EP0042852A1 - Chemical resistant coatings - Google Patents

Abstract

The chemical and soil resistance of coatings applied by a fusion coating process is improved by mixing in the melt a small amount of hydrophobic silica airgel in the coating powders.

Description

Chemical Resistant Coatings

Technical Field

This invention relates to coating powders and more particularly to coating powders that are especially adapted to yield coatings that are resistant to staining and chemical degradation.

Background Art

The coating compositions of this invention are dry, free-flowing powders adapted for application to substrates by fusion coating processes. The term "fusion coating processes" is here used to mean those coating processes in which powders are distributed over a' substrate and heated to above their melting points to fuse them into a continuous protective film. The powders may be based either on thermoplastic resins or thermosetting resins and, in the latter case, the heating must be sufficient to cure the resins and develop their ultimate properties. Examples of fusion coating processes include fluidized bed, electrostatic spraying, hot flocking, cloud chambers, fluid transport of powder through heated pipe, and the like.

The environment in which coated articles are used may require that their coatings be resistant to staining and corrosion for either decorative or functional reasons. For example, decorative coatings are applied to kitchen appliances which lose their attractiveness when they became stained by such things as fruit and vegetable juices, catsup, mustard, or the like. At the other extreme are functional coatings which may be used in the oil fields to protect pipe and tubing from the corrosive effects of such things as brine, drilling muds and acid forming gases at pressures as high as 700 kg/c 2 and temperatures which not uncommonly reach 200°C.

In the past, it has been conventional to formulate highly resistant coatings from phenolic and epoxy/phenolic resins and apply them from solutions. These resins are difficult to use in fusion coating processes because they cure, at least in part, by condensation reactions which generate water and gases that form voids in the protective films unless they are cured under pressure or are applied in comparatively thin layers.

Disclosure of the Invention

Accordingly, it is an object f this invention to provide coatings that are stain and corrosion resistant. Another object of this invention is to provide coating powders that will provide dense, void free, highly chemical and temperature resistant films when applied by fusion coating methods.

These and other objects of this invention are achieved by melt mixing a small amount of an extremely hydrophobic material with coating powders. At concentrations even as low as .5%, significant improve¬ ment in stain and corrosion resistance has been observed The preferred hydrophobic materials for use in this invention are fumed silicas which have been treated by reacting the surface silanol groups with a silane to tie up the free hydroxyl groups and provide a hydrophobic surface.

A suitable hydrophobic silica for use in this invention is sold by Tulco, Inc. under its trademark Tullanox 500. This material is described as a fumed silica having a nominal particle size of 0.007 microns and a theoretical surface area of 325 square meters per gram. The surface of the fumed silica is chemically treated to replace the silanol groups with trinethyl- siloxyl groups.

Another similar hydrophobic material is manufacture by Degussa under its trademark Aerosil R 972. This material is described as having particle sizes in the range of from .005 to .050 microns, surface areas of fro 50 to 400 square meters per gram, and surfaces that have been made hydrophobic by reacting the silanol groups on the silica surface with alkyl chlorosilane. In the following examples:

DGEBA refers to diglycidal ethers of bisphenol A epoxy resins having the structure:

ci-i

and the numerical designation of the type approximates the value of n;

Epoxy novolac resins refers to epoxidized novolac resins having the structure

in which the epoxy functionality is approximately x + 2 and y may be 0 or 1; and phr is used to mean parts by weight per hundred parts by weight of resin. EXAMPLE I

The following components were blended together: phr DGEBA - type 7 epoxy -resin 36.0 DGEBA - type 4 epoxy resin 36.0 DGEBA - type 3 epoxy resin 15.2 Epoxy-novolac (epoxy functionality 3.2) 12.8 Polyalkylacrylate flow promoter 0.8 Dicyandiamide 4.36 2-methylimidizole 0.2 Silica filler 100.0 TiO., 10.0

Cr-O., (green pigment) 20.0

Surfactant (Dow Corning DC 2106) 0.67 Hydrophobic silica (Silanox 101) 1.0

The above materials were melt-mixed in an extruder and the extrudate was chopped and ground to a fine powder that all passed through a 60 mesh screen. 0.67 phr of an untreated hydrophilic silica aerogel was dry blended to promote powder flow. Test panels prepared for coatin by sand blasting, deburring cleaning, degreasing and priming were heated to a temperature of 165°C. The panels were coated by immersing them in a fluidized bed of the powders and postheated for 30 minutes at 205°C. to complete the curing of the coatings.

A uniform film thickness of from about 10 to 15 mils was obtained and when the coatings were evaluated in qualification testing for use as coatings for water flood pipe, they were found to be superior to the indust standards including liquid and solid epoxy systems and liquid epoxy/phenolics. EXAMPLE II

A coating powder was compounded as in Example I by melt-mixing the following ingredients: phr DGEBA - type 4 epoxy resin 50

Epoxy novolac - functionality 3.8 50

Diamino diphenyl sulfone (curing agent) 20 CaSi0₃ (Nycore 300) 125

Ti0₂ (R-900) 10.0

Pigment (Green Cr„0₃) 20.0

BCl^-amine complex (catalyst) 1.0

The blended materials were chopped and ground to form a powder that passed through a 60 mesh screen and 0.67 phr of an untreated hydrophilic fumed silica was dry blended to improve powder flow. EXAMPLE III

A coating powder identical to that of Example II was prepared in which 1.0 phr of the hydrophobic silica of this invention (Tullanox 500) was included in the melt mixed materials.

