Epoxide advancement

This invention relates to a process for preparing sterically stabilised dispersions of epoxy resin particles in a non-polar organic liquid carrier.
Known processes for producing non-aqueous dispersions of epoxy resins involve simple dispersion of the epoxy resin in a non-aqueous medium in the presence of a suitable stabiliser. An example of such a process is described in British Patent No. 1 458 607. Commonly the epoxy resins are prepared by a process of epoxide advancement. In epoxide advancement suitable epoxides of low epoxy equivalent weight are reacted with difunctional materials such as diols and this reaction results in epoxy resins of higher epoxy equivalent weight. Such a two stage process of an advancement step followed by a dispersion step is described in U.S. Pat. No. 4,579,887. In practice, it is found that such a two stage process is very cumbersome. This is particularly so as the higher epoxy equivalent weight epoxides are commonly highly viscous or solid at ambient temperatures and must be heated to high temperatures to allow the dispersion to be made. The dispersion step then usually either comprises feeding the continuous phase into the hot viscous epoxide melt or more commonly pumping the hot epoxide into the continuous phase. We have now found that it is possible to greatly simplify this former two stage process.
According to the present invention, there is provided a process for preparing a sterically stabilised non-aqueous dispersion of a polyepoxide of epoxy equivalent weight in the range 350 to infinity, which comprises reacting a sterically stabilised non aqueous dispersion of a compound with at least two epoxy groups with a diol of formula 1:
HOBOH (1)
in which B is a group of formula (2) ##STR3## where D is a methylene group or propane-2,2-diyl.
By `polyepoxide` is meant a polymeric material which is derived in part from an epoxy functional starting material. It will be readily appreciated that the polyepoxide may be either epoxy terminated or aromatic hydroxyl terminated depending on the relative proportions of the diol of formula (1) and the compound with at least two epoxy groups used in the process. An excess of epoxide will result in a predominantly epoxy functional polyepoxide and an excess of diol will result in a predominantly hydroxy functional polyepoxide.
Referring to the diol of formula (1), B is preferably a group of formula (2) where D is propane-2,2-diyl. Diols of formula (1) are available commercially. Those where D is propane-2,2-diyl are known as bisphenol A or diphenylol propane (DPP). Those where D is methylene are known as bisphenol F, or diphenylol methane (DPM).
Minor proportions of the diol of formula (1) may be replaced by other difunctional compounds which will react with epoxy groups. Such difunctional compounds may for example, be added to improve the physical properties such as flexibility of films or blocks formed from the compositions by later removal of the continuous phase.
Examples of this are the improvements in flexibility obtained by the replacement of some of the diol with flexibilisers such as adipic acid or dimerised fatty acid.
An example of one class of polyepoxide which may be prepared by the process of the invention are those which are prepared by reacting an epoxy novolac compound with a diol of formula (1). Epoxy novolacs may be approximated as a phenol novolac resin containing groups such as those given in formula (3). ##STR4## An example of a preferred class of polyepoxide which may be prepared by the process of the invention are those of formula (4);
A.sup.1 OBO[A.sup.2 OBO].sub.a A.sup.1 ( 4)
where a is a number such that the epoxy equivalent weight is in the range 350 to infinity, and B is a group of formula (2). Polyepoxides of formula (4) are prepared by reacting a diol of formula (1) with a compound with two epoxy groups.
One example of a class of compounds with two epoxy groups useful in the process of the invention to give dispersions of polyepoxide of formula (4) are those of formula (5). ##STR5## in which n is from 1 to 4. Use of a compound of formula (5) in the process of the invention gives rise to dispersions of formula (4) in which A.sup.1 is hydrogen or a group of formula (6). ##STR6## in which n is as defined in formula (5), and A.sup.2 is a group of formula (7). ##STR7## in which n is as defined in formula (5).
A further example of a compound with two epoxy groups useful in the process of the invention to give dispersions of polyepoxide of formula (4) is a compound of formula (8). ##STR8## Use of a compound of formula (8) is the process of the invention gives rise to dispersions of formula (4) in which A.sup.1 is hydrogen or a group of formula (9). ##STR9## and A.sup.2 is a group of formula (10) ##STR10##
An example of a preferred class of compounds with two epoxy groups useful in the process of the invention to give dispersions of polyepoxide of formula (4) are those of formula (11). ##STR11## where D is as defined with reference to formula (2) and b is from 0 to 2. Using compounds of formula (11) gives rise to dispersions of formula (4) in which A.sup.1 is hydrogen or a group of formula (12); ##STR12## where D and b are as defined with reference to formula (11), and in which A.sup.2 is a group of formula (13). ##STR13## where D and b are as defined with reference to formula (11). It will of course be appreciated that formulas (11), (12) and (13) are idealised structural formulae.
