EP0817684B1 - Method of applying a multiple-layer enamelling - Google Patents

Abstract

Disclosed is a method of applying a multiple-layer enamelling on electrically conductive substrates by electrophoretic deposition of a first coating layer of electrophoretically depositable aqueous coating agents onto which a second coating layer of a first pigment- and/or effect-creating base enamel coating agent is applied wet-in-wet, and the first and second coating layers thus produced are then burned in together; a third coating layer of a second pigment and/or effect-creating base enamel coating agent is then applied, a fourth coating layer of a transparent coating agent is applied wet-in-wet, and the third and fourth coating layers are then burned in together. The total dry layer thickness of the second and third coating layers of base enamel coating agents is between 15 and 40 νm and the second coating layer accounts for between 20 and 50 % of the combined dry layer thickness of the second and third coating layers.

Description

The invention relates to a method for producing Multi-layer paintwork.

Today's automotive OEM coatings mostly consist of one Basecoat / clearcoat top coat based on an electrophoretic primed and coated with filler body is applied. Here basecoat and clearcoat are preferably applied wet-on-wet, i.e. of the Basecoat is applied after a flash-off time, if necessary with heating, and afterwards applying a clear coat together with branded this. It is also reducing others Processes serving for stoving have become known in which electrophoretically applied primer and filler layer after Wet-on-wet processes are applied, such as in DE-A-41 26,476 or EP-A-0 595 186. The filler layers must be in a dry film thickness of 30 µm and more, which is common for filler coatings be applied.

When working according to DE-A-41 26 476 and EP-A-0 595 186 apply Restrictions on the composition of the wet-on-wet applied Filler layers, i.e. it cannot be any filler coating agent be used. In addition, electrocoat material and Filler material should be coordinated in their properties.

From EP-A-0 265 363 it is known to use a previously burned-in product Cataphoretically applied primer with a wet-on-wet method applied two-layer basecoat / clearcoat top layer to provide. The filler layer is saved. Is problematic however, that stone chip damage to painted by this process Motor vehicles are particularly striking because the Primer layer exposed in the event of stone chipping through top coat detachment becomes. Corrosion protection is then still guaranteed However, visual impression cannot be tolerated.

For reasons of rationalization and material savings there is in automotive painting the desire for reduced thickness of the paint structure, but without significant loss in it Allow overall property level.

The object of the invention is to provide a method for producing Multi-layer paintwork, in particular of automotive paintwork with comparable to the prior art Overall property level, but reduced layer thickness of the To provide overall paint structure, which the effort of coordination the individual layers of paint are minimized with one another and if possible a few baking steps can be carried out.

Surprisingly, the object is achieved by a method for Multi-layer painting of electrically conductive substrates electrophoretic deposition of a first coating layer from a aqueous coating agents which can be deposited electrophoretically and Subsequent application of further coating layers is characterized in that by electrophoretic deposition obtained first coating layer wet-on-wet a second coating layer from a first color and / or effect basecoat is applied and the first and second coating layers thus obtained be baked together, resulting in a third coating layer a second color and / or effect basecoat applied and a fourth coating layer on this wet-on-wet a clear coat and the third and fourth Coating layer are baked together, the Total dry layer thickness (sum of the layer thicknesses) from the Basecoat coatings produced second and third coating layers between 15 and 40 microns, preferably between 20 and 35 microns, and Proportion of the second coating layer between 20 and 50%, preferred between 25 and 40%, the total dry film thickness of second and third coating layer.

The inventive method makes it possible to directly not yet burned in electrophoretically deposited first Apply a basecoat coating agent and this together with the electrophoretically deposited coating layer burn in, filling layers or other intermediate layers omitted.

The process according to the invention is preferably carried out so that the jointly baking the third and fourth coating layers at one Temperature takes place, which is the same as when the joint first and second coating layer prevailing baking temperature or particularly preferably falls below this.

In the method according to the invention can be used as electrophoretic depositable coating agents known per se anodically or cathodically separable electrodeposition paints (ETL), which are not special Restriction are used to generate the first Coating layer, namely a primer.

