DE3223410C2 - Solvent-based paint with color pigment - Google Patents

Abstract

The invention relates to a new color pigment for solvent-based lacquers or paints, which at the same time also has an excellent corrosion-preventing effect. It has been found that smoke dust of manganese (II, III) oxide (Mn ↓ 3O ↓ 4) fulfills these tasks with excellent success. Mn ↓ 3O ↓ 4 smoke dust is obtained as a waste product from the exhaust gases of metallurgical furnaces for ferromanganese production. This smoke dust has an Mn ↓ 3O ↓ 4 content of 96 to 98% by weight and the degree of fine division required for a color pigment.

Description

a) the chemical composition contains at least 96% by weight Mn3O ₄ and the remainder may consist of calcium oxide, magnesium oxide, potassium oxide and silicon oxide with less than about 1% by weight free manganese metal;

b) the material is so finely divided that 98% of the particles are smaller than about 10 micrometers.

10

20th

is contained in the paint, which has the following composition:

10 to 30 weight percent resin binder;

20 to 35 wt% MmCV smoke dust pigment;

2 to 25% by weight additional pigments, inclusive Extender pigments, fillers and corrosion inhibitors;

0 to 1.5% by weight pigment suspending agent;

30 to 90% by weight solvent.

2. The lacquer of claim 1, characterized by a MnaCVRauchstaub, of about 96 to 98 wt contains ⁰ / ') Mn3Ü4 and the particles of spherical shape and have a size such that 99% of a Tyler mesh of 325 mesh (0.045 mm clear mesh size).

3. Paint according to claim 1 or 2, characterized by the use of a MnjCV smoke dust, obtained as a waste product from the exhaust gases of metallurgical furnaces for ferromanganese production is.

₃₅

50

55

45

The invention relates to solvent-containing paints or varnishes with a color pigment, which significantly improves the corrosion resistance of the paint.

According to the usual formulations, solvent-containing Paints by mixing one or more pigments with solvents, resins or Binders and other auxiliaries such as dispersants, stabilizers, thickeners, etc., manufactured. The most important requirement for a pigment is that it be in the paint, alone or together with others Pigments, producing a specific and pleasing color. In addition, the pigment must be stable, like this that the color is retained for a long time. Another requirement is a very fine particle size, generally less than ten micrometers. The fine particle size of the pigment enhances its dispersibility Favored in the preparation of the lacquer mixture and can use the lacquer in a thin layer can be applied evenly without streaks or other defects. The last requirement is especially important if the varnish is by painting or

Rolls is applied.

It is the object of the invention to provide an improved pigment for solvent-containing paints. It is also an object to use such a pigment to provide a solvent-containing paint which is one has a high corrosion resistance wedge.

These objects are achieved according to the invention by using an improved color pigment which consists of manganese (II, III) oxide smoke dust (MOjO ₄ ) or a material which _{contains MnjO 4} smoke dust as the most important component. The Mn / V fume dust pigment can be used together with a resin binder, solvents, co-solvents, suspending agents, etc. in a formulation. In a typical application, the MnsCV smoke dust pigment can be contained in the component system of the lacquer in about 20 to 35% by weight.

The invention is based on the finding that MnjQr smoke dust or a material which predominantly contains this smoke dust, in finely divided or powdered state, is an ideal color pigment for the formulations of a variety of solvent-based paints. The MnAi smoke dust color pigment is particularly advantageous for applications in which iron oxide pigments have previously been used. It was z. B. also found that finely divided Mn3O ₄ smoke dust as a color pigment leads to a deep red-brown color which is similar, but not very slightly different from the brown colorations produced by various synthetic iron oxide pigments, e.g. B. by yellow, yellow-brown and red iron oxide pigments. The MnjOr smoke dust color pigments can be produced in a wide range of particle sizes, which is close to the particle sizes of conventional iron oxide pigments. As mentioned, it is desirable for various reasons that a color pigment is used in very finely divided particles, in particular because of the uniform distribution in the paint system. In general, the MnjO ^ smoke dust pigment should have a particle size such that about 98% of the particles are smaller than 10 micrometers.

