used for the production of powder coatings, the class of polyesters plays a special role due to their balanced property profile and the resulting broad applicability.

The term "pyrogenic oxides" is used to summarize highly disperse oxides which are produced by flame hydrolysis and which are hydrophilic as such. There are also versions which more or less result from a more or less extensive subsequent chemical reaction of their surface hydroxyl groups with organosilicon compounds have a pronounced hydrophobic character.

The largest range of technical applications has pyrogenic silica, it is - more than the other pyrogenic oxides - in numerous different subtleties (average particle sizes of the different types from approx. 7 - 40 nm) and is hydrophilic as such.

The use of such pyrogenic oxides in powder coating formulation is state of the art and is carried out for many reasons; Particularly noteworthy here are the reduction in the tendency of the varnish to run off when it is stoved or the improvement of its hiding power on edges. In addition, they represent fillers with a particularly pronounced reinforcing effect. These highly disperse substances are added to the dry mixture of the powder coating raw materials as an additive, ie in a small amount, and incorporated into the mass after the mixing process by subsequent extraction.

Corresponding experiments, a powder coating formulation containing numerous craters after only a single extraction by adding 0.75% Aerosil® 200 (highly disperse "pyrogenic" silica produced by flame hydrolysis of over 99.8% SiO ₂ content) - based on the formulation of the powder coating - to give a perfect appearance brought a significant improvement with regard to the craters to be observed, but on the other hand it could be seen that the surface of the powder coating now showed other defects: a slight ripple, which appears primarily to the eye as a lower gloss, as well as a noticeably poorer course These deficiencies could be largely eliminated by re-extrusion, but repeated extrusion, as previously stated, is not desirable.

The object of the invention is to create a possibility which makes it possible to provide powder coatings without technical or aesthetic defects by means of a single extrusion step of the underlying dry mixture.

The object is surprisingly achieved according to the invention in that the plastic binder is mixed with pyrogenic oxides of silicon, aluminum or titanium or mixtures thereof with primary particle sizes between 5 and 65 nm. Such a plastic binder is then used to produce powder coatings. The pyrogenic oxide (s) added to the plastic binder have, on the one hand, a reinforcing effect for the plastic binder and lead to an increase in the viscosity of the plastic binder. On the other hand, that brings before its deployment Powder coating production with pyrogenic oxides plastic binders that have already been mixed provide a significantly improved distribution of pyrogenic oxides in the finished powder coating than would be achieved when added to the dry batch of a powder coating.

This fact is surprising because, based on the manufacturer's information, the use of devices with a high shear rate (high-speed dissolvers, for example) to disperse Aerosil® - and accordingly also for aluminum oxide C and titanium dioxide P - in liquid media is necessary in order to remove these very finely divided substances disperse that their technical potential can be exploited, whereby details such as the design of the dissolver disc, its peripheral speed, the melt temperature and the optional use of ultrasound are also covered in the application notes (see for example: Technical Bulletin Aerosil® No. 54, Degussa AG, Frankfurt, Germany, "Aerosil® for Unsaturated Polyester Resins and Vinyl Ester Resins"). Surprising also because the half-moon stirrer of a laboratory apparatus for the production of polyester resins on a kg scale with a speed of only approx. 60 - 100 min ^_1 added one in tests en aerosil amount of 1% helps to achieve an incomparably better distribution in the final powder coating than can be achieved by adding an equivalent amount in the manner not according to the invention but according to the prior art, namely directly into the raw batch of the powder coating. These facts can also be seen from the examples below.

It is also surprising that a powder coating produced from the resin according to the invention not only shows advantages over a conventionally produced one in terms of its appearance, but also exceeds it in technical terms as well. The so-called "water stain test" (it is part of the quality specifications of the "Gütegemeinschaft für Stückbeschichtung", eV), in which powder-coated test sheets with water-dampened filter paper are kept under seal for 4 hours at 60 ° C, after which the extent of an undesired resulting lightening To examine, for example, shows clear advantages for that powder coating which was produced from the resin according to the invention. In addition, there are quality features such as flexibility of the lacquer layers (tested in the reverse impact test) or their resistance to rapid weathering (carried out with the UVB-313 fluorescent lamps in the Accelerated Weathering Tester from Q-Panel Comp.) At least equal to the powder coatings produced in a manner not according to the invention.

It is particularly advantageous if, according to the invention, the plastic binder is mixed with pyrogenic silica. According to the invention, the pyrogenic oxides can be surface-treated. According to a further feature of the invention, it is preferred that the primary particle sizes of the pyrogenic additive (s) are between 7 and 40 nm.

