Title of Invention

A COATING SOLUTION COMPRISING POLYSILAZANE

Abstract A coating solution comprising a polysilazane characterized in that a Si-H bond, a diluting solvent, land a catalyst wherein diluting solvent is selected from petroleum solvent, an aromatic or alicyclic solvent, a halogenated hydrocarbon paraffin type solvent mineral spirit, terpene mixtures an ether such as dibutyl ether, dimethyl ether, diethyl ether, polyglycol ether or tetrahydrofurane or a mixture thereof.
Full Text Technical Field
The present invention relates to a coating solution capable of forming a coating
excellent in characteristics such as corrosion resistance, anti-scratch properties,
abrasion resistance, wetting properties to water, easy-to-clean properties, sealing
properties, chemical resistance, oxidation resistance, physical barrier effect, heat
resistance, fire resistance, antistatic properties and anti-fouling properties by
applying it onto the surface of base materials such as metals, plastics, wood,
ceramics, cement, mortar, bricks, clay, etc. of the bodies and wheels of
automobiles, trains, airplanes, etc., dentures, tombstones, the interior and exterior
of a house, products used with water in toilets, kitchens, washrooms, bathtubs,
etc., signboards, signs, plastic products, and glass products.
Background Art
Conventionally, various measures are taken to prevent pollution of the surfaces of
articles. For example, automobile bodies are easily fouled with dust, combustion
products such as exhaust gas, or the like. Therefore the bodies are coated with
wax to form a wax coating thus preventing pollution of the bodies. By rendering
the surface of the body water-repellent, water upon contacting with the surface of
the body forms drops of water to roll down the surface of the body, whereby fouling
components in the water can be prevented from adhering and remaining on the
surface of the body, while the wax coating makes adhesion of fouling components
to the surface of the body difficult, and even if fouling components adhere to the
surface, they can be easily washed away with water.
Further, products used with water, such as bathtubs, kitchen sinks, washstands,
etc. are contacted during use with various materials such as soap liquid containing
oils and oily components, facial cleansing cream, hair shampoos, etc. in addition
to water. At this time oily substances and calcium salts of soap (i.e. soap dregs)
are considered to adhere to the surfaces of the products with dust etc. to form
fouling. To prevent fouling on the product, a glazed surface constituting a glassy
surface formed on the product is subjected sometimes to water repellency
treatment with wax, a fluorine-containing material, etc. to prevent fouling from
remaining on the glazed surface. By this water repellency treatment, it is also
attempted to prevent adhesion of fouling to the interior and exterior of a house,
toilet stools, products used with water, signboards, signs, tombstones, etc.
On the other hand, the modification of the surface of a base material by coating
the surface with a surfactant to render it hydrophilic has been known for a long
time, and a further improvement in durability of this hydrophilicity by adding and
incorporating a water-soluble organic polymer such as polyacrylic acid or polyvinyl
alcohol into the surfactant is described in JP-A 52-101680 etc. Further, a method
of applying and fixing a hydrophilic material such as cellulose, glycols and
glycerine via a coating of a polyvinyl alcohol-vinyl acetate copolymer to the surface
and inside of a porous film made of a hydrophobic polymer is known as described
in JP-B 5-67330 etc.
However, the water-repellent effect of water-repellency treatment with conventional
water-repellant wax cannot be said to be satisfactory, or even if sufficient water-
repellency treatment is initially conducted, the effect cannot be said to be long-
lasting, thus failing to exhibit a long and sufficient anti-fouling effect. Further, the
conventional hydrophilic coating confers hydrophilicity merely temporarily or in a
short time, and therefore the sufficient durability of the hydrophilic effect can hardly
be expected, and the water film on the hydrophilic coating is hardly rendered
uniform, thus causing a transmission image or reflected image to be warped and
making practical application thereof to the products problematic.
Furthermore with respect to prevention of dentures from fouling and generating
smell, fluorine treatment and the like have been examined, but cannot be said to
achieve a sufficient effect for a long time by treating the dentures once.
In addition, there is also demand for a coating solution capable of forming a
coating excellent in characteristics such as corrosion resistance, anti-scratch
properties, abrasion resistance, easy-to-clean properties, wetting properties to
water, sealing properties, chemical resistance, oxidation resistance, physical
barrier effect, low shrinkage, UV-barrier effect, smoothening effect, durability effect,
heat resistance, fire resistance and antistatic properties, and there is strong
demand for improvement particularly in corrosion resistance and anti-scratch
properties.
The present invention was made to solve the problems described above.
Therefore an object of the present invention is to provide a coating solution which
after application, can form a rigid and dense coating excellent in adhesion to a
base material and which can form a coating excellent in corrosion resistance and
anti-scratch properties and simultaneously excellent in characteristics such as
long-lasting hydrophilic and anti-fouling effect, abrasion resistance, easy-to-clean
properties, anti-scratch properties, corrosion resistance, sealing properties,
chemical resistance, oxidation resistance, physical barrier effect, low shrinkage,
UV-barrier effect, smoothening effect, durability effect, heat resistance, fire
resistance and antistatic properties on the surfaces of various base materials.
Thereby the surfaces of various products or articles such as automobile bodies,
automobile wheels, dentures, tombstones, the interior and exterior of a house,
products used with water in toilets, kitchens, washrooms, bathtubs, etc., toilet
stools, signboards, signs, plastic products, glass products, ceramic products, wood
products, etc., can be endowed with the above-described various effects including
corrosion resistance and anti-scratch properties.
The required characteristics of the coating solution, for example, the outward
appearance such as uniform transparency after coating, drying characteristics,
smell, safety, less damage to base materials, etc. are varied depending on base
materials, setting conditions, and application modes of products or articles to be
coated with the coating, solution and necessity for consideration of the surrounding
environment upon application of the coating solution. Therefore, another object of
the present invention is to provide a coating solution capable of easily preparing a
suitable coating solution adapted to various applications.
Disclosure of the Invention
The present invention relates to a coating solution having the following
characteristics:
(1) A coating solution comprising a polysilazane having a Si-H bond, a diluting