These are aqueous coating compositions with a solids content of, for example, 10 to 20% by weight. The solid is formed from binders customary for electrocoating, which carry ionic groups or groups which can be converted into ionic groups and groups capable of chemical crosslinking, as well as pigments, fillers and / or customary additives. The ionic groups or groups which can be converted into ionic groups can be anionic or groups which can be converted into anionic groups, for example acidic groups such as -COOH groups or cationic or groups which can be converted into cationic groups, for example basic groups, such as amino, ammonium or quaternary ammonium groups, phosphonium -, And / or sulfonium groups. Binders with basic groups are preferred. Nitrogen-containing basic groups are particularly preferred. These groups can be present in quaternized form or they are at least partially converted into ionic groups with a customary neutralizing agent, an acid, for example an organic monocarboxylic acid, such as, for example, formic acid or acetic acid.
DE-A-28 24 418 describes examples of anodically depositable electrodeposition paint binders and paints (ATL) which contain anionic groups and can be used in the process according to the invention. These are, for example, binders based on polyesters, epoxy resins, poly (meth) acrylates, maleate oils or polybutadiene oils with a weight average molecular weight of, for example, 300 to 10,000 and an acid number of 35 to 300 mg KOH / g. The binders carry -COOH, -SO ₃ H and / or -PO ₃ H ₃ groups. After neutralization of at least some of the acidic groups, the resins can be converted into the water phase. The lacquers can also contain customary crosslinking agents, for example triazine resins, crosslinking agents which contain groups capable of transesterification or blocked polyisocyanates.

However, they can preferably be used in the process according to the invention cathodic electrocoat materials (KTL) based on cationic or basic binder. Such basic resins are, for example resins containing primary, secondary or tertiary amino groups, the Amine numbers e.g. are 20 to 250 mg KOH / g. The weight average of the Molar mass (Mw) of the base resins is preferably 300 to 10,000. Examples of such base resins are amino (meth) acrylate resins, Amino epoxy resins, amino epoxy resins with terminal double bonds, Amino epoxy resins with primary OH groups, aminopolyurethane resins, amino group-containing polybutadiene resins or modified epoxy resin-carbon dioxide-amine reaction products. These base resins can be self-crosslinking or they are used with known crosslinkers Mixture used. Examples of such crosslinkers are Aminoplast resins, blocked polyisocyanates, crosslinkers with terminal Double bonds, polyepoxide compounds or crosslinkers Contain transesterifiable groups.

Examples for use in cathodic dip lacquer (KTL) baths Base resins and crosslinkers are described in EP-A-0 082 291, EP-A-0 234 395, EP-A-0 227 975, EP-A-0 178 531, EP-A-0 333 327, EP-A-0 310 971, EP-A-0 456 270, US 3 922 253, EP-A-0 261 385, EP-A-0 245 786, DE-A-33 24 211, EP-A-0 414 199, EP-A-0 476 514. These resins can work alone or used in a mixture. So-called "non-yellowing" CTL systems are preferred used a yellowing or discoloration Avoid multi-layer painting when baking. For example it is blocked by means of specially selected KTL systems crosslinking polyisocyanates, such as in EP-A-0 265,363.

In addition to the base resins and any crosslinking agents present Can the electrocoat (ETL) coating agent pigments, fillers and / or conventional paint additives. As pigments and fillers come the usual inorganic and / or organic pigments and Fillers in question. Examples are carbon black, titanium dioxide, iron oxide, Kaolin, talc or silicon dioxide.

The pigments can be dispersed into pigment pastes, e.g. under Use of known paste resins. Such resins are known to the person skilled in the art common. Examples of paste resins that can be used in KTL baths are in EP-A-0 183 025 and EP-A-0 469 497.

The usual additives for ETL coating agents are possible as additives. Examples include wetting agents, neutralizing agents, leveling agents, Catalysts, anti-foaming agents, solvents, but especially Light stabilizers, if necessary in combination with antioxidants.

In the process according to the invention, the second and the third coating layer known per se color and / or effect-imparting basecoat coating agents used as for Manufacture of basecoat / clearcoat two-coat paint used and in large numbers, for example, from the patent literature are known.

