DE4133487A1 - Determining stability of aq. compsn. contg. metal pigment esp. lacquer - by homogenising and degassing, leaving without drying and assessing surface change, useful for testing e.g. water-based, metallic paint of cars - Google Patents

Abstract

Determn. of the stability of an aq. compsn. (I) contg. metal pigment (II), is conducted by homogenising (I) and removing the gases present, then leaving (I) unagitated, without drying or evapn. of volatiles and determining the surface change. Pref. (I) is an aq. coating compsn. an intermediate for this or a component contg. (II) and pref. is dark-coloured. It contains 1.0-25.0 (wt.)% (II) which may be increased before test. (II) pref. is finely-divided Al pigment. (I) is pref. stirred for 1 hr to 5 days. The surface is tested in a film thickness of over 0.5 cm. The compsn. is left at 20-40 deg. C and the test time is 3 hrs to 3 days. The surface change is determined by direct or pref. indirect comparison with the surface of freshly homogenised and degassed (I), pref. by comparing the change in brilliance, hue and/or (II) orientation, esp. using a computer technique. USE/ADVANTAGE - The technique is quick and simple and can be automated. Suitable for testing e.g. water-based metallic paint for cars

Description

Lacquers are used on a large scale in the automotive industry. These often contain fine to create a special effect distributed metal pigments. For environmental reasons, more and more of organic solvents and water Solvent passed over. It turned out that fine distributed metal pigments are not always stable in the water phase are dispersible. On the one hand, this is due to the type and the size Surface of the metal pigment particles, on the other hand on the manufacturing necessary components of the water-based paint. The water-based paints can either contain acidic or alkaline components. These components exist however, increases the risk that under the storage conditions themselves react with the metal pigments or a chemical reaction of the water catalyze the pigment. On the one hand, this leads to a change in physical properties of the water-based paint material, on the other hand the optical properties of the finished paint film are also impaired.

In addition, however, there are also dangers as there are many reactions Hydrogen is created as a gas. This accumulates in sufficient Concentrations with oxygen, there is a risk of fire and explosion. The water-based paints are usually in tightly closed containers supplied so that no external influences can affect the paint. There is then a risk that due to the evolution of hydrogen forms an increased pressure. This can cause deformation of the storage vessel and even lead to leakage. So there is a risk that liquid paint material leaks and endangers the environment. From these For reasons it is necessary to check the stability properties of the water-based paints, check the metal pigments.

A common practice is that according to different Storage conditions the physical properties of the coating agent or the finished hardened lacquer layer can be examined. These However, proceeding requires a lot of experimental effort, it  application of the coating agent is sometimes necessary. These methods are therefore very time consuming and very expensive. Furthermore In this way, intermediate products can only be examined when they are processed into a ready-to-use paint material, whose measurement parameters correspond to the usual end product. However, that is very complex.

Another test method for the gassing stability of aqueous lacquer containing metal pigments is available in Color + Lacquer 4/1991, pp. 311-314, described. It consists in having such paints in tight introduces closed vessels over a long period of time - if necessary also at elevated temperature - stores and measures the gas volume formed. Here the problem arises that a sufficient amount of gas evolves and must be driven out of the paint, so that on the one hand Pressure increase, a noticeable deformation of the storage container or a Gas volume flow occurs. Another requirement is that the Storage containers or the connections of the measuring apparatus must be tightly closed have to. However, this is difficult to achieve especially with hydrogen, for which series tests and multiple parallel tests are necessary. This procedure therefore has a high sensitivity to errors and is therefore not suitable for practice.

The object of the present invention is therefore to provide a method deliver with the quick and easy way, if necessary also automatically detectable, a test for gas stability from Waterborne basecoats containing metal pigments or precursors therefor can be carried out.

The procedure consists in first either investigating waterborne basecoat containing metallic pigments, or the investigating metal pigment-containing component mixed with a test lacquer or the intermediate to be examined containing metallic pigments, if necessary, increasing the proportion of metal pigments, homogeneous stirred and freed of dissolved gases. Then you create one homogeneous surface from the material obtained and leaves it still and rest without drying or evaporation of volatile components.  

