CA1046197A - Polymer process and paint - Google Patents

Abstract

ABSTRACT

A process of preparing vesiculated polyester resin granules in which self-stabilising and self-vesiculating disperse particles of an unsaturated polyester resir., wherein the polyester contains 2-50%
of poly(ethylene oxide) of average molecular weight 1.000 to 10,000 are polymerised in an aqueous medium to polymeric vesiculated granules. The aqueous slurry of granules may be dried to a soft powder. These granules are useful as a component in paint.

Description

~ his invention relates to a novel process of preparing vesiculated polyester resin granules.
It has been proposed that granules of vesiculated polymer with diameters of~the order of 0.5 to 500 micron be used as matting and texturing agents in paints and plastics and as fillers in paper. Granules of this general type are described in, for example, Aus~ralian patent specification No.439,4~2, in which it is further disclosed that the ratio of granule diameter to vesicle diameter should be at least Australian patent specification ~o. 455,277 discloses that useful vesiculated cross-linked polyester resin granules can be prepared from selected carboxylated ~ saturated polyester resins by-a process which involves the emulsification of an unsaturated monomer, for example styrene, in water in the presence of a strong base, followed by curing of the resin~ Particles of pigment can be incorporated in the granules by first pigmenting the polyester resin solution and by a double-emulsion technique, in which a dispersion of the pigment in water is first suspended in droplet form within the unsaturated polyester resin solution. That suspension in turn is dispersed in bead form in water.
~he beads are stabilised by the presence of a water-soluble polymer, for example a partially hydrolysed poly(vinyl acetate), in the external water phase.

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Curing of the unsaturated polyester resin is initiated in conventional manner, e.g. by the use of free-radicle initiators. ~he resultant product is an aqueous slurr~
of vesiculated cross-linked polyester resin granules.
While vesiculated granules in the form of aqueou~
~lurries may be well suited to direct incorporation into a~ueous products, for example aqueous latex paints~
without first extracting and drying the granules, this step clearly cannot be avoided when preparing non-aqueous end products. ~he presence of water-soluble polymeric stabiliser or protective colloid in the slurries can introduce undesirable economic and technical complications into the extraction and drying process, so that when anhydrous granules are required it would be desirable to eliminate or drastically reduce the use of such a water-soluble polymeric component.
We have now discovered a process of preparing vesiculated polye3ter resin granules whereby certain of the existing limitations of known processes can be avoided. ~he granules so-prepared have certain important and surprising advantages over vesiculated polyeqter resin granules hitherto known to the art.
~ he process we now disclose involves the use of an unsaturated pol~ester resin in which is incorporated chains of poly(ethylene oxide). ~his resin co-reacts in known manner with ethylenically unsaturated monomer.
Furthermore, a solution of the resin in ethylenicall~ -- 1~46~97 unsaturated monomer on agitation with water forms a self-stabilised globular dispersion of the resin solution in water and the individual globules spontaneously acquire a vesiculated structure.
Accordingly we now provide a process of preparing an aqueous ~lurry of ve~iculated polyester re~in granule~
by stirring into water a solution of an unsaturated polyester resin in ethylenically unsaturated monomer to form a dispersion in the water of globule~ of the unsaturated polyester resin solution and then adding to the dispersion a free radicle initiator to i n; tiate co-reaction of the unsaturated monomer, the process being further characterised in that;
(1) the polyester resin shall comprise from

2-50% by weight of poly(ethylene oxide) chain~ of average molecu~.ar weighb 1000 - 10~000 which are water soluble at the granule processing temperature and (2) the ethylenically unsaturated monomer shall have a solubility of less than 5% by weight i~ water.
~he polyester resin granules may be separated from the water of the slurry and dried.
Unsaturated polyester resins which co-react with eth~lenicall~ unsaturated monomer to give a cross-linked polymer structure are? as a class, well know~