The one for the production of the second and third coating layers Basecoats which can be used according to the invention can be physically drying or be crosslinkable to form covalent bonds. Both it can form crosslinking basecoats, forming covalent bonds are self- or third-party networking systems.

The color and / or Effect basecoats are liquid coating agents. It can be act single- or multi-component coating agents, are single-component prefers. It can be systems based on organic solvents act or it is preferably water-based paints, the Binder systems in a suitable manner, e.g. anionic, cationic or are non-ionic, stabilized.

In the process according to the invention for the production of the second and third coating layer usable basecoat coating agents it is common paint systems that one or more common Contain base resins as film-forming binders. You can if the base resins are not self-crosslinking or self-drying, optionally also contain crosslinkers. Both the base resin component and the crosslinker component are not subject to any restrictions. As film-forming binders (base resins), for example Polyester, polyurethane and / or (meth) acrylic copolymer resins used become. In the case of the preferred waterborne basecoats are preferred Contain polyurethane resins, particularly preferably at least one Share of 15 wt .-%, based on the solid resin content of Water-based paint. The selection of the crosslinkers that may be included is not critical, it depends on the functionality of the Base resins, i.e. the crosslinkers are selected so that they are one for Functionality of the base resins complementary, reactive functionality exhibit. Examples of such complementary functionalities between Base resin and crosslinker are: hydroxyl / methylol ether, hydroxyl / free Isocyanate, hydroxyl / blocked isocyanate, carboxyl / epoxy. Provided compatible with each other, several such complementary Functionalities in a varnish side by side. The crosslinking agents optionally contained in the basecoats can be used individually or in a mixture.

Contain the basecoats used in the process according to the invention in addition to the usual physically drying and / or chemically crosslinking binders inorganic and / or organic colored pigments and / or effect pigments, e.g. Titanium dioxide, iron oxide pigments, carbon black, Azo pigments, phthalocyanine pigments, metal pigments, e.g. made of titanium, Aluminum or copper, interference pigments, e.g. titanium dioxide coated aluminum, coated mica, Graphite effect pigments, platelet-shaped iron oxide, platelet-shaped Copper phthalocyanine pigments.

The basecoats can also contain customary auxiliaries, such as e.g. Fillers, catalysts, leveling agents, anti-cratering agents or in particular light stabilizers, if appropriate in conjunction with Antioxidants.

Examples of solvent-based basecoat systems, which in Processes according to the invention can be found in DE-A-37 15 254, DE-A-39 13 001, DE-A-41 15 948, DE-A-42 18 106, EP-A-0 289 997 and W0-91 00 895.

Examples of those which can preferably be used in the process according to the invention Waterborne basecoat systems can be found in DE-A-29 26 584, DE-A-36 28 124, DE-A-38 41 540, DE-A-39 03 804, DE-A-39 15 459, DE-A-40 01 841, DE-A-40 09 857, DE-A-40 11 633, DE-A-41 07 136, DE-A-41 22 266, EP-A-0 089 497, EP-A-0 226 171, EP-A-0 228 003, EP-A-0 287 144, EP-A-0 297 576, EP-A-0 301 300, EP-A-0 353 797, EP-A-0 354 261, EP-A-0 401 565, EP-A-0 424 705, EP-A-0 422 357, EP-A-0 512 524 and EP-A-0 584 818.

It can be used for those produced by the process according to the invention second and third coating layers different basecoats, however, preferably similar basecoats or particularly preferably in each case the same basecoat can be used, as explained below.

n ≤ 90 im mit ΔE* = 0,3 gekennzeichneten Bereich des CIE-x,y-Diagramms,

n ≤ 50 im mit ΔE* = 0,5 gekennzeichneten Bereich des CIE-x,y-Diagramms,

n ≤ 40 im mit ΔE* = 0,7 gekennzeichneten Bereich des CIE-x,y-Diagramms,

n ≤ 30 im mit ΔE* = 0,9 gekennzeichneten Bereich des CIE-x,y-Diagramms.

