DE3600395A1 - Triboelectrically depositable powder coatings - Google Patents

Abstract

The invention relates to the possibility for the triboelectric processing of pulverulent, thermosetting coating compositions composed on a binder base of polyester-epoxy resin mixtures or free of epoxy resin. The advantages of such coating materials, in accordance with methods of triboelectric processing, can be derived from the "pure" epoxy resin powder coatings.

Description

Thermosetting powder coatings with triboelectric spraying devices too processing brings compared to corona electrodes containing spray guns as is well known, a number of advantages. This property is based u. a. that there is no potential between the spraying device and the workpiece, no electric field and no field lines. This allows Powder coatings also penetrate into "Faraday cages". Was disadvantageous so far that the commercially available thermosetting powder coatings with more frequent Except for pure epoxy resin powder coatings, do not charge yourself enough and thus gave a very poor separation efficiency.

When charging by friction, it is assumed that on the surfaces the coating powder in question electrical double layers are present (Dr. Heinz Haase: Statistical electricity as a danger, Specialist brochure, Verlag Chemie GmbH, Weinheim / Bergstrasse). The outer part of such a layer consists, for. B. from electrons, which come from solid charge carriers bound to matter to be kept in a state of equilibrium, facing the body outwards makes it appear neutral.

When two surfaces are touched, electrons can be released from one Surface of the other surface, so that after the Separation of the first by an excess of electrons negative and the others are positively charged due to lack of electrons.

It depends on the electrical conductivity of the substances involved primarily depends on how a charge separation is noticeable can make. The "voltage state" caused by the fault becomes the quicker the better the electrical conductivity charge equalization until complete reunification can.

If the conductivity of the substances involved is sufficiently high, the complete one is acceptable Reunification practically simultaneously with the charge separation from. Prerequisite for charging to occur at all is that more cargo quantities separated than reunited at the same time will.

To do this, at least one of the partners must generally have a worse one Be a leader. Both surfaces have poor conductivity (good Insulation capacity), then in any case after charge separation the contact partners involved are charged in opposite directions. It has to be additional be expected to be due to charge separation charged surface of a fabric with good insulation properties not only different charge densities can occur, but even also different polarity of the charges.

According to these considerations, the possible charge ratios,  caused by friction or separation on a powder particle, derive as follows:

- due to the presence of electrical double layers in the envelope surface powder coating particles can be charged by friction (separation).

- To generate friction electricity on powder particles an insulator (e.g. the charging tube a friction gun made of a certain plastic). But it can also by friction (contact) with a charged conductor Lead success because only one partner needs to be an isolator.

- Considered locally, charges in different Density and even different polarity arise (probably to be included to explain the adhesion of several grain layers during the coating process).

- The charge due to friction sits in the envelope and can only compensate by line. The state of charge remains the longer the lower the conductivity of the powder coating is.

- in contrast to the frictional electricity, which is located in the envelope surface and is thus bound to the fabric, air ions, such as previously described, only deposited on the grain surface (W. Anselment, J. Kähn, and R. Kreisler: The physical basics of powder coating, powder conference 1973).

According to W. Kleber et al. (W. Kleber, D. Auerbach and H. Bauch: powder coating in hollow bodies, surface + jot, 2, 10-14), the minimum charge for powder adhesion is:

This results in an epoxy resin powder

There are:
Q ^* _{at least} ≈ = minimum charge / g
r _s  = rel. DK the powder layer
G = 9.81 ms^-2
γ _s  = Material density
 = average particle diameter

To achieve this minimum charge is a sufficient charge current required.

It must meet the following conditions: Safety factor 3).
It is

For an example withM _p  = 2.4 kg / h,
 γ _s  = 1.5 g / cm^3rd,  = 50 µm results yourselfI. ≧ 0.28 µA.

Since the current I is proportional to the air flow in the area of interest, it can be adjusted so that I ≧ I becomes _{at least} .

From the coating tests carried out and the tests carried out in parallel Current measurements show that the charge reached is close to the maximum charge lies. This makes the charging system the prerequisite for one given maximum coating efficiency.

Practical experience has shown that powder coatings with low charging capacity can only be incompletely processed triboelectrically. In tests ² ) on several powder spraying devices of different origins via their charging capacity, the following relationship clearly emerged in comparison with determinations of the application efficiency carried out in parallel:

The more a spray device was able to charge the powder coating, the greater the application efficiency that could be achieved with this spray device. The best results were achieved when a charge of 2 × 10 ^-6 coulombs / gram was measured for the powder coating and the application efficiency was about 90% because of this relatively high charge.

According to the authors mentioned above, the specific charge of functional powder coatings is around ≧ 1 · 10 ^-7 Cb / g.