Panels were sand blasted, deburred, cleaned, degreased and primed and then coated with the powders of Examples II and III. The coatings were applied by pre¬ heating the panels to 190°C, immersing them in a fluid¬ ized bed of the coating powders, and then postheating th for 60 minutes at 220°C. Smooth, uniform coatings of approximately 10 mils were obtained.

The coated panels were immersed to 2/3 of their length in a given test solution and the solution was then purged with hydrogen sulfide. After the autoclave was sealed, it was charged with 140 psi of C0₂ and the pressure was increased to 2,800 psi with air. The temperature was raised to 150°C. and these conditions were maintained for 24 hours. The test solutions used were four drilling muds including weighted lignosulfate, Baroid K Plus (TM N.L. Baroid) , salt water polymer and fresh water polymer. In all of the tests, the coatings of Example IV which included the hydrophobic silica proved significantly superior in resistance to attack by the drilling muds and dissolved gases than did the coatings of Example II. EXAMPLE IV phr DGEBA - type 3 epoxy resin 8.0

DGEBA - type 4 epoxy resin 17.0 Epoxy-novolac (epoxy functionality 3.2) 3.0

Polyalkylacrylate flow promoter 0.8

Dicyandiamide 4.36

2-methylimidizole 0.2

Silica filler 100.0 Ti0₂ 10.0

Cr₂0₃ (green pigment) 20.0

Surfactant (Dow Corning DC 2106) 0.67

Hydrophobic silica (Silanox 101) - 2.0

The above materials were melt-mixed in an extruder and the extrudate was chopped and ground to a fine powder that all passed through a 60 mesh screen. 0.67 phr of an untreated hydrophilic silica aerogel was dry blended to promote powder flow.

Steel panels were degreased, cleaned and primed. The panels were preheated for 5 minutes to a temperature of 205°C. and then immersed in the fluidized bed until a 10-15 mil coating had adhered to the steel panel. The panel was placed in an oven and postheated for 30 minutes at 190°C. EXAMPLE V

A coating material was prepared that was identical to that of Example I except that 0.5% of a hydrophobic fumed silica (Tullanox 500) was included in the formu¬ lation. A steel panel was coated with this powder in a similar manner to the panel in Example IV.

The steel panels coated in Example IV and Example V were compared by exposing them to common foods that read cause staining such as grape juice, red beet juice, cats and mustard. It was found that the panels coated with the composition of Example IV was permanently stained when exposed to these foods whereas the panels coated with a composition of Example V resisted staining and the foods were easily wiped away leaving no trace of color.

* * * *

In the above examples a significant improvement in chemical resistance was obtained using as little as 0.5 phr of the hydrophobic silica. Larger quantities can be used but, as a practical matter, when the amount of silica approaches 3 phr, its thixotropic effect makes it impossible to obtain adequate melt flow of the coatin powders. A related advantage that accrues in the practice of this invention is that the hydrophobic silicas are also extremely oleophilic. Oil will adhere to substrates coated with these materials which will provide lubricity and reduce wear in those applications in which the substrate is used in moving contact with other surfaces.

It is also believed that an oil film over a coated surfa will be further protection from attack by water borne chemical agents.

In the preferred form of this invention, the hydro- phobic silica aerogels are used in coating powders based upon epoxy resins having epoxy functionalities of greate than 2, as can be achieved through the use of epoxy novolacs. Also, high filler loadings of at least 50 __r-~- parts per hundred parts resin are believed to contribute the chemical resistance of the coatings.

Claims

Claims

1. A powdered coating composition adapted for application in fusion coating processes to provide a coating having a high degree of resistance to staining and chemical attack, the improvement comprising melt mixing minor amounts of a hydrophobic fumed silica into the coating powders.

2. A coating powder according to Claim 1 wherein the hydrophobic fumed silica is used in amounts from 0.5 to about 3 parts per hundred parts of resin and has a particle size less than 0.05 microns and a surface area in excess of 50 square meters per gram.

3. A coating powder according to Claim 2 wherein the resin is an epoxy.

4. A coating composition according to Claim 3 wherein the epoxy resin includes an epoxy novolac resin.

5. A coating powder according to Claim 4 wherein the epoxy novolac has a functionality greater than 3.

6. A coating powder according to Claim 5 wherein the epoxy novolac is present in an amount in excess of 25 parts per hundred parts resin.

7. A method of -improving the stain and chemical resistance of coating powders which comprises melt mixing between 0.5 and 5.0 parts per hundred parts resin of a hydrophobic fumed silica into an epoxy based resin.

8. ^' A method according to Claim 7 wherein the epoxy resin includes a major portion of an epoxy novolac having an epoxy functionality greater than 3.