In practice the epoxy equivalent weight is 350 to 500,000, more particularly 350 to 250,000 or 350 to 5,000 or 350 to 15,000.
It will be understood by those skilled in the Art that where the polyepoxide product is predominantly aromatic hydroxy terminated it will have a very large epoxy equivalent weight.
Epoxy novolacs containing groups of approximate formula (3) may be made by the reaction of a novolac resin with epichlorohydrin. Epoxy novolacs of this type are commercially available from Ciba Giegy Chemicals as XPY 307 or EPN 1139 or from Dow Chemicals as DEN 438.
Referring to the diepoxides of formula (5) n is preferably 4. A diepoxide of formula (5) in which n is 4 is available as ERL 4299 from Ciba Giegy Chemicals.
A diepoxide of formula (8) is available as Diepoxide 133 from Degussa Chemicals.
Referring to the epoxide (11), D is preferably propane-2,2-diyl. Values for b can be 0, 1 or 2 or a fractional value.
The epoxides of formula (11) are commercially available and are supplied as mixtures with slight impurities so the value for b can be a fraction.
In particular, b is 0.1.
Examples of epoxides of Formula (11) which can be used in the process of this invention are: Epikote 828 where D is propane-2,2-diyl and b is 0.1 GY 250 or DER 330 or DER 333 where D is propane-2,2-diyl and b is 0.1.
Epikote is a Registered Trade Mark and Epikote resins are available from Shell Chemicals. GY250 is available from Ciba-Giegy. DER 330 or DER 333 are from Dow Chemicals.
It will be understood that all of these epoxide functional compounds are technical grade materials subject to minor variations in structure and in the level of impurities.
The epoxides reacts with the diol in a sterically stabilised dispersion. The dispersion is maintained by a steric stabilising agent. A steric stabilising agent is a compound in which the molecule is essentially amphipathic. That is, it has chain-like part which associates with the epoxide to be dispersed (this is referred to as an anchor component) and another chain-like part which associates with the liquid (this is referred to solvated component).
For example, the stabiliser can have an anchor component based on an acrylate polymer. Suitable acrylate polymers are homopolymers and co-polymers of acrylic acid esters (for example polymethyl methacrylate, polyethyl methacrylate, polymethyl acrylate, polymethyl methacrylate, co-ethyl methacrylate polyethyl acrylate) and co-polymers of acrylate esters and acrylic and methacrylic acid. In such co-polymers, acrylic acid or methacrylic acid derived units make up no more than 10% by weight of the co-polymer. There may also be present minor proportions of itaconic acid, crotonic acid maleic acid or alkyl esters of those acids.
The solvated component can be a poly C.sub.6-18 alkyl acrylic ester for example poly-2-ethyl hexyl acrylate, a polyester, for example poly-12-hydroxy stearic acid or a hydrocarbon, for example polybutadiene or degraded natural rubber.
Preferably the stabiliser is one where the anchor component is a co-polymer of methyl methacrylate and acrylic acid or methacrylic acid. Preferably the stabiliser is one where the solvated component is derived from polybutadiene.
The stabilisers can be made by standard methods. For example, where the anchor component is an acrylate polymer and the solvated component is poly-12-hydroxy stearic acid, the stabiliser can be prepared by co-polymerising the reaction product of glycidyl(meth)acrylate and poly-12-hydroxystearic acid and the acrylate monomers. Where the anchor component is an acrylate polymer and the solvated component is a hydrocarbon or a poly C.sub.6-18 alkyl acrylic ester the stabiliser can be made by a hydrogen abstraction reaction.
The liquid carrier for the dispersion is a non-polar organic liquid. It can be in particular an aliphatic hydrocarbon. The hydrocarbon can contain up to 30% by weight of other solvents for example, aromatic hydrocarbons and esters.
Preferably, the liquid carrier is a medium to high boiling aliphatic hydrocarbon particularly a hydrocarbon having a boiling point in the range 130.degree.-350.degree. C.
The process is preferably carried out in the presence of a base catalyst. Examples of suitable catalysts are alkali metal carbonates for example sodium carbonate and potassium carbonate, alkali metal hydroxides, for example, sodium hydroxide and potassium hydroxide, quaternary ammonium salts and triaryl alkyl phosphonium salts for example, triphenyl ethyl phosphonium iodide and triphenyl ethyl phosphonium acetate.