Surprisingly, it has now been found that solvent-containing paints in which MnjO, »- Smoke dust used as a color pigment has excellent corrosion resistance. at the test under the same conditions, the corrosion resistance is at least equal to that of Paints with the usual iron oxide pigments.

The color pigment to be used according to the invention is Mn3O4 smoke dust or a composition or a material with a predominant content of Mn3C> 4 smoke dust, d. H. greater than about 60 weight percent.

The M ^ O ₄ smoke dust to be used according to the invention is obtained easily and cheaply by blowing an oxygen through a molten bath of ferromanganese or over its surface. Ferromanganese, which is produced in a blast furnace or in an electrometallurgical furnace and the like at 1200 ° C. or higher temperatures, normally contains up to 6 or r ^ hr% carbon. The carbon content is usually reduced, for example to about 1.5%, by blowing oxygen or a mixture of oxygen into the ferromanganese melt or over its surface. This occurs at 1000 ⁰ C or higher temperatures, preferably higher at about 1300 ° C, or even in a separate vessel containing the freshly tapped melt.

A process to reduce the carbon

.τ, .J

vi j * * m H

ΐ'Γ ¹

i "

> * · Ι [<yvM «v

Halts of molten ferromanganese is described in US-PS 33 05 352 of February 21, 1967. In this preferred method for obtaining the MnjOn smoke dust to be used according to the invention, the ferromanganese is transferred from the electric furnace in which it was produced into a treatment vessel, such as a pan or an oven, at a temperature of about 1300 ° C. or higher. Slag is preferably removed. Oxygen is then blown against the surface of the molten pool by any known means. For this purpose z. B. serve lances which are held about 2.54 cm above the surface and expel one or more streams of oxygen which impinge on the surface of the molten bath ^{at a pressure of about 7.7 to 10.5 kg / cm 2.} The amount of oxygen used is about 1.8 to 2.3 kg per minute for a melt of 227 kg in a pan 76.2 cm high and 50.8 cm inside diameter. Of course, this process can also be carried out with larger amounts. The resulting exhaust gases contain very fine particles of MnjO4 smoke dust. These have a spherical shape and can be easily separated using conventional equipment.

The M ^ O ₄ smoke dust to be used according to the invention can be obtained as a waste product of the process according to US Pat. No. 3,3 05,352 for reducing the carbon content of ferro-manganese melts. Here, the melt is maintained at a temperature of about 1250 ⁰ C and the oxygen is blown in such a way that it heats up the melt to 1700 ° C before the carbon content is reduced to 1.5% C of the melt. The blowing of the oxygen is continued - as described in the patent specification - until the temperature of the molten bath has reached 1750 ° C. The Mn3O4 smoke dust is extracted from the exhaust gas using conventional methods.

_{The terms Mn 3} O ₄ smoke dust and manganese (II, III) oxide smoke dust used in this description and the claims denote fine, spherical particles of smoke dust that is obtained from ferromanganese by blowing oxygen into a melt.

Then some typical properties of M ^ Oi smoke dust, as described above, are presented was won.

Chemical analysis (wt%): 65.27 Mn, 2.03 Fe, 0.029 Al, 0.28 Si, 0.17 C, 0.040 P, 0.045 As, 0.46 Ca, 1.43 Mg, 0.072 K, 0.023 Cr, 0.002 Pb.

Bulk density: 0.78 to 3.04 g / cm ³ .

Moisture: 0.22% (1 hour at 17O ⁰ C).

Particle size: 98% below about 10 microns (99% pass through a Tyler sieve of 325 mesh).

pH value: 9 to 13 (50% Mn ₃ O ₄ in distilled water).

Particle shape: spherical.

Specific weight: 4.6 to 4.75 g / cm ³ .