solvent, and a catalyst.
(2) The coating solution according to the above-mentioned item 1, wherein
petroleum solvent, an aromatic or alicyclic solvent, an ether, a halogenated
hydrocarbon or a terpene mixture or a mixture of those solvents is used as
the diluting solvent.
(3) The coating solution according to item 1, wherein a paraffin type solvent, a
mineral spirit, a paraffin type solvent, terpene mixtures or an ether or a
mixture thereofis used as the diluting solvent.
(4) The coating solution according to item 3, wherein dibutyl ether, dimethyl
ether, diethyl ether, polyglycol ether or tetrahydrofurane or a mixture thereof
is used as the diluting solvent.
(5) The coating solution according to any one of the items 2 to 4, wherein the
diluting solvent further comprises one or more of solvents selected from
xylene, methylcyclohexane and ethylcyclohexane.
(6) The coating solution according to any one of the items 1 to 5, wherein the
concentration of the polysilazane having a Si-H bond is 0.1 to 35% by
weight.
(7) The coating solution according to any one of the items 1 to 5, wherein the
concentration of the polysilazane having a Si-H bond is 0.5 to 10% by
weight.
(8) The coating solution according to any one of the items 1 to 7, wherein the
catalyst is contained in an amount of 0.01 to 30% by weight based on a
pure polysilazane content having a Si-H bond.
(9) The coating solution according to any one of the items 1 to 8, wherein the
catalyst is an N-heterocyclic compound, an organic or inorganic acid, a
metal carboxylate, an acetylacetona complex, fine metal particles, an
peroxide, a metal chloride or an organometallic compound.
(10) The coating solution according to any one of the items 1 to 9, wherein the
polysilazane having a Si-H bond is an inorganic polysilazane synthesized
by reacting SiH2CI2 with a base to form an adduct of SiH2CI2 and then
reacting the adduct of SiH2CI2 with ammonia.
(11) The coating solution according to any one of the items 1 to 9, wherein the
polysilazane having a Si-H bond is a polysilazane synthesized by reacting
SiH2CI2 and CH3SiHCI2 with a base to form adducts of SiH2CI2 and
CH3SiHCI2 and then reacting the adducts of SiH2CI2 and CH3SiHCI2 with
ammonia.
(12) Use of the coating solution according to any one of the items 1 to 11 for the
coating of surfaces of a base material to enhance the anti-corrosion,
abrasion resistance, anti-fouling properties, easy-to-clean properties,
wetting properties to the water, sealing effect, chemical resistance, anti-
oxidation, physical barrier effect, heat resistance, fire resistance, low
shrinkage, UV-barrier effect, smoothening effect, durability effect, antistatic
properties and anti-scratch characteristics of the surfaces of the base
materials of products or articles.
(13) Use according to item 12, wherein the coating solution is applied to the
surface of the base material in combination with a primer.
(14) Use according to claim 12 and/or 13, wherein the surface has been coated
with laquers, varnishes or paints prior to the application of the coating
solution.
Preferred Mode of the Invention
Hereinafter, the present invention is described in further detail.
The coating solution of the present invention comprises a polysilazane haying a
Si-H bond, a diluting solvent and a catalyst as essential components. The
polysilazane having a Si-H bond used in the coating solution of the present
invention includes the inorganic polysilazane soluble in a solvent and having
repeating units represented by the general formula:
The inorganic polysilazane having repeating units represented by the above
general formula and soluble in a solvent, used in the present invention, may be
any inorganic polysilazanes produced by a method known in the art.
As the method of producing the inorganic polysilazane having repeating units
represented by the above general formula and soluble in a solvent, any one of
arbitrary methods including methods known in the art may be used as described
above. One of the methods is, for example, a method of synthesizing an inorganic
polysilazane by reacting a dihalosilane represented by the general formula SiH2X2
(X is a halogen atom) with a base to form a dihalosilane adduct and then reacting
the dihalosilane adduct with ammonia. The halosilane is generally acidic and can
react with a base to form an adduct. Because the rate of formation and the stability
of the adduct depend on the acidity of the halosilane and the basicity or steric
factor of the basic substance, the type of halosilane and the type of base may be
selected suitably to form a stable adduct capable of reacting with ammonia to
produce an inorganic polysilazane easily. The stability of adduct in this case does
not necessarily mean such stability as to be able to be isolated in the form of
adduct, but means all possible cases where, for example, the adduct exists stably
in a solvent and also functions substantially as a reaction intermediate.
As the halosilane, a dihalosilane represented by the general formula SiH2X2
(X = F, Cl, Br, or I) is preferably selected from the viewpoint of the handling and
reactivity thereof, and particularly dichlorosilane is preferably selected from the
viewpoint of the reactivity, the price of its starting material, etc.
The base used for forming the adduct may be a base not causing other reactions
than the reaction of forming an adduct with a halosilane, and preferable examples
thereof include Lewis bases, tertiary amines (trialkylamines), pyridine, picoline and
derivatives thereof, secondary amines having a sterically hindered group,
phosphine, arsine and derivatives thereof (for example, trimethyl phosphine,
dimethylethy! phosphine, methyldiethyl phosphine, trimethyl arsine, trimethyl
stilbene, trimethylamine, triethylamine, thiophene, furan, dioxane, selenophene,
etc.), among which pyridine and picoline are particularly preferable for handling
and from an economical viewpoint. The amount of the base used is not
particularly required to be strict, and the base may be present in excess over the
stoichlometric ratio of the base (including an amine in an adduct) to the silane, that
is, in excess over the ratio of amine : silane = 2:1. The reaction of forming an
adduct is carried out in a solvent.
In synthesis of the inorganic polysilazane via an adduct, the adduct is reacted with
ammonia in an inert solution to form the inorganic polysilazane, wherein the
amount of ammonia may be in excess over silane, and the reaction conditions are
that the reaction temperature is usually -78°C to 100°C, preferably -40°C to 80°C,
and the reaction time and reaction pressure are not particularly limited. The
polymerization reaction of the inorganic polysilazane is carried out preferably in an
inert gas atmosphere, and the inert gas is preferably nitrogen or argon gas.
In the present invention, the inorganic polysilazane may be the one soluble in a
solvent and having repeating units represented by the general formula above, but
usually the one having a number-average molecular weight in the range of 600 to
3000 is preferably used. Further, the inorganic polysilazane is used preferably in
an amount of 0.1 to 35% by weight based on the total weight of the coating
solution, preferably in an amount of 0.5 to 10 % by weight.