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- 1~46197 to the art, as are ways of initiating the polymerisation reaction. ~he most widely recognised t~pe of unsaturated polyester resin is the condensation reaction product of polyols and polybasic agids, at least a portion of which acid is ethylenically u~saturated, for example ethylene glycol reacted with maleic acid or acid anhydride. A
resin of this type will normally contain unreacted carboxyl groups, the concentration of which is expressed as the acid value of the resin, in units of mgm EOE
equivalent to one gm of the resin.
~ he exercise of this invention places no unusually critical requirements on the nature or acid value of the polyester resin to be used therein, other than the requirement in respect of poly(ethylene oxide) content.
~owever, for the most stable processing conditions we have found it preferable to work with resins which have acid values of from 10-50 mgm ~OH per gm.
~ he choice of components available to the polyester formulator is illustrated but not limited by the following examples:
Unsaturated aliphatic acids, e.g. maleic, fumaric, itaconic, citraconic and mesaconic acids.
Saturated aliphatic acids, e.g. malonic, succinic, glutaric, adipic, pimelic, azaleic, hexa-hydrophthalic and sebacic acids; and ~romatic acids, e.g. phthalic, iso-phthalic, tere-phthalic, tetrachlorophthalic, trimellitic and trimesic acids~

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~ he corresponding acid anhydrides, where they exist, are also common components of such polyesters.
Suitable dihydric alcohols are chosen from, for example, ethylene glycol, diethylene gl~col, hexane 1, 6-diol, propylene glycol, dicyclohexanol and neopentyl glycol. Alternatively the alcohol may be one which initiall~ contained three or more hydroxyl OEoups, the groups in excess of two optionally being at least in part etherified with, for example, a monohydric alcohol e.g. methanol, ethanol and n-butanol, or esterified with a monobasic acid, e.g. benzoic acid~
p tert-butyl benzoic acid and chain-like aliphatic acids of up to 18 carbon atoms chain length e.g. coconut oil fatty acid.
~he methods by which unsaturated polyesters of this type are formulated and made are well known in the art.
As disclosed hereinabove, the requirements of this invention superimpose on the above-described formulating practices the essential requirement that the unsaturated polyester resin shall comprise 2-50%
by weight of poly(ethylene oxide) chains. For some applications, the preferred range is 2-20% by weight.
~here are a number of ways in which a moiety of this type may be incorporated into a polyester resin. ~he terminal groups of poly(ethylene oxide) chains as normally prepared are usually hydroxyl, although . .
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104ti~97 (depending on the pol~merisation method used) one group can be an alkoxy, e.g. methoxy group. ~hus, with respect to hydroxyl group concentration the poly(ethylene oxide) may be mono- or di-functional, the difunctional species commonly being referred to as poly(ethylene glycols).
~he nature of poly(ethylene oxides) is well known and reviewed in~ for example, "Organic Polymer Chemistry"~
Saunders, E,J., Chapman and Hall, ~ondon, 1973. ~hus, the most direct way of attaching a poly(ethylene oxide) moiety to an unsaturated polyester is to utilise its hydroxyl group or groups in an esterification reaction.
For example, a mono-hydroxy-terminated poly(ethylene oxide) may be reacted through its hydroxyl group and a carboxyl group of the polyester resin to lln;te both - 15 ¢omponents through an ester linkage. On the other hand, if the poly(ethylene oxide) chain is terminated at both end~ by hydroxyl groups, it may be used as a dihydric alcohol in the preparation of the unsaturated polyester resin itself.
Poly(ethylene oxide) for use in this manner may be readily prepared by known methods from ethylene oxide and is also known commercially; for example, certain proprietary products sold under the trade mark - "Carbowaxr' (r~rade Mark of Union Carbide Corp , U.S.A,) ~or our purpose, the poly(ethylené oxide) must be ~ater-soluble at the granule processing temperature and . . , , . .
:, have an average molecular weight of 1000 - 10,000~
Although the polymers must be essentially those of ethylene oxide, we do not exclude by the use of this term the presence therein of-a minor proportion of some other alkylene oxide, for example propylene oxide, provided the poly(alkylene oxide) as a whole remains water soluble at the granule processing temperature.
An alternative indirect way of introducing poly (ethylene oxide) into the polyester is to first react a mono-hydroxyl-terminated poly(ethylene oxide) with a tribasic acid, for example trimellitic acid anhydride, ~ -in equimolar proportions, and then to use the dibasic acid ester so-formed in the uL~aturated polyester resin preparation as a diba~ic acid reactant.
~ he first step in preparing vesiculated granules by our new process, is to dissolve the selected unsaturated polye8ter resin in eth~lenically unsaturated monomer with which it will co-react when polymerisation is initiated by a free radicle mechanism. ~he unsaturated monomer should be essentially water-insoluble and we have found monomers with a solubility of le~s than 5% by weight in water to be satisfactory for our purpose.
A single monomer or a mixture of monomers may be used and in general the monomer will contain only a ~ingle polymerisable double bond. However, it is known that poly-functional monomers, that is, monomers containing more than one polymerisable double bond, are .
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Such poly-functional monomers are, however, normally present only as a minor constituent of a mixture of monomers~ the major proportion of which is monofunctional monomer. Hence, mixtures comprising e.g~ divinyl benzene may be used in the performance of our invention.
~ he basis for selection of ethylenically unsaturated monomer which will react with an unsaturated polymer is well understood in the art and can be applied directly to the process of the present invention. In practice, we have found the most generally useful monomer to be styrene, because of the ease with which it can be polymerised with a broad range of unsaturate~ polyester resins. However, excellent results are given by blends of styrene with other monomer, notably Ivinyl toluene' and methyl methacrylate. ~or the best results, we prefer that the monomer shall oomprise at least 50% by weight of styrene.
~ ~he choice of monomer is not, however, restricted to the above monomers alone. ~earing in mind the requirements that the total monomer must be essentially insoluble in water and also be a solvent for the unsaturated polyester resin, there may be present in a minor proportion other polymerisable 11n~aturated monomers to, for example, modify the physical properties of the co-reacted resins. ~ypical co-monomers are, for example~
athyl acrylate, n-butyl methacrylate, acrylonitrile, , - ' ''' ' ' ':, ' ~ " ~