Thermal resistance: No action up to

60

Today's coating technology requires the use of color pigments with a very fine particle size for the purpose of increasing the coloring effect or covering power, the suspension properties and the even distribution of the pigment in the paint system. It has been found that these conditions are met very well with Mn3O4 smoke dust in which 98% of the particles are smaller than 10 micrometers. In the case of the MnjOi smoke dust obtained as described above, this can contain about 1.0 to 2.0% of particles which are larger than about 10 micrometers. In certain cases it may therefore be desirable or necessary to remove these larger particles. For this purpose, one can use the usual classification technique or reduction methods, e.g. B. ball mills apply. Mn3O ₄ smoke dust, which has been brought to a particle size of 98% below 10 micrometers by classifying or grinding, can be removed by means of conventional dispersion units, e.g. B. with a Cowless dissolver, easily dispersed in the component mixture. Formulations which _{contain Mn 3} O ₄ smoke dust in the range of this particle size can generally be applied to the surfaces to be coated without streaks or other defects occurring.

The following is a typical formulation according to the invention for a solvent-based paint specified.

Components Wt% <><a
, ti I. / ■ Ά Resin binder 10-30 B. Mn ₃ O ₄ dusty dust pigment 25-35 k C. other pigments, extenders, 2-25 Filler etc. i D. Pigment suspending agent 0-1.5 E. solvent 30-90

Formulations according to the invention or the finishing of the paints can be made according to known principles and methods. For example, by mixing the resin binder with the M ^ O ₄ smoke dust, other pigments and suspending agents with the addition of the solvent. For this purpose, a shearing dispersing unit, e.g. B, a cowless dissolver, can be used, in which a stirrer side with saw blade-like teeth moves at high speed. The stirrer brings the mixture of liquid and pigment to high speed, resulting in shear conditions. The ball mills customary for this purpose also lead to the same success.

The resins customary in the paint industry can be used as binders. In general one of the following four groups is chosen as the binding agent:

1) reactive binders, such as epoxy resins made from bisphenol A and epichlorohydrin, which are hardened by means of polyamines such as polyaminoamides, diethylenetriamine, triethylenetetramine or coal tar amines;

2) air-drying binders made by reacting diglycidyl ether of bisphenol A and vegetable oil fatty acids;

3) Solvent-soluble binders that harden by evaporation of the solvent, such as Polyhydroxy ethers of bisphenol A from bisphenol A and epichlorohydrin;

4) binders commonly used in moisture curing systems such as alkyl silicates, produced by hydrolysis or polymerisation of tetraethylsilicates, alcohol and glycol.

Typical binders that can be used with polyaminoamide curing epoxy resins are condensation pro-

/ Γ

Ir ρ

products of epichlorohydrin and bisphenol A. This resin has an epoxy equivalent weight of 450 to 550 g per gram equivalent of epoxy (ASTM D-1652), or 75% Solid in methyl isobutyl kelon / xylene in the ratio 65/35. Suitable hardeners for this resin are recative polyaminoamide resins based on polymerized vegetable fatty acids.

These hardeners have an amine value of 230-246 mg, based on the KOH equivalent of basic nitrogen content in one gram and a viscosity of about 31 to 38 poise at 75 ° C.

Polymerized ethyl silicas are good examples of Binder for use in moisture-curing systems. Suitable binders soluble in solvents, which harden by solvent evaporation are polyhydroxy ethers made from bisphenol A and epichlorohydrin.

Solvent-soluble binders are useful for formulations according to the invention furthermore, for example, high molecular weight epoxy resins, alkyd resins, polyester, chlorinated rubber and vinyl chloride-vinyl acetate copolymers with or without hydroxyl or carboxyl functions. χ · The Mn3C> 4 pigment can be used in a - ßen component system alone or together with * other known color pigments, pigment extenders, Fillers, corrosion inhibitors, etc. can be used. For example, it can be used together with '' known TiCh pigments or the various iron oxide pigments, such as red or yellow iron oxides, be used. As pigment extenders, for. B. Talc, clay (aqueous aluminum silicates Diatomaceous earth and silicon dioxide can be considered.

In addition, other anti-corrosive pigments, such as B. zinc chromate can be used.

As pigment suspending agents are, for. B. suitable organic derivatives of aqueous magnesium aluminum silicate.