Further, the organic polysilazane having a Si-H bond suitable as the polysilazane
used in the present invention includes polysilazanes synthesized by reacting a
dihalosilane (preferably dichlorosilane) and R1R2SiX2 (R1 and R2 represent a
hydrogen atom or an alkyl group (preferably a methyl group) provided that R1 and
R2 do not simultaneously represent a hydrogen atom; and X represents F, Cl, Br or
I, preferably Cl) with a base to form their corresponding adducts and then reacting
the adducts with ammonia. The base and reaction conditions for forming the
adducts and the conditions for the reaction of the adducts with ammonia may be
identical with those for production of the inorganic polysilazane described above.
On the other hand, the catalyst used in the present invention may be any one
which has a function of converting the polysilazane into silica at ordinary
temperatures. Preferable examples of the catalyst in the invention include
N-heterocyclic compounds such as 1-methylpiperazine, 1-methylpiperidine, 4,4"-
trimethylene-dipiperidine, 4,4"-trimethylenebis(1-methylpiperidine), diazabicyclo-
[2,2,2]octane, cis-2,6-dimethylpiperazine, 4-(4-methylpiperidine)pyridine, pyridine,
diperidine, a-picoline, ß-picoline, ?-picoline, piperidine, lutidine, pyrimidine,
pyridazine, 4,4"-trimethylenedipyridine, 2-(methylamino)pyridine, pyrazine,
quinoline, quinoxaline, triazine, pyrrole, 3-pyrroline, imidazole, triazole, tetrazole
and 1-methylpyrrolidine; amines such as methylamine, dimethylamine,
trimethylamine, ethylamine, diethylamine, triethylamine, propylamine,
dipropylamine, tripropylamine, butylamine, dibutylamine, tributylamine,
pentylamine, dipentylamine, tripentylamine, hexylamine, dihexylamine,
trihexylamine, heptylamine, diheptylamine, octylamine, dioctylamine, trioctylamine,
phenylamine, diphenylamine and triphenylamine; DBU (1,8-diazabicyclo[5,4,0] 7-
undecene), DBN (1,5-diazabicyclo[4,3,0] 5-nonene), 1,5,9-triazacyclododecane,
1,4,7-triazacyclononane, etc.
Further, an organic acid, an inorganic acid, a metal carboxylate, an acetylacetona
complex and fine metal particles can also be exemplified as a preferable catalyst.
The organic acid includes acetic acid, propionic acid, butyric acid, valeric acid,
maleic acid and stearic acid, and the inorganic acid includes hydrochloric acid,
nitric acid, sulfuric acid, phosphoric acid, hydrogen peroxide, chloric acid and
hypochlorous acid. The metal carboxylate is a compound represented by the
formula: (RCOO)nM wherein R represents a C1-22 aliphatic or alicyclic group; M
represents at least one metal selected from the group consisting of Ni, Ti, Pt, Rh,
Co, Fe, Ru, Os, Pd, Ir and Al; and n is the valence of M. The metal carboxylate
may be an anhydride or a hydrate. The acetylacetona complex is a complex
comprising a metal atom coordinated with an anion acac" generated from
acetylacetone(2,4-pentadione) via dissociation of an acid, and is generally
represented by the formula (CH3COCHCOCH3)nM wherein M is a n-valent metal.
Preferable examples of the metal M include nickel, platinum, palladium, aluminum
and rhodium. The fine metal particles are preferably those of Au, Ag, Pd or Ni,
particularly preferably Ag. The particle diameter of the fine metal particles is
preferably smaller than 0.5 µm, more preferably 0.1 µm or less, still more
preferably smaller than 0.05 µm. In addition to these materials, peroxides, metal
chloride, and organometallic compounds such as ferrocene and zirconocene can
also be used. These catalysts are incorporated in an amount of 0.01 to 30 %,
preferably 0.1 to 10%, especially preferred 0.5 to 7 % based on a pure
polysilazane content.
The diluting solvent used in the coating solution of the invention may be any of
diluting solvents capable of dissolving the polysilazane having a Si-H bond and the
catalyst. In consideration of storage stability, the diluting solvent is preferably a
solvent having a sustained ability to dissolve the polysilazane and the catalyst, and
the solvent even used for a long time is preferably stable without evolution of
gases such as silane, hydrogen, ammonia, etc. The diluting solvent used in the
coating solution of the present invention includes petroleum solvents such as
mineral spirit, paraffin type solvents, aromatic solvents, alicyclic solvents, ethers
and halogenated hydrocarbons. Examples of these solvents or solvent
components include paraffin type solvents or solvent components such as octane
and 2,2,3-trimethylpentane with 8 carbons, nonane and 2,2,5-trimethylhexane with
9 carbons, decane with 10 carbons, n-undecane with 11 carbons, etc., aromatic
solvents or solvent components such as xylene with 8 carbons, cumene and
mesitylene with 9 carbons, naphthalene, tetrahydronaphthalene, butylbenzene, p-
cymene, diethylbenzene and tetramethylbenzene with 10 carbons, pentylbenzene
with 11 carbons, etc., alicyclic solvents or solvent components such as
methylcyclohexane with 7 carbons, ethylcyclohexane with 8 carbons, p-menthane,
a-pinene, dipentene and decalin with 10 carbons, etc., ethers such as dimethyl
ether, diethyl ether, dibutyl ether, polyglycol ether, tetrahydrofurane, etc., and
halogenated hydrocarbons such as chlorinated hydrocarbons of dichloromethane,
dichloroethane, chloroform, etc. or the respective fluorinated, brominated or
iodated hydrocarbons and chlorinated aromatic compounds of chlorobenzene, etc.
Furthermore it has been proven useful to employ terpene mixtures, like for
instance Depanol® as solvents. However these solvents are exemplified merely as
illustrative purpose, and the solvents or solvent components are not limited to
those exemplified specifically. Further, these solvents or solvent components are
used alone or as a mixture thereof. Mineral sprit, paraffin type solvent and dibutyl
ether are particularly preferred in these solvents.
The coating solution of the invention can be applied onto the surfaces of
automobile bodies, automobile wheels, dentures, tombstones, the interior and
exterior of a house, products used with water in toilets, kitchens, washrooms,
bathtubs, etc., toilet stools, signboards, signs, plastic products, glass products,
ceramic products, wood products, etc. or the surfaces of various articles, to form
dense and hydrophilic coatings on the surfaces of these products or articles. The
base materials to which the coating solution of the invention is applied include a
wide variety of materials, for example metals such as iron, steel, zinc, aluminum,
nickel, titanium, vanadium, chromium, cobalt, copper, zircomium, niobium,
molybdenum, ruthenium, rhodium, boron, tin, lead or manganese or alloys thereof
provided if necessary with an oxide or plating film, various kinds of plastics such
as polymethyl methacrylate (PMMA), polyurethane, polyesters such as PET,
polyallyldiglycol carbonate (PADC), polycarbonate, polyimide, polyamide, epoxy
resin, ABS resin, polyvinyl chloride, polyethylene, polypropylene, polythiocyanate,
POM and polytetrafluoroethylene, if necessary in combination with a primer to
enhance the adhesion to the said materials. Such primers are for instance silanes,
siloxanes, silazanes to name only a few. Further base materials to which the
coating solution of the invention can be applied include glass, wood, ceramic,