W. Kleber and co-workers (W. Kleber, D. Auerbach and H. Bauch: Electrokinetic charging opens up new areas of application for electrostatic powder coating, EPS Congress, May 30 - June 1, 1983) assume that the current values are specific Powder charge of Q ^* ≧ 7.2 · 10 ^-7 As / g are in the same order of magnitude as for ionization charging with high-voltage corona, and this is based on an epoxy resin lacquer and PTFE tube with a powder throughput in the range of 15. . . 30 kg / h at current values of I = 3. . . 6 µA. With this current, the function is also manageable, and the control variables for conveying and blown air can also be obtained from it. However, the restrictions that not all powder materials can be charged equally well should not go unmentioned.

A. W. Bright and R. P. Corlett (A. W. Bright and R. P. Corlett: The electrostatic powder coating in industry.- An overview of new advances and future developments, I. E. E. Conference on Maschining. . . ) mention the development work of the N.R. D .C. about promoting a tribo gun. In this the polymer powder charged by friction when touching a rotor. Again, there are only encouraging results with polyamide 11, epoxy resin and acrylic polymer variants.

If one examines the dependence of the charging on different hose materials ( Fig. 1 + 2), the five tested products (soft PVC, natural rubber, polyethylene, silicone rubber, Teflon), Teflon show the best behavior.

Because the degree of chargeability is essential for practical processability it is necessary to use appropriate raw materials. The raw materials used for the powder coatings are very numerous and electrical Behavior quite different, so extensive measurements must be carried out. The measuring device can be arranged that a dipstick is attached to an ammeter and the powder spray is directed against the dipstick. The result is then in the ammeter read.

Results processed using Airstatik (from INTEC-Maschinenbau, Dortmund), using 3 bar compressed air gave the following picture for carboxyl-containing resins:

It can already be seen from the aforementioned tests, but also in general known that especially those based on carboxyl-containing and acidic polyesters Powder coatings that are not suitable for triboelectric processing. Conditional, or case by case, are hydroxyl-containing polyesters with IPDI adducts or chemically related crosslinking component can be processed.

With epoxy resins, the perfect coating depends on the type of hardener from.

The selection of the pigments also comes, as the previous tests show of particular importance.

A formulated, pigmented polyester TGIC powder coating results in the above Test conditions insufficient charging. Be mentioned pigmented polyester TGIC powder coating substances or mixtures of different substances Polarity added by a sufficiently high conductivity that a reunification with simultaneous charge separation will be good processable Get powder coatings. The addition of these materials can already in resin production, powder coating production in the extruder, during the grinding process in the granulate, but also by simply mixing in the finished Powder paint done. The latter way is always problematic if the "Over spray" of the powder coating during processing in a recovery system is caught. Particle separations from powder coating to Additive enter the reprocessing process in the friction charging make it uncontrollable with generally insufficient coating results.

Powder coatings based on epoxy resin polyester (so-called mixed powder) can be made using the same procedure Scheme as described above, can be produced. It will be analog Get results.

Further, other commercially available thermosetting powder coating systems, such as u. a. Epoxy resin and polyurethane powder coatings can significantly increase the frictional charge be improved.

Powder coatings built up according to the above guidelines have an average Separation behavior that in the order of those of the known electrostatic powder spraying process with negative charge.

Below are three coating results.

As a comparison using the corona electrode method (spray gun: manufactured by GEMA, St. Gallen):
40 kV, separated quantity: 9.87 g.

The results of the separation showed that the addition concentration a layer thickness regulation of the additive could, making this process more economical at the same time can.

Basically, these powder coatings are produced according to the current production processes, d. H. the meltable binder is included the usual additives such as hardeners, pigments, leveling agents, others Additives premixed in a mixer. After that, the meltable portions the mixture melted in an extruder under the influence of heat and the Solids dispersed. The warm, liquid mass leaving the extruder becomes cooled and then by breaking and grinding, possibly combined with sifting reduced the desired particle size. During the shredding process additional additives can be added.

These coating materials produced according to the invention are by means of a triboelectric spray gun applied to the part to be coated.

The article coated with powder coating is between in a baking oven 120 ° C and 250 ° C heated for 35 to 1 minute. Here, the powder coating melts and it a chemically hardened thermosetting film is created.

The use of short-wave light is also applicable.

The invention will now be illustrated by the following non-limiting examples explained.

Example 1 - Epoxy resin polyester powder coating (so-called mixed powder coating)

395 parts by weight of Uralac 2450 (DSM, NL-Zwolle), oil-free, free carboxylgr. polyester
172 parts by weight of Araldit GT 7203 (Coba-Geigy, Basel), (epoxy resin)
3 parts by weight of accelerator VP XB 3126 (Ciba-Geigy, Basel)
3 parts by weight of benzoin (Plato, Koblenz)
4 parts by weight of Ionol CP (Shell, Frankfurt)
10 parts by weight of leveling agent Byk-VP 360 P (Byk-Gulden, Düsseldorf)
50 parts by weight of triaethylamine
200 parts by weight of titanium dioxide anatase
170 parts by weight of barium sulfate
1000 parts by weight

In a mixer, the aforementioned materials were now in the quantities intimately mixed. Then this mixture is extruded, e.g. B. in a penitentiary Kneader (shaft temperature about 60 ° C, first zone about 60 ° C, second zone about  80 to 90 ° C, product temperature about 100 to 120 ° C, residence time in the extruder about 60 to 90 seconds). The extrudate obtained is then after cooling with z. B. a micro pul mill to a particle size range of 10 to 150 microns (with an average of 40 to 60 µm) finely ground.