and triallyl cyanurate. In general, we have found that the upper limit of usefulness of such monomers is 10%
by weight based on the total monomer used. Higher concentrations give granules which can be either too 5 brittle or too rubbery to be used effectively in~
for example~ paint compositions.
Optionally a few percent by weight of a non-polymerising organic liquid, e.g. n-butanol or toluene, may be mixed with the monomer to increase the solubility of the pol~ester resin therei~ or may be introduced as an incidental part of the process, e.g. in preparing the polyester When a solution of unsaturated polyester in polymerisable monomer of this type is added to water with vigorous stirring, it forms a self-stabilising suspension of globules of polyester solution in the water. Stirring is continued vigorou91y until the desired globule size, which will correspond approximately to the final granule size, is achieved. Reduction of the globules to size may be hastened by the addition to the water of a limited amount, not more than 5% by weight of the polyester, of an anionic surfactant such as, for examp~e, "Aérosol" M.A.
(Aerosol is a- trade mark of the Americal Cyanimid Co.)~
or a water-æoluble colloid, for example hydroxy ethyl 2~ cellulose. At the same time, small discrete liquid filled vesicles form spontaneously within the globules of polyester resin solution. Each globule contains a plurality of vesicles, the diameters of which are small ... . . . .
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relative to that of the globule diameter. Vesicle volumes lie within the range of 20-60% of the globule volume.
When the globules haYe been reduced by stirring to the desired granule diameter,a free radicle initiator is added to the suspen~io~ to polymerise and hence cross-link the polyester re~in granules. ~he initiator may be~
for example, an organic peroxide, e.g. benzoyl peroxide, di-tert-butyl peroxide and methyl ethyl ketone peroxide, in combination with an accelerator such as for example diethyl aniline.
It has been proposed, for example in the Australian patent specifications referred to hereinabove, that the usefulness of vesiculated polymer granules is enhanced by the inclusion in them of pigments, especially opaque white pigments such as, for example, titanium dioxide. Pigment may be incorporated in the granules of this invention by pre-dispersing particles of the chosen pigment in the unsaturated polyester resin solution. In general, when the granule incorporates a proportion of pigment, we have found it preferable to adopt the option of adding up to 5% by weight of the polyester of an anionic surfactant or a water-soluble colloid, for example hydroxy ethyl cellulose, to the water in which the suspension of globules of unsaturated polyester resin solution is made, Granules according to this process may be prepared free of external added polymeric stabiliser which appears, without preaudice to the nature of this invention, to . .................................... . .
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be a contributing factor to the relative ease with which they can then be separated from the water and dried.
~ he slurry of granules prepared as described hereinabove may be concentrated by settling and then 'j deca~tating, the granules then being centrifuged or filtered from the bulk of the remaining water. ~he wet granules may then be dried by, for example, tray drying in a hot air atmosphere or by using fluidized bed techniques.
Granules of the type we now disclose, that is granules of cross-linked polyester resin comprising 2-5~/o by weight of moieties of poly(ethylene oxide) of average molecular weight 1000-10~000 are particularly useful as components of paint films. A surprising and 15 valuable feature of these granules is that when they are used at high concentrations by volume in the dry paint fiim, that i5 when they comprise 60-90% by volume of the film, the paints so-produced usually have improved stain resistance to that of similar formulations made 20 from granules of the prior art referred to hereinabove.
~ he invention is illustrated by the following examples in which all parts are given by weight:

E~AMPLE: 1 Preparation of a poly(e~hylene oxide) modified 25 unsaturated polyester resin.
A mixture of 29 parts of propylene glycol 27 parts of fumaric acid 12 parts of phthalic anhydride and 7 parts ... , ,. . , :
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~ 046197 of a poly(ethylene oxide) of molecular weight 6000 known as "Carbowax"6000 (Trade Mark), were heated in a reaction vessel fitted with a stirrer~ thermometer and condenser and held under total reflux conditions for 2 hours.

3,5 part~ of xylerle wa~ then added to the flask and a Dean and Stark trap fitted to collect water distilled from the reaction. ~'he reaction mixture was kept under reflux at temperature up to 210C and water was removed until the acid value of the polyester fell to 30 mg ~OH/g resin. Heating was then stopped and the reaction mixture cooled. 0.015 parts of hydroquinone was added to the resin when the temperature had fallen to 140C and 21 parts of styrene was added when the temperature had fallen to 110C. The product was a viscous amber coloured li~uid.

F~AMpIE 2 Preparation of pigmented vesiculated polyester granules according to the invention.
14.16 parts of the polyester of Example 1 was mixed with 5.80 parts of styrene, and 16.00 parts of rutile titanium dioxide pigment was dispersed therein by high speed mixing. 0.50 parts of a paste consisting of 55% benzoyl peroxide in n-butyl benzyl phthalate was added to the dispersion and thoroughly mixed.
~he above mixture was added with stirring to a mixture of 62.40 parts of water and 0.29 parts of ~ydroxy ethyl cellulose. ~he actual grade used was -10461g~
"~atrosol" 250 HR,("Natrosol"being a trade mark of Hercules Co., U.S.A.). After stirring for one minute f 0.46 parts of an 80% aqueous solution of sodium dihexyl sulphosuccinate was added and stirring continued.
5 A stable oil-in-water emulsion of globules of polyester resin solution in water was formed and stirring was ¢o~tinued until the maximum emulsion particle size observed by microscopy was 30 micron. ~hen, 0.16 parts of diethyl aniline was added and stirring stopped.
10 Over a period of 1 hour the temperature rose from 20C
to 40C indicating that an exothermic polymerization reaction was occurring. ~he product was a slurry of spherical pigmented vesiculated polymer granules~ the vesicle volume of which was estimated by microscope 15 examination to be about 50% of the total OE anule volume.