concrete, mortar, brick, clay or fibers etc. These base materials may be coated if
necessary with lacquers, varnishes or paints such as polyurethane lacquers,
acrylic lacquers and dispersion paints.
These methods of applying the coating solution of the invention may be any of
known methods of applying liquids. Specifically, the method of applying the coating
solution of the invention includes, for example, a method of wiping with a cloth, a
method of wiping with a sponge, spray coating, flow coating, roller coating, dip
coating, etc., but the coating method is not limited to these exemplified methods.
The preferable method of applying the coating solution of the invention is varied
depending on various conditions such as the shape, size and quantity of a product
to which the coating solution is applied; for example, in the case of automobile
bodies and tombstones, a method of wiping with a cloth, a method of wiping with a
sponge and spraying are preferable in operation, and in the case of the interior
and exterior of a house, roller coating and spray coating are preferable. In the
case of dentures, spray coating and dip coating are preferable. Preferably, the
coating solution is applied in such an amount as to form a coating of about 0.1 to 2
microns in thickness after drying.
By applying the coating solution of the invention, a dense coating can be formed
on the surface of a product, and thus giving anti-corrosion, abrasion resistance,
anti-fouling properties, easy-to-clean properties, wetting properties to the water,
sealing effect, chemical resistance, anti-oxidation, physical barrier effect, heat
resistance, fire resistance, low shrinkage, UV-barrier effect, smoothening effect,
durability effect, antistatic properties and anti-scratch characteristics to the
surfaces of the base materials of products or articles. The reason why the above-
described characteristics can be given to the products and articles is that the
polysilazane contained in the coating solution is converted into a dense silica
coating by the action of the catalyst. Further, by the formation of silica coating, the
surface of the products or articles shows strongly hydrophilic properties based on
silica film. When dried at ordinary temperatures, the coating solution of the
invention easily forms a rigid and dense coating made of silica. The formation of
this silica coating is varied depending on the type of polysilazane, the type of
catalyst, etc., but the coating will.be formed in a period of about 1 to 2 weeks. The
coating solution of the invention is in a solution form at the time of application, and
can thus be applied very easily to form a coating. The coating can be converted
into a dense and rigid hydrophilic coating after application, thereby giving above-
described properties onto the various surface of products and articles. The surface
of the formed coating is so rigid and dense that it is excellent as a corrosion-
resistant coating and anti-scratch coating and simultaneously the coating is
excellent in abrasion resistance, anti-fouling effect and easy-to-clean properties
when fouled. Further, the coating solution of the invention can be used not only as
a corrosion-resistant coating, an anti-scratch coating, an abrasion-resistant
coating, an anti-fouling coating or a coating excellent in easy-to-clean properties,
but also as a film-forming coating solution for forming a hydrophilic coating, a
sealing material, a chemical-resistant coating, an anti-oxidization coating, a
physical barrier coating, a heat resistance-conferring coating, a fire-resistant
coating, an antistatic coating, a low shrinkage coating, a UV-barrier coating, a
smoothening coating, a durability coating etc.
When the coating solution of the invention is used to form a hydrophilic and dense
silica coating by using of the inorganic polysilazane on the surface of e.g. an
automobile, a tombstone, the outer wall of a house, or the like, the resultant
hydrophilic surface, upon contacting with rainwater, comes to be in the state of a
watery coating without forming water drops thereon. In addition, the hydrophilic
surface has higher affinity for water than for hydrophobic substances such as
combustion products including dust etc., thus permitting these foul substances to
be easily washed away with rain water. Further, the amount of smoke and dust
adhering thereto can be reduced because of formation of the dense surface.
Accordingly, visually noticeable fouling hardly occurs, and the amount of adhering
fouling is reduced. And because of the dense coating formed, it is difficult to be
scratched and is attained to prevent corrosion.
In the case of dentures, acrylic resin as the material of dentures absorbs water
with which foul substances enter the resin or foul substances adsorb or adhere
onto the resin, and these foul substances is a source of the smell of dentures. As
the coating solution of the invention forms a hydrophilic and dense silica coating
adhering well to dentures at a temperature at which acrylic resin as the denature
material is not deformed or deteriorated, the absorption of water into the resin can
be prevented, thus preventing the invasion of foul substances into the denture
material, and even if foul substances adhere to the silica coating, they can be
easily washed away with water, and thus evolution of smell can be prevented.
Further, dentures are coated with the coating solution of the invention, so that
even if unevenness occurs on denatures in finish polishing, the silica coating
makes this unevenness smooth to make adhesion of foul substances more
difficult. Further, the formed silica coating has high surface hardness and high
durability, and is thus not abraded with foods or upon biting, is stable in the living
body, and is not eluted. Even if the silica is released, it is nontoxic.
The required properties of the coating solution of the invention, for example,
outward appearance, drying characteristics, smell, safety, damage to a base
material, and storage stability of the coating solution, are varied a little bit
depending on the use of a product to which the coating solution is applied. To cope
therewith, the most suitable coating solution for intended use can be easily
provided by changing not only the type and amount of the polysilazane and
catalyst used but also the type of the solvent and the compounding ratio.
For example, a heavy solvent such as mineral spirit is suitable as the solvent for
readily noticeably fouled base materials whose outward appearance is regarded
as important, such as an automobile coated in dark color, dentures, polished
granite, a mirror-finish metal or plated substrate, transparent resin and glass.
Mineral terpenes Pegasol AN45 and Pegasol 3040 from Mobil Sekiyu Corp. are
also preferably usable solvents. By using mineral sprit as the solvent, base
materials whose spots, interference colors, whiteness and grittiness are readily
noticeable can be beautifully coated with the coating solution. Mineral spirit has
the above-described advantage, but is relatively poor in the solubilizing power so
that for compensating for the solubilizing power, mixed aromatic solvents such as
Solvesso 100 and Solvesso 150 from Esso Sekiyu Co. and Pegasol R-100 and
Pegasol R-150 from Mobil Sekiyu Corp. may be compounded in addition to
mineral sprit. Further, paraffin type solvents free of aromatic components can also
be used as the solvent. Specifically, low-odor solvents Exxol DSP100/140, Exxol
D30, Exxol D40 etc. from Tonen Chemical Co. can be mentioned.
Further, it is also important that products used with water, such as those in toilets,
kitchens, washrooms, bathrooms, etc. and dentures are odorless. By adding a
low-odor solvent such as methylcyclohexane or ethylcyclohexane if necessary as
a part of the solvent, a coating solution with less smell can be provided for such
products required to be odorless.
The coating solution of the invention may be applied to a product and goods newly
produced or to a product during use.
Then, examples of compositions of the inorganic polysilazane, the catalyst and the
diluting solvent in the coating solution intended for the respective uses are shown
below. These are shown merely for illustrative purposes, and the composition and
compounding ratio of the coating solution may be adapted to the use of a product
coated therewith, and the composition and compounding ratio of the coating
solution of the invention are not limited to those shown below.
A. Automobile bodies, wheels
The solution should not damage a coating sublayer and be stable such that
particularly when the solution is applied by a cup gun, it is not whitened in the cup
gun.
B. Dentures
The solution should be stable without whitening for a long time and safe to the
human body with less smell without deforming or deteriorating acrylic resin as the
denture material.
C. Tombstones
The solution should show less interference color when applied on granite or the
like and be stable for a long time so as not to be whitened.
D. The interior and exterior of a house, bathtubs, kitchens, etc.
The solution should scarcely smell, be safe to the human body, and have a high
drying characteristic.
The solvents Pegasol AN45 and Pegasol 3040 (Mobil Sekiyu Corp.), which are
fractions produced by hydrogenation and refining of distillated oil obtained by
distillation of crude oil at normal pressures, are mainly C8 to C11 petroleum type
hydrocarbons, and their aniline points are 43°C and 54°C respectively, and
Pegasol AN45 contains aromatic components in a higher amount than in Pegasol
3040.
Best Mode for Carrying Out the Invention
Hereinafter, the present invention is described in more detail by reference to the
Production Examples and the Examples, but the present invention is not limited to
the Production Examples and the Examples described below.
Production Example 1 (Production of the inorganic polysilazane)
A gas inlet tube, a mechanical stirrer and a Dewar condenser were fit into a four-
necked flask with an internal volume of 300 ml. The inside of the reactor was
replaced by dry deoxygenated nitrogen, and then 150 ml of dry degassed pyridine
was introduced into the four-necked flask and cooled on ice. Then, 16.1 g
dichlorosilane was added thereto over 50 minutes, to form a white solid adduct
(SiH2Cl22Py). The reaction mixture was cooled on ice under vigorous stirring and
bubbled over 1 hour with a mixture of a nitrogen gas and 10.9 g ammonia
previously purified by passage through a soda lime tube and an active carbon
tube. After the reaction was finished, the solid product was removed by
centrifugation and subsequent filtration. By removing the solvent from the filtrate
under reduced pressure (50°C, 5 mmHg, 2 hours), 5.52 g glassy solid polysilazane
was obtained. The molecular weight of the polysilazane determined by a vapor
pressure depression method was 2000. The yield was 77%.
Production Example 2 (Production of the organic polysilazane)
A gas inlet tube, a mechanical stirrer and a Dewar condenser were fit into a four-
necked flask with an internal volume of 300 ml. The inside of this reactor was
replaced by dry deoxygenated nitrogen, and then 150 ml of dry degassed pyridine
was introduced into the four-necked flask and cooled on ice. Then, 9.2 g methyl
dichlorosilane and 8.1 g dichlorosilane were added thereto to form a white solid
adduct. The reaction mixture was cooled on ice under vigorous stirring and
bubbled with a mixture of a nitrogen gas and 12.0 g ammonia previously purified
by passage through a soda lime tube and an active carbon tube. After the reaction
was finished, the solid product was removed by centrifugation and subsequent
filtration. By removing the solvent from the filtrate under reduced pressure (50°C,
5 mmHg, 2 hours), 5.2 g viscous liquid polysilazane was obtained. The molecular
weight determined by a vapor pressure depression method was 1,600. The yield
was 72%.
Example 1
0.5 part by weight of the inorganic polysilazane obtained in Production Example 1
and 0.02 part by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 1.98 parts by weight of xylene and 97.5 parts by weight of Pegasol AN45 (Mobil
Sekiyu Corp.), to give an anti-fouling coating solution for automobile bodies and
wheels.
The coating solution was coated by spraying with a spray gun onto a coated steel
plate in such an amount as to give a coating of 0.2 urn in thickness after
conversion into silica. After drying, the coating was examined in an outdoor
exposure test, and the change in contact angle was observed, to give the results in
Table 1.
As can be seen from Table 1, formation of a silica coating gradually proceeded,
and 2 weeks later, a hydrophilic coating had been almost formed, and by this
hydrophilic silica coating, the coated steel plate remained in a stably coated state
for a long time. The coated steel plate, observed after 6 months and 1 year
respectively, was not recognized to be fouled.
This coating solution was sealed in a nitrogen atmosphere, stored at ordinary
temperatures, and examined for generation of monosilane after 1 month, 3 months
and 6 months respectively, and as a result, the amount of monosilane generated
was 43 ppm after 1 month, 61 ppm after 3 months and 75 ppm after 6 months,
indicating good storage stability.
When the coating solution in Example 1 was placed in the cup of a spray gun and
left for 30 minutes at ordinary temperatures in the air, the solution maintained its
transparent state. Separately, a coating solution was prepared from the same
composition described above except that Pegasol AN45 was replaced by Pegasol
3040 (Mobil Sekiyu Corp.) having a lower aromatic content than in Pegasol AN45,
and this coating solution turned turbid after 20 minutes. From this result, it was
found that when an automobile anti-fouling coating solution having the composition
described above is applied by a spray gun, a solvent containing aromatic
components in a higher amount within a range not influencing a coating sublayer
is preferably used in the coating solution from the viewpoint of stability of the
coating solution.
Example 2
One part by weight of the inorganic polysilazane obtained in Production Example 1
and 0.04 part by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 98.96 parts by weight of Pegasol AN45 (Mobil Sekiyu Corp.), to give an anti-
fouling coating solution for dentures.
This coating solution was applied by a spray gun onto the whole of dentures to
form a silica coating of 0.3 µm in thickness thereon. The coating was converted
completely into silica by drying it at 45°C for 60 minutes in an oven and
subsequent treatment for 12 hours under the conditions of 40°C and 90% relative
humidity in a high-temperature high-humidity apparatus. A hydrophilic and dense
silica coating was formed on the surface of the dentures, and when the dentures
were used, the coating was not deteriorated, and fouling could be easily washed
away with water, and no smell was generated.
Example 3
One part by weight of the inorganic polysilazane obtained in Production Example 1
and 0.04 part by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 11.46 parts by weight of xylene and 87.5 parts by weight of Pegasol 3040 (Mobil
Sekiyu Corp.), to give an anti-fouling coating solution for tombstones.
This coating solution was applied by aerosol spraying onto polished granite. A
uniform coating of 0.4 µm in thickness was thereby formed. After 2 weeks, a
hydrophilic and dense silica coating was formed on the surface, and when left
outdoors for 1 year, the coating was not deteriorated, and no fouling was
observed.
Example 4
0.5 part by weight of the inorganic polysilazane obtained in Production Example 1
and 0.02 part by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 1.98 parts by weight of xylene, 32.5 parts by weight of Pegasol AN45 (Mobil
Sekiyu Corp.), 32.5 parts by weight of ethylcyclohexane and 32.5 parts by weight
of methylcyclohexane, to give an anti-fouling coating solution for coating of
products used with water, such as bathtubs, washstands etc. This coating solution
was applied onto the surfaces of a washstand made of ceramic ware and an
enameled bathtub. A 0.2 µm uniform coating was formed respectively. Fouling
hardly adhered, and if adhered, the fouling could be easily removed.
Example 5
One part by weight of the inorganic polysilazane obtained in Production Example 1
and 0.04 part by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 3.96 parts by weight of xylene, 31.7 parts by weight of Pegasol AN45 (Mobil
Sekiyu Corp.), 31.7 parts by weight of ethylcyclohexane and 31.7 parts by weight
of methylcyclohexane, to give an anti-fouling coating solution for the interior and
exterior of a house. This coating solution was applied by rolling onto the surface of
the outer wall of a house. The outer wall was not fouled for a long time. Fouling
such as dust could be easily removed by spraying with water.
Example 6
Two parts by weight of the inorganic polysilazane obtained in Production Example
1 and 0.08 part by weight of DMPP (catalyst) were dissolved in a solvent
consisting of 7.92 parts by weight of xylene and 90 parts by weight of Pegasol
3040 (Mobil Sekiyu Corp.), to give an anti-fouling coating solution for
polycarbonate plates. Using a cloth impregnated with this coating solution, the
coating solution was applied by hand onto a polycarbonate plate. A hydrophilic and
dense silica coating could be formed on the surface without erosion of the
substrate by the coating solution.
Example 7
5 parts by weight of the inorganic polysilazane obtained in Production Example 1
and 0.035 part by weight of Pd propionate (catalyst) were dissolved in a solvent
consisting of 25 parts by weight of xylene and 69.97 parts by weight of Solvesso
150 (Esso Sekiyu Co.), to give a coating solution. An aluminum plate was coated
by flow coating with this coating solution in an amount to give a coating of 0.3 µm
in thickness after conversion into silica. After drying, the aluminum plate was
calcinated at 120°C for 1 hour in the air to give a sample for a corrosion resistance
test. Separately, a PET film was coated by flow coating with the coating solution in
an amount to give a coating of 0.3 µm in thickness after conversion into silica.
After drying, the aluminum plate and the PET film were treated at 90°C, 90% RH
for 3 hours, to give a sample for a scratch test. The characteristics of the coating
were evaluated in the following manner, to give the results of corrosion resistance
in Table 2 and anti-scratch properties in Table 3.
Evaluation of Characteristics of the Coating
(I) Corrosion resistance
A coating was formed on an aluminum plate and then examined for the degree of
corrosion of the base material for 96 hours in a CASS test wherein the test
specimen was sprayed with a solution prepared by adding acetic acid and copper
(II) chloride to an aqueous solution of sodium chloride.
© : Significantly superior in corrosion resistance.
o : Superior in corrosion resistance.
? : Slightly inferior in corrosion resistance.
x : Inferior in corrosion resistance.
CASS test method
The test specimen is sprayed with a mixture of 4% brine and 0.027% cupric
chloride (dihydrate) in a test bath set at 50°C, and its corrosiveness and corrosion
resistance are evaluated.
The term CASS is an abbreviation of "copper-accelerated acetic acid salt spray".
(2) Anti-scratch properties
A coating was formed on a polyethylene terephthalate film (PET film) and then
tested with steel wool No. #000 under a loading of 500 g (area: 2 cm2)
reciprocated 300 times, and its haze was measured with a haze meter.
Example 8
0.2 parts by weight of the inorganic polysilazane obtained in Production Example 1
and 0.002 part by weight of Pd propionate (catalyst) were dissolved in a solvent
consisting of 1 parts by weight of xylene and 98.80 parts by weight of Solvesso
150 (Esso Sekiyu Co.), to give a coating solution. An aluminum plate was coated
by flow coating with this coating solution in an amount to give a coating of 0.03 µm
in thickness after conversion into silica. After drying, the aluminum plate was
calcinated at 120°C for 1 hour in the air to give a sample for a corrosion resistance
test. Separately, a PET film was coated by flow coating with the coating solution in
an amount to give a coating of 0.03 µm in thickness after conversion into silica.
After drying, the PET film was treated at 90°C, 90% RH for 3 hours, to give a
sample for a scratch test. The coatings were evaluated in the same manner as
Example 7, to give the results of corrosion resistance in Table 2 and anti-scratch
properties in Table 3.
Example 9
20 parts by weight of the inorganic polysilazane obtained in Production Example 1
and 0.14 part by weight of Pd propionate (catalyst) were dissolved in a solvent
consisting of 25 parts by weight of xylene and 54.86 parts by weight of Solvesso
150 (Esso Sekiyu Co.), to give a coating solution. An aluminum plate was coated
by flow coating with this coating solution in an amount to give a coating of 1.2 µm
in thickness after conversion into silica. After drying, the aluminum plate was
calcinated at 120°C for 1 hour in the air to give a sample for a corrosion resistance
test. Separately, a PET film was coated by flow coating with the coating solution in
an amount to give a coating of 1.2 µm in thickness after conversion into silica.
After drying, the PET film was treated at 90°C, 90% RH for 3 hours, to give a
sample for a scratch test. The coatings were evaluated in the same manner as
Example 7, to give the results of corrosion resistance in Table 2 and anti-scratch
properties in Table 3.
Example 10
5 parts by weight of the organic polysilazane obtained in Production Example 2
and 0.035 part by weight of Pd propionate (catalyst) were dissolved in a solvent
consisting of 94.97 parts by weight of dibutyl ether, to give a coating solution. An
aluminum plate was coated by flow coating with this coating solution in an amount
to give a coating of 0.3 µm in thickness after conversion into silica. After drying, the
aluminum plate was calcinated at 120°C for 1 hour in the air to give a sample for a
corrosion resistance test. Separately, a PET film was coated by flow coating with
the coating solution in an amount to give a coating of 0.3 µm in thickness after
conversion into silica. After drying, the PET film was treated at 90°C, 90% RH for
3 hours, to give a sample for a scratch test. The coatings were evaluated in the
same manner as Example 7, to give the results of corrosion resistance in Table 2
and anti-scratch properties in Table 3.
Example 11
20 parts by weight of the organic polysilazane obtained in Production Example 2
and 0. 14 parts by weight of Pd propionate (catalyst) were dissolved in a solvent
consisting of 79.86 parts by weight of dibutyl ether, to give a coating solution. An
aluminum plate was coated by flow coating with this coating solution in an amount
to give a coating of 1.2 µm in thickness after conversion into silica. After drying, the
aluminum plate was calcinated at 120°C for 1 hour in the air to give a sample for a
corrosion resistance test. Separately, a PET film was coated by flow coating with
the coating solution in an amount to give a coating of 1.2 µm in thickness after
conversion into silica. After drying, the PET film was treated at 90°C, 90% RH for 3
hours, to give a sample for a scratch test. The coatings were evaluated in the
same manner as Example 7, to give the results of corrosion resistance in Table 2
and anti-scratch properties in Table 3.
Example 12
5 parts by weight of the inorganic polysilazane obtained in Production Example 1
and 0. 2 parts by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 25 parts by weight of xylene and 69.8 parts by weight of Pegasol AN45 (Mobil
Sekiyu Corp.), to give a coating solution. An aluminum plate was coated by flow
coating with this coating solution in an amount to give a coating of 0.3 µm in
thickness after conversion into silica. After drying, the aluminum plate was
calcinated at 120°C for 1 hour in the air to give a sample for a corrosion resistance
test. Separately, a PET film was coated by flow coating with the coating solution in
an amount to give a coating 0.3 µm in thickness after conversion into silica.
After drying, the PET film was treated at 90°C, 90% RH for 3 hours, to give a
sample for a scratch test. The coatings were evaluated in the same manner as
Example 7, to give the results of corrosion resistance in Table 2 and anti-scratch
properties in Table 3.
Example 13
15 parts by weight of the inorganic polysilazane obtained in Production Example 1
and 0.6 parts by weight of DMPP (catalyst) were dissolved in a solvent consisting
of 25 parts by weight of xylene and 59.4 parts by weight of Pegasol AN45 (Mobil
Sekiyu Corp.), to give a coating solution. An aluminum plate was coated by flow
coating with this coating solution in an amount to give a coating of 1.0 µm in
thickness after conversion into silica. After drying, the aluminum plate was
calcinated at 120°C for 1 hour in the air to give a sample for a corrosion resistance
test. Separately, a PET film was coated by flow coating with the coating solution in
an amount to give a coating of 1.0 µm in thickness after conversion into silica.
After drying, the PET film was treated at 90°C, 90% RH for 3 hours, to give a
sample for a scratch test. The characteristics of the coatings were evaluated in the
same manner as Example 7, to give the results of corrosion resistance in Table 2
and anti-scratch properties in Table 3.
Effect of the Invention
As described above, the coating solution of the present invention is in a liquid form
at the time of application, and thus the coating solution can be easily applied by
spray coating, a method of wiping with a cloth or sponge or the like onto the base
material. After application, the polysilazane in a liquid form can be converted into
a rigid and dense coating, thus easily forming a coating film excellent in anti-
corrosion and anti-scratch properties. In addition, the hydrophilicity of the coating
film thus formed is durable and its effective hydrophilicity can be maintained
usually for 1 to 2 years. Besides the hydrophilicity, the coating can give such
characteristics as abrasion resistance, anti-fouling properties, wetting properties to
the water, anti-scratch properties, anti-corrosion properties, sealing effect,
chemical resistance, anti-oxidation properties, physical barrier effect, heat
resistance, fire resistance and antistatic properties to the products or the articles.
Further, the coating solution can be applied in very wide uses by merely regulating
the type of solvent, the amounts of compounding materials- etc.
We Claim:
1. A coating solution comprising a polysilazane characterized in that a Si-
H bond, a diluting solvent, and a catalyst wherein diluting solvent is
selected from petroleum solvent, an aromatic or alicyclic solvent, a
halogenated hydrocarbon paraffin type solvent mineral spirit, terpene
mixtures an ether such as dibutyl ether, dimethyl ether, diethyl ether,
polyglycol ether or tetrahydrofurane or a mixture thereof.
2. The coating solution as claimed in claim 1, wherein the diluting solvent
further comprises one or more of solvents selected from xylene,
methylcyclohexane and ethylcyclohexane.
3. The coating solution as claimed in any one of claims 1 or 2, wherein
the concentration of the polysilazane having a Si-H bond is 0.1 to 35%
by weight.
4. The coating solution as claimed in any one of claims 1 to 2, wherein
the concentration of the polysilazane having a Si-H bond is 0.5 to 10%
by weight.
5. The coating solution as claimed in any one of claims 1 to 4, wherein
the catalyst is contained in an amount of 0.01 to 30% by weight based
on a pure polysilazane content having a Si-H bond.
6. The coating solution as claimed in any one of claims 1 to 5, wherein
the catalyst is an N-heterocyclic compound as herein described, an
organic or inorganic acid such as herein described, a metal
carboxylate, an acetylacetona complex, fine metal particles, an
peroxide, a metal chloride or an organometallic compound.
7. The coating solution as claimed in any one of claims 1 to 6, wherein
the polysilazane having a Si-H bond is an inorganic polysilazane
synthesized by reacting SiH2CI2 with a base to form an adduct of
SiH2Cl2 and then reacting the adduct of SiH2CI2 with ammonia.
8. The coating solution as claimed in any one of claims 1 to 6, wherein
the polysilazane having a Si-H bond is a polysilazane synthesized by
reacting SiH2Cl2 and CH3SiHCl2 with a base to form adducts of SiH2CI2
and CH3SiHCI2 and then reacting the adducts of SiH2CI2 and CH3SiHCI2
with ammonia.
A coating solution comprising a polysilazane characterized in that a Si-H bond, a
diluting solvent, and a catalyst wherein diluting solvent is selected from
petroleum solvent, an aromatic or alicyclic solvent, a halogenated hydrocarbon
paraffin type solvent mineral spirit, terpene mixtures an ether such as dibutyl
ether, dimethyl ether, diethyl ether, polyglycol ether or tetrahydrofurane or a
mixture thereof.