This powder coating composition obtained is by means of a triboelectric powder spray gun with 3 bar conveying air at room temperature sprayed and then thermally crosslinked at 180 ° C for 12 minutes. It will be one Obtained total layer thickness of about 70 microns.

Example 2

As example 1, but without triaethylamine.
4% Hyamine 1622 (cationic, capillary-active additive, product from Rohm and Haas, Frankfurt) was added to the grinding process.

The processing data also according to example 1.

Example 3

As example 1, but without triaethylamine.
The amount of Hyamine 1622 from Example 2 is introduced separately into the corresponding powder spray element and mixes there with the powder coating by means of the conveyed air carried along.

The manufacturing and processing data correspond to Example 1.

Example 4

55 parts by weight of Grilesta P 7305 (oil-free, carboxyl-containing polyester; from Emser-Werke, Cologne)
4 parts by weight of Araldit PT 810 (TGIC triglycidyl isocyanurate, Ciba-Geigy, Basel)
1 part by weight of Perenol F 30 P mod. (acrylic flow agent, Henkel, Düsseldorf)
3 parts by weight of Triton X 200 (capillary-active wetting agent, Rohm and Haas, Frankf.)
20 parts by weight of titanium dioxide rutile
17 parts by weight of barium sulfate
100 parts by weight

The mixing and extruder manufacturing data correspond to example 1. As in Example 2, the grinding process was 4% VP-LA 915 (capillary-active wetting agent from Henkel, Düsseldorf).

The powder coating was processed in accordance with Example 1.  

Example 5

55 parts by weight of Grilesta P 7305 (oil-free, carboxyl-containing polyester), containing 6% VP-LA 915 (capillary-active wetting agent from Henkel, Düsseldorf), which was added to the resin production melt phase
4 parts by weight of Araldit PT 810 (TGIC)
2 parts by weight of leveling agent Byk-VP 360 P (Byk-Gulden, Düsseldorf)
20 parts by weight of titanium dioxide rutile
19 parts by weight of barium sulfate
100 parts by weight

The manufacturing and processing data correspond to example 1

Example 6

50 parts by weight composition as in Example 1, also the preparation
50 parts by weight of Gotamid ES, natural (colorless polyamide 6 powder, Gotek, Frankf.)
100 parts by weight

The production is done by simple mixing; the processing as in Example 1 described.

Claims (13)

1. Powdered thermosetting coating compositions comprising as a binder polyester-epoxy mixtures or epoxidharzfrei which can be sufficiently deposited on the substrate by a triboelectric coating process to substrates for the purpose of corrosion protection and / or the decorative appearance with a triboelectric spray device not or not characterized characterized in that by means of an additive with a greater electrical conductivity and higher polarity than the binder or binder mixture used and which alone gives a value of over 2 µA in the triboelectric charge. 2. Powdery, thermosetting coating compositions, which as Binder polyester-epoxy resin mixtures or are free of epoxy resin, according to Claim 1 characterized in that the additive already in the melting phase is incorporated in the resin production. 3. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1 and 2 characterized in that the additive in the extruder Powder coating manufacturing phase is incorporated. 4. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-3 characterized in that the additive during the fine grinding is added to the granules. 5. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or epoxy-free, according to Claims 1-4 characterized in that the additive during the processing Spraying process is added to the spray organ. 6. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or epoxy-free, according to Claims 1-5 characterized in that the amount added of the additive depends on the desired layer thickness and between 0.5 to 50%. 7. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-6, characterized in that the friction-charging additive of organic, hydrophilic structure.   8. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-7 characterized in that friction-charging mixtures of cationic and / or anionic capillary-active wetting agents are added. 9. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-7 characterized in that the friction-charging Additive based on quaternary ammonium compounds. 10. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-9 characterized in that pigments containing metal for can be used alone or together with an organic additive, which result in a value of more than 2 µA in the triboelectric charge. 11. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claim 10, characterized in that preferably as a metal pigment Zinc dust is used. 12. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claims 1-11 characterized in that thermoplastic, powdery Coating agent with a triboelectric charge of over 2 µA in an amount of 5 to 50%. 13. Powdery, thermosetting coating compositions, which as Binders are polyester-epoxy resin mixtures or free of epoxy resin, according to Claim 12, characterized in that as a thermoplastic coating agent preferably polyamide is added.