For example, a solvent-based basecoat or preferably a water-dilutable basecoat can be used to produce the second coating layer. The same selection option exists for the third coating layer, but it is preferred to use either a solvent-based basecoat or a water-based basecoat for each of the two coating layers. It is particularly preferred if the solid resin composition of the basecoats used for the production of the second and third coating layers is essentially the same, ie has the same solid resin composition (the same binders and optionally crosslinking agents are present) and only a fluctuation range of less than 30 in the quantitative solid resin composition %, preferably less than 20%, particularly preferably less than 15%, each based on the relative weight fraction of the individual binders and any crosslinking agents present. In addition, it is preferred if the basecoat used to produce the second coating layer has a color tone which is close to that of the basecoat used to produce the third coating layer or, particularly preferably, is identical to it. In the context of the present invention, the closest color tones are to be understood to mean that the difference in color, comprising the difference in brightness, hue and difference in color, between the hues of the second and third coating layers determined in each case with opaque coating and a measurement geometry of (45/0 °) n times ΔE * (CIELAB) does not exceed. The ΔE * (CIELAB) reference value is the value obtained in the CIE x, y diagram (chromaticity diagram) familiar to the person skilled in the art, based on DIN 6175, for the color of the third coating layer, and the following relationship applies:

n ≤ 90 in the area of the CIE x, y diagram marked with ΔE * = 0.3,

n ≤ 50 in the area of the CIE x, y diagram marked with ΔE * = 0.5,

n ≤ 40 in the area of the CIE x, y diagram marked with ΔE * = 0.7,

n ≤ 30 in the area of the CIE x, y diagram marked ΔE * = 0.9.

In the case of the generation of the second and third coating layers preferably used water-based paints can be the inventive Methods are carried out in a special embodiment. It is used for the production of the second coating layer from the Spray booth circulation water recycled overspray, which at Generation of the third coating layer is used. Such a Recycled water-based paint can, for example, by Ultrafiltration can be obtained from the cabin circulating water. in the general is a variety of colors in the series painting processed. Therefore, it is preferred to work in such a way that the Generation of the third coating layer used waterborne basecoats suitable color groups are summarized so that one or more recycled water-based basecoats are obtained, each one Have mixed color. The summary of color groups at the The third coating layer can be produced, for example, by that the mixed shades that form subsequently for production the second coating layer used water-based paint recyclates and the hue of each one for the generation of the third Coating layer used water-based paint come close to each other. This approach is, for example, to be understood exactly as explained above for the color difference.

It goes without saying that the composition of the Color groups is also preferred if the different pigmented waterborne basecoats are essentially the same Have solid resin composition, i.e. they prefer to own them the same solid resin composition and have in their quantitative solid resin composition only a fluctuation range in the relative proportions by weight of the individual binders plus optionally present crosslinkers of less than 30%, preferably less than 20%, particularly preferably less than 15%.

As a clear coat for the production of the fourth The coating layer is basically all known or transparent pigmented coating agent suitable. It can be one or act multi-component clear lacquer coating agents. You can be solvent-free (liquid or as a powder clear coat), or it can are systems based on solvents or are are water-thinnable clear coats, whose binder systems in suitably, e.g. anionic, cationic or non-ionic, are stabilized. With the water-borne clear varnish systems it can are water-soluble or water-dispersed systems, especially Act emulsion systems. The clear lacquer coating agents harden during Burn-in to form covalent bonds due to chemical Networking out.

The clear lacquers which can be used in the process according to the invention are concerned it is usual clearcoat coating agents, the one or more usual Contain base resins as film-forming binders. You can if the base resins are not self-crosslinking, if necessary also Crosslinker included. Both the base resin component and the Crosslinker components are not subject to any restrictions. As Film-forming binders (base resins) can, for example, be polyester, Polyurethane and / or poly (meth) acrylate resins can be used. The Selection of any crosslinker that is included is not critical to them depends on the functionality of the base resins, i.e. the crosslinker are selected so that they are one for the functionality of the base resins have complementary, reactive functionality. Examples of such Complementary functionalities between base resin and crosslinker are: Carboxyl / epoxy, directly bound to carbon or silicon Hydroxyl / methylol ether, directly bound to carbon or silicon Hydroxyl / free isocyanate, directly on carbon or silicon bound hydroxyl / blocked isocyanate, (meth) acryloyl / CH-acidic Group. In this context, are directly bound to silicon Hydroxyl groups also latent silanol groups, e.g. Alkoxysilane groups to understand. If compatible with each other also several such complementary functionalities in one clear coat coexist. The possibly in the clear coats contained crosslinkers can be present individually or in a mixture.