Solvents which can be used for the formulations according to the invention are those which are customary for these purposes Solvents and solvent mixtures can be used. Examples include: ketones, such as Methyl isobutyl ketone, aromatics and mixtures of ■ ketones and aromatics. Typical aromatic solvents are xylene and toluene. Also aromatic solvents based on diethylbenzene are suitable. Other commercially available solvents are ethylene glycol monoethyl ether and ethylene glycolnionoethyl ether acetate, this is particularly suitable when phenoxy resins are used in the component system will. When an alky resin is used as the solvent-soluble binder, petroleum distillates are used usable. Xylene and toluene are good solvents for chlorinated rubber. Others expedient Solvents for these binders are ketones and / or mixtures of or with ketones. A Another solvent is a mixture of one third each of xylene, methyl isobutylene ketone and ethylene glycol monoethyl ether.

A component system according to the invention can also contain various other constituents usually used in solvent-based paints. For example additives to improve the Film formation of the coating. Commercial products

for this are z. B. urea resins in 60% solution of Butanol / xylene and ethanol with a suspending agent. An agent such as diatomaceous earth can be used to adjust the viscosity. On other components the following are to be refused. Degassing agents and water displacing agents such as silica and House preventive agents.

A series of tests were carried out to determine the corrosion- _{preventing properties of the Mn 1} O _{4 smoke dust pigment.} These were carried out according to the instructions of GA Salensky, described in "Corrosion Inhibitor Test Method", presented to the NACE International Conference On Corrosion Control, Lehigh University. August 11, 1980. The test setup simulates the area around the coating when exposed to salt spray and uses a model liquid as the coating material for the water-insoluble corrosion inhibitor to be tested. In the present case, the model liquid was 5 ml of phenyl ether, which was brought to the bottom of a test tube together with 1 ml of a 3% saline solution. As a test piece, a sheet of cold rolled steel measuring about 40 × 12 1 mm was weighed and then placed in the solution at the bottom of the test tube. The test tube was shaken at approximately 240 oscillations per minute, the solution was maintained at a temperature of about 40 ⁰ C. The test piece was removed after 24 hours. It was cathodically cleaned to remove the corrosion products and then weighed. The weight loss was recorded. This test was repeated under otherwise identical conditions with the addition of 5% by weight of MnjO ^ smoke dust pigment and in a further experiment with the addition of 5% by weight of zinc chromate. The degree of corrosion was calculated by dividing the percent weight loss when tested with the inhibiting pigment by the percent weight loss when tested without an inhibitor. The subtraction of this calculated value from "1" gives the degree of the treasure or the effectiveness of the corrosion prevention, which is classified as follows: 1.0 complete protection, 0.9 good protection, 0.0 as without inhibitor and 0.1 accelerated Corrosion. According to this test, it was found that the inhibitory _{effect for Mn 3} O ₄ smoke dust pigment was 0.94 and that for zinc chromate was 0.99. It is well known that zinc chromate is an excellent agent for preventing corrosion. It was also found that the control solution, which did not contain either inhibitor, gave a value of 0.00.

Other series of tests were also carried out to demonstrate the anti-corrosion effect of the MnjO ₄ smoke dust material. In these tests, a number of cotton patches, about 2.54 cm round and about 12.7 · ΙΟ- ³ to 25.4 · 10- ^J cm thick, completely soaked with distilled water for one test series and with a 3 wt Use the above saline solution, each with 10% pigment, for the other series of experiments. These Baumwoüfücken were placed on bare steel. The patches soaked with distilled water were removed after 72 hours and the patches soaked with saline solution were removed after 48 hours. The results of this test are shown in Table 1.

Table 1

Corrosion test with MnjO ^ smoke dust in distilled Water and 3% saline solution

pigment

Distilled
water

(72 hours)

Saline solution (48 hours)

Mn ₃ O ₄
Zinc chromate

good, no rust mediocre *)

little rust little rust *)

*) = Peripheral grate.