Preferably the catalyst is triphenyl ethyl phosphonium iodide.
The sterically stabilised non aqueous dispersion of the compound with at least two epoxy groups may be produced by stirring the compound in the non-aqueous medium in the presence of the stabiliser.
The process may be carried out by slowly adding the diol of formula (1) to a preformed sterically stabilised dispersion of the compound with at least two epoxy groups at a suitable temperature so as to cause the components to react.
Preferably the process may be carried out by firstly mixing the diol of formula (1) with the compound with two epoxy groups and any catalyst for the reaction, subsequently forming a non aqueous dispersion of the mixture in the presence of a steric stabiliser and finally heating the dispersion to cause the components to react.
The reaction may be conveniently carried out at temperatures between 120.degree. and 250.degree. C.
Generally the components are heated for between one and four hours.
Certain dispersions of polyepoxides produced according to the process are novel. Accordingly, the invention also provides a sterically stabilised non-aqueous dispersion of a polyepoxide as previously defined where the dispersion is maintained by a steric stabiliser in which the solvated component is derived from polybutadiene.
It has been found that films cast upon metal substrates from dispersions in which such a preferred stabiliser is used and which are subsequently dried by heating exhibit improved adhesion to the substrate.
Preferably these dispersions have a solids content of at least 60%.
The dispersion produced by the process may be applied by standard methods to suitable substrates.
The present invention also provides a coating process which comprises applying a film of a dispersion as described above and removing the continuous phase by evaporation.
Examples of suitable application methods include spraying, brushing dipping or rollercoating.
After application the continuous phase is conveniently removed by heating to between 100.degree. and 200.degree. C. for between 1 and 10 minutes.
The present invention also provides a coated article which has been coated according to the above coating process.
The dispersions produced by the process of this invention can be formulated by standard methods so as to produce coating compositions. They are particularly suitable for can coatings.

The following Examples illustrate the invention.
EXAMPLES
EXAMPLE 1
1.1 Poly-12-hydroxystearic acid
A mixture of 12-hydroxystearic acid (847.61 g), toluene (150.69 g), and methane sulphonic acid (1.70 g) was heated to between 140.degree.-150.degree. C. Water was removed azeotropically and was replace during its removal by an equal volume of toluene. Water removal was continued from 6 to 7 hours until the acid value was between 32 and 34 mg g.sup.-1.
The product obtained was a solution of poly-12-hydroxystearic acid in toluene of solids Content 81%.
1.2 Poly-12-hydroxystearic Acid: Glycidyl Methacrylate Adduct
A mixture was made up of the following reagents:
______________________________________poly-12-hydroxystearic acid solution 565.19 g(81% in toluene)Hydrosol 130-160.degree. C.; <5% 21.29 gglycidylmethacrylate 51.63 gArmeen DMCD 1.92 ghydroquinone 0.67 gHydrosol 130-160.degree. C.; <5% 359.30 g______________________________________
(Armeen DMCD is dimethyl "coconut fatty amine")
(Hydrosol 130.degree.-160.degree. C. <5% is an aliphatic hydrocarbon mixture containing less than 5% of aromatic hydrocarbon available from Hydrocarbures St Denis, France).
The mixture as described above was heated to reflux (140.degree.-150.degree. C.) for 6 hours until an acid value of 1 mg g.sup.-1 was obtained. Further amounts (0.67 g each) of Armeen DMCD were added to the refluxing mixture after 3 and 4 hours of reflux. The product was a solution of adduct of 50% solids content.
1.3 Poly-12-hydroxystearic Acid Based Dispersant
The following mixture of reagents was made up:
______________________________________methyl methacrylate 190.05 gacrylic acid 10.00 gazodiisobutyronitrile 3.96 gpoly-12-hydroxystearic acid- 395.90 gglycidyl methacrylate adduct______________________________________
The reaction mixture as described above was added over 3 hours to a mixture of butyl acetate (133.37 g) and ethyl acetate (266.72 g) at reflux temperature. When the addition had been completed, heating was continued. After 30 minutes a portion of azodiisobutyronitrile slurry in ethyl acetate (1 g in 1.5 g) was added to the reaction mixture. After a further 30 minutes another portion of azodiisobutyronitrile slurry in ethyl acetate (1 g in 1.5 g) was added.