Then the visual change in the surface is assessed. This can e.g. B. directly compared to a surface of a fresh homogenized same material. The comparison can also indirectly by recording surface measurements of the freshly prepared Surface with appropriate values after resting. Latter Procedure is particularly good for automatic measurement and Suitable for image recording devices.

In the following, the material to be examined is used as a lacquer for simplification referred to, it being understood that this includes the above explained test varnishes and intermediates are to be understood.

While in the freshly homogenized surface the pigments are even are finely distributed and show a uniform appearance a gas movement, albeit slow, in the Paint surface. This leads to the fact that the originally homogeneous Surface divided into areas where the orientation of the pigments and Effect pigment particles is disturbed. This leads to this Surface areas have a color and brightness behavior that is significantly different from the starting material and therefore in many Gradations can be assessed gradually. Assessing the Differences to the freshly homogenized starting material can either visually with the naked eye, or by measuring equipment, for example Differences in brightness and / or color and / or different Detect alignments of metal pigments or effect pigments. Measuring equipment can optionally with automatic Image processing devices can be combined. If the storage conditions of the surface to be tested are reproducible Get measurement results.

In order to get a sufficient statement about the stability, it is necessary that the amount of finely divided metal pigments contained is from 0.2 to 35% by weight, preferably from 1.0 to 25% by weight, in each case based on the total composition of the surface to be tested educational material. Usual metallic base lacquers for the The automotive industry generally contains 1 to 5% by weight. Metal pigment particles. Intermediates or aqueous metal pigment containing  Paints for other industrial purposes can have significantly higher proportions 25% included. To make a clear statement about the stability of the Obtaining pigments yourself can help check the level of fine distributed metal pigment to a higher than that used in practice Concentration can be increased. By doing this, the The duration of the test was reduced and the unambiguity of the statement increased without falsifying the chemical reaction.

The finely divided metal pigments are the usual ones in the paint industry pigments used. For example, they are finely divided Aluminum flakes, but other metal pigments are also possible. The Metal pigments are in the commercially available form, e.g. B. as Metal pigment paste or used as a powder. It is possible that these are specially prepared to achieve higher stability, e.g. B. can the surface of the particles with a hydrophobic Protective coating or a corrosion inhibitor. For that are for example, phosphoric acid esters or stearates.

The composition of a metallic waterborne basecoat makes it possible to that parts of the protective layer on the pigments dissolve and thus unite Allow attack and decomposition of the metal pigments. To one Statement about the stability of the paint or the intermediate products too obtained, these metal pigments are in the commercial, with the Protective layer provided, form the test method according to the invention subjected.

Well-known metallic basecoats are also known as waterborne basecoats understand. These contain the usual metal pigments water-dilutable binders, e.g. B. based on polyester, polyacrylates or polyurethanes, water and organic cosolvents, e.g. B. alcohols or glycol ethers, pigments and fillers, e.g. B. titanium dioxide, Iriodin pigments, carbon black or organic coloring pigments, leveling agents, Anti-cratering agents, wetting agents, defoamers, neutralizing agents, e.g. B. organic acids or bases such as amines and / or catalysts.

The waterborne basecoats can either be examined directly or they are in the shade, e.g. B. adjusted by tinting pastes. These adjustments  do not change the gassing stability behavior. Intermediate and intermediate products can be incorporated into a test varnish that contains the individual components contains a common waterborne basecoat. This way too components other than metal pigments such. B. catalysts, Neutralizers or binders related to their influence be examined with the metal pigments. Such a test varnish needs in its application properties are not to be optimized. It is also possible to directly target intermediates for their stability examine. This is necessary, for example, if it is intermediates containing metallic pigments that are said to be storable.

The test time can be 1 hour to 5 days. The storage or that Leave to stand at temperatures of 15-65 ° C, preferably at 20-40 ° C. Due to the increased temperature, the chemical Response of gas evolution accelerates and the storage time can be shortened will. However, care must be taken to ensure that the temperature increases Convection processes occur that can falsify the test result.

It is necessary to degas the paint well before the examination, because rising gas bubbles bursting open on the surface Initial state of the surface as well as the result achieved change. The removal of gas bubbles can be done by applying vacuum and be supported by stirring the paint mixture.