20th

In these experiments Ig pigment was mixed with 9g of distilled water or saline solution,

Working examples Example 1

A solvent-based paint was produced using the usual TiC> 2 color pigment. The mixture was made with the following formulation:

10

15th

1683 grams of epoxy binder;
236.2 grams of TiO ₂ pigment;

42.5 g Tafk;

4.8 g suspending agent, organic derivative of

Montmorillonite;
0.7 g of lecithin;

39.6 grams of xylene;

9.3 g of ethylene glycol monoethyl ether;

19.9 grams of aromatic solvent; y,

15.1 g of methyl isobutyl kelon (MIBK); 4.5 grams of urea resin;

1.4 g of isopropyl alcohol.

This mixture (blend A) was then durchgrei- w fend mixed with a second mixture (mixture B) of the following components:

169.6 g polyamide epoxy hardener;

1363 g talc; '"

553 g of ethylene glycol monoethyl ether acetate

Mixtures A and B were mixed in a volume ratio of 2: 1. The paint produced according to this formulation was sprayed onto the bare surface of such a number of test panels. The panels consisted of cold rolled steel and have the dimensions of about 10.1 χ 20.2 cm, the thickness was about 5 x l ³ cm. The coated panels were cut across one part

Table 2

scratched their surface and subjected to an atmosphere of salt spray according to ASTM B117. the Resistance of each coating was determined by determining the amount of rust that was on it the bare metal.

Example 2

With otherwise identical components of the formulation according to Example 1, the same amount of red iron oxide pigment was used _{instead of 263.2 g of TiO 2.} Test panels were sprayed with this lacquer as in Example 1 and these were subjected to the same corrosion resistance.

Example 3

Using the same procedure as in Examples 1 and 2, in the production of a lacquer in the Formulation that replaces T1O2 or iron oxide with 193.7 g of zinc chromate pigment. Just like in the previous examples test panels were sprayed and subjected to the corrosion test.

Example 4

Using the same procedure as in Examples 1 and 2, a lacquer was produced in the Formulation that replaces ΤΊΟ2 or iron oxide with an equal amount of MnsO-t smoke dust. As well as In the previous examples, test panels were sprayed and subjected to the corrosion test.

Example 5

Using the same procedure as in Example 4, a larger amount of Mn3O4 smoke dust _r namely 276.2 g was used in the formulation. The rest of the process was carried out as in the previous examples.

Example 6

Using the same procedure as in Example 4, a smaller amount of Mn3Ü4 smoke dust, namely 206.0 g and also 30.2 g of zinc chromate used previous examples.

The results of the corrosion tests on the paints described in Examples 1 to 6 are shown in Table 2 reproduced.

The size and type of blistering in the coating is as follows according to ASTM Std. D 714-56 graded:

The values 2 to 8 apply to the size of the bubbles, the higher number stands for the smallest bubbles, while the smaller bubbles are rated “little”, “medium”, “medium density” or “dense” are.

Corrosion tests of coatings of epoxy-polyamide systems and various Pigments

example
Kr.

Pigment coating thickness.

(X JO " ³ cm)

Blistering

1 titanium dioxide

2 red iron oxide

4.3 2 - little 6.4 2 - little 4.1 4 - medium 6.1 4 - medium

continuation

example

No.

pigment

Zinc chromate
Mn ₂ O ₄ smoke dust

Mn ₃ O ₄ smoke dust
(higher amount)

Mn ₃ O4 smoke dust plus
Zinc chromate

Coating
thickness Blistering (X 10 " ³ cm) 4.1
6.9 6 - medium density
6 - medium density 3.8
5.6 4 - medium
4 - medium 3.8
6.1 4 - medium density
4 - medium 3.6
5.6 2 - little
4 - little

From the results of Table 2 it can be seen that solvent-based paints based on an epoxy-polyamide system, which according to the invention contain MnjCV smoke dust as a pigment, have good to excellent corrosion resistance. In particular, when these lacquers are applied in a relatively thick layer (about 6.4 x 10 ^-3 cm), the same or better corrosion resistance is achieved than with formulations which contain conventional pigments such as titanium dioxide and red iron oxide. Similar results are also obtained when the paint in a thin layer - is applied (about 3.8 10- ³ cm). Table 2 also shows that the corrosion resistance of paints according to the invention is not increased if larger amounts of smoke leaf are used.