Following the addition of the second portion of azodiisobutyronitrile, part of the solvent (140 g) was removed by distillation and replaced by Hydrosol 130.degree.-160.degree. C.<5% (140 g). A further portion (140 g) of solvent was removed by distillation and replaced by a further portion (140 g) of Hydrosol 130.degree.-160.degree. C.<5%.
1.4 Epoxide Diol Reaction
A mixture of epoxide GY250 (343.35 g), diphenylol propane (201.23 g), triphenyl ethyl phosphonium iodide (1.09 g) and dispersant prepared as described in paragraph 1.3 above (136.41 g) in high boiling aliphatic solvent b.p. 270.degree.-310.degree. C. (317.92 g) was heated with stirring. The temperature of the reaction mixture was maintained at between 170.degree.-180.degree. C. for 2 hours. The mixture was allowed to cool to produce a dispersion having a 60% solids content of particle size 0.5 .mu.m, viscosity of 0.07 Pas and epoxy equivalent weight of 6,200.
EXAMPLE 2
2.1 Poly-2-Ethylhexyl Acrylate
A mixture of ethyl acetate (297.92 g), 2-ethylhexyl acrylate (198.60 g) and azodiisobutyronitrile (1.99 g) were mixed and heated to reflux temperature. After 15 minutes at reflux temperature a further mixture of 2-ethylhexyl acrylate (496.52 g) and azodiisobutyronitrile (4.97 g) was added dropwise over 1.5 hours. Heating under reflux was continued for a further 1 hour and the product was diluted with ethyl acetate to produce a solution of poly-2-ethylhexyl acrylate in ethyl acetate having a 65% solids content and viscosity of 0.9-1.1 Pas.
2.2 Poly-2-Ethylhexyl Acrylate: Methyl Methacrylate: Acrylic Acid Dispersant
______________________________________Charge 1Poly-2-ethylhexyl acrylate 283.00 g(70% in ethyl acetate)Ethyl acetate 85.08 gBenzoyl peroxide 2.66 gCharge 2Methyl methacrylate 188.13 gAcrylic acid 9.91 gBenzoyl peroxide 7.96 g______________________________________
Charge 1 was made up and heated to reflux temperature for 0.5 hours. Charge 2 was then added at reflux temperature to charge 1 over 1.5 hours. The product so obtained was diluted first to 60% solids by addition of ethyl acetate (88.83 g) and then to 50% solids by addition of a further portion (132.00 g) of ethyl acetate. Heating at reflux temperature was continued and after a further 0.25 hours the solution was diluted to 45% solids by the addition of a further portion of ethyl acetate (88.65 g).
Heating at reflux temperature was continued and two portions of t-butyl per-2-ethylhexanoate (0.99 g) were added to the reaction mixture after 0.5 hourly intervals.
The reaction mixture was diluted with a further portion of ethyl acetate (110.81 g). Heating at reflux temperate was continued for 0.5 hours and a third portion of t-butyl per-2-ethylhexanoate (0.99 g) was added to the reaction mixture. The solvent was then changed from ethyl acetate to a white spirit and ethyl acetate mixture by distilling off portions of ethyl acetate and replacing the volume distilled with an equal volume of white spirit.
The stabiliser so produced can be used in the method of Example 1.4 to prepare a dispersion of epoxy resin.
EXAMPLE 3
3.1 Polybutadiene Methyl Methacrylate/Acrylic Acid Dispersant
______________________________________Charge 1Toluene 593.08 gPolybutadiene (Lithene N4 5000) 199.47 gCharge 2Methyl methacrylate 189.50 gAcrylic acid 9.97 gBenzoyl peroxide 5.32 g______________________________________ (`Lithene` is a Trademark of Revertex)
Charge 2 was added over 1.5 hours to Charge 1 while Charge 1 was held at reflux temperature. Heating was continued for a further 1.5 hours and two portions (1.33 g) of t-butyl peroctoate were added one each after two 0.5 hour intervals. The solution if allowed to cool produced a clear solution of resin having a viscosity of 70 poise.
The solvent was then changed by portionwise distillation of toluene and addition of white spirit, to give a solvent mixture having equal proportions of toluene and white spirit.
The stabiliser so produced can be used in the method of Example 1.4 to prepare a dispersion of epoxy resin.
EXAMPLE 4
4.1 Polybutadiene Methyl Methacrylate/Methacrylic Acid Dispersant
______________________________________Charge 1Toluene 396.14Polybutadiene (Lithene N4 5000) 199.74White Spirit 197.74Charge 2Methyl Methacrylate 187.74Methacrylic acid 11.98Lucidol P 25 (Benzoyl peroxide 5.33containing 25%water)Trigonox 21B 70 (tert butyl per 1.332-ethyl hexanoate)______________________________________
Charge 2 was added over 1.5 hours to charge 1 at 120.degree.-125.degree. C., reflux temperature. After a further 0.5 hours the Trigonox was added, and heating was continued for a further hour. Solvent (99.1 parts) was removed by distillation and replaced by an equal volume of white spirit.
The product was opalescent with a viscosity of 0.5 to 1.0 Pas and a measured solid content of 37%.
4.2 Epoxide Dispersion
Liquid Epoxy (GY 250 from Ciba Chemicals: 372.5 parts), diphenylol propane (DPP) (218.31 parts), triphenol ethyl phosphonium iodide (1.19 parts), dispersant from Example 4.1 (147.98 parts), and Hydrosol PW2H (predominantly aliphatic solvent from Hydrocarbures St Denis France: 188.59 parts) were charged to a flask fitted with a separator and heated with stirring to 160.degree. C. There was an initial exotherm to 180.degree.-190.degree. C. and the mixture was then maintained at 170.degree.-175.degree. C. The mixture was maintained at 170.degree.-175.degree. C. and after 55 minutes further Hydrosol PW2H (71.43 parts) was added. The mixture was maintained at 170.degree.-175.degree. C. for 1 hour and then allowed to cool to room temperature. The cooled mixture was filtered through a 50 micron nylon mesh. The epoxy equivalent weight was 6467 and the dispersion had a viscosity of 0.18 Pas seconds, and a solid content of 65%.
EXAMPLES 5 TO 9
Dispersions were made by the method of Example 4.2 replacing the Hydrosol PW2H non-aqueous carrier with various other organic liquids. These liquids together with the characteristics of the dispersions obtained are shown in Table 1 below (`Hydrosol` solvents are available from Hydorcarbures St Denis, France, `Exxsol` `Isopar` and `Norpar` solvents are available from Exxon Chemicals)
TABLE 1______________________________________SOLVENT VARIANTS DISPERSION CARRIER BP NON-EX. LIQUID .degree.C. TYPE VOL. Pas EEW______________________________________4.2 Hydrosol 270- 57% Alkanes 65% 0.18 6467 PW2H 310 40% Cyclo Alkane 3% Aromatic5 Exxsol 240- Dearomatised 65% 0.24 6334 D 240-270 2706 Exxsol 280- Dearomatised 65% 0.30 6738 D 280-310 3107 Isopar M 205- Isoparaffin 65% 0.11 6712 2558 Isopar V 278- Isoparaffin 65% 0.35 6915 3059 Norpar 15 252- Linear 65% 0.115 6760 277 paraffin______________________________________
EXAMPLES 10-20
Dispersions were made according to the method of Example 4.2 but replacing the GY250 liquid epoxy with various other epoxy functional compounds, with the replacement of the DPP diol with several different diol compounds, and with slight variations in iodide catalyst, dispersant, and solvent weights. These are listed in Table 2 together with the properties of the resulting dispersions.
In Table 2:
ERL 4299 is a compound approximated by formula (5) of epoxy equivalent weight 202, available from Ciba Geigy Chemicals.
XPY 306 is a Compound approximated by formula (11) in which D is methylene, of epoxy equivalent weight 156 g from Ciba Geigy.
XPY 307 is an epoxy novolac resin of epoxy equivalent weight 178 g from Ciba Geigy Chemicals.
EPN1139 is an epoxy novolac resin of epoxy equivalent weight 136 g from Ciba Geigy Chemicals.
DEN 438 is an epoxy novolac resin of epoxy equivalent weight 155 g from Dow Chemicals.
DER 330 is a compound approximated by formula (11) of epoxy equivalent weight 174 g from Dow Chemicals.
DER 333 is an epoxide functional compound of approximate formula (11) of epoxy equivalent weight 185 g available from Dow Chemicals, and which already contains a catalyst believed to be triphenyl ethyl phosphonium acetate.
Degussa Diepoxide 133 is a diepoxide compound of formula (8) from Degussa Chemicals of epoxy equivalent weight 133.
DPM is diphenylol methane, a diol of formula (1) in which D is methylene.
LMB 4337 is crude DPM from Ciba Geigy.
DPP is diphenylol propane, a diol of formula (1) in which D is a 2,2-propylene group.
