CA2032921A1 - Thermosettable composition - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

A thermosettable resin composition having a viscosity that decreases during processing temperatures and increases as the temperature is raised to curing temperatures is provided. The composition comprises thermosettable resins and thermoplastic particles that are insoluble in the thermosettable resins at processing temperatures but soluble in the thermosettable resins at curing temperatures. Prepregs prepared from the thermosettable resin composition are also provided.

Description

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T~ERMOSETTABLE COMP~SITION

FIELD OF T~E INVENTION
The present invention relates to thermosettable resin compositions and their use together with reinforcing filaments in the production of advanced composites.

BAC~GROUND OF THE ?NVENTION
Thermosettable resins are weIl known for their use in structural adhesives, in high performance composites, and in prepregs. Composites and prepregs made from these thermosettable resins and high strength fibers such as glass, ceramics, carbon and the like provide articles having considerably less weight than the same article made from metal. The articles, however, made using these thermosettable resins have been brittle, a characteristic that necessarily seriously limits their use. Also, because the viscosity of the thermosettable 20 resins has been either too hiyh~during processing or too low during curing~many of the articles are rejected because of the development of voids and imperfections in the articles.
Efforts have been made to control the viscosity 25 of the thermosettable resins. Flow control agents, suah as fumed silica, clay, whiskers, and high molecular weight polymers, have been added to khermosettable resins. These agents increase the viscosity over all temperature ranges, often making processing difficult or impossible and 30 frequently harm the physical characteristics of the cured ! .' article. I
High performance thermosetting resins include such resins as epoxies, bismaleimides, and cyanates.
These resins react with curing~agents or in the presence 3~ of polymerization catalysts to yield high performance resins that have gained wide acceptance as protective coatings, electrical insulations, structural adhesives, ;~;

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: , . ,. ,. ' . : :: :',, , ' . , and as a matrix resin together with rein~orci~g filam~nts in advanced composites. Where high glass transition temperatures, thermal resistance, and chemical resistance has been attained by the cured resin, the cured resin has generally had poor physical characteristics and been brittle, had poor impact resistance and fracture properties.
There are many references in the art teaching means for improving physical characteristics of cured thermosetting resins, primarily thermosetting epoxy resins, by use of a particular hardener and/or the addition of another polymer and/or an inorganic particulate material.
References among many others that teach means for improving the physical characteristics of cured thermosetting epoxy resin by the addition of a thermoplastic resin include the following:
U. S. Patent No. 3,784,433 discloses that composites of unidirectional carbon fibers and a 20 thermosettable resin are made by applying the resin as a continuous film to the carbon fibers, applying heat and pressure so that the resin flows about the fibers and forms a coherent structure, and then converting the resin .into its solid, fusible B-stage. Heating cycles can be 25 very short as there is no solvent to evaporate, and the thln layers can be cooled quickly.
U. S. Patent ~,524,1B1 discloses compositions curable to articles having reduced susceptibility to mechanical and thermal shock comprising an epoxy resin and 30 colloidally dispersed elastomeric particles.
U. S. Patent 4,558,078 discloses compositions useful as a prepreg comprising an epoxy prepolymer and curative and optionally a second resin that can be present homogeneously or in the form of an interpenetrating 35 network.

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European Patent Application 0 274 899 discloses a prepreg consisting of a fiber reinforced resin having as a separate phase fine thermoplastic or thermosetting resin particles distributed throughout the prepreg, pre~erably 5 the particles are localized in the inter-layer zones of the composite material and remain as a separate phase upon curing the prepreg.
In U.S. Patent No. 4,157,360 there is disclosed melts of dicyanates and thermoplastic polymers and in U.S.
10 Patent Nos. 4,745,215 an~ 4,780,507, there are disclosed blends of dicyanates and thermosetting or thermoplastic polymers. In European Patent Application 0 301 361 there are described rubber-modified cyanate ester resins and polytriazines derived therefrom and in U.S. Patent No.
15 4~804~740 there are described curable cyanate ester formulations containing thermoplastics. In U.S. Patent No. 4,468,497, there is disclosed bis-imides, crosslinking agents, and compatible elastomers; the compositions of these references being useful for making prepregs.
M. T. Blair et al. at the 33rd International SAMPE Symposium of March 7-10, 1988, presented a paper titled "The Toughening Effects of PBI in a BMI Matrix Resin" in which they disclosed the dispersion of 10 polybenzimidazole into a blend of hismaleimide and 25 o,o'-diallylbisphenol A. Such a composition would not exhibit a "dissolution temperature" required in the composition o~ the instant invention.

SUMMARY OF THE ~NVENTION
sriefly, the present invention provides a ~, thermosettable resin composition having a viscosity at ~i temperatures used for processing and compounding similar to the viscosity of the unmodified thermosetting resin but having a significant increase in viscosity at a higher 35 resin curing temperatures. The thermosettable resin composition comprises a thermosettable resin mixture, which is a liquid at a temperature in the range of 20 to lOO~C, comprising:

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a) one or more thermosettable resins and one or more of c~ratives, hardeners, and catalysts or the thermosettable resin in an amount sufficient for cure of the thermosettable resin, and b) 2 to 50, preferably 2 to 30, parts per 100 parts of thermosettable mixture, of resin particles of one or more amorphous thermoplastic polymers having a Tg of 140~ or higher, the particles having a dissolution temperature (defined hereinafter) of 50C or higher, 10 preferably 70 or higher, and the particles being essentially insoluble in the thermosettable resin at temperatures up to about 15~C below the dissolution temperature. The composition may optionally contain additives for property enhancement.
The invention also provides prepregs for structural composities comprising a web of fibrous material impregnated with the thermosettable composition of the invention.
As used in this application:
"dissolution temperature" means the temperature at which the viscosity of a composition of thermosettable resin and thermoplastic particles in the absence of curatives, hardeners, or catalyts far the thermosettable resin, when raised at a rate of about 2C per minute, 25 reaches a minimum value and then begins to rise as the thermoplastic particles begirl to dissolve.
Means disclosed in the b~ckground art ~or solving physical shortcomings o~ the cured thermosetting resin have not solved problems arising in processing of 30 thermosetting resins into useful articles. In processing of a thermosetting resin composition into an article such as a prepreg that can be used in the manufacture of composite structures, the viscosity profile of the thermosetting resin composition is very important. ~t is 35 important that the viscosity of the composition be relatively low during compounding, coating and impregnating of a fiber reinforcement but becomes ' :~ .

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relatively high during the curing process to allow the application of vacuum to remove volatiles and the application of pressure to shape the composite part without bleeding of excessive amounts of resin that would 5 cause voids and imperfections in the cured composite part.

BRIEF DES(:RIPTION OF TIIE DRAWING
Aspects of the invention which are capable of illustration are shown in the accompanying Drawing wherein 10 graphs show the relationship of viscosity to temperature for compositions according to the invention and for state-of-the-art compositions.
In the Drawing (details of the formulation and procedures are given in Example 1, below), curve A
15 (comparative) represents the viscosity profile for a conventional thermosetting resin. As can be seen, the viscosity decreases with increasing temperature. Curve B
(comparative) is the viscosity pro~ile for a composition of the thermosetting resin of Curve A and 8.5% by weight 20 f polyetherimide thermoplastic. For this trial the thermoplastic has been completely dissolved into the thermoset during mixing to form a completel~ homogeneous blend. This formulation exhibits a viscosity profile which is well above the unmodified thermosetting resin over all temperature ranges. The formulation of curve C
(present invention) is id~ntical to that of curve B, however, in thls trial, the polyetherimide thermoplastic is in particle form and is mixed into the thermo~et to form a dispersion where none of the thermoplastic is 30 dissolved. The viscosity profile obtained is unique in that, the initial viscosity is essentially the same as that for curve A. However, after the first minimum in viscosity occurs, which is the dissolution temperature (Td ) ~ the thermoplastic particles dissolve~ This raises 35 the viscosity of the composition up to the level obtained for the homogeneous blend of Curve B.

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DETAILED DESCRJ:PTION OF_THE _EIEPERRED EMBODIMENTS
OF THE INVENTION
. _ Thermosetting resins that can be used as component (a) in the composition of the invention are 5 epoxy, N,N~-bismaleimide, and polycyanate monomers and prepolymers that are liquid at a processing temperature and can be cured to a thermoset resin composition at a temperature of 100C or higher.
Epoxy monomers and prepolymers that can be used 10 in the compositions of the invention are well ~nown and most are commercially available. They are compounds in which there is present at least an aromatic or cycloaliphatic ring structure and one or more epoxy groups, e.g., O
-CH CH- .
Compounds having more than one epoxy group are preferre~.
Aromatic polyepoxides, the most preferred epoxy compounds, 20 are the polyglycidyl ethers of polyhydric phenols, glycidyl esters of aromatic carboxylic acid, and polyglycidyl derivatives of aromatic amines such as N-glycidylaminobenzene, and glycidylamino-glycidyloxy-benzenes.
Examples of aromatic polyepoxides, useul in the thermosettable resin composition of the invention, include the polyglycidyl derivatives of polyhydric phenols such as 2,2 bis[4-~2,3-epoxypropoxy)phenyl]propane and those described in U.S. Patent Nos. 3,018,262 and 3,29~,998, 30 and in "Handbook of Epoxy Resins" by Lee and Neville, McGraw-Hill Book Co., New York (1967). A preferred class of poly(glycidyl ether)s of polyhydric phenols of use in the compositions of the invention are the diglycidyl ethers of bisphenols that have pendent carbocyclic groups 35 such as those described in U.S. Patent No. 3,298,998, which is incorporated herein by reference. Examples of ' _7_ 2~