Example 7

For the production of a solvent-based paint the following components were mixed:

73.8 grams of epoxy ester resin;
137.3 grams of zinc chromate pigment;

24.4 g talc;
1.9 g pigment suspending agent;

70.9 g of aromatic solvent, in this case

Xylene.

This mixture was brought to a fineness of 6 NS (Hegman) in a Myers mixer, then the following components were added:

188.1 grams of epoxy ester;
2.2 grams of 24% lead naphthenate;
0.8 g of 6% cobalt naphthenate;
0.5 g anti-skinning agent.

A paint with this formulation was sprayed cm to test panels in a coating thickness of about 3.8 × 10 ^third These consisted of bright cold rolled steel (SAE 1010) and had the dimensions 10.2 × 20.3 cm. It was dried in a room climate for a week. The test panels were then scratched on one side and exposed to a 5% salt spray for about 100 hours. Thereupon signs of corrosion (rust, blisters) were examined.

Example 8

With otherwise the same formulation as in Example 7, 101.7 g of TiO2 pigment were used instead of 1373 g of zinc chromate. This lacquer was sprayed onto the test panels described in Example 7 with a layer thickness of about 3.8 × 10 ^-3 cm. The further test procedure was carried out as in Example 7.

Example 9

With otherwise the same formulation as in Example 8, the same amount of Mn3O4 smoke dust pigment was used instead of the 161.7 g of TiO _2. Further processing and testing took place as in the previous examples.

Example 10

With otherwise the same formulation as in Example 9, the 161.7 g M ^ CV smoke dust was replaced by the the same amount of red iron oxide pigment was used. Further processing and testing took place as in the previous examples.

Example 11

The following components were mixed to produce a solvent-based paint:

73.8 grams of epoxy ester resin;
241.7 g MnjOi smoke dust pigment j
1.9 g pigment suspending agent.

This mixture was with for about 30 minutes

200 rpm thoroughly mixed up to a fineness of 5

to 6 NS (Hegman) and then a second mix

admitted. This consisted of the following components:

148.1 grams of epoxy ester resin;

2.2 g of 24% lead naphthenate;

0.8 g of 6% cobalt naphthenal;

0.5 g anti-skinning mill.

Further processing and testing took place as in the previous examples.

The results of the salt mist corrosion test according to Examples 7 to 11 are shown in Table 3. Evaluation of corrosion resistance was carried out according to ASTM Std. D 714-56.

Table 3

Corrosion tests on coatings with epoxy-ester systems and various pigments

example
No.

pigment

Coating

management

thickness

(X 10 " ³ cm)

Blistering

10

10

11th

Zinc chromate

Titanium dioxide

Mn ₃ O ₄

red iron oxide

Mn ₃ O ₄
(higher amount)

3.6
3.8
3.8

was therefore somewhat higher than in the formulations of Examples 12 and 13. Further processing and The test was carried out as in Examples 12 and 13.

The results of the salt spray corrosion test are shown in Table 4.

Table 4

Corrosion resistance of coatings based on phenoxy resin systems

8 - tight
2 - little,

without
8 - tight *)

without

*) = Blisters often near the scratches on the test panel.

The table shows that paints based on epoxy ester systems which contain M ^ O ^ smoke dust pigment have a higher corrosion resistance than similar paints in which the usual pigments of red iron oxide, TiO ₂ and zinc chromate are used.

Example 12

^: To produce a solvent-based paint, the following components were mixed:

20th

25th

30th

120.0 g polyhydroxy ether made from bisphenol A and epichlorohydrin;

30 g phenol-aldehyde condensation product;
1.1 grams of suspending agent;
1.1 grams of suspending agent; pyrogen treated with silane

nes silica;
179 g zinc dust.

The first two components were in ethylene glycol monoethyl ether acetate (21% solids) solved. The mixture was treated in a Cowles dispersing unit for so long that all components were evenly distributed throughout the approach.