TABLE 2__________________________________________________________________________ DISPERSANT SOLVT NVC EPOXY DIOL CAT. WT PW2H VIS-EX. (WT) (WT) WT TPEPI (WTS) CO EEW__________________________________________________________________________10 GY 250 DPM 1.17 g 154,38 g 184.78 + 65% 6887 (388.57 g) (CIBA) 71.42 0.24 199.68 g11 ERL 4299 DPP 1.11 g 138.27 g 194.42 + 65% 4122 (EEW 202) 203.98 g 71.6 0.152 390.58 g Pas12 XPY 306 DPP 1.2 g 159.41 g 181.25 + 65% 6041 351.65 g 235.10 g 0.20 71.4 g Pas13 XPY 307 DPP 1.19 g 148 g 188.59 + 65% 4996 372.5 g 218.31 g 0.24 71.4 g Pas14 EPN 1139 DPP 1.19 g 148 g 188.59 + 65% 4670 372.5 g 218.3 g 71.4 g 0.192 Pas15 DEN 438 DPP 1.19 g 148 g 188.59 + 65% 5316 372.5 g 218.3 g 71.49 g 0.192 Pas16 DER 330 DPP 1.19 g 148 g 188.59 + 65% 5020 372.5 g 218.3 g 71.4 0.33 Pas17 DER 330 DPP 1.19 g 148 g 188.59 + 65% 7988 365.55 g 225.26 g 71.4 g 0.25 Pas18 DER 333 DPP 1.19 g 148 g 188.59 + 65% 3772 372.5 g 218.3 g 71.4 g 0.32 Pas19 Degussa DPP 1.25 g 169.36 g 164.45 + 62% 2616 Diepoxide 249.85 g 107.16 0.23 133 Pas 307.93 g20 XPY 306 DPM 1.16 g 166.80 176.79 + 65% 5565 368.0 (LMB 4337) 71.4 g 0.07 215.8 Pas__________________________________________________________________________
EXAMPLES 21 TO 31
Dispersions with various ratios of epoxy compound to diol compound
Various epoxy dispersions were made by the process of Example 1.4 using the following ingredients:
______________________________________GY250 Epoxy + Diphenylolpropane (DPP) diol 544.56 gTPEPI Catalyst 1.09 gPHSA dispersant from Example 1.3 136.41 gHydrosol PW2H Solvent 317.94 g______________________________________
(GY250 is from Ciba Chemicals)
(TPEPI is triphenyl ethyl phosphonium iodide)
The total weight of epoxy and diol compound was kept constant while varying the ratio between the two. The ratios used and the properties of the dispersions obtained are given in Table 3 below:
TABLE 3______________________________________Ratios of Epoxy to diol NVCTo give 544.56 g Theoretical EEW ViscoEX. WT GY250 WT DPP EEW Found Pas______________________________________21 422.28 122.26 450 550 60% 0.0722 378.90 165.66 915 1182 60% 0.072 Pas23 355.58 188.98 2060 2663 60% 0.072 Pas24 349.71 194.85 3000 3660 60% 0.072 Pas25 346.57 197.99 4000 4673 60% 0.072 Pas26 344.63 199.95 5000 5482 60% 0.072 Pas27 343.35 201.23 6000 6194 60% 0.072 Pas28 342.43 202.15 7000 6570 60% 0.072 Pas29 340.79 203.79 10000 9578 60% 0.072 Pas30 338.87 205.71 20000 11570 60% 0.072 Pas31 336.95 207.64 INFINITY 14941 60% 0.072 Pas______________________________________
EXAMPLE 32 TO 42
Ratios of Epoxy Compound to Diol Compound
32.1 to 42.1 Polybutadiene Dispersant
Methyl methacrylate (187.5 parts), methacrylic acid (11.97 parts) and Lucidol P25 (5.23 parts) were added to a mixture of Lithene N 4500 (199.47 parts) and toluene (593.17 parts) at reflux over 1.5 hours. The mixture was held at reflux for 0.5 hours and Trigonox 21B 70 (1.33 parts) was added. The mixture was heated for 0.5 hours and more Trigonox 21B 70 (1.33 parts) was added. The mixture was held at reflux for a further 0.5 hours and about half the toluene was removed by distillation and replaced by white spirit. The resulting product had a solid content of 40% and a viscosity of approximately 10 Pas.
32 to 42 Epoxy Dispersions
Epoxy dispersions were made using the method of 4.2 and the following ingredients:
______________________________________GY250 epoxy + diphenylol propane 590.91TPEPI Catalyst 1.19Polybutadiene dispersant 147.98from Example 32.1 to 42.1Hydrosol PW2H solvent 188.59 + 71.43______________________________________
The total weight of epoxy compound and diol compound was kept constant and the ratio between the two was varied the various weights of these together with properties of the dispersions obtained are shown in Table 4.