Comparative example of a paint composition which shows improved properties over a similar paint comprising vesiculated polymer granules of the type disclosed in 20 Australian patent specification ~o.445,277.
Paint A
~o 4~.86 parts of the polymer granule slurry of Example 2 was added 19.92 parts of an aqueous acrylic latex (Rohm and Haas AC 61 was used) and 16.58 parts 25 of a 71% aqueous dispersion of rutile titanium dioxide pigment. 1.4 parts of tributyl phosphate, 16.5 parts of water and 0.18 parts of hydroxyethyl cellulose were :

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-` 1046197 added slowly and the mixture stirred until the viscosity reached a constant value.
Paint B
A paint similar to paint A was made, with the exception that the polymeric granules a~ u~ed in paint A
were substituted on a dry weight basis with vesiculated polyester resin granules of the same size range but prepared a¢cording to the teachings of Australian Patent Specification 445,277.
Paint A and paint B were drawn down side b~ side on a Morest hiding power chart to films of the same thickness and allowed to dry in air overnight~ then aged for a further 24 hours. Stains~ including a dispersion of carbon black in mineral oil, black pencil, 15 red chalk and household dust, were then applied evenly to both paint films.
~ he paints were scrubbed with a rag wet with water and household detergent. It was observed that the stains were removed more readily from paint A than from paint B.
20 In the case of the mineral oil stain, removal was almost complete from film A but very slight only from film B

Preparation of pigment-free vesiculated polyester resin granules by the process of this invention ~ 9 parts of polyester resin as prepared in example 1 was added 30 parts of styrene and 3 parts of a ..

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55% by weight paste of benzoyl peroxide in n-butyl benz~l phthalate, to form a clear solution. ~his solution was then added with stirring to 200 parts of water and formed therein a stable water-in-oil type dispersion, ~ o the dispersion so-formed was added 0.8 parts of diethylaniline, which initiated an exothermic polymerisation reaction lasting about 2 hour~. The product so-produced was an aqueous slurry of polyester resin granules with a maximum diameter of about 50 micrometres, corresponding to the maximum diameter of the unpolymerised initial water-in-oil type dispersion.
~he granules were found to contain about 50% by volume of fine vesicles, which had formed therein spontaneously during the granule manufacturing process.
Whe~ spread on trays and exposed to a current of warm air~ the slurr~ dried to a soft white powder.
~ he preparation was repeated but with the addition of 0.7 parts of hydroxyethyl cellulose to the water in which ths initial oil-in-water type emulsion was made, Approximatel~ the same degree of agitation was used in preparing the dispersion, but in this case the final maximum granule diameter was of the order of 20 micro-metre, thus showing the usefulness of a water-soluble colloid in aiding size reduction of ~ranules during this process. ~he size and degree of vesiculation and the facility with which these granules could be dried, closely ,,~ .

.: , , .. . : . ~ , . . -1046197resembled those of the 50 micrometre granules.

EXAMPIæ 5 This example illustrates the preparation of 30 micrometre pigmented vesiculated polymeric polyester resin granules according to the invention.
~ o 14.16 parts of the poly(ethylene oxide) modified polyester of ~xample 1 was added 5.80 parts of styrene, then 16.00 parts of rutile titanium dioxide pigment was dispersed therein by high speed mixing. 0.50 parts of a paste consis~ing of 55% by weight benzoyl peroxide in n-butyl benzoyl phthalate was added to the dispersion and thoroughly mixed.
~ he above mixture was added with stirring to a m;Yture of 62.40 parts of water, 0.29 par~s of hydroxy eth~l cullulose (as in example 2) and 0.52 parts of a 30% aqueous solution of a polyphosphate pigment dispersant, After stirring for one minute, 0.46 parts of an 80% aqueous solution of sodium dihexyl sulpho-succinate was added and stirring continued. A stable oil-in-water type dispersion was formed and stirring was continued until the maximum disperse particle size observed by microscopy was ~0 micrometres, after which 0.16 parts of diethyl aniline was added an~ stirring stopped.
Over a period of 1 hour the temperature rose from 20C
25 to 40C indicating that an exothermic polymerisation -- reaction was occurring. ~he product was a slurry of spheroidal pigmented vesiculated polyester granules, the vesicle volume of which was about 50% of the total ~ .