The paint produced in this way was tested on test panels made of bright cold rolled steel with the dimensions 10.2 χ 15.2 cm applied. Then during 15 Cured minutes at 177 ° C and then measured the coating thickness. The test panels were after Standard procedure subjected to the Saizsprühkorrosionstest. The evaluation was carried out in accordance with ASTM D 714-56, D 610-68.

example

Test time
(H)

corrosion

Blistering

12 (zinc dust)

13 (Mn ₃ O ₄ )

.14 (Mn ₃ O ₄ )

100
260
360

100
260
360

100
260
360

7th
7th
8th
8th
5

4th
4th

8 M.
8 M.
8M

6-8MD 6-8MD 6-8MD

6-8MD 6-8MD

45

50

55

Example 13

With otherwise the same formulation as in Example 12, 118 g of Mn ₃ O ₄ smoke dust pigment were used instead of 179 g of zinc dust. The paint had approximately the same volume percent of solids as that of Example 12, namely 48%. Further processing and testing took place as in Example 12,

Example 14

With otherwise the same formulation as in Example 13, a higher amount of MnjO ^ smoke dust pigment, namely 147.5 g. The paint had a solids content of about 53 percent by volume. This According to the results shown in Table 4, for formulations based on phenoxy resin systems, which contain MnjCr smoke dust pigment that Corrosion resistance about the same as that of formulations with zinc dust up to about 260 hours of test time. It should be noted that paints that contain zinc dust as a corrosion-preventing pigment, as special apply high quality under salt spray conditions.

Example 15

The following components were mixed to produce a solvent-based paint:

120.0 g polyhydroxy ether made from bisphenol A and epschlorhydrin;

30 g phenol-aldehyde condensation product;
118 g Mn3O ₄ smoke dust pigment.

The first two components mentioned were dissolved in ethylene glycol monoethyl ether acetate (21% solids). Mixing is carried out in a Cowles dissolver until all components are evenly mixed. The paint so produced had a solids content of about 79% by weight (49% by volume) and a Brookfield viscosity of 1000 centipoise at a spindle speed of 2 rpm. The paint was applied to test panels (10.2 × 15.2 cm) made of bright cold rolled steel. The curing of the coating was carried out at 35O ⁰ C for 15 minutes. The thickness of the coating was about 1.27 x 10 ⁶ cm. The test panels were subjected to the spray corrosion test according to the standard procedure. The evaluation was carried out in accordance with ASTM D 714-56 and D 610-68 ..

Example 16

With otherwise the same formulation as in Example 15, 31.5 g of red iron oxide and 31.5 g of talc were used _{instead of the 118 g of Mn 3} O _{4 smoke dust.} The paint so produced had a solids content of about 67% by weight (40% by volume) and a viscosity of 5000 centopoise (spindle speed 2 rpm).

13th

14th

Further treatment and testing took place as in Example 15.

With otherwise the same formulation as in Example 15, 31.5 g were used instead of 118 g of MnsOi pigment black iron oxide and 315 gtalk are used. The so The paint produced has a solids content of 67% by weight (40% by volume) and a viscosity of

Table 5

Centipoise (spindle speed 2 rpm). The paint was applied as in Example 15 to test panels, the layer thickness was again about 1.27-ΙΟ- ³ cm. The test was carried out as in the previous examples.

The results of the salt spray corrosion test with the paints from Examples 15 to 17 are shown in Table 5 reproduced.

Corrosion resistance of coatings with MnjC ^ pigment and iron oxide pigments

example
No.

Test time

(h) corrosion

Blistering

(Mn ₃ O ₄ )

(red
Iron oxide)

(black
Iron oxide)

100 245

100 245

100 245 6M
6 M.
6 MD
6 MD

6 M.
6 MD

The results shown in Table 5 show that red or black iron oxide are pigmented:

Paints based on phenoxy resin systems, which show this superior property in particular

Mn3O.f smoke dust contained as a pigment, a better ^3Ü longer test times of up to 245 hours. Have corrosion resistance than paints with

Claims (1)

Patent claims: 1. Solvent-based paint, which is the main Component contains a resin binder and a color pigment as well as customary auxiliaries, wherein the color pigment at the same time has corrosion-preventing properties, characterized by ^ that, as a coloring and corrosion-preventing pigment, finely divided MnjOa smoke dust with the following properties: