ACRYLIC MELAMINE COATING COMPOSITIONS FIELD OF INVENTION The present invention relates to acrylic melamine coating compositions. More particularly, the present invention relates to the incorporation of polytrimethylene carbonate diols and triols into acrylic melamine coatings to obtain high gloss acrylic coatings with improved impact resistance, with no significant loss of other properties.

BACKGROUND OF THE INVENTION Thermoset or cured coating compositions are widely used in coatings operations on a variety of substrates, including plastic, metal, wood, primed metals, or previously coated or painted metals.

One type of thermosetting coating is an acrylic coating composition. In automotive applications, in particular, acrylic coatings provide durable finishes.

Acrylic coating compositions are well known and have been widely used to finish automobiles and trucks.

Automotive coatings include primers and topcoats, which may be single layer topcoats or two layer basecoat/clearcoat topcoat systems. The primer may be applied either as a first coating layer or over another layer, for example, over an electrocoat primer layer. The topcoats are then usually applied as a protective coat over the primer layer.

In order to make the coating more chip resistant, one recognized solution is to cover all or parts of the

finished surface of the automobile with a protective coating. However, the acrylic enamel, acrylic lacquer, or nitrocellulose lacquer typically used on vehicles produce coatings which are difficult to overcoat with protective materials due to problems with adhesion, yellowing, etc.

A useful protective coating composition should first and foremost be chip-and abrasion-resistant, have good adhesion to the painted surface, be clear, smooth (i. e., without surface roughness) and indistinguishable over the painted surface when applied to the areas being protected.

There are a number of considerations regarding the use of thermosetting coating compositions. One consideration involves the curing conditions needed to achieve sufficient crosslinking of the film, with higher curing temperatures and longer times at the curing temperature generally increasing the manufacturing costs of the coated article. Another concern in some cases is the generation of undesirable by-products of the curing reaction. For example, blocked curing agents may release the blocking agents as volatile organic compounds that are emissions regulated by various government regulations. It is also important that the crosslinks that are formed by curing thermosetting compositions are suitable for providing long life to the coating under the particular conditions to which the coated article will be exposed.

Several different crosslinking mechanisms may be employed in thermosetting coatings. Polyisocyanate

crosslinkers may be reacted with amine or hydroxyl groups on the resin. This curing method provides desirable urea or urethane crosslinked bonds, but may also entail certain drawbacks. In order to prevent premature gelation of the coating composition, the polyisocyanate must either be kept separate from the resin in what is known in the art as a two-package or two-pack coating system, or else the highly reactive isocyanate groups on the curing agent must be blocked (e. g., with an oxime or alcohol). Blocked polyisocyanates, however, require higher temperatures (e. g., 150°C, or more) to unblock and begin the curing reaction. The volatile blocking agents released during curing can possibly adversely affect coating properties, as well as increase the volatile organic content for the composition.

Another curing mechanism utilizes a melamine formaldehyde resin curing agent in the coating composition to react with hydroxyl groups on the resin.

Where suitable, this curing method provides good cure at relatively low temperatures, for example 121°C (250°F) with a blocked acid catalyst, or even lower with an unblocked acid catalyst. However, higher curing temperatures can also be effective.

There are some advantages in curing with melamine where suitable. Melamine can exhibit moisture resistance, cure at lower temperatures, and can be extremely hard, and yet colorless. The moisture resistance feature of melamine-based adhesives, combined with its durability, may provide advantages for exterior applications. Curing temperatures as low as 60°C (140°F)

have been used for melamine adhesives, with a normal range of from 115. 6-126. 7°C (240-260°F) for 2 to 5 minutes, depending upon the thickness of the composite assembly. Crosslinked melamine-based coatings are colorless, chemically resistant and resilient. They provide a tough and durable finish to items that will be repeatedly exposed to harsh environments.

Few applications experience such demanding and harsh environments over time as automotive paints. In this application, melamine can deliver chemical resistance and durability. Melamine resins also provide the long-term buffability that vehicle-owners desire. Melamine-based coatings also permit coils of metal sheeting to be prepainted, then stamped into the final product, as in the case of appliance and automotive parts and panels.

Another important benefit of high solids melamine- based coatings is that they are low in volatile organic emissions during application and curing.

The use of various modifiers to attempt to improve impact properties of acrylic coatings has been addressed in the art. Polytrimethylene ether glycol (PTMEG) has been suggested as a modifier. However, this is at the expense of optimum W resistance. The addition of glycol adipates to improve impact resistance has been suggested, but results in the reduction of hydrolytic stability.

Impact modifiers previously proposed in the art typically result in the loss of other properties.

The preparation of trimethylene carbonate is known.

US-A-5 212 321 discloses a process for preparing trimethylene carbonate, wherein 1, 3-propanediol is

reacted with diethylcarbonate in the presence of zinc powder, zinc oxide, tin powder, tin halide or organo-tin compound, at an elevated temperature. It is also known in the art to use polytrimethylene carbonate in polyester applications. For example, US-A-5 225 129 and US-A-5 849 859.

The preparation of polycarbonate polyols is known in the art. US-A-4 533 729 discloses a process for preparing amorphous polycarbonate polyols by reacting phosgene, a branched-chain polyhydric alcohol, and a straight chain polyhydric alcohol in the presence of a solvent and in the absence of a catalyst at a temperature of from about 60 to 100°C. The reaction mixture is then contacted with a catalytic amount of a tertiary amine at reflux temperature for a period of time of at least about 30 minutes. It is suggested that the resulting polycarbonate polyol can be used in coating compositions.

In JP 64001724 there is disclosed the preparation of a polycarbonate polyol from (di) allyl-, alkyl-or alkylene carbonate and a polyhydroxy compound using a titanium catalyst.

Polycarbonates have been used in acrylic and polyester coatings. US-A-5 525 670 describes a coating composition based on either acrylic or polyester resins modified with polycarbonates which are cured by either urethane or melamine formaldehyde chemistries. The polycarbonate described preferably has a number average molecular weight above 2000. The polycarbonate of this reference is made from a mixture of straight chain diols, branched chain diols, and polyhydric alcohols and an

aliphatic carbonate, where both the branched chain diols and the polyhydric alcohols are present in at least 10 mol%. It is stated in this reference that if less than 10 mol% is present, the material crystallizes (branched chain diol), and inferior curing characteristics (polyhydric alcohols) and inferior water resistance (polyhydric alcohols) are exhibited. See also US-A-5 527 879.

EP-A2-0 712 873 describes an acrylic copolymer which is an acrylic monomer having a hydroxy alkyl carbonate group and an acid group-containing monomer. The composition is said to be crosslinked with melamine to prepare a thermosetting water borne coating composition.

There does not appear to be any reference in the art that discloses or suggests the use of polytrimethylene carbonate diols and triols and higher functionality polyols in relatively small amounts to provide improved impact resistance in acrylic melamine coatings.

There is a need in the art for coating compositions with improved impact resistance. Attempts have been made to produce tougher, more chip-resistant coatings, particularly for automobiles, but these have not been completely satisfactory. In view of the some of the desirable properties of melamine as a crosslinking agent, it would be particularly desirable if it were possible to obtain acrylic melamine coatings with improved impact resistance, with minimal effect on other properties.

SUMMARY OF THE INVENTION In a first embodiment, the present invention comprises :

An acrylic melamine coating composition characterized by improved impact resistance which comprises : a) a polyol having an equivalent weight of from 300-1300 ; b) said polyol having incorporated therein from 2 to 50% by weight of a polytrimethylene carbonate polyol ; c) a melamine crosslinking agent ; d) optionally a catalyst ; and e) optionally pigments and other additives commonly used in coatings.

In a second embodiment, the present invention further provides a melamine/urea formaldehyde polytrimethylene carbonate coating composition which comprises : a) 5 to 80% by weight polytrimethylene carbonate, optionally blended with. 0 to 30 % glycol ; b) 5 to 70% by weight melamine crosslinking agent ; c) 0 to 70% solvent ; and d) optionally a catalyst.

The compositions can be applied over a variety of substrates.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described by way of example with reference to the accompanying drawings, in which :- Figure 1 is a graph of the tan delta versus temperature curves of PTMC diol coatings.

Figure 2 is a graph of the tan delta versus temperature curves of PTMC triol coatings.

Figure 3 is a graph of the storage modulus versus temperature curves of PTMC diol coatings.

Figure 4 is a graph of the storage modulus versus temperature curves of PTMC triol coatings.

Figure 5 is a graph of the tan delta versus temperature curves of PTMC diol modified melamine coatings.

Figure 6 is a graph of the tan delta versus temperature curves of PTMC triol modified melamine coatings.

Figure 7 is a graph of the storage modulus versus temperature curves of PTMC diol modified melamine coatings.

Figure 8 is a graph of storage modulus versus temperature curves of PTMC triols modified melamine coatings.

Figure 9 is a bar graph of 20° and 60° gloss of PTMC diol modified melamine coatings.

Figure 10 is a bar graph of 20° and 60° gloss of PTMC triol melamine coatings.

Figure 11 is a graph of the effect of curing conditions on Tg of 20% PC597 modified melamine coatings.

Figure 12 is a graph of the effect of curing conditions on modulus of 20% PC597 modified melamine coatings.

DETAILED DESCRIPTION OF THE INVENTION In the present invention it has been found that modified acrylic melamine coatings with improved impact resistance can be achieved through incorporation of polytrimethylene carbonate polyols (hereafter referred to as PTMC polyols) selected from polytrimethylene carbonate diols and triols, and higher functionality polytrimethylene carbonate polyols. Furthermore, these improvements were observed while maintaining high gloss,

weather resistance, and overall durability. It has surprisingly been found that to have both high impact resistance and high gloss, polytrimethylene carbonate diols and triols, and higher functionality polytrimethylene carbonate polyols within a specific molecular weight range provide the best results.

In a related embodiment of the present invention it has also been found that a new baked coating composition can be prepared without acrylic from poly (trimethylenecarbonate), optionally substituted with a glycol, and a melamine/urea formaldehye which provides a number of formulating options for coatings manufacturers. Various formulations have been demonstrated to have desirable levels of adhesion, mar resistance, and low haze.

Typically when PTMC polyols are incorporated into acrylic polyols as potential coatings modifiers, problems can be observed with phase separation, hazy coating appearance, and reduced gloss. In the present invention it has been discovered that the compatibility of PTMC with acrylic copolymers can be greatly improved by lowering the carbonate molecular weight and increasing PTMC polyol functionality. In addition, it has surprisingly been found that the use of lower percentages of polytrimethylene carbonate diols and triols provides the desired improvements in key properties of the cured compositions.

In another embodiment, the present invention provides an acrylic melamine coating composition characterized by high impact resistance and high gloss which comprises :

a) an acrylic polyol having an equivalent weight in the range of 300 to 1300 dissolved in a suitable solvent to 40-90% solids ; b) said acrylic polyol having incorporated therein from 5 to 20 % by weight of a polytrimethylene carbonate polyol selected from a polytrimethylene carbonate diol and polytrimethylene carbonate triol, and higher functionality polytrimethylenecarbonate polyols ; c) a methyl substituted melamine ; d) optionally a catalyst ; and e) optionally pigments and other additives commonly used in coatings.

PTMC polyols used in the present invention generally have molecular weights in the range of from 360 to 2700, with preferred molecular weights in the range of 360 to 2000. Overall performance, particularly with respect to coating gloss and appearance, was found to be a function of molecular weight, with particularly preferred PTMC polyols being those having molecular weights in the range of 360 to 1500. It has been found that coating performance improved with increasing PTMC polyol molecular weight until incompatibility adversely impacted the gloss and overall appearance. The Examples herein demonstrate that PTMC polyols having molecular weights in the range of from 360 to 1000 are very compatible as modifiers and result in no loss of gloss.

2 to 50 wt%, preferably 5 to 20 wt% poly (trimethylenecarbonate) polyol, comprising preferably PTMC diols with equivalent weights ranging from 300 to 1350

and triols with equivalent weights ranging from 120 to 575 may be conveniently incorporated into an acrylic polyol and crosslinked by a melamine crosslinking agent.

Higher molecular weight PTMC polyols tend to result in incompatible coatings with hazy appearance and reduced gloss compared to the control. In comparison with higher molecular weight PTMC polyols, PTMC diols and triols with lower molecular weights are more compatible with the acrylic polyol, provide cured coatings with the desired properties, and have less tendency to crystallize.

For example, at 20 wt% PTMC diol, improved impact resistance with high gloss may be obtained when the equivalent weight is equal to or less than 328, when applied to polished iron phosphated steel panels.

For PTMC triols, improved impact with high gloss may be obtained for equivalent weights up to 308.

The PTMC polyol modifiers of the present invention exhibit additional improvements compared with the control or at least maintained desirable properties. The PTMC polyol modifiers of the present invention provide improved flexibility for the melamine coatings. The PTMC modifiers may also provide a significant improvement in coating adhesion. Under W testing improved non- yellowing properties may be observed. Incorporation of the carbonate polyols have no appreciable effect on pencil hardness, chemical and stain resistance, or MEK double rub resistance. All fully cured coatings may exhibit good humidity resistance.

In a preferred embodiment, the acrylic melamine coating composition of the present invention requires a

polyol, a PTMC diol, triol, or higher functionality PTMC polyol, a solvent, optionally a co-solvent, a melamine crosslinking agent, and optionally an acidic catalyst.

A variety of polyols may be used, including, but not limited to, polyether polyols, polyurethane polyols, acrylic polyols, and polyester polyols.

The acrylic polyols are copolymers of one or more alkyl esters of acrylic acid or methacrylic acid optionally together with one or more other polymerizable ethylenically unsaturated monomers. These polymers are generally of the thermosetting crosslinking type.

Suitable alkyl esters of acrylic acid or methacrylic acid include methyl methacrylate, ethyl methacrylate, butyl methacrylate, ethyl acrylate, butyl acrylate, and 2-ethyl hexyl acrylate. Suitable other copolymerizable ethylenically unsaturated monomers include vinyl aromatic compounds such as styrene and vinyl toluene ; nitriles such acrylonitrile and methacrylonitrile ; vinyl and vinylidene halides such as vinyl chloride and vinylidene fluoride and vinyl esters such as vinyl acetate.

Acrylic polyols can be prepared via aqueous emulsion polymerization techniques or can be prepared via organic solution polymerization techniques. Generally, any method of producing such polymers that is known to those skilled in the art utilizing amounts of monomers recognised in the art can be used.

Suitable functional monomers may be used in addition to the other acrylic monomers mentioned above for crosslinking purposes and include, for example, acrylic acid, methacrylic acid, hydroxyalkyl acrylates, and

hydroxyalkyl methacrylates. Preferably, the hydroxyalkyl group of the latter two types of compounds contains from about 2 to 4 carbon atoms. Examples thereof are hydroxyethyl acrylate, hydroxyethyl methacrylate, hydroxypropyl acrylate, hydroxypropyl methacrylate, 4- hydroxybutyl acrylate and 4-hydroxybutyl methacrylate and the like. Also, the acrylic polyol can be prepared with N- (alkoxymethyl) acrylamides and N- (alkoxymethyl) methacrylamides.

The polymeric film-forming resin for the composition can also be selected from suitable polyesters. Such polymers may be prepared in a known manner by condensation of polyhydric alcohols and polycarboxylic acids. Suitable polyhydric alcohols include ethylene glycol, propylene glycol, butylene glycol, 1, 6-hexylene glycol, neopentyl glycol, diethylene glycol, glycerol, trimethylolpropane, pentaerythritol, 1, 3-propanediol, and 2-methyl-1, 3-propanediol.

Suitable dicarboxylic acids are known to those skilled in the art and include terephthalic acid, isophthalic acid, succinic acid, adipic acid, azelaic acid, sebacic acid, maleic acid, fumaric acid, phthalic acid, tetrahydrophthalic acid, hexahydrophthalic acid, dodecanedioic acid, and trimellitic acid. In addition to the polycarboxylic acids mentioned above, functional equivalents of the acids, such as anhydrides, where they exist, or lower alkyl esters of the acids, such as the methyl esters, may be used.

Acrylic polyols are preferred for good results.

Suitable acrylic polyols have hydroxyl value in the range

of from 43 to 187. Preferably, the acrylic polyol has an equivalent weight in the range of from 400 to 700 and a hydroxyl value in the range of from 80 to 140.

Suitable acrylic polyols are, for example, SCX 902, SCX 912, and Joncryl 587, commercially available from S.

C. Johnson Polymer. The acrylic polyol used in the examples to demonstrate the benefits of the PTMC diols and triols was Joncryl 587 polyol.

The melamine resin used for the curing agent of the present invention may be the resin obtained by addition- condensation of an amine compound such as melamine, guanamine, and urea with formaldehyde by methods known in the art, or the resin obtained by further addition- condensation of such resin with alcohol. For instance, it may be methylated melamine, butylated melamine, methylated benzoguanamine, butylated benzoguanamine, etc.

Particularly suitable crosslinking agents are fully or partially methylolated melamine resins, such as hexamethylol melamine, pentamethylol melamine, tetramethylol melamine, etc and mixtures thereof. These are made by reacting 6 or less moles of formaldehyde with each mole of melamine. The reaction causes the addition of hydroxymethyl groups to the amine groups of the melamine resin. The fully or partially methylolated melamine may also be fully or partially alkylated by reacting with an alcohol, such as methanol. In acid environments (pH preferably less than 5) at elevated temperatures (preferably about 121°C (about 250°F)), these melamine-formaldehydes react with the hydroxy

groups of the resin to form complex crosslinked polymer structures.

In a preferred embodiment, the crosslinking agent is a partially alkoxylated melamine resin.

Suitable melamine resins include those hydrophilic melamines and/or hydrophobic melamines, such as, for example, CYMEL 303, CYMEL 325, CYMEL 1156, manufactured by Cytec ; YUBAN 20N, YUBAN 20SB, YUBAN 128, manufactured by Mitsui Toatsu Chemicals, Inc. ; SUMIMAL M-50W, SUMIMAL M-40N, SUMIMA L M-30W, manufactured by Sumitomo Chemical Co. Ltd, used alone or in combination.

In the examples herein, good results were achieved using CYMEL 303, a hexamethoxymethylmelamine resin, commercially available from Cytec. Melamine resins of this type may be produced as set forth in U. S. Pat. Nos.

-A-2 906 724 ; 2 918 452 ; 2 998. 410 ; 2 998 411 ; 3 107 227 ; 3 422 076.

The glycol that may be optionally blended with polytrimethylene carbonate in the melamine/urea formaldehyde/polytrimethylene carbonate coating composition of the present invention may be conveniently selected from aliphatic, alicyclic, and aralkyl glycols.

For example, said glycol may be selected from ethylene glycol ; propylene glycol ; 1, 3-propanediol ; 2, 4- dimethyl-2-ethylhexane-1, 3-diol ; 2, 2-dimethyl-1, 3- propanediol ; 2-ethyl-2-butyl-1, 3-propanediol ; 2-ethyl-2- isobutyl-1, 3-propanediol ; 1, 3-butanediol ; 1, 4-butanediol ; 1, 5-pentanediol ; 1, 6-hexanediol ; 2, 2, 4-trimethyl-1, 6- hexanediol ; thiodiethanol ; 1, 2-cyclohexanedimethanol ; 1, 3-cyclohexanedimethanol ; 1, 4-cyclohexanedimethanol ;

2, 2, 4, 4-tetramethyl-1, 3-cyclobutanediol ; and p-xylylenediol, and combinations thereof. Preferably said glycol is 1, 3-propanediol.

In a preferred embodiment, said glycol may be conveniently 1, 3-propanediol blended in an amount of 5- 25%.

Suitable solvents for use in the invention include a number of conventional solvents. However, PTMC diols are typically not soluble in aliphatic or aromatic hydrocarbon solvents, such as, for example, hexane, toluene, xylene, etc.

Examples of solvents-which are generally suitable include, but are not limited to, esters such as butyl acetate, n-propyl acetate, and ethylene glycol diacetate ; ketones such as methyl ethyl ketone, methyl n-propyl ketone, and methyl amyl ketone ; ethers such as propylene glycol methyl ether acetate and ethylene glycol methyl ether acetate ; and alcohols, such as butanol and diacetone alcohol. The preferred solvents were glycol ethers and/or esters, particularly propylene glycol methyl ether acetate (PGMA), which is also a good solvent for acrylic polyols.

It is also desirable to incorporate a co-solvent to improve the solubility and evaporation rate for coatings applications.

Suitable co-solvents include, but are not limited to, methyl ethyl ketone, methyl n-propyl ketone, acetone, ethyl acetate, methyl isobutyl ketone, and tertiary butyl acetate. The preferred co-solvent is methyl ethyl ketone (MEK). Approximately 0 to 40% of the primary solvent

used in the formulations may be conveniently substituted with co-solvent, preferably from 10 to 30%.

In order to formulate the modified coatings, the polyol may be conveniently dissolved in a suitable solvent to 40-90%, preferably 40-70%, more preferably 50- 60% solids.

The coatings can be cured without the use of catalyst. However, a catalyst can optionally be used to promote the crosslinking reaction of the melamine crosslinking agent with the acrylic polyols. Suitable catalysts include acid catalysts, such as, for example, p-toluenesulfonic acid,-xylenesulfonic acid, dodecyl benzene sulfonic acid, didodecyl naphthalene sulfonic acid, didodecyl naphthalene sulfonic acid, dinonyl naphthalene sulfonic acid, dinony naphthalene disulfonic acid, their amine blocks, phosphoric acid, etc.

The catalyst used herein to demonstrate the invention is dinonyl naphthalene disulphonic acid, sold under the name of Nacure 155, and commercially available from King Industries, Inc.

Where an acid catalyst is employed, an effective amount is generally in the range of from 0. 1 to 3. 0%, based on the total weight of the resin. The preferred amount of catalyst is in the range of from 0. 5 to 2. 0%, most preferably about 1. 0%.

The composition can be applied over a wide variety of substrates such as plastic, metal, wood, primed metals, or previous coated or painted metals. If used on an existing finish, the composition is usually applied over an acrylic primer surfacer. The composition can be

applied directly to an acrylic lacquer or enamel finish that has been sanded and cleaned with an aliphatic hydrocarbon solvent. The composition can be applied as an original finish over an epoxy primer or other conventional primers or can be applied directly to bare metal. It is preferred to have the metal surface treated with a phosphate.

The coating composition may contain, in addition to the above components, in the range of from 0. 5 to 5% by weight, based on the weight of the binder, of ultraviolet light stabilizers, preferably a derivative of benzophenone, such as, for example, benzotriazole.

Other useful ultraviolet light stabilizers are benzophenones such as hydroxydodecycl benzophenone ; 2, 4- dihydroxybenzophenone ; hydroxybenzophenones containing sulfonic acid groups ; 2, 4-dihydroxy-3', 5'-di-t- butylbenzophenone ; 2, 2', 4'-trihydroxybenzophenone esters of dicarboxylic acids ; 2-hydroxy-4- acryloxyethoxybenzophenone ; aliphatic monoesters of 2, 2', 4-trihydroxy-4'-alkoxybenzophenone ; 2-hydroxy-4- methoxy-2'-carboxybenzophenone ; triazoles such as 2- phenyl-4- (2'-4'-dihydroxybenzoyl) triazoles ; substituted benzotriazoles such as hydroxyphenyltriazoles such as 2- (2'-hydroxy-5'-methylphenyl) benzotriazole ; 2- (2'- hydroxyphenyl) benzotriazole ; 2- (2'-hydroxy-5'- octylphenyl) naphthotriazole ; triazines such as 3, 5- dialkyl-4-hydroxyphenyl derivatives of triazine ; sulfur- containing derivatives of dialkyl-4- hydroxyphenyltriazines ; hydroxypheny-1, 3, 5-triazines and such triazines containing sulfonic acid groups ; aryl-

1, 3, 5-triazines ; orthohydroxyaryl-s-triazine ; and benzoates such as dibenzoate of diphenylolpropane ; t- butyl benzoate of diphenylolpropane ; nonyl phenyl benzoate, octyl phenyl benzoate ; and resorcinol dibenzoate.

The coating may also optionally contain color pigments or metallic pigments known to those skilled in the art. Suitable metallic pigments include, for example, aluminum flake, copper bronze flake, and metal oxide coated mica. The coating may also include nonmetallic colored pigments conventionally used in surface coating compositions, including inorganic pigments such as titanium dioxide, iron oxide, chromium oxide, lead chromate, carbon black, and the like, and organic pigments such as phthalocyanine blue and phthalocyanine green.

In general, pigment is incorporated in amounts in the range of from 1 to 80% by weight, based on weight of coating solids. Metallic pigmentation is employed in amounts in the range of from 0. 5 to 35% by weight of the aforesaid aggregate weight. If desired, the coating composition may additionally contain other materials well known in the art of formulating surface coatings such as surfactants, flow control agents, thixotropic agents, fillers, anti-gassing agents, and other similar auxiliary additives.

The present invention will now be illustrated by the following Examples, which should not be regarded as limiting the scope of the present invention in any way.

Examples In order to formulate the modified coatings, the acrylic polyol was dissolved in a suitable solvent to about 40-70%, preferably 50-60% solids. The PTMC diols and triols were typically dissolved in PGMA and a co- solvent to improve solubility and evaporation rate for the coating composition, to about 40-70%, preferably 50- 60% solids. The PTMC diols and triols were incorporated into the formulation at 5, 20, and 50% levels, based on the weight of total polyols. The resulting polyol solutions were then blended in a high-speed mixer. A weight ratio of polyols-to melamine of about 65-90/10-35, preferably 70-80/20-30, and more preferably about 75/25, was used to provide crosslinked coatings. An acid catalyst was used to provide acceptable cure rates for the coatings.

Where the film was cured, the desired results were obtained using temperatures in the range of from 120°C to 240°C, more often from 140°C to 200°C, with curing temperatures at or above 150°C providing better results.

For example, all PTMC polyol modified melamine coatings baked at 150°C for 30 minutes exhibited excellent humidity resistance.

Dynamic Mechanical Analysis (DMA) of the Modified Acrylic Coatings Dynamic mechanical analysis confirmed that the glass transition temperature (Tg) of the PTMC polyol modified acrylic melamine coatings decreased with increasing PTMC molecular weights, likely a function of crosslink density. PTMC triols provided a wider range of Tg values

than the diols over the molecular weight range investigated. Tgs for the triol coatings decreased from 76 to 25°C with increasing the triol molecular weights, while the Tg range for the diol coatings varied from 25 to 9°C The damping-temperature curves of pure PTMC diol and triol cured films with melamine formaldehyde are given in Figures 1 and 2, while their moduli variation with temperature are given in Figures 3 and 4, respectively.

Two separate peaks were clearly visible for both of the diols and triols with higher molecular weight modified coatings when Tan delta was plotted vs. temperature for 20% PTMC diol and triol modified melamine coatings (Figures 5 and 6). DMA properties of polymers are primarily sensitive to the microstructure of the materials. For a two component system only one relaxation is shown in the damping-temperature curve when the two polymers are compatible. A two-phase system shows two peaks. Hence, DMA studies indicate that the higher molecular weight PTMC polyols were incompatible with the acrylic copolymer.

