 |
Description  |
|
|
BACKGROUND OF THE INVENTION
The present invention is concerned with coating processes, particularly
those utilizing high-solids alkyd paints.
In order to minimize the amount of solvent required in coating
compositions, most of which is released to the atmosphere during painting
operations, it is desirable to produce coating compostions having
relatively small amounts of solvents and relatively large amounts of
solids. The time and energy required to cure such coatings are important
parameters.
Alkyd paints are relatively inexpensive, and it would be desirable to have
a high-solids, alkyd-based paint which could be cured at low temperatures
in a short period of time. U.S. Pat. No. 4,014,830--Rumfield (Mar. 29,
1977), assigned to Celanese Coatings and Specialities Company uses up to
10 weight percent of a polyacrylate or polymethacrylate ester of a polyol
as as a modifier in an alkyd resin to allegedly speed up the through-dry
of the coatings and to permit obtaining harder films after overnight
drying. Although methacrylates are mentioned, the disclosure focuses on
acrylates including trimethylol propane triacrylate. Similar technology
using 0.1 to 10% monomer is disclosed in French Patent Publication
2,312,302 (1976), assigned to Societe Continentale Parker, and
corresponding Belgian Patent 842,167 (1976).
U.S. Pat. Nos. 3,743,615--Yethon (1973) and 4,049,599--Lott (Sept. 20,
1977) discuss methods of increasing the drying speed or the solids content
of paints.
German Offenlegunschrift 2,710,032, published Sept. 9, 1977 and based on
two U.S. applications filed Mar. 8, 1976, discloses the use of
dicyclopentenyl acrylate or methacrylate as a reactive, nonvolatile
monomer in an alkyd resin paint which can also contain a cobalt salt and a
volatile ketoxime. However, the (meth)acrylate acid ester of
dicyclopentadiene used in that patent has just one acrylic or methacrylic
group.
It would be desirable to have a paint which is capable of application with
less solvent and curing at a higher speed and lower temperatures than is
available from the prior art.
SUMMARY OF THE INVENTION
The present invention provides a process of applying a coating composition
to a substrate wherein said coating composition comprises an unsaturated
fatty acid alkyd resin, an alkyl dimethacrylate or trimethacrylate
monomer, a cobalt salt effective as a catalyst for the oxidative
crosslinking of the alkyd resin, a complexing agent to block the cobalt
catalyst, and a polar solvent; wherein the coating composition contains by
weight, based on the alkyd resin plus the methacrylate monomer, at least
about 50% of the alkyd resin, about from 10 to to 40% by weight of the
methacrylate monomer, and at least about 10% polar solvent; and wherein
said process comprises adding a peroxide to the coating composition prior
to application of the coating composition to the substrate to enhance
oxidative crosslinking of the alkyd resin and the methacrylate monomer.
A particularly preferred embodiment is about 70% alkyd resin, 25%
hexanediol dimethacrylate, 5% dibutyl phthalate, 0.1% cobalt, 0.4% methyl
ethyl ketone oxime, and 20% isopropyl alcohol.
About 20-85% of the solvent can be water in water-soluble coating
compositions of the invention.
A peroxide, such as preferably methyl ethyl ketone peroxide, may be added
to the paint shortly before it is applied to the substrate to enhance
oxidative crosslinking cure. The addition is most readily handled by
adding the peroxide in a spraying procedure, preferably at 1-7.5% levels.
DETAILED DESCRIPTION OF THE INVENTION
The present invention utilizes a modification of normal alkyd paint
mechanisms. Although the following is thought to constitute an explanation
of how the invention operates, it is merely a hypothesis offered for
better understanding of the invention. Applicant should not be considered
to be bound by this hypothesis. After the paint has been applied to a
substrate, and while it is being dried, either under ambient conditions or
at elevated temperatures, oxygen enters the film by diffusion. Oxygen is
consumed by the olefinic drying oil groups to form hydroperoxides and
peroxides as potential oxidative crosslinking sites on the alkyd.
Cobalt-catalyzed oxidation of the olefinic unsaturation in the alkyd forms
hydroperoxides. Simultaneously, cobalt ions, regenerated from an
oxime-blocked complex, decompose the hydroperoxides to peroxides. The
cobalt ions then couple with the peroxides to create a redox catalyst
pair. This pair initiates copolymerization of the reactive monomer with
the unsaturated backbone of the alkyd.