TABLE 4______________________________________Ratios of Epoxy to Diol NVCTo give 590.81 Theoretical EEW ViscoEX. WT GY250 WT DPP EEW Found Pas______________________________________32 411.08 179.73 915 1145 65% 0.224 Pas33 385.78 205.03 2060 2643 65% 0.223 Pas34 379.42 211.39 3000 4173 65% 0.223 Pas35 376.00 214.81 4000 5065 65% 0.253 Pas36 373.90 216.91 5000 5917 65% 0.235 Pas37 372.50 218.31 6000 6630 65% 0.186 Pas38 371.50 219.31 7000 7184 65% 0.258 Pas39 370.76 220.05 8000 8014 65% 0.230 Pas40 369.71 221.10 10000 7953 65% 0.224 Pas41 367.62 223.9 20000 9986 65% 0.186 Pas42 365.56 225.25 INFINITY 11348 65% 0.152 Pas______________________________________
EXAMPLE 43
Dispersions Using an Acid Free Dispersant
43.1 The Dispersant
Methylmethacrylate (177.47 parts) and Lucidol P25 (4.73 parts) were added to a mixture of Lithene N4 5000 (221.54 parts) and toluene (593.85 parts) at reflux temperature over 1.5 hours. The mixture was held at reflux temperature for a further 30 minutes and Trigonox 21B70 (1.18 parts) was added. The mixture was held at reflux ratio 0.5 hours and more Trigonox 21B70 (1.18 parts) was added. The mixture was held at reflux temperature for a further 0.5 hours and half of the toluene was then removed by distillation and replaced by white spirit (296 parts). The resulting dispersant was jelly like and had a solid Content of 37%.
43.2 Epoxy Dispersion
GY250 liquid epoxy (372.5 parts), DPP diol (218.30 parts), triphenyl ethyl phosphonium iodide catalyst (1.19 parts), dispersant from example 43.1 (147.99 parts) and Hydrosol PW2H solvent (188.59 parts) were heated to 160.degree. C. with stirring. The temperature rose by exotherm to 175.degree.-185.degree. C., and the time at which it reached 170.degree. C. was taken as time 0. 55 minutes after this time Hydrosol PW2H (71.43 parts) was added. The mixture was held at 170.degree. C. for a further 1 hour and 5 minutes and allowed to cool. The product was a milky dispersion with a solids content of 65%, a viscosity of 0.25 Pas, and an epoxy equivalent weight of 5900.
EXAMPLE 44
Dispersions of Non-epoxy Functional Polymer
GY 250 liquid epoxy (343.26 parts), DPP diol (307.50 parts), TPEPI Catalyst (1.31 parts), the dispersant from example 4.1 (122.3 parts) and Hydrosol PW 2H solvent (225.63 parts) were heated to 160.degree. C. with stirring. The heat was removed and the temperature of the mixture continue to rise to 170.degree. C., and the time at which it reached 170.degree. C. was taken as time zero. The temperature of the mixture continued to rise to 180.degree.-190.degree. C. and when the temperature had ceased to rise the mixture was maintained at 170.degree.-175.degree. C. After one hour the epoxy equivalent in weight of the mixture was 100.000, and after two hours the epoxy equivalent weight was 211.000. After two hours the mixture was cooled and filtered through a 50 microns Nylon mesh. The cooled mixture had a 70% solid content and a viscosity of 0.6 Pas.
EXAMPLE 45
GY 250 liquid epoxy (379.32 parts), diphenylol propane (270.53 parts), triphenyl ethyl phosphonium iodide catalyst (1.31 parts), the dispersant from example 4.1 (122.11 parts) and Hydrosol PW 2H solvent (226.73 parts) were heated to 160.degree. C. with stirring. The heat was removed and the temperature of the mixture Continue to rise to 170.degree. C., and the time at which it reached 170.degree. C. was taken as time zero. The temperature of the mixture continued to rise to 180.degree.-190.degree. C. and when the temperature had eased to rise the mixture was maintained at 170.degree.-175.degree. C. After one hour the epoxy equivalent in weight of the mixture was 34.890, and after two hours the epoxy equivalent weight was 76.423. After two hours the mixture was cooled and filtered through a 50 microns Nylon mesh. The cooled mixture had a 70% solid content and a viscosity of 0.6 Pas.