The two peaks in the damping-temperature curves correspond to the Tg of the crosslinked acrylic polyol exhibiting the main relaxation at higher temperature, and the crosslinked PTMC modifiers providing the relaxation at low temperature. The data also indicated that incorporation of PTMC polyols resulted in reduced Tgs for the modified coatings, i. e., the main relaxation at the high temperature (Figures 5 and 6). Therefore, DMA studies confirm that higher molecular weight PTMC diols

and triols are essentially immiscible with the acrylic polyol, thereby giving rise to a hazy appearance and reduced gloss.

The storage modulus was also affected with incorporation of the PTMC polyol modifiers. The storage modulus-temperature curves of 20% carbonate diols and triols modified coatings resulted in slightly reduced modulus at room temperature compared with the control (Figures 7 and 8).

Appearance and Gloss The immiscibility effect of the acrylic polyol and PTMC polyol modifiers on coating appearance was generally obvious over polished iron phosphated steel panels. For instance, the low molecular weight PTMC polyols modified coatings and the control were clearly transparent, while the higher molecular PTMC polyol modified coating exhibited visual haze. This hazy appearance had a detrimental effect on the coatings gloss. However, no loss of 20° or 60° gloss was observed in coatings modified with low molecular weight PTMC polyols such as PC328 diol and PT217, PT121, and PT308 triols (Figures 9 and 10). Gloss generally decreased with increasing PTMC molecular weights. Therefore, the incompatibility of the PTMC modifier with acrylic polyol resulting in the loss in gloss is attributed to phase separation consistent with DMA data.

Humidity Resistance Test Dynamic mechanical analysis (DMA) showed that the Tg and storage modulus increased when the curing temperatures and/or the curing time increased (Figure 11 and 12).

Modification of Pigmented Coatings The effect of PTMC polyols on the performance of the pigmented acrylic melamine coatings can be summarized by the following observations : 1. PTMC polyol modifiers improved the flexibility of pigmented melamine coatings.

2. PTMC polyol modifiers had no effect on the ultimate hardness, acid, caustic, mustard, and gasoline resistance.

3. Pigmented PTMC polyol modified coatings had good gloss retention compared to, the control and to modified clear top coatings.

4. The PTMC polyol modified melamine coatings exhibited equivalent resistance to UV radiations as indicated by gloss and color change compared to the control.

Polytrimethylene Carbonate Melamine/Urea Formaldehyde Baked Coatings In the related embodiment of the invention in which new melamine/urea formaldehyde polytrimethylene carbonate coating composition is prepared, a polycarbonate, optionally substituted with a glycol, is reacted in the presence of a solvent, and optionally a co-solvent, with one or more of several melamine/urea formaldehyde precursors.

The polycarbonate is preferably polytrimethylene carbonate, which can be used alone, or substituted with a glycol. The glycol can be blended in an amount of 0-30%, preferably 5-25%, more preferably 5-20%.

The examples demonstrate the effectiveness of 1, 3- propanediol.

Suitable solvents and co-solvents include those listed for use with the modified acrylic coatings. Good results were obtained using methyl isobutyl ketone.

Suitable catalysts may be selected from the acidic catalysts listed for use with the modified acrylic coatings. Example 11 demonstrates the usefulness of p- toluene sulphonic acid.

The baked coatings are prepared by adding polytrimethylene carbonate, optionally substituted with a glycol, melamine/urea formaldehyde, and solvent, and optionally co-solvent, into a kettle and heating at a temperature of 80 to 130°C, preferably 100 to 110°C, for about 1 to 10 hours, preferably about 3 to 5 hours under nitrogen gas. The solution obtained at the end of the reaction, as noted in Examples 11 and 12, is clear. These compositions illustrate a few of the formulating options for coatings manufacturers.

Example 1 (Preparation of PTMC triols) The preferred results were obtained using PTMC diols and triols. Polytrimethylene carbonate triols were prepared by reacting trimethylene carbonate with trimethylol propane. The trimethylene carbonate and trimethylol propane were weighed and measured into a

three-necked flask equipped with a stirring bar. The mixture was then heated slowly to 120°C and held at that temperature for about three hours.

The contents were then analyzed by GC and NMR spectroscopy for unreacted starting materials. The reaction can be represented by the following : x = 0 to total of TMC units y = 0 to total of TMC units z = 0 to total of TMC units x + y + z = Total of TMC units Table 1 shows the amounts of starting materials used to make the PTMC triols and the calculated properties : Table 1 PI P2 P3 STARTING MATERIALS Trimethylene Carbonate, parts 55 75 85 Trimethylol Propane, parts 45 25 15 CALCULATED PROPERTIES Equivalent Weight 100 180 300 Molecular Weight 300 540 900 TMC units 1. 6 4 7. 5

Example 2 (Preparation of PTMC diols and triols) A number of diol and triols were prepared. The diols were prepared by reacting PTMC with 1, 3-propanediol and the triols were prepared by the procedure discussed in Example 1.

Although no catalyst was used in Example 1, the diols and triols can be prepared using, for example, dibutyl tin dilaurate or sodium acetate as a catalyst, as discussed in copending U. S. Patent Application Ser. No.

09/671, 572. In the case of sodium acetate, an effective amount is about 50 ppm, based on sodium. The physical properties of these diols and triols are presented in Table 2. All the diols and triols have very low glass transition temperatures (Tg), which increase as the polyol molecular weights increase. The triols produced a slightly higher Tg than the diols at similar molecular weights.

Depending upon the molecular weight, PTMC diols were semisolid or very low melting solids that produced a clear liquid upon melting.

Differential Scanning Calorimetry (DSC) indicated that the degree of crystallinity increased with increasing molecular weights. Also, the speed of recrystallization was faster as the molecular weight increased for the molecular weights studied.

In comparison with the PTMC diols, the triols were clear liquids at room temperature. This characteristic provides the triol solutions with an extra degree of stability, hence it is an additional advantage with respect to the suitability of triols for coating formulations.

Table 2<BR> Properties of Polytrimethylene Carbonate Polyols PTMC PC PC PC PC PC PT PT PT PT PT Sample 328 478 597 813 1336 121 217 308 445 573 Functionality Diol Diol Diol Diol Diol Triol Triol Triol Triol Triol Molecular weight 656 948 1194 1626 2672 363 651 924 1336 1718 Equivalent Weight 328 474 597 813 1336 121 217 308 445 573 Tg (°C) -46.4 -40.9 -35.6 -30.2 -25.7 -48.9 -38.8 -35.9 -28.3 -26.3 Melting Point (°C) 33.3 33.4 34.8 38.4 41.7 ---- ---- ---- ---- ---- Fusion Heat (J/g) 0.3 7.0 17.0 32.3 39.0 ---- ---- ---- ---- ----

Example 3 The purpose of Example 3 was to investigate the solubility of the PTMC diol, PC813 with various solvents.

The selection of solvents for the PTMC diols was restricted due to the susceptibility of them to crystallize. The results are shown in Table 3.

In Table 3, the symbol"S"means soluble, and that a clear solution was formed.