When storing, make sure that there is a greater evaporation of to avoid volatile components such as solvent components. It is also important to ensure that gas exchange is possible no dangerous gas concentrations form. That can be achieved be covered by a masking device be covered.

The formation of the surface depends on the viscosity or thixotropy of the paint. The viscosity of the paint to be measured is to be set so that the pigments have sufficient stability against sedimentation or Show phase separation. On the other hand, there must be a flow and a Alignment of the metallic pigment particles on the surface may be possible. The viscosity can optionally be increased by adding water or organic solvent can be adjusted.  

The surface to be examined can be formed, for example by leaving the homogenized material to be examined in a vessel, e.g. B. the homogenizing or stirring vessel or another Vessel. The layer thickness is preferably more than 0.5 cm, particularly preferably more than 1 cm.

The measuring effect is mainly based on the alignment of the metallic Pigment particles; however, it is also the visual assessment for Color effects sensitive. These effects are preferred for dark ones Color tones can be seen particularly well. Become commercially available paint materials examined, the light shades can therefore use a dark tint paste, e.g. B. a soot paste. Intermediates can also be dark be colored. For the investigation of preliminary and intermediate products, e.g. B. Metallic pastes, solid metallic pigment particles, additives or Lacquer binders, a test lacquer is preferred. In this test varnish that is Integrated preliminary or intermediate product to be examined. The test varnish is preferably dark pigmented and contains all essential for Lacquer formulation necessary components. It is an appropriate one Adjust the viscosity of the test varnish.

The measurement samples can be assessed at different times occur. It can be done visually, e.g. B. by measuring the Brightness, photographically or with a computerized Image processing. Gassing-stable samples show only a slight drop the brightness, the metal orientation and / or the color values over several Days, while in the case of unstable samples significant changes in the Surface structures can be observed within a few hours.

Another possibility for using the method according to the invention is that generally unstable, gas evolving preparations can be examined. However, it is then used to generate the measuring effect necessary, these preparations a suitable amount of a stable finely divided metal pigment or another stable effect pigment to add.

The method according to the invention enables fast and reproducible mode of operation to ensure the gassing stability of a  water-based paint containing metal pigments and its precursors examine.

Claims (14)

1. A method for examining the stability of an aqueous metal pigment-containing composition, characterized in that the composition is homogenized and freed from gases contained therein, whereupon the composition is left to stand still without substantial drying out or substantial evaporation of volatile constituents and then the change in the surface of the Composition judged. 2. The method according to claim 1, characterized in that as an aqueous metal pigment-containing composition an aqueous coating agent Intermediate for it, or a component containing metal pigment for aqueous coating agent, mixed with a test bath is examined. 3. The method according to claim 1 or 2, characterized in that 1 hour to 5 days. 4. The method according to any one of claims 1 to 3, characterized in that the surface of the composition with a layer thickness of is examined more than 0.5 cm. 5. The method according to any one of the preceding claims, characterized characterized in that the composition to be investigated sets a content of 1.0 to 25.0% by weight of metal pigments. 6. The method according to any one of the preceding claims, characterized characterized in that the composition to be examined is dark colors.   7. The method according to any one of the preceding claims, characterized characterized in that one pre-the amount of the metal pigments contained the investigation increased. 8. The method according to any one of the preceding claims, characterized characterized in that a composition with finely divided Aluminum pigment examined. 9. The method according to any one of the preceding claims, characterized characterized that the temperature at rest between 20-40 ° C. is held. 10. The method according to any one of the preceding claims, characterized characterized in that the test time is 3 hours to 3 days. 11. The method according to any one of claims 1 to 10, characterized in that that one can change the surface by direct or indirect Comparison with the surface of the freshly homogenized and from contained in the gas-free composition. 12. The method according to claim 11, characterized in that one for indirect comparison of surface measurements of the freshly homogenized and records the composition freed of gases contained therein and later with corresponding measurements of the surface after compares still rest. 13. The method according to any one of the preceding claims, characterized characterized in that for the assessment or comparison of the Surfaces the different brightness, the different Color and / or the different orientation of the metal pigments is measured. 14. The method according to any one of the preceding claims, characterized characterized in that the evaluation of the assessment or the Comparison carried out via computer-aided image processing becomes.