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16~4~197 granule volume. ~he aqueous slurr~ of granules was dried after washing to give a soft powder of pigmented vesiculated granules.

, EXAMPIE 6 Preparation 5 micrometre pigmented vesiculated polymeric polyester resin granules according to the invention.
~o 27 parts of the poly(ethylene oxide) modified polyester of example 1 was added 11 parts of styrene and 31 parts of a rutile titanium dioxide pigment was dispersed therein. ~o this blend was then added 1 part of a 55% by weight paste of benzoyl peroxide in n-butyl ,~
benzyl phthla's;e. ~he above dispersion was added with stirring to a mixture of 118 parts of water, 1.8 parts of hydroxyethylcellulose and 1.6 pàrts of sodium dihexyl sulphosuocinate. An oil-in-water type dispersion was formed, the particle ,size of which was ,' reduced by vigorous mixing to an average value of about ,'~ ,' 5 micrometres. 16 part~ of water and 0.3 parts of '~`
diethylaniline were added and an exothermic reaction was observed to take place over a period of about 2 hours.
~he product was a slurry of pigmented vesiculated polymer ' granules of an average size of about 5 micrometres.
~his was dried after washing to give a dry powder of pigmented vesiculated polyester granules.

EXAMPI~ 7 Preparation according to the invention of pigmented polyester resin granules with a low vesicle volume.

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-., . ~ -~ o 27 parts of the poly(ethylene oxide)modified polyester of Example 1 was added 11 parts of styrene, then 31 parts of a rutile titanium dioxide pigment were di~persed therein. Next, 1 part of a 55% by weight paste of benzoyl peroxide in n-butyl benzyl phthalate wa~
added. ~his mixture was then added with ~tirring to an a~ueou~ phase consisting of 120 parts of water, 0.5 parts of hydroxyethyl cellulose, 3.5 parts of sodium chloride and 0.5 parts of sodium dihexyl sulphosuccinate.
An oil-in-water type dispersion was formed, the disperse particles of which were reduced by stirring to approximately 30 micrometres maximum diameter. ~hen, 0.3 parts of diethylanili~e was then added to the dispersion and an exothermic curing reaction was observed to take place over a period of 2 hours. ~he product was a slurry of pigmented polye~ter granules up to 30 micro-metres in diameter and with a vesicle volume about 20%
of the total granule volume. ~he slurry dried in a current of warm air to a soft white powder, ~his example illustrates the preparation of vesiculated polyester resin granules according to the invention.
A poly~thylene-oxide)modified polyester suitable for the preparation of vesiculated polyester resin granules according to the invention was prepared as follows:

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'' ' - ' 33 parts of a methoxy poly(ethylene oxide) (containing one terminal methoxy and a terminal hydroxyl group per molecule) of average molecular weight 2100 was added to a reaction vessel fitted with a stirrer, thermometer and 5 condenser together with 5 parts of xylene and ~.2 parts of trimellitic anhydride. ~his mixture was held under reflux at about 160C until the anhydride group concentration by infra-red analysis had fallen to a constant low value. ~he mixture was cooled to 1~0C
10 and 4 parts of phthalic anh~dride, 14 parts of fumaric acid and 1~ parts of propylene glycol were added. ~he mixture was heated to reflux and held for 1 hour~ A
Dean & Stark trap was then fitted to collect water condensed from the reaction. ~he mixture was kept under reflux 15 at temperatures up to 210C and water was removed until the acid value of the pol~ester fell to 30 mg EOH/g resin.
Heating was then stopped and the reaction mixture cooled.
0.015 parts of hydroquinone was added when the temperature had fallen to 140C and 26 parts of styrene 20 was added when the temperature had fallen to 110C.
The product was a viscous turbid amber coloured liquid.
~ he polyester resin so-produced was then used to prepare vesiculated granules by the methods described in examples 4-7. Granules of similar properties were 25 obtained from the polyester of this example to those obtained from the polyester of example 1.