The invention further consists in that the pyrogenic additive (s) is contained in an amount of 0.05 to 10%, preferably 0.25 to 2.5, in particular 1%, based on the weight of the plastic binder ( are). The amount of pyrogenic oxides to be used advantageously depends inter alia on on the type, particle size and chemical surface properties of the pyrogenic additives.

The invention also relates to a powder coating consisting of a plastic binder, additives and optionally pigments and fillers, which is characterized in that the plastic binder is mixed with pyrogenic oxides of silicon, aluminum or titanium or mixtures thereof with primary particle sizes between 5 and 65 nm. The invention also includes a coating or a coating consisting of such a powder coating.

The nature of the invention is illustrated by the examples below, without restricting the invention thereby.

Comparative example - polyester resin containing carboxyl groups (resin 1) not according to the invention:

552.05 g of 2,2-dimethylpropane diol, 1.3 and 3.10 g of ethylene glycol are placed in a 2-1 reaction vessel equipped with a stirrer with a half moon-shaped stirring blade, temperature sensor, partial reflux column, distillation bridge and inert gas inlet (nitrogen) and with addition melted from 20 g of water and heating to a maximum of 140 ° C under a nitrogen atmosphere. 702.77 g are then added with stirring Terephthalic acid and 0.1%, based on the total amount of the finished resin, Sn-containing catalyst are added and the melt temperature is gradually increased to 240 ° C. The reaction is continued at this temperature until no more distillate is formed and the acid number of the hydroxy-functional polyester resin is <10 mg KOH / g polyester resin.

Then 207.68 g of isophthalic acid and 29.23 g of adipic acid are added and the esterification is continued until the desired acid number (about 33) has been reached, the reaction being last supported by the application of a vacuum, about 100 mbar. The finished resin 1 ultimately had the following key figures: SZ 33.4, OHZ 3.4.

Example - polyester resin (resin 2) containing carboxyl groups according to the invention:

13.19 g of Aerosil® 200 are added to the batch of the above first reaction stage, consisting of 2,2-dimethylpropanediol 1,3, ethylene glycol, terephthalic acid and Sn-containing catalyst, and the whole is reacted in an analogous manner to a hydroxy-functional polyester resin.

Isophthalic acid and adipic acid are then added in a manner analogous to that above, and the esterification process is continued as before until the desired acid number (about 33) is reached. The finished resin 2 ultimately had the following key figures: SZ 33.0, OHZ 3.7.

Using these polyester resins, which had previously been reduced to a grain size of <2 mm, green powder coatings were produced according to the following test recipe:

Production of powder coatings:

The raw materials of the individual formulations were intimately mixed and then extruded using a Prism TSC 16 PC extruder, screw length = 24 times the screw diameter (temperature control of the heating zones in the direction of the material flow: 110, 120 and 130 ° C, speed 400 min ^_1 ) , The cooled extra data were broken, ground on a classifier mill and sieved with a grain size limit of 100 μm. The powder coatings were then applied with a layer thickness of approx. 80 μm (finished coating film) to chromated aluminum sheets 0.7 mm thick and baked in a convection oven at 200 ° C. for 10 minutes.

Powder coating evaluation, visual:

Evaluation of the powder coatings, technical ("water stain test"):

Powder coating C made of resin 2 (according to the invention) is clearly superior to powder coatings A and B made of resin 1, which demonstrates the technical value of the invention.

Claims

claims:

1. Plastic binder for the production of powder coatings, characterized in that it is mixed with pyrogenic oxides of silicon, aluminum or titanium or mixtures thereof with primary particle sizes between 5 and 65 nm.

2. Plastic binder according spoke 1, characterized in that it is mixed with fumed silica.

3. Plastic binder according spoke 1 or 2, characterized in that the pyrogenic oxides are surface-treated.

4. Plastic binder according to one of claims 1 to 3, characterized in that the primary particle sizes of the (s) pyrogenic additives (s) are between 7 and 40 nm.

5. Plastic binder according to one of claims 1 to 4, characterized in that the (the) pyrogenic (n) additives (s) in an amount of 0.05 to 10% based on the weight of the plastic binder is (are).

6. Plastic binder according spoke 5, characterized in that the (the) pyrogenic (n) additives (s) in an amount of 0.25 to 2.5%, preferably 1%, based on the weight of the plastic binder is (are).

7. powder coating consisting of a plastic binder, additives and optionally pigments and fillers, characterized in that a plastic binder is mixed with pyrogenic oxides of silicon, aluminum or titanium or mixtures thereof with primary particle sizes between 5 and 65 nm.

8. Coating or coating consisting of a powder coating according to spoke 7.