such diglycidyl e~hers are 2,2-bis[4-(2,3-epoxypropoxy)phenyl~norcamphane, 9,9-bis[4-(~,3-epoxy-propoxy)phenyll~luorene, and 2,2-bis[4-(2,3-epoxypropoxy)phenyl~decahydro-1,4,5,8-5 dimethanonaphthalene. A much preferred diglycidyl ether is diglycidyl ether of bisphenol A.
Examples of N-glycidylaminobenzenes suitable for use in the epoxy resin composition of the invention include the di and polyglycidyl derivatives of 10 benzenamine, benzene diamines, naphthylenamine and naphthylene diamine such as N,N-diglycidylbenzenamine, N,N-diglycidylnaphthalenamine lgiven the name of N-1-naphthalenyl-N-(oxiranylmethyl)oxiranemethanamine by Chemical Abstracts 9th Coll. Index, Vol. 76-85, page 2660 15 CS (1972-76), 1,4-bis(N-glycidylamino)benzene, 1,3-bis(N,M-diglycidylamino)benzene, and bis[4-(diglycidylamino)phenyl]methane (MY 720~, Ciba Geigy, Inc.). The polyglycidyl derivatives of aromatic aminophenols are described in U.S. Patent No. 2,951,825.
20 An example of these compounds is N,N-diglycidyl-4-glycidyloxybenzenamine (ERL oSlO~M, Ciba Geigy, Inc.).
When component (a) of the composition of the invention contains an epoxy monomer or prepolymer it can be cured by a variety of curing agents as are known in the 25 art, some of which are described, toyether with the method for calculating the amount to be used, in the book by Lee and Neville, "Epoxy Resins," pages 36 to 140, McGraw-Hill Book Company, New York, 1957. ~seful curing agents include amines such as ethylenediamine, 30 diethylenetriamine, aminoethylethanolamine, and the like, diaminodiphenylsulfone, 9,9-bis(4-aminophenyl)fluorene, 2,7-dichloro-9,9-bis(4-aminophenyl)fluorene, an amide such as dicyandiamide, organic acids such as adipic acid, and acid anhydrides such as phthalic anhydride and chlorendic 35 anhydride, and polyphenols such as bisphenol A, and the like. The curing agent is chosen such that very little if any polymerization of the epoxy takes place under about .
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100C but does take place with increasing rapidity as the temperature is increased above about 125C. Generally, the epoxy composition and curing agent are used in stoichiometric amounts. However, the curing agent can be 5 used in amounts ranging from about 0.1 to 1.5 times the stoichiometric amount of epoxy resin.
Thermally activated catalytic agents may also be used, e.g., Lewis acids and bases, tertiary amines, imidazoles, complexed ~ewis acids, and organometallic 10 compounds and salts, such as the sF3-amine complexes, SbFs, and benzyldimethylamine. When a thermally activated catalyst is included, about 0.01 to 5 percent by weight of catalyst, based on the amount of epoxy compound present in the thermosettable resin composition, is used.
15N,N'-bismaleimide monomers and prepolymers that can be used in the composition of the invention are also well known, many of which can be purchased commercially.
They are compounds in which there is present at least one, preferably two, maleimido groups and have general formula 20 I:

O O
Il 11 .
C C
/ \ / \
Y N-Z-N Y
C C

where Y represents an alkylene group of at least 2 carbon atoms, preferably 2 to 6 carbon atoms, and Z is a divalent 30 organic group containing at least 2 carbon atoms and generally no more than 20 carbon atoms. Z may be aliphatic, cycloaliphatic, aromatic or heterocyclic, these groups optionally having up to two of each of sulfur and non-peroxidic oxygen heteroatoms. Y may be derived from 35 dicarboxylic acids or anhydrides such as maleic, citraconic, tetrahydrophthalic, and the like.

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Representative N,N~ bis-imides that may he employed are the N,N~bismaleimides of 1,2-ethanediamine, 1,6-hexanediamine, trimethyl-1,6-hexanediamine, 1,4-benzenediamine, 4,4'-methylenebisbenzenamine, 5 2-methyl-1,4-benzenediamine, 3,3'-methylenebisbenzenamine, 3,3'sulfonylbisbenzenamine, 4,4'-sulfonylbisbenzenamine, 3,3'oxybisbenzenamine, 4,4'oxybisbenzenamine, 4,4'-methylenebiscyclohexanamine, 1,3-benzenedimethanamine, 1,4-benzenedimethanamine, and 10 4,A'-cyclohexanebisbenzenamine and mixtures thereof.
Other N,N~bis-maleimides and their process of preparation are disclosed in U.S. Pat. Nos. 3,562,223, 3,627,780 and 3,839,358.
The preparation of the N,N'-bismaleimides is 15 well known and described in U.S. Patent No. 4,468,497.
The N,N'-bismaleimides are polymerized by heating them together with a diamine into which they can be dissolved at temperatures of 100C or lower and optionally a diunsaturated crosslinking agent.
Diamines that can be used in polymerizing the N,N'-bismaleimides are described in U.S. Patent No.
3,562,223. Preferred diamines which may be employed are diamines having a cycloalkyl or aryl group, and are the same as those listed above, that are of use in the 25 preparation of the N,N'-bismaleimides.
Generally, rom about 0.2 to 0. a moles of diamine are used per mole of N,M'-bi.smaleimide.
Diunsaturated cross-linking agents of use in the N,N'-bismaleimide compositions of the invention are any 30 diunsaturated compounds having a boiling point at atmospheric pressure of about 150C or higher and terminal ethylenic unsaturation. Preferred cross-linking agents are divinylbenzene, diallyl phthalate, and bis~4~allyloxyphenyl)ether.
Dicyanate monomers and prepolymers that can be used in the composition of the invention are also well known. References to their preparation and use in , .

polycyclotrimerization to produce polycyanurates are described in U.S. Patent No . 4,157,360. The dicyanates are compounds having general formula II:

wherein R is a divalent aromatic hydrocarbon residue and comprises at least one aromatic moiety, i.e., aromatic ring including benzene, naphthalene, anthracene, 10 phenanthrene and the like, and where R contains a total of up to 40 carbon atoms, including the aromatic moiety. For example, R can be 1,4-di(2'-phenylpropyl)benzene moiety, to which the cyanate groups are attached in the para positions of the benzene rings of the phenylpropane 15 substitutents to provide one embodiement of compounds of formula II. The aromatic rings of R may be further substituted with groups that are inert during the polymerization process, i.e., the polycyclotrimerization process, and include halogen, incLuding fluorine, 20 chlorine, bromine, and iodine; C1-C9 alkoxy, being linear or branched and including methoxy, ethoxy, isopropoxy, and t-butoxy; and C1-C4 alkyl carbonyloxy group, being linear or branched, including methoxycarbonyl~ ethoxycarbonyl, isopropoxycarbonyl and t-butoxycarbonyl; wherein the 25 number o~ substitutents on the aromatic rings may be one or more with the proviso that the groups are inert during the polymerization process and do not substantially interere with the formation of the crosslinked triazine polymer upon polycyclotritrimerizing of the aromatic 30 dicyanate moiety.
Ry the term "polycyclotrimerization" is meant forming a cyanurate ring system by the polymeric condensation of three aromatic cyanate groups to form a crosslinked aromatic ring system, which has as its basic 35 repeating unit the group of formula III:

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R
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N N III

o/~NJ o R R

10 in which R substituents, independently as defined above, .:
are attached to oxygen atoms. Methods for conducting the polymerization are well known, including thermal annealing above about 200C and are described in the Korshak referènce discussed in U.S. Patent No. 4,157,360, cited 15 above.
Preferred dicyanates are those in which R in Formula III can:have any of~the structural ~ormulae:

1 3 ~3H3 C~H3 ~ C~ ~
C~3 ~3 ~3 C~3 ~ 11 ~O-OC~ CO- 0~ 11 ~ ' CH3 ~H3 C~H3 C~3 35 ~ll~o~ 0 ~H3 ~: ' :. ' ' ~ ' -12~

I ~ ~ 2 ~ ~ a~d S C~F3 ~ I ~ ~
~H3 or combinations thereof.
When polycyanates are used in component (a) of the composition of the invention, mixtures of any proportions of polycyanates and prepolymers of the polycyanates and optionally monocyanates that are liquid at the processing temperature which preferably is in the range of 20~to 100C can be used. Prepolymers are made by heating the blends with or without catalyst at a temperature of about 140C to about 220C for a time sufficient to cyclotrimerize from about 5 to about 50 percent of the cyanate functional groups.
Catalysts that can be used in cyclotrimerizing the polycyanates to form prepolymers and completely polymerized polycyanurates include zinc octoat~, tin octoate, zinc stearate, tin stearate, copper acetylacetonate, phenol, catechol, triethylendiamine and chelates of iron, cobalt, zinc, copper, manganese and ~itanium with bidentate liquids such as catechol. Such catalysts are used in the amounts of about 0.001 to about 20 parts by weight per 100 parts of the polycyanate ester blend. Other catalysts and their use in curing polycyanates are disclosed in Great Britain Patent No. ~-1,305,762. It is, however, possible to conduct the ' .

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formation of prepolymers and the complete polymerization without a catalyst, utilizing only heat.
Cyanate esters that can be used include RDX
80352TM a prepolymer of bisphenol A dicyanate, by Interez, Inc; Xu71787TM a polycyanate of a polyphenol adduct of dicyclopentadiene by Dow Chemical Company; and BT 2160 resin, a prepolymer of bisphenol A dicyanate containing 10% by weight of 4,4~-methylenedianiline bismaleimide, commercially available from Mitsubishi Gas Chemical Company.
Resin particles which can be used as component (b) in the thermosettable resin composition of the invention have a dissolution temperature above about 50C, preferably above about 70C, and are insoluble in the thermosettable resin at temperatures up to about 15C
below the dissolution temperature but soluble at a temperature below the onset of curing which varies depending on the resin but generally is in the range of 100 to 200C.
The resin particles are prepared frnm amorphous thermoplastic resins having a glass transition temperature above about 140C. Resin particles having the required solubility characteristics have a solubility in the thermosettable resin that is low enough to prevent the particles f~om dissolving when the particles are mixed into the thermosettable resin or during storage o~ the thermosettable mixture. The resin particles, however, .also have a solubility sufficient to allow the particles to be completely dissolved in the thermosettable resin during th0 cure cycle of the composition.
Thermoplastic resins suitable for preparation of the resin particles of the invention are amorphous thermoplastics including polycarbonates, polysulfones, polyarylates, polyethersulfones, polyarylsulfones, polyesters, polyetherimides, polyamideimides, polyimides, .

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polyamides, and polyethers. Preferred thermoplastic resins are polyetherimides such as ULTEM~M 1000, available from General Electric polyethersulfone, such as VictrexTM
4800P, available from ICI, and polyarylsulfone, such as RadelTM A-200 available from Amoco. The suitability of a particular thermoplastic resin is dependent on meeting the above solubility characteristics in the specific thermosettable resin being used in the thermosettable resin composition.
The resin particles having the desired solubility characteristics can be prepared by a variety of well know techniques, including techniques such as grinding of the solid amorphous thermoplastic resin, spray drying of solutions of the amorphous thermoplastic resin, or coagulation of emulsions of the amorphous thermoplastic resin. Suitable particles preferably have a surface area of at least 0.5 square meter per gram and most preferably a surface area of 1.0 m2/g or greater. Particle si~es generally are in the range o~ 0.5 to 50 micrometers, preferably 1 to 40 micrometers.
The surface area of the amorphous resin particle is important. The surface area of the particle controls the dissolution rate of the thermoplastic particle into the thermosetting resin to form a homogeneous solution.
If the sur~ace area is too low the dissolution rate is slow and can result in the thermosetting resin curing beore the particle can dissolve. If the particle does not di.ssolve prior to curing the desirable enhanced viscosity will not be imparted.
Particles having high surface area can be prepared in several ways. A small particle has a high surface area. These particles can be prepared by grinding or ooagulation of a polymer dispersion. Another method of obtaining a high surface area is to prepare porous particles. Porous particles can be obtained by spray drying solutions of amorphous thermoplastics, as is known in the art.
The solubility characteristics of a particular resin particle can be adjusted, i.e., the dissolution temperature lowered, by the incorporation of a plasticizer, i.e., from about 5 to 50 percent by weight, into the thermoplastic resin from which the resin particle is prepared. Preferably, the plasticizer has a functional group that will copolymerize with the thermosettable 1 resin, i.e. a reactive plasticizer. As examples, an epoxy resin, for example the diglycidyl ether of bisphenol A, can be used to plasticize a particle to lower its dissolution temperature, i.e., increase its rate of dissolution into an epoxy resin or a cyanate resin composition. For example, an amine can be used to plasticize a particle to increase its rate of dissolution into N,N'-bismaleimide monomers and prepolymers.
By the phrase "essentially insoluble'l, it is meant that generally less than about 25~ of the particles dissolve when the composition is held at a temperatue of 15C less than the dissolution temperature for at least two hours, such that the viscosity of a composition of the thermoplastic particles in the thermosettable resin does not change significantly, i.e., to a point making processability difficult.
The thermosettable compositions o the invention are suitable for use as impregnating, laminating or molding resins. They can be used as sealants, insulating materials and adhesives. They are particularly suitable for use in prepregs ~or the production of space age reinforced composite structures.
The thermosettable resin CompositiQn of the invention can be used to impregnate woven or non-woven webs, filaments, rovings or the like at a temperature below the dissolution temperature in the preparation of `:

-16- ~ ~i prepregs. Fibers that can be used in such prepregs include organic and inorganic fibers including, for example, glass fibers, carbon or graphite fibers, ceramic fibers, boron fibers, silicon carbide fibers, polyimide fibers and the like, and mixtures thereof. The thermosettable composition of the invention can also be used to coat woven and non-woven webs, films and foils of organic and inorganic materials including, for example, such organic materials as polyolefins, polyesters, 1~ polyimide, and the like and inorganic materials such as ceramics, copper, and nickel, and gold. These materials can be useful in printed circuit technology and as structual components for machinery.
The composition of the invention can also contain additives to modify characteristics of the cured composition. Additives among others that can be used include: inert fillers, touyheners, whiskers, pigments, dyes and flame retardents such as, for example, chopped fibers such as ceramic fibers, glass fibers, boron fibers, carbon fibers, and their woven and nonwoven fabrics;
inorganic powders such as kaolin, chalk, silica, antimony trioxide, titanium oxide, carbon; and solid microspheres of glass, ceramicl and metal.
The thermosettable compositions of the invention are prepared by dispersion of the thermoplastic particles, 2S curatives, hardeners, catalysts, and modifying additive~
into the thermosettable resin at a temperature at which the thermosettable resin is liquid, generally at about 30 to 60C but below the dissolution temperature of the particle in the thermosettable resin. The dispersion of the particles into the thermosettable resin is generally accomplished by conventional high shear mixing devices, such as by use of a planitary mixer, kneader, ~acuum mixer, ball mill, paint mill or high speed stirrer. When the mixed composition is then maintained at a temperature -17- ~ .J

of 15C or more below the dissolution temperature, the composition is stable against gelling for two hours or longer.
While these thermosettable compositions of the invention are generally processed by hot melt coating techniques, organic solvents such as methyl ethyl ketone, toluene, tetrahydrofuran, ethyl acetate, ethyl alcohol, etc., can also be used to process these resin compositions. For example, solvent processing may be desirable to prepare a thin adhesive film from these thermosettable compositions When solvents are used care must be used to select a solvent that will dissolve the liquid thermosetting resin but will not dissolve the thermoplastic particle. Suitable substrates for coating the compositions of the invention include sheets and foils of polyimide, polyester, polyolefin, metal, and the like, and fibers such as carbon, glass, aramide, ceramic, and the like.
Objects and advantages of this invention are further illustrated by the following examples, but the particular materials and amounts thereof recited in these examples, as well as other conditions and details, should not be construed to unduly limit this invention. In the examples all parts and percentages are by weight and temperatures are in degrees centigrade unless otherwise noted.
In the examples which follow, the viscosity proEiles were obtained using an RDA-700 M Dynamic Mechanical Analyzer (Rheometrics, Inc.~. The instrument was used in the parallel-plate mode under the following conditions: gap = 1 mm, radius = 19.02 mm, frequency = 100 rad/sec, strain = 20%, temperature ramp at ~C/min, initial temperature = 50C, and final temperature = 177C.

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, Example 1 A thermosettable resin composition was prepared by mixing 35 parts of 9,9-bis[4-(2,3-epoxypropoxy)-phenyl]fluorene (DGF) and 65 parts of diglycidyl ether of bisphenol A (DGE8A). The resin composition was then used in three formulations: into Formulation A, no additional material was added; into Formulation C, 8.5% by weight of a particulate PEI (ULTEM resin, a polyetherimide resin available from General Electric) having a particle size of 3.2 microns and a surface area of about 5.4 m2/g was dispersed into the résin composition at 60~C using an air stirrer; Formulation B was the same as Formulation C, however the mixture was heated to 120C and stirred to allow the thermoplastic ULTEM to completely dissolve into the resin composition. The viscosity profile of each formulation was determined using the RDA-700 Dynamic Mechanical Analyzer described above and plotted in Figure l. Curve A, for unmodified resin composition shows a steady decrease in viscosity as the temperature of the composition is increased. Curve C, for the resin 20 composition modified with particulate thermoplastic, shows about the same decrease in viscosity of the mixture as for the unmodified resin composition as the temperature is increased up to the dissolution temperature, Td, where the thermoplastic begins to dissolve. At this temperature the 25 viscosity increase, due to the dissolving thermoplastic ?
particles, of~sets the viscosity decrease o the resin composition alone and prevents urther decrease in the viscosity of the mixture. Curve B, for the resin composition modified with dissolved thermoplastic shows an initial viscosity much higher tkan the viscosity of the composition modified with particulate thermoplastic.
Formulation C thus provides the low viscosities desirable at the initial temperatures of a processing operation, e.g., prepreg fabrication, and the higher viscosities (i.e., controlled flow) that are advantageous at cure temperatures to insure void-free cured composites.

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Ex_mple 2 Thermosettable resin compositions wer~ prepared as shown in Table I.

TABLE I
Composition Minimum Thermosettable % Thermoplastic Viscosity Formulation Reslnparticled T C (poi~e~
d _ .
D (a) None (e) 0.36 E (a) 8.5 115 4.78 F (b) None (e) 0.15 G (b) 8.5 ll9 2.55 H (c) None (e) 1.20 I (c) 8.5 115 10.60 (a) Thermosettable resin is 100 parts of 4,4'-tetraglyci-dyldiaminodiphenylmethane (TGDDM) and 31 parts of 4,4'-diaminodiphenylsulfone ~DDS) mixed at 1~0C with an air stirrer to completely dissolve the ~DS.
(b) Thermosettable~resin is AroCy B_30S , a dicyanate available from Hi-Tek Polymers Inc.
(c) Thermosettable resin is CompimideTM, a bismaleimide resin available from Shell Chemical Co.
(d) PEI thermoplastic particle (disclosed in Example No. 1).
(e) Thermosettable resin without the thermoplastic particle does not reveal a dissolut.ion temperature, Td ~

Viscosity proiles of each formulation was determined 3~ using the RDA-700 Dynamic Mechanical Analyzer and the di~solution temperature, Td, and minimum viscosity of each recorded in Table I. Ea ch of the thermosettable resins, an epoxy, a dicyanate, and a bismaleimide show minimum viscosities of 0.36, 0.15j and 1.20 poise, respectively .
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while these thermosettable resins to which 8.5~ by weight of thermoplastic particulate resin have been added show a dissolution temperature of 115, 119, and 115, respectively, and a corresponding minimum viscosity of 4.78, 2.55, and 10.60 poise, respectively.

Example 3 Thermosettable compositions of a fluorene epoxy resin PR-500 (3M), with various thermoplastic resins were prepared by mixing 4.65 parts of each thermoplastic resin shown in Table II with 50 parts of PR-500 at 60C using an air stirrer. The viscosity profile of each mixture as well as that of the composition without added particulate thermoplastic was obtained and minimum viscosity and dissolution temperature of each recorded in Table II.

TABLE II
Composition Minimum Thermosettable Thermoplastic Viscosity Formulation Resin particle (Tg) TdC (polse) J PR-500~ None ~e) 0.30 K PR-500~ PESg ~230) 119 1.61 L PR-500f pCh ~154) 74 2.3~
M PR-500f pS1 ~190) 86 6.50 N PR-500 PASi ~220) 106 3.76 O PR-500~ PÆI ~217) 106 9.30 P PR~500~ 50 PAS/50PEI106 4.15 Q PR-500f FPEm (330) 105 2.80 (e) no dissolution temperature observed (f) an aromtic epoxy resin available from 3M
(g) Victrex 4800TM, a polyethersulfone available from ICI Americas, Inc.
(h) Lexan~M, a polycarbonate available from General Electric Co.

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(i) Ude1~M P1700, a polysulfone available from Amoco Performance Products, Inc~
(j) RadelTM A-200, a polyarylsulfone available from Amoco Performance Products, Inc.
(k) UltemTM 1000, a polyetherimide available from General Electric Company (1) The glass transition temperature of the thermoplastic resin (m) A polyester resin prepared from a fluorene bisphenol and isophthalic/terephthalic acid ~a 50/50 mole ratio) The data of Table II show that on heating an unmodified epoxy resin, Formula J, that the viscosity dropped to a minimum of 0.30 poise while for epoxy resin modified by a variety of thermoplastic particles that were soluble at a dissolution temperature, Td, and essentially insoluble below this temperature, the viscosity of the composition does not drop below a much higher value depending on the particular thermoplastic.

Example 4 Portions of Formulation J and Formulation O of Example 3 were degassed and cured in molds at 177C ~or four hours. Fracture toughness, KIC (critical plane-strain fracture toughness in Mode I), and Tensile Modulus for each cured sample were determined ~ollowing the procedures o~ ASTM E39~-83 and ASTM D638-86, respectively. Values obtained are recorded in Table II.

TABLE III
Composition Tensile Thermosettable Thermoplastic KI C Modulus Formulation Resin Particle MPa-ml~2 GPa J PR-500 None 0.644 3.52 O PR-500 8.5~ PEI0.909 3.42 :

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AS the dat~ of Table III illustrates, the addition o~
thermoplastic particles, PEI, that began to dissolve at a dissolution temperature but were essentially insoluble below this temperature, provided an increase of about 44~
in the fracture toughness of cured resin with essentially no loss in the tensile modulus.

~xample 5 A formulation of PR-500 epoxy resin and 8.5% by weight of PEI particles was examined in an RDA-700 Dynamic Mechanical Analyzer as described above with the exception that the temperature was elevated at 2C per minute until the temperature of the formulation reached 70 whereon the temperature was held at 70C for a two hour dwell. The viscosity of the formulation remained unchanged during this dwell time. Upon raising the temperature, the characteristic Td was seen and the viscosity of the formulation increased.