The addition of peroxides, such as methyl ethyl ketone peroxides, prior to
painting, hastens drying times by providing a more readily available
radical source by means of a cobalt-hydroperoxide decomposition mechanism.
Other peroxides that can be used with the invention include benzoyl
peroxide, lauroyl peroxide, acetyl peroxide, 2-4 pentane dione peroxide,
peroxydicarbonate, diisopropyl peroxydicarbonate, tert-butyl
peroxypivolate, tert-butyl peroxybenzoate, dicumyl peroxide, and
ditert-butyl peroxide. For use with aqueous compositions, preferred
peroxides are hydrogen peroxide, ditert-butyl peroxide, tert-butyl
peroxide, and cumene peroxide.
Conventional alkyd compositions can be used as the alkyd component of
coating compositions of the invention. It is desirable for the alkyd to
contain at least a small amount of maleic anhydride, such as at least
about 1%. Alkyds generally are made by condensation copolymerization of a
dibasic acid, a monobasic acid, and a polyol.
The three components are heated together in a one or more step process,
with or without solvent, to give a polyester. Azeotropic processes may be
used to advantage. U.S. Pat. No. 4,045,392--Callahan and Coe (Aug. 30,
1977) discloses an improved alkyd resin manufacturing process using water
or stream to reverse or retard gelation. Such a process may be used
advantageously.
For the alkyd composition itself, suitable starting materials include
linseed or soya oil fatty acids; phthalic anhydride, adipic acid or
isophthalic acid; benzoic acid or tertbutyl benzoic acid; and
pentaerythritol or glycerine, trimethylol ethane, trimethylol propane,
neopentyl glycol, or trimethylpentane diol.
Typical alkyds are made by the copolymerization of phthalic anhydride
(equivalent to a dibasic acid), a fatty acid and glycerol. Multiple double
bonds in the carbon chain of the fatty acid enable the alkyd to dry
through oxidative crosslinking.
With compositions and processes of the present invention, methacrylate
monomers act as a solvent until oxidative crosslinking commences. Then
they polymerize into the resin film by reacting with the alkyd through a
vinyl polymerization mechanism.
Also, aqueous coating compositions can be used in accordance with the
invention if the alkyd is made compatible with water. Such alkyd resins
can be made from isophthalic acid, trimellitic anhydride, tall oil fatty
acids, and trimethyl pentane diol. For aqueous coating compositions, it is
desirable for the alkyd resins to have an acid number of 40 to 60 and a
hydroxy number of 210 to 260, and for them to contain sufficient ammonia
or amine to provide a pH about in the range of 7 to 9.
The di- and trimethacrylates have been found to be much more reactive in
high-solids coating compositions of the invention than monomethacrylates
such as dicyclopentadiene methacrylate. This permits much more rapid
curing and/or the use of lowered temperatures for curing and thus
increases the likelihood of obtaining a practical system.
The requirement that the methacrylate be present as a monomer is for the
purpose of obtaining a minimum viscosity so that a maximum solids content
can be achieved in a practical paint. Of course, the use of some dimers or
oligomers of methacrylates may not substantially change the results and
thus may be equivalent to and within the invention.
In contrast to acrylates, the methacrylate monomers used in the invention
are less toxic and more reactive, giving faster cures at lower
temperatures.
In the present invention, dimethacrylates appear to be used more
efficiently than trimethacrylates. Apparently, only about two methacrylate
groups from each monomer, on the average, are actually polymerizable with
the alkyd chains. Thus, trimethacrylates can be used, but dimethacrylates
are preferred, at least for some purposes. Over about 25%
trimethylolpropane trimethacrylate leads to undesirable brittleness in the
cured paint film. Less than about 10% of any of the methacrylates fails to
give the advantages of the invention in terms of high-solids coating
compositions and tends, instead, to be merely a methacrylate modification
of the alkyd paint itself.