Documents:

00767-kolnp-2005-abstract.pdf

00767-kolnp-2005-claims.pdf

00767-kolnp-2005-description complete.pdf

00767-kolnp-2005-drawings.pdf

00767-kolnp-2005-form 1.pdf

00767-kolnp-2005-form 2.pdf

00767-kolnp-2005-form 3.pdf

00767-kolnp-2005-form 5.pdf

767-kolnp-2005-granted-abstract.pdf

767-kolnp-2005-granted-claims.pdf

767-kolnp-2005-granted-correspondence.pdf

767-kolnp-2005-granted-description (complete).pdf

767-kolnp-2005-granted-drawings.pdf

767-kolnp-2005-granted-examination report.pdf

767-kolnp-2005-granted-form 1.pdf

767-kolnp-2005-granted-form 18.pdf

767-kolnp-2005-granted-form 2.pdf

767-kolnp-2005-granted-form 26.pdf

767-kolnp-2005-granted-form 3.pdf

767-kolnp-2005-granted-form 5.pdf

767-kolnp-2005-granted-letter patent.pdf

767-kolnp-2005-granted-reply to examination report.pdf

767-kolnp-2005-granted-specification.pdf

767-kolnp-2005-granted-translated copy of priority document.pdf

abstract-00767-kolnp-2005.jpg


Patent Number 216045
Indian Patent Application Number 00767/KOLNP/2005
PG Journal Number 10/2008
Publication Date 07-Mar-2008
Grant Date 06-Mar-2008
Date of Filing 02-May-2005
Name of Patentee CLARIANT INTERNATIONAL LTD.
Applicant Address ROTHAUSSTRASSE 61, CH-4132 MUTTENZ
Inventors:
# Inventor's Name Inventor's Address
1 SUZUKI, TADASHI B-206 2824-1 NARA-CHO, AOBA, YOKOHAMA CITY, KANAGAWA PREFECTURE 227-0036
2 FUNAYAMA, OSAMU 2-12-3 HACHIMANYAMA SETAGAYA-KU, TOKYO 156-0056
3 DIERDORF, ANDREAS USINGER STR. 16F, 65719 HOFHEIM
4 LIEBE, HUBERT ODENWALDBLICK 52, 65207 WIESBADEN
PCT International Classification Number C 09 D 183/16
PCT International Application Number PCT/EP03/011614
PCT International Filing date 2003-10-21
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 03007726.7 2003-04-04 Japan
2 2002-320482 2002-11-01 Japan