It was determined that propylene glycol methyl ether acetate (PGMA) solubilized PTMC polyols well, and was likewise a good solvent for acrylic polyols.

Consequently, a mixture-of PGMA and methyl ethyl ketone (MEK) was chosen as solvent for the acrylic melamine coatings.

Table 3<BR> Solubility of PC813 in some Conventional Solvents Solvent Butyl n- Diace- Methyl Methyl Methyl Propylene Ethylene Ethylene Toluene Acetate Propyl tone Ethyl n- Amyl Glycol Glycol Glycol Acetate Alcohol Ketone propyl Ketone Methyl Methyl Dia- ketone Ether Ether cetate Acetate acetate Room I I I S I I S S S I Temp. 60°C S S S S S I S S S I After Cooling I S S S S I S S S I * Concentration of solutions was 33%. Abbreviation; I, insoluble; S, soluble

Example 4 In Example 4, levels of PTMC polyols of 5, 10, 20, and 50% were added to the acrylic polyol and observed for homogeneity. Hazy solutions of acrylic and PTMC polyols indicated polymer immiscibility. The data confirmed that compatibility increased as the PTMC polyol molecular weights decreased. For example, the blend solution of acrylic polyol with as low as 5% PC1336 was hazy, while the solution containing even 50% of PC328 diol was still clear. For the triol system, the blend containing 5% higher molecular weight PT573 was hazy, whereas the solutions containing 50% of PT121 and PT217 were still clear. The data also revealed that the compatibility of PTMC diol or triol with acrylic polyol decreased as the modifier content in the formulations was increased.

However, the polytrimethylene carbonate triols are more compatible than the diols at similar molecular weights, i. e. PC474 and PT308 triol. Results are shown in Table 4 : Table 4 Compatibility of Polytrimethylene Carbonate Polyols with an Acrylic Polyol PTMC Content PC1336 PC813 PC597 PC474 PC328 5% Hazy Hazy Slightly Clear Clear Hazy 10% Opaque Hazy Hazy Slightly Clear Hazy 20% Opaque Opaque Opaque Hazy Clear 50% Opaque Opaque Opaque Opaque Clear PTMC PT573 PT445 PT308 PT217 PT121 Content 5% Hazy Clear Clear Clear Clear 10% Hazy Hazy Clear Clear Clear 20% Opaque Hazy Clear Clear Clear 50% Opaque Opaque Slightly Clear Clear Hazy _-

Example 5 Example 5 demonstrates the formulation of the acrylic melamine coatings.

Joncryl 587, a 100% solids acrylic polyol from S. C.

Johnson was selected as the commercial acrylic polyol for formulation studies.

Joncryl 587 typically has a hydroxyl number of 94, an equivalent weight of 600, an acid number of 5, and a glass transition temperature of 50°C. It is a solid flaked acrylic polyol designed for use in thermosetting coatings at conventional solids. Joncryl 587 allows the formulator to select the solvent and the optimized equivalent weight of this product results in sufficient crosslink density to provide good chemical and solvent resistance.

Joncryl 587 and the PTMC polyols were dissolved in propylene glycol methyl ether acetate (PGMA) and methyl ethyl ketone (MEK) to 50% solids (Table 5). The resulting polyol solutions were then blended in a high- speed mixer. A 75/25 weight ratio of polyols to Cymel 303, a hexamethoxymethylmelamine resin sold by Cytec Industries, Inc., was used to provide crosslinked coatings. A 1% acid catalyst, dinonyl naphthalene disulphonic acid, from King Industries, Inc., sold under the name of Nacure 155, based on resin weight, provided acceptable cure rates for the coatings.

Solutions containing higher molecular weight PTMC diol or triol were hazy, indicating incompatibility with the acrylic polyol (Table 6). However, the solution of pure PTMC polyols with melamine crosslinking agent was totally clear, demonstrating that the polycarbonates themselves were compatible with the crosslinking agent.

Coating properties were evaluated after casting films on cold-rolled (Q panel S-36) and iron phosphated steel panels (Q panel S-36-I) and curing for 30 minutes at 150°C.

Table 5<BR> Formulation of PTMC Diol Modified Melamine Coatings Resin Control PC1 PC2 PC3 PC4 PC5 PT1 PT2 PT3 PT4 PT5 Joncryl 587, 60 60 60 60 60 60 60 60 60 60 60 50% (PGMA) PC328, 50% (MEK) ---- 15 ---- ---- ---- ---- ---- ---- ---- ---- ---- PC474, ---- ---- 15 ---- ---- ---- ---- ---- ---- ---- ---- 50% (MEK) PC 597, ---- ---- ---- 15 ---- ---- ---- ---- ---- ---- ---- 50% (MEK) PC813, ---- ---- ---- ---- 15 ---- ---- ---- ---- ---- ---- 50% (mek) PC1336, ---- ---- ---- ---- ---- 15 ---- ---- ---- ---- ---- 50% (MEK) PT121, ---- ---- ---- ---- ---- ---- 15 ---- ---- ---- ---- 50% (MEK) PT217, ---- ---- ---- ---- ---- ---- ---- 15 ---- ---- ---- 50% (MEK) PT308, ---- ---- ---- ---- ---- ---- ---- ---- 15 ---- ---- 50% (MEK) Table 5 (cont'd)<BR> Formulation of PTMC Diol Modified Melamine Coatings Resin Control PC1 PC2 PC3 PC4 PC5 PT1 PT2 PT3 PT4 PT5 PT445, ---- ---- ---- ---- ---- ---- ---- ---- ---- 15 ---- 50% (MEK) PT573, ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- 15 50% (MEK) MEK 3.0 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 PGMA 3.0 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 3.75 Cymel 303 10 12.5 12.5 12.5 12.5 12.5 12.5 12.5 12.5 12.5 12.5 Nacure 155, 0.73 0.91 0.91 0.91 0.91 0.91 0.91 0.91 0.91 0.91 0.91 55% Solid 53% 53% 53% 53% 53% 53% 53% 53% 53% 53% 53% Table 6 Appearance of Coating Solutions Before Application Coating PC1336 PC813 PC597 PC474 PC328 Composition 20% PTMC Opaque Hazy Hazy Near Clear Clear Coating PT573 PT445 PT308 PT217 PT121 Composition 20% PTMC Opaque Hazy Clear Clear Clear

Example 6 In Example 6, all of the PTMC polyol modified melamine coatings, prepared as described in Example 5, were baked at 150°C for 30 minutes and tested for humidity resistance. All exhibited excellent humidity resistance. The coatings passed over 500 hours without failure in the ASTM D2247-94 test conducted in a chamber with a heated tank at 40°C.