Example 6 Illustrating control of dissolution temperature by control of the surface area of the thermoplastic particle.
Particles of PEI were prepared to have surEace areas, as shown in Table IV, of about 1.0 to 9.0 square meters per gram as determined by BET ((~runauer, ~mmett, and Teller), surface areas obtained on a Quantasorb BET~M
Surace Analyzer (manufactured by Quantachrome, Co.)) surface analysis. Compositions of each were prepared by mixing 4.65 parts of the particles in 50 parts of PR-500 epoxy resin at 60C as described in Example 3 and their viscosity profiles were determined by RDA-700. The dissolution temperature, Td, of each composition is given in Table IV.

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TABLE IV
Surface Dissolution CompositionArea (m2/g)Temp. (C) R 1.01 127 S 2.65 114 T 2.73 108 U 3.60 107 V 4.73 95 W 8.~8 9Z

From Table IV, it is to be observed that for the thermoplastic polyetherimide, PEI, that by control of the surface area rom about 1.0 to 9.0, the dissolution temperature of the composition was controlled from 127 to 92C.

Example 7 ( comparative) The viscosity profile of a 10.0 weight %
composition of the particulate thermoplastic polyimide, DurimidT~I (available from Rogers CorportionJ in PR-500 epoxy resin was obtained by RDA-700. No dissolution temperature was observed; the composition therefore, illustrated a thermosettable compositon not included in the invention.
Example 8 (comparative) A thermosettable composition of 50 parts of PR-500 epoxy resin and 5.56 parts of conventionally ground polyetherimide thermoplastic resin, having a surface area of 0.3 m2/g, was prepared as described above and its viscosity profile obtained. No dissolution temperature was observed,~ the viscosity continued to drop with increasing temperature up to onset of polymerization of the epoxy resin. Prepregs prepared~of t~his composition possessed voids and discontinuities similar to that of epoxy resin without the modifying thermoplastic.

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~: ' ' . ' . ' , Three thermosettable compasitions, X, Y, and Z
of PR-500 epoxy resin and polyetherimide ( PEI) partlcle having a surface area of 4 . 73 m2 /g were prepared by mixing the components at 60C using an air stirrer. Compositions X, Y, and z contained 2.63 parts (5.0%), 4.65 parts (8.5%), and 5.56 parts (10.0%) of PEI, respectively, in 50 parts of PR-500 epoxy resin. Viscosity profile of each composition was obtained and the minimum viscoslty observed to be 3.5 poise, 10.35 poise, and 21.22 poise respectively. This illustrated the control of viscosity that was important during the early stages of a processing operation, e.g., prepreg fabrication, that was obtained using compositions of the invention.

ExampIe 10 -A thermosettable resin composition was prepared by mixing 91.5 parts of PR-500 epoxy resin and 8. 5 parts of particulate polyetherimide having a surface area of 5.37 m2/g. The mixing was performed in a planetary mixer at 35C under vacuum. The resin composition was further processed into a resin film approximately 66 micrometers thick. The film was laminated with continuous carbon fibers (IM7 fibers ~lercules Co.) using a conventional 30 cm wide prepregging machine (available ~rom California Graphite Machines, Inc.). Sixteen plies of prepreg made by this process were layed-up and cured by a conventional autoclave cycle, to form a void free composite panel having a glass transition temprature of 205C, useful as a structural component in a machine.
When the procedure of Example 10 was repeated using prepreg that had not been modified with particulate thermoplastic resin, the panel obtained had many voids due to excessive resin flow.

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EX ample 11 Illustrating the control of the dissolution temperture by plasticizing the thermoplastic particle Plasticized polyetherimide thermoplastic particles (PEI/DGF) were prepared by dissolving 90 parts PEI and 10 parts by weight of bist4-(2,3-epoxypropoxy1-phenyl]fluorene in 300 parts of dichloromethane, emulsifying in water and coagulating by pouring into methanol. Particles having an average diameter of 3 micrometers and a surface area of 5.40 m2/g were obtained.
Into 50 g of PR-500 epoxy resin at 60C were dispersed 4.65g of these particles and the viscosity profi].e of the mixture was obtained. A dissolution temperature of 95C
as compared to 106C for the unplasticized polyetherimide particles (Example 3) was obtained.

Example 12 Formulations AA, BB, and CC were prepared, each to contain 50 parts of epoxy resin mixture of 35~
bis[4-(2,3-epoxyproproxy)phenyl]fluorene (DGF) and 65~ of diglycidyl ether of bisphenol A (DGEBA) and 4.65 parts, respectively, of polysulfone (PS), PEI/DGF (the epoxy plasticized polyetherimide described in Example 11), and polyetherimide PEI (the polyetherimide as used in Example 3) by mixing at 60C using an air stirrer. An RDA lO0 viscosity profile o each was obtained, each including a dwell period at a temperature about 15C below the dissolution temperature. Table V shows the dissolution temperature, the dwell temperature, and the viscosity at the beginning and end of the two hour dwell time.

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TABLE V
Td Temp, (C) Viscosity (poise) Formulation(C) of Dwell Initial Final AA 86 70 10.8 11.0 5~B 95 80 4.3 4.5 CC 106 90 2.8 2.8 The data of Table V show that for compositions of the invention of a thermosettable resin and particles of thermoplastic having a dissolution temprature of 86, 95, and 106C, respectively, can be held at a temperature about 15C below the dissolution temperature for at least two hours without an appreciable change in the viscosity of the composition.