In addition to the chemically crosslinking binders and, if appropriate Crosslinkers can be used in the process according to the invention Clear varnishes auxiliary materials, such as Catalysts, Leveling agents, but especially light stabilizers, if appropriate Combined with antioxidants.

Examples of one (1K) and two-component (2K) non-aqueous Clear lacquer systems used as clear lacquer in the process according to the invention can be used can be found in DE-A-38 26 693, DE-A-40 17 075, DE-A-41 24 167, DE-A-41 33 704, DE-A-42 04 518, DE-A-42 04 611, EP-A-0 257 513, EP-A-0 408 858, EP-A-0 523 267, EP-A-0 557 822, WO-92 11 327.

Examples of one (1K) or two-component (2K) Water-clear lacquer systems used as clear lacquer in the process according to the invention can be used can be found in DE-A-39 10 829, DE-A-40 09 931, DE-A-40 09 932, DE-A-41 01 696, DE-A-41 32 430, DE-A-41 34 290, DE-A-42 03 510, EP-A-0 365 098, EP-A-0 365 775, EP-A-0 496 079, EP-A-0 546 640.

Examples of powder clearcoat systems used in the process according to the invention can be used as a clear lacquer, can be found in EP-A-0 509 392, EP-A-0 509 393, EP-A-0 522 648, EP-A-0 544 206, EP-A-0 555 705, DE-A-42 22 194, DE-A-42 27 580.

As a substrate for the method according to the invention are electrical conductive materials, such as metals. Particularly suitable are e.g. Automobile bodies or parts of them, them can be made of pretreated or untreated metal, with a electrically conductive layer provided metal or electrically conductive or provided with an electrically conductive layer Plastic. For example, an electrically conductive Layer on the metal substrates by electrophoretic deposition and baking a corresponding coating. On these substrates become the first coating layer, especially in shape a corrosion protection primer, electrophoretically in the usual way and in a dry layer thickness of 15, which is common for ETL primers deposited up to 35 µm. In the special case of pre-coated substrates multi-layer coatings with more than those according to the invention are obtained generated four coating layers, but subsequently the inventive method first applied electrocoat referred to as the first coating layer.

The first coating layer produced according to the invention is used for removal non-adherent excess paint with an aqueous Solution or water rinsed and then before the wet-on-wet application of second coating layer from a first color and / or effect Basecoat or a recycled basecoat with a mixed color freed from adhering moisture. This happens e.g. by Flash off. This can, for example, by IR radiation and / or by a possibly heated air flow happen that over the Substrate is guided. The temperature of the airflow can for example at room temperature to 120 ° C, preferably it is over 80 ° C. The electrodeposition paint film should not be crosslinked occur.

On the one obtained with an uncrosslinked ETL layer The second coating layer from the first color and / or effect basecoat applied by spraying. examples for Suitable spray application methods are compressed air spraying, airless spraying or electrostatic (ESTA) high-rotation spraying. After a short flash-off time, possibly up to 80 ° C, the workpiece with the two coating layers for example at temperatures between 130 and 190 ° C, for example preferably between 140 and 180 ° C, baked. After stoving can the surface may be post-treated, e.g. by Loops around e.g. Repair bugs.