Example 7 In Example 7, the modified acrylic melamine coatings, prepared as described in Example 5, were examined for various properties. Data are shown in Table 7 : Table 7<BR> Properties of Cured Coatings Control PC1 PC2 PC3 PC4 PC5 PT1 PT2 PT3 PT4 PT5 Film Thickness 27.94 27.94 25.4 30.48 25.4 27.94 27.94 27.94 27.94 27.94 30.48 (µm) (mil) (1.1) (1.1) (1.0) (1.2) (1.0) (1.1) (1.1) (1.1) (1.1) (1.1) (1.2) (F./R.) Impact 2.3/ 3.8/ 3.8/ 3.8/ 4.07/ 3.8/ 3.16/ 3.62/ 4.29/ 4.52/ 4.52/ (Nm) (in. lb.) <0.23 0.56 0.56 0.56 0.56 0.56 0.45 0.56 0.68 0.68 0.68 (20/<2) (34/5) (34/5) (34/5) (36/5) (34/5) (28/4) (32/5) (38/6) (40/6) (40/6) Adhesion 1B 3B 4B 5B 5B 5B 3B 3B 3B 5B 5B Pencil Hardness 2H 2H 2H 2H 2H 2H 2H 2H 2H 2H 2H MEK Rubs >200 >200 >200 >200 >200 >200 >200 >200 >200 >200 >200 24 hr 10% HCl NE NE NE NE NE NE NE NE NE NE NE 10% NaOH NE NE NE NE NE NE NE NE NE NE NE Spot Mustard NE NE NE NE NE NE NE NE NE NE NE Tests Gasoline NE NE NE NE NE NE NE NE NE NE NE Color ? B 6.37 6.28 5.98 6.15 5.86 6.08 6.06 6.10 6.10 5.9 6.31 Yellowness Index 14.45 14.12 13.64 13.86 13.42 13.7 13.65 13.73 13.74 13.46 14.33 Q- Gloss 96% ---- ---- 92% ---- ---- ---- 92% ---- ---- ---- UV Ren. 20° Test Gloss 98% ---- ---- 98% ---- ---- ---- 98% ---- ---- ---- Ren. 60 Color 1.59 ---- ---- 0.43 ---- ---- ---- 0.42 ---- ---- ---- ?B YI 1.35 ---- ---- 0.93 ---- ---- ---- 0.86 ---- ---- ---- Change

Flexibility. Hardness and Adhesion PTMC polyols improved the front and reverse impact resistance of the acrylic melamine coatings. All the diols afforded similar improvements in the coating flexibility, while the triols with higher molecular weight provided more flexibility. The ultimate pencil hardness of the modified coatings was not affected with incorporation of the PTMC polyols.

Incorporation of the PTMC polyol modifiers provided great improvement in the coating adhesion for melamine cured coatings. The control melamine coatings performed poorly with a value of 1B according to the standard testing method ASTM D3359-95. As shown in Table 7, higher molecular weight PTMC polyol modified melamine coatings passed the cross-hatch tape adhesion with a value of 5B, i. e., without failure (Table 7).

Chemical. Stain, and MEK-Rub Resistance Control and PTMC polyol modified coatings provided excellent acid, caustic, and stain resistance after 24 hours exposure. Modified coatings had good gasoline resistance compared with the control. All the modified and control coatings passed over 200 MEK double rubs without failure (Table 7).

W Resistance and Colour Evaluation The UV resistance of PTMC polyol modified melamine coatings was evaluated after 500 hours exposure in a Q-UV cabinet using WA 340 light bulbs at 60°C with no humidity cycle according to ASTM D4587-91. The results confirmed that colour changes for the modified coatings were similar to the control after UV-exposure. A slight

gloss reduction was observed at 20° for the PTMC modified coatings. In addition, the PTMC polyol modifiers provided improved yellowing resistance compared to the control.

Example 8 In Example 8, white topcoats based on Joncryl 587 modified with 20% PC597 and TiO2 were formulated to a pigment to binder ratio of 0. 7/1 and a resin/melamine ratio of 75/25 by weight and cured at 149°C for 30 minutes. The modified PTMC polyol melamine coatings were tested for a number of properties. The tests showed improvements in adhesion-and impact, with other properties being essentially unaffected. Results are shown in Table 8 : Table 8<BR> Properties of PTMC Modified Pigmented Melamine Coatings Sample Pencil Adhesion Front Reverse Humidity Hardness Impact Impact Resistance 24-Hour Spot Test (Nm) (Nm) (hours) (in-pl) (in-pl) HCl NaOH Gasoline Mustard Control 3H 1B 1.81 < 0.23 >500 10 10 9 10 (16) (<2) 205 2.82 0.23 PC597 3H 5B (25) (2) >500 10 10 9 10 Sample Colour B Yellow- Gloss Gloss MEK Q-UV Test Ness 20° 60° Double Rubs Gloss Gloss Color B YI 20 60 Change Change Control -0.81 -1.28 36 82 >200 33 79 0.24 0.38 20% PC597 -0.88 -1.42 34 81 >200 32 79 0.18 0.32

Example 9 Example 9 demonstrates the formulation of 5% and 50% PTMC polyols modified acrylic melamine coatings. Joncryl 587 and the PTMC polyols were dissolved in propylene glycol methyl ether acetate (PGMA) and methyl ethyl ketone (MEK) to 50% solids. The resulting polyol solutions were then blended in a high-speed mixer. A 75/25 weight ratio of polyols to melamine resin was used to provide crosslinked coatings. A 1% acid catalyst, dinonyl naphthalene disulphonic acid, based on resin weight, provided acceptable cure rates for the coatings.

Coating properties were evaluated after casting films on cold-rolled (Q panel S-36) and iron phosphated steel panels (Q panel S-36-I) and curing for 30 minutes at 150° C. PTMC polyols improved the front and reverse impact resistance and the adhesion of the melamine coatings.

The ultimate pencil hardness of the modified coatings was not affected with incorporation of the PTMC polyols. The control and modified coatings provided excellent acid, caustic, and stain resistance after a 24 hour exposure.