Cobalt salts protected with a suitable complexing agent such as oximes must
be used in coating compositions of the invention to obtain rapid drying to
a desirable film structure. The reason for this is not known, but it is
probably related to the sensitive balance between the action of the
catalyst in opening the hydroperoxide bond on the alkyd for oxidative
crosslinking; the prevention of gelation on the surface or throughout the
paint during its useful life; and the formation of a cobalt peroxide for
initiating the subsequent vinyl polymerization. For satisfactory blocking
of the cobalt, it is desirable to use oximes in an amount of 4-6 times the
mols of cobalt. Preferably, the cobalt is used at levels of 0.05 to 1.5%
equivalent metal content. Various soluble cobalt salts are suitable.
Salts of other metals, known in the trade to work as auxiliary driers, may
also be used along with the cobalt salts. For instance, up to 1.0%
equivalent metal content of salts of calcium, zirconium or lead optionally
may be used. In addition to inducing or accelerating drying, they also
promote better water resistance, film hardness, compatability and other
desirable properties. Paint dryer technology is discussed in "Treatise on
Coatings," Volume 3, Pigments, Part 1, in article on "Additives" by E.
Singer, pp. 11-14. The treatise is edited by Myers and Long and published
by Marcel Dekker (New York) in 1975.
It has been found that it is quite desirable to use polar solvents in
coating compositions of the invention, especially with lower levels of
methacrylate monomer. While it is possible, and perhaps sometimes
desirable, to have nonpolar solvents present, polar solvents should also
be provided, preferably in an amount of at least 10% by weight of the
coating composition. The methacrylate monomers also serve as polar
solvents until they react with the alkyd resin to become part of the
coating solids.
The improved dry paint film hardness obtained when the solvent is a highly
polar solvent such as butanol may be due in part to stabilization of
hydroperoxides formed on the alkyd chains. The solvent may interfere with
decomposition of the hydroperoxides by forming a stable intermediate
involving hydrogen bonding with the hydroperoxides, such as using an
alcohol solvent:
##STR1##
Although such interference with hydroperoxide decomposition seems
undesirable in conventional alkyd crosslinking, it may be helpful with the
present invention. A stable peroxide is desired to form a cobalt-peroxide
pair which is a low-temperature vinyl polymerization initiator. This would
encourage copolymerization of the alkyd and the methacrylate monomer.
In addition to stabilizing hydroperoxides, it may be that lower volatility
polar solvents also aid in keeping the film open longer. This minimizes
skin formation and allows more oxygen to diffuse into the film. Oxygen is
more soluble in more highly polar solvents, and this too can aid in curing
the film.
Coating compositions of the invention may also contain additional paint
constituents used in the art including plasticizers, such as dibutyl
fumerate, dibutyl itaconate, and dibutyl sebacate. Hydrocarbon resin
modifiers based on such monomers as dicyclopentadiene, dipentene, B-pinene
and styrene may be used to promote lacquer dry. Additives can be used to
prevent wrinkling and for other purposes, such as phenolic varnishes and
silicone resins. Pigments and fillers known in the art can be used, so
long as they do not deleteriously interact with the alkyd-monomer
stability and curing mechanism.
The following examples illustrate the invention
EXAMPLE I
______________________________________
ALKYD PREPARATION
Parts
______________________________________
Linseed oil fatty acids
362.0
Phthalic anhydride 251.5
Maleic anhydride 5.3
Benzoic acid 119.1
Pentaerythritol 262.1
______________________________________
The ingredients were mixed with 5% xylene as an azeotroping solvent, heated
under nitrogen to 230.degree. C. and held there until an acid number of
14-17 was obtained. The reaction product was then mixed with butanol
solvent to obtain a solids content of 80% and a viscosity of Z5-Z6
Gardner-Holdt.
EXAMPLE II
WHITE PAINT
Seven parts of the alkyd of Example 1 were mixed with one part
trimethylolpropane trimethacrylate, 0.05% cobalt, 0.5% methyl ethyl ketone
oxime, and a titania pigment at a ratio of pigment to binder of 85/100.
When coated on a substrate by conventional means such as spraying with 7%
methyl ethyl ketone peroxide injected by a two-component spray gun, the
paint dried under ambient conditions (about 25.degree. C., circulating
air) to a tack-free condition in 30 minutes.
* * * * *
|
|
 |
|
 |
Description |
|