Then, according to the invention, the third spray is applied Coating layer from the second color and / or effect Basecoat, for example by compressed air spraying, airless spraying or ESTA high-rotation syringes, it being essential to the invention that the total dry layer thickness from the second and third Coating layer between 15 and 40 microns, preferably between 20 and 35 microns is, the proportion of the first color and / or effect Coating layer between 20 and 50%, preferably between 25 and 40% the total dry layer thickness from the color and / or effect Coating layers generated coating layers. For example the dry layer thickness of the second coating layer is between 5 and 15 µm and that of the third coating layer is for Basecoat layers usually 10 to 30 µm. Without being tied to a theory to be, it is assumed that the thin layer thickness of the second Coating layer the implementation of the inventive method enables without a special coordination between the Generation of the first coating layer used electrocoat and the basecoat used to create the second coating layer necessary is.

Subsequent to the application of the third coating layer follows a short flash-off phase, e.g. at 20 to 80 ° C, the order of the Clear coats in the wet-on-wet process.

The fourth coating layer is made from a common liquid clear coat or powder clearcoat (in this case it is a dry-on-wet application) in a usual for clear lacquer layers Dry layer thickness of preferably 30 to 80 microns overpainted and baked together with the third coating layer. Here is the Baking temperature is preferably the same as when baking together first and second coating layer prevailing baking temperature or this is particularly preferred. For example, the Baking temperature when jointly baking the third and fourth Coating layer at up to 160 ° C, preferably below 140 ° C.

The method according to the invention allows the production of four layers or also multi-layer paintwork, in particular Automotive paintwork with compared to the prior art, the Includes filler layers and / or other intermediate layers, reduced total layer thickness and comparable Overall property level. Only two burn-in steps are necessary. A coordination of the generation of the first and the second Use coating layer Coating agent with each other is not necessary. Especially when using waterborne basecoats in the method according to the invention there is the possibility of Overspray recycling by using the concentrated overspray in the creation of the second coating layer.

Claims (10)

1. A process for multilayer lacquer coating of electrically conductive substrates by electrophoretic deposition of a first coating layer from an electrophoretically depositable aqueous coating composition, and subsequent application of further coating layers, characterised in that a second coating layer of a first coloured and/or effect base lacquer coating composition is applied wet-on-wet to the first coating layer obtained by electrophoretic deposition and the first and second coating layers thus obtained are stoved together, whereupon a third coating layer of a second coloured and/or effect base lacquer coating composition is applied and a fourth coating layer of a clear lacquer coating composition is applied thereto wet-on-wet and the third and fourth coating layers are stoved together, wherein the overall dry film thickness of the second and third coating layers produced from the base lacquer coating compositions is between 15 and 40 µm and the second coating layer accounts for between 20 and 50 % of the overall dry film thickness of the second and third coating layers.
2. A process according to claim 1, characterised in that the overall dry film thickness of the second and third coating layers produced from the base lacquer coating compositions is between 20 and 35 µm.
3. A process according to claim 1 or claim 2, characterised in that the proportion accounted for by the second coating layer of the overall dry film thickness of the second and third coating layers produced from the base lacquer coating compositions is between 25 and 40 % of the overall dry film thickness of the second and third coating layers.
4. A process according to any one of the preceding claims, characterised in that, to produce the second and third coating layers, base lacquer coating compositions are used which are of similar or preferably identical shades.
5. A process according to any one of the preceding claims, characterised in that, to produce the second and third coating layers, base lacquer coating compositions are used which contain identical binders and optionally cross-linking agents.
6. A process according to any one of the preceding claims, characterised in that an aqueous base lacquer coating composition is used for each of the second and third coating layers.
7. A process according to claim 5 or claim 6, characterised in that base lacquer coating compositions are used, in which the binders and optional cross-linking agents are present in equal quantities or the amount by which the quantities of binders and optional cross-linking agents in the solid resin composition may vary, in each case in relation to their relative percentages by weight, is less than 30 %.
8. A process according to any one of the preceding claims, characterised in that an aqueous base lacquer coating composition is used to produce the second coating layer, which aqueous base lacquer coating composition is obtained using, or using at least in part, the overspray arising during production of the third coating layer.
9. A process according to any one of the preceding claims, characterised in that it is used for multilayer lacquer coating of motor vehicle bodywork or components thereof.
10. Motor vehicle bodywork or components thereof having a multilayer lacquer coating obtained by the process according to any one of claims 1 to 9.