Modified coatings had good gasoline resistance compared with the control. All the modified and control coatings passed over 200 MEK double rubs without failure. Data are shown in Tables 9 and 10 : Table 9<BR> Formulations of 5% and 50% PTMC modified melamine coatings Resin Joncry 1587 5% PC328 5% PT217 50% PC328 50% PT217 Joncryl 587, 50% in PGMA 48.00 54.00 54.00 21.00 21.00 Joncryl 587, 50% in MEK 12.00 6.00 6.00 12.00 12.00 PC328, 50% in PGMA ---- 3.16 ---- 33.00 ---- PT217, 50% in PGMA ---- ---- 3.16 ---- 33.00 MEK 1.33 4.72 4.72 1.15 1.15 PGMA 5.33 2.30 2.30 1.60 1.60 Cydmel 303 10.00 10.53 10.53 11.00 11.00 Nacure 155, 55% 0.73 0.77 0.77 0.80 0.80 Weight 79.33 83.51 83.51 82.68 82.68 Table 10<BR> Properties of 5% and 50% PTMC modified melamine coatings Joncryl 5% 5% 5% 5% 5% 50% 50% 50% 50% 50% 587 PC328 PC474 PT217 PT308 PT445 PC328 PC474 PT217 PT308 PT445 Film Thickness 27.94 27.94 27.94 27.94 27.94 27.94 30.48 30.48 27.94 30.48 27.94 (µm) (mil) (1.1) (1.1) (1.1) (1.1) (1.1) (1.1) (1.2) (1.2) (1.1) (1.2) (1.1) (F./R.) Impact 2.3/ 2.71/ 2.49/ 2.49/ 2.49/ 2.71/ 9.04 7.91/ 3.84/ 5.42/ 5.65/ (Nm) (in.lb.) <0.23 0.45 0.34 0.23 0.34 0.45 6.78 4.52 0.68 1.13 3.39 (20/<) (24/4) (22/3) (22/<2) (22/3) (24/4) (80/60) (70/40) (34/6) (48/10) (50/30) Adhesion 1B 3B 3B 3B 2B 4B 4B 4B 4B 4B 5B Pencil Hardness 2H 2H 2H 2H 2H 2H H-2H 2H 2H 2H 2H MEK Rubs >200 >200 >200 >200 >200 >200 >200 >200 >200 >200 >200 10% HCl NE NE NE NE NE NE NE NE NE NE NE 24-hour Spot Tests 10% NaOH NE NE NE NE NE NE NE NE NE NE NE Mustard NE NE NE NE NE NE NE NE NE NE NE Gasoline NE NE NE NE NE NE NE NE NE NE NE 20° Gloss 92 92 91 94 91 92 90 47 84 82 75 60° Gloss 120 120 121 120 120 119 112 84 116 114 96

Example 10 Example 10 demonstrates the related alternative embodiment comprising the formulation of a melamine/urea formaldehyde polytrimethylene carbonate coating composition. In this example a coating composition is made from PTMC, CYMEL 327, MIBK as the solvent, and p- toluene sulphonic acid (PTSA) solution as catalyst. In a 500 ml resin kettle, the following were added : PTMC (number-average MW 3400, 53. 2 gm), CYMEL 327 (106. 2 gm) and MIBK (81. 8 gm) and PTSA solution (1 : 99 PTSA : MIBK, 12. 6g). This mixture was heated at 100°C for 5 hrs. under N2 gas, using a reflux condenser. The solution obtained at the end of the reaction, designated 23720-184, was clear. Samples of 23720-184 (20-grams) were made up into blends as shown below in Table 11.

Some of the blends had FC430 added to help improve wetness, in order to obtain a smooth coat. Each sample was aged by rolling its container at 23°C over one or two nights as indicated. The sample was then cast on a QD412 stainless steel panel using Rod #42 and the panel coating cured 20 minutes at 175°C. Panels were cooled for one hour to approximately room temperature, visually examined for clarity, and tested for mar and adhesion. Mar test was by attempting to damage with the nylon guide bar of an adhesion test cutter. Adhesion testing was according to ASTM D-3359-95, method B.

Table 11 Sample 23/20- PDU PTSA, 1% Aged ADHE- MAR APPEAR- Substrate Material identification 184 in MIBK (hrs) SION ANCE 23720-184-1 20 gm. 1.2 gm 40 2 POOR HAZY QD 412 (SS) 23720-184-2 20 gm 2.4 gm 40 0 POOR HAZY QD412 (SS) 23720-184-3 20 gm 4.8 gm 40 0 FAIR HAZA QD412 (SS) 23720-184-4 20 gm 8.4 gm 40 0 FAIR HAZY QD412 (SS) 23720-184-5 20 gm 1 gm 0 gm 40 4 POOR HAZY QD412 (SS) 23720-184-6 20 gm 2 gm 0.6 gm 40 2 POOR HAZY QD412 (SS) 23720-184-A 20 gm 0 gm 16 4 FAIR CLEAR QD412 (SS) 23720-184-B 20 gm 1.2 gm 16 3 GOOD SLIGHTLY QD412 (SS) HAZY 23720-184-2B 20 gm 1.2 gm 16 4 GOOD CLEAR QD412 (SS)

Example 11 Example 11 also demonstrates the alternative embodiment comprising the formulation of a coating from PTMC, 1, 3- propanediol, CYMEL 327, and MIBK as the solvent, without a catalyst. In a 500 ml resin kettle, the following were added : PTMC (number-average MW 3400, 41. 75 gm), 1, 3-PDO (41. 75 gm), CYMEL@327 (83. 5 gm) and MIBK (142. 8 gm).

This mixture was heated at 110°C for 3 hrs. under N2, using a reflux condenser. The solution obtained at the end of the reaction, identified as 23720-181, was clear.

Sample blends were made-and evaluated similarly to Example 11, except that all aging was for 16 hours. The only difference among samples was the amount of PTSA solution (if any) added to 20g of 23720-181 before aging.

Unlike Example 10, a variety of substrates were used.

Details and results are in Table 12 : Table 12 Sample PTSA, 1% in Substrate Adhesion Mar Appearance Identification MIBK Material 23720-181 None QD-412 (SS) 4 POOR CLEAR 23720-181-1 1.1 gm QD-412 (SS) 0 GOOD CLEAR 23720-181-2 2.2 gm QD-412 (SS) 0 GOOD CLEAR 23720-181-3 3.3 gm QD-412 (SS) 0 GOOD CLEAR 23720-181-4 4.4 gm QD-412 (SS) 0 GOOD CLEAR 23720-181-5 5.5 gm QD-412 (SS) 0 POOR HAZY 23720-181-6 6.6 gm QD-412 (SS) 0 POOR HAZY 23720-181-7 7.7 gm QD-412 (SS) 0 POOR HAZY Expoxy-primed 23720-181 None steel 2 POOR HAZY Expoxy-primed 23720-181-1 1.1 gm steel 2 POOR HAZY Expoxy-primed 23720-181-2 2.2 gm steel 5 GOOD CLEAR Expoxy-primed 23720-181-3 3.3 gm steel 2 GOOD HAZY A-412 23720-181 None (Aluminum) 2 GOOD HAZY A-412 23720-181-1 1.1 gm (Aluminum) 0 FAIR SLIGHTLY HAZY Table 12 (cont'd) Sample PTSA, 1% in Substrate Adhesion Mar Appearance Identification MIBK Material A-412 23720-181-2 2.2 gm (Aluminum) 0 GOOD HAZY A-412 23720-181-3 3.3 gm (Aluminum) 0 GOOD HAZY A-412 23720-181-4 4.4 gm (Aluminum) 0 GOOD HAZY A-412 23720-181-5 5.5 gm (Aluminum) 0 POOR HAZY A-412 23720-181-6 6.6 gm (Aluminum) 0 POOR HAZY A-412 23720-181-7 7.7 gm (Aluminum) 0 POOR HAZY Galvanized 23720-181 None Steel 2 POOR SLIGHTLY HAZY Galvanized 23720-181-1 1.1 gm Steel 2 POOR SLIGHTLY HAZY Galvanized 23720-181-2 2.2 gm Steel 2 GOOD SLIGHTLY HAZY Galvanized 23720-181-3 3.3 gm Steel 2 GOOD CLEAR