EXAMPLE 46
GY 250 liquid epoxy (260.62 parts), diphenylol propane (330.16 parts), triphenyl ethyl phosphonium iodide catalyst (1.30 parts), the dispersant from example 4.1 (147.75 parts) and Hydrosol PW 2H solvent (188.69 parts) were heated to 160.degree. C. with stirring. The heat was removed and the temperature of the mixture continue to rise to 170.degree. C., and the time at which it reached 170.degree. C. was taken as time zero. The temperature of the mixture continued to rise to 180.degree. 190.degree. C. and when the temperature had ceased to rise the mixture was maintained at 170.degree.-175.degree. C. After one hour the epoxy equivalent in weight of the mixture was 141,000, and after two hours the epoxy equivalent weight was 197.925. After two hours the mixture was cooled and filtered through a 50 microns Nylon mesh. The Cooled mixture was very thick at 70% thus a part was diluted to 65% solids giving 0.29 Pas.
EXAMPLE 47
Epoxide Dispersion
Liquid Epoxy (GY 250 from Ciba Chemicals: 374.65 parts), diphenylol propane (141.78 parts), adipic acid (49.03 parts) triphenyl ethyl phosphonium iodide (1.19 parts), dispersant from Example 4.1 (148.84 parts), and Hydrosol PW2H (predominantly aliphatic solvent from Hydrocarbures St Denis France: 177.36 parts) were charged to a flask fitted with a separator and heated with stirring to 160.degree. C. There was an initial exotherm to 180.degree.-190.degree. C. and the mixture was then maintained at 170.degree.-175.degree. C. The mixture was maintained at 170.degree.-175.degree. C. and after 55 minutes further Hydrosol PW2H (107.15 parts) was added. The mixture was maintained at 170.degree.-175.degree. C. for 1 hour and then allowed to cool to room temperature. The cooled mixture was filtered through a 50 micron nylon mesh. The epoxy equivalent weight was 8517 and the dispersion had a viscosity of 0.3 Pas and a solid content of 62.59 %.
EXAMPLE 48
Epoxide Dispersion
Liquid Epoxy (GY 250 from Ciba Chemicals: 316.81 parts), diphenylol propane (168.46 parts), dimerised fatty acid (Pripol 1013 from Unichem), (39.77 parts) triphenyl ethyl phosphonium iodide (1.01 parts), dispersant from Example 4.1 (125.92 parts), and Hydrosol PW2H (predominantly aliphatic solvent from Hydrocarbures St Denis France: 169.20 parts) were charged to a flask fitted with a separator and heated with stirring to 160.degree. C. There was an initial exotherm to 180.degree.-190.degree. C. and the mixture was then maintained at 170.degree.-175.degree. C. The mixture was maintained at 170.degree.-175.degree. C. and after 55 minutes Hydrosol PW2H (63.41 parts) was added. The mixture was maintained at 170.degree.-175.degree. C. for 35 minutes Hydrosol PW2H (73.76 parts) was added and the mixture was held at 170.degree. to 175.degree. C. for 30 minutes. Hydrosol PW2H (41.66 parts) was added and the mixture was allowed to cool to room temperature. The Cooled mixture was filtered through a 50 micron nylon mesh. The epoxy equivalent weight was 6170 and the dispersion had a viscosity of 0.17 Pas and a solid content of 571/2%.
Application of the Dispersions to Metal Substrates
Each of the dispersions from examples 1 to 48 was applied to a steel substrate. The application was carried out using a spinning panel in the following general method. A 15 Cm.times.15 Cm panel was spun at 2950 rpm and 5 to 6 g of the dispersion was placed on its surface at its center. Spinning was continued for 10 seconds.
Each of the coated panels was heated to 200.degree. C. for 10 minutes in a box oven to remove the continuous phase. The dry films were all of 8 g/m.sup.2 film weight (approximately 6.mu. thickness).
Film Properties
All of the dispersions formed good coherent films.
It was found that the dispersion from Example 1 and 21 to 31 produced a film which had poor adhesion to the metal substrate.
It was found that the dispersion from Example 2 produced a film which was rather soft and which had somewhat poor adhesion to the substrate.
It was found that the dispersions from Examples 3 to 20 and 32 to 48 all produced films which had excellent adhesion to the metal substrate.

Number	Name	Date
3297784	Snedeker et al.	Jan 1967
3931109	Martin	Jan 1976
4122067	Anderson	Oct 1978
4341682	Tobias	Jul 1982
4579887	Mizusawa et al.	Apr 1986

Epoxide advancement

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