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EXAMP~E 9 - ~his example illustrates the preparation of vesiculated polyester resin granules according to the invention using various poly(ethylene oxide) modified polyester resins as described hereunder:
(a) A poly(ethylene oxide) modified polyester was prepared by the method of example 1, but with the substitution of one half of the propylene glycol with neopentyl glycol on an equimolar hasis.
(-bj A poly(ethylene oxide) modified polyester resin was prepared by the method of example 1 but with the substitution of the fumaric acid with maleic anhydride on a equimolar basis.
(c) A poly(ethylene oxide) modified polye~ter resin was prepared by the method of example 1, but with the substitution of 10 percent by weight of the styrene monomer with methyl methacrylate monomer.
(d) A poly(ethylene oxide) modified polyester resin was prepared by the method of example 1, but with the substitution of 10 percent by weight of the styrene monomer with vinyl toluene monomer.
~ he above polyesters were converted in turn into vesiculated polymer granules by the method of example 2 and found to give satisfactory vesiculated polyester re~in granules.
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Thi~ example illustrates by way of comparison processes for preparing vesiculated polyester resin granules outside the scope of the present invention.
Ve~iculated polyester granules were attempted to be prepared, wherein the polyester resins were as follows.
(a) A polyester resin was prepared by the method of example 1 but using 70 parts of a 6000 molecular weight poly(ethylene oxide) ~ -in place of 7 parts thereof.
~he product when cooled was a semi solid and could not be converted into vesiculated pol~mer granules by the method of the invention.-(b) A polyester resin was prepared by the method of example 1 but using 1 part of poly (ethylene oxide) molecular weight 6000 in place of 7 parts thereof, ~he product was a viscous amber liquid which did not produce a stable dispersion in water by the method of example 2 and could not be cured to give a dispersion of vesiculated polyester resin granules according to the invention.
(c) A polyester resin was prepared by the method of example 1 but using an equal weight of a poly(ethylene oxide) of average molecular weight 600 in place of the poly(eth~lene oxide) of average molecular weight 6000.

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~he product waq a viscous amber liquid which did not form a stable dispersion in water by the method of ~ ~-Example 2 and could not be cured to ~ive a dispersion of ve~iculated polyester resin granules according to the invention.

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Claims (7)

The embodiments of the invention in which a particular property or privilege is claimed are defined as follows:

1. A process of preparing an aqueous slurry of vesiculated polyester resin granules by stirring into water a solution of an unsaturated polyester resin in ethylenically unsaturated monomer to form a dispersion in the water of globules of the unsaturated polyester resin solution and then adding to the dispersion a free radials initiator to initiate co-reaction of the unsaturated polyester resin and ethylenically unsaturated monomer, the process being further characterised in that;
(1) the polyester resin shall comprise from 2-50% by weight of poly(ethylene oxide) chains of average molecular weight 1000 - 10,000,which are water soluble at the granule processing temperature and (2) the ethylenically unsaturated monomer shall have a solubility of less than 5%
by weight in water.

2. A process according to claim 1 in which the unsaturated polyester resin has an acid value of 10-50 mgm KOH per gm.

3. A process according to claim 1 in which the ethylenically unsaturated monomer comprises at least 50% by weight of styrene.

4. A process according to claim 3 in which the ethylenically unsaturated monomer comprises up to 10% by weight of monomer selected from the group consisting of ethyl acrylate, n-butyl methacrylate, acrylonitrile and triallyl cyanurate.

5. A process according to claim 1 in which the dispersion in water of globules of unsaturated polyester resin solution is made in the presence in the water of up to 5% based on the weight of polyester resin of an anionic surfactant or a water-soluble colloid.

6. A process of preparing vesiculated polyester resin granules wherein granules are separated from the water of an aqueous slurry prepared according to claim 1 and the separated granules dried.

7. A paint composition comprising vesiculated polyester resin granules prepared by a process according to claim 1.