Example 13 (comparative) A thermosetta~le composition of PR-500, an aromatic epoxy resin available from 3M, and 8.5~ by weight of polybenzimidazole (PBI) particle was prepared by mixing 4.65 parts of ultrafine PBI (Celanese Corporation) having 20 a surface area of 12.3 m2/g with 50 parts of PR-500 at 60C using an air stirrer. The viscosity profile for this composition showed no evidence of dissolution of PBI. The profile is essentially the same as that obtained for an unmodified PR-500 composition.

Various modifications and alterations of this inven~ion will become apparent to those skilled in the art without departing from the scope of the invention.

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Claims (34)

1. A thermosettable resin composition comprising:
a) a thermosettable mixture that is liquid at a temperature in the range of 20 to 100°C
comprising one or more thermosettable resins and one or more of curatives, hardeners, and catalysts for the thermosettable resins and b) resin particles of one or more amorphous thermoplastic polymers, the particles having a dissolution temperature of 50°C or higher and being essentially insoluble in the thermosettable resin at temperatures up to 15°C below the dissolution temperature;
said resin composition having a viscosity that decreases with increasing temperature up to a dissolution temperature and that increases with increasing temperatures at temperatures above the dissolution temperature.

2. The composition according to claim 1 wherein said thermosettable resin is at least one of aromatic epoxy, cycloaliphatic epoxy, N,N'-bismaleimide, and polycyanate monomers and prepolymers.

3. The composition according to claim 1 wherein said resin particles are at least one of polyesters, polyethers, polycarbonates, polyamides, polyimides, polyetherimides, and polyamideimides, polyarylates, polysulfones, polyarylsulfones, and polyethersulfones.

4. The composition according to claim 1 wherein said resin particles are polyetherimide.

5. The composition according to claim 1 wherein said resin particles have an average diameter in the range of 0.5 to 50 micrometers.

6. The composition according to claim 1 wherein said resin particles have a surface area of at least 0.5 m2/g.

7. The composition according to claim 6 wherein the particle is prepared by spray drying or by coagulation.

8. The composition according to claim 2 wherein said thermosettable resin is an aromatic epoxy selected from the group consisting of glycidyl ethers of polyhydric phenols and polyglycidyl derivatives of aromatic amines.

9. The composition according to claim 1 wherein said curative is an amine, an amide, an organic acid or anhydride, or a polyphenol.

10. The composition of claim 1 wherein said catalyst is selected from organometallic compounds or salts, Lewis acids or bases, imidazoles, tertiary amines, and complexed Lewis acids.

11. The composition according to claim 2 wherein said N,N'-bismaleimide has the formula I

wherein Y represents an alkylene group of at least 2 carbon atoms, and Z is a divalent organic group containing at least 2 carbon atoms.

12. The composition according to claim 11 wherein Z is an aliphatic, cycloaliphatic, aromatic or heterocyclic group, these groups optionally having up to two of each of sulfur and non-peroxidic oxygen atoms.

13. The composition according to claim 11 wherein Y comprises 2 to 6 carbon atoms.

14. The composition according to claim 9 wherein said curative is a diamine.

15. The composition according to claim 1 further comprising a diunsaturated cross-linking agent.

16. The composition according to claim 2 wherein said polycyanate monomer has the formula N ? CO-R-OC ? N

wherein R is a divalent aromatic hydrocarbon residue and comprises at least one aromatic moiety, i.e., aromatic ring including benzene, naphthalene, anthracene, phenanthrene and the like, and where R contains a total of up to 40 carbon atoms, including the aromatic moiety.

17. The composition according to claim 16 wherein R of said polycyanate is substituted by at least one group inert in the polycyclotrimerization process of said dicyanate.

18. The composition according to claim 16 wherein R of said polycyanate is selected from the group consisting of , , , , , and

19. The composition according to claim 1 wherein said resin particles further comprise an effective amount of a plasticizer.

20. The composition according to claim 19 wherein said plasticizer is an epoxy, amine, or cyanate compound.

21. The composition according to claim 1 wherein said resin particles comprise 2 to 50 parts per 100 parts of thermosettable mixture.

22. The composition according to claim 1 wherein said resin particles comprise 2 to 30 parts per 100 parts of thermosettable mixture.

23. The composition according to claim 20 wherein said plasticizer is present in an amount of 5 to 50 parts per 100 parts of said resin particles.

24. The composition according to claim 1 further comprising an effective amount of at least one of inert fillers, tougheners, whiskers, pigments, dyes, and flame retardants.

25. The composition according to claim 24 wherein said filler is selected from the group consisting of fibers, powders, and solid microspheres.

26. A prepreg comprising reinforcing filaments and the composition according to claim 1.

27. A prepreg comprising reinforcing filaments and the composition according to claim 4.

28. A composition of matter comprising the composition according to claim 1 and incorporated therein at least one of fillers, tougheners, whiskers, pigments, chopped fibers, fabrics, inorganic powders, and solid microspheres.

29. The prepreg according to claim 26 wherein said reinforcing fibers are selected from the group consisting of organic and inorganic fibers.

30. The prepreg according to claim 29 wherein said fibers are selected from the group consisting of glass fibers, carbon or graphite fibers, ceramic fibers, silicon carbide fibers, and polyaramide fibers.

31. The prepreg according to claim 29 wherein said fibers are in the form of a woven or nonwoven web.

32. An article comprising a woven or nonwoven web, film, or foil coated with the composition according to claim 1.

33. An article comprising a polyimide film coated with the composition according to claim 1.

34. An article comprising a polyimide film coated with the composition according to claim 4.