DE1107934B - Heat-curable, plastic molding, adhesive and coating compound - Google Patents

Description

Thermosetting, plastic molding, adhesive and coating compounds In the USA patent 2 324483 describes epoxy resins with at least two epoxy groups, which are represented by Reaction of a phenol containing at least two phenolic hydroxyl groups with an epihalohydrin, e.g. B. epichlorohydrin, obtained and by use a polybasic acid or its anhydride, e.g. B. phthalic acid or its anhydride, can be hardened in the heat as a hardening accelerator. Although the use polybasic carboxylic acids or their anhydrides in epoxy resins are valuable products results, there are certain disadvantages in their application.

First and foremost is the "pot life" of the partially converted mixture insufficient epoxy resin and polybasic carboxylic acid or anhydride, because after a relatively short time the mixture begins to harden and for most applications become unusable if they are not used within a short period of time after addition of the acid or the anhydride is used. Furthermore, these tend to Anhydrides are used as curing accelerators after their introduction into the epoxy resin when heated to 150 to 200 "C (at these temperatures generally takes place hardening), especially if the mixture is applied in the form of thin films, to evaporate. The loss of the hardening accelerator creates an uneven surface Composition. The physical properties of the cured resin are deteriorated. It is also known for the production of cured elastic epoxy resins to use as hardener substances that contain at least two reactive groups included, separated by a long chain of at least ten links are.

It has now been found that the combination of an epoxy resin Based on polyhydric phenols with a low molecular weight acidic polyester, the contains at least two free carboxyl groups, has an acid number above 200 and the reaction product of one trihydric or tetravalent alcohol and one not polymerizable, i.e. saturated, dicarboxylic acid, molding, adhesive and coating compositions results, through which the hitherto when using a polybasic carboxylic acid or their anhydride as a curing accelerator for the epoxy resins be resolved. The mixture of the acidic polyester and the epoxy resin can be Room temperature even in the already partially converted state for a long time, for example 6 months. After this time it is still soluble and meltable, while resin compositions of epoxy resins and polybasic carboxylic acids or their anhydrides as the sole curing accelerator at room temperature in less than 31 days have become completely insoluble and infusible. Still seem the cured resins according to the invention to be less brittle and tougher.

The low molecular weight acidic polyesters used are a reaction product of a trihydric or tetravalent alcohol with a non-polymerizable, saturated dicarboxylic acid or its anhydride. The acidic polyesters as they are according to of the invention are used, thus have an excess of carboxyl groups on. Since these polyesters are essentially completely converted, only few, if any, hydroxyl groups unreacted. The excess carboxyl groups are not implemented, but are bound to the polyester molecule. Because of the application an equivalent excess of carboxyl groups in forming these polyesters they generally have a higher acidity; H. a higher acid number, or lower acid equivalent weights than the usual alkyd resins. So have z. B. the usual alkyd resins have acid numbers of close to 0 up to 30 and 50. Glyceryl phthalate alkyd resins are also unsuitable, although they have higher acid numbers, because of the undesirably high concentration of free Hydroxyl groups. According to Polyesters to be used according to the invention have acid numbers of over 200.

The use of conventional alkyd resins instead of acidic polyesters together with epoxy resins do not give the same results. Is z. B. a common one Resin made from 291 0 / o ethylene glycol and 70.9 01o phthalic anhydride, which has an acid number of about 38, mixed with an epoxy resin, one succeeds in curing not such a mixture. Even after curing the mixture at 150 "C for 18 hours still obtained liquid resins. Also made from a mixture of an ordinary resin 29.2 0 / o glycerine and 70.80 / 0 phthalic anhydride, which has an acid number of about 125 has, when mixed with an epoxy resin, results in a mass that is not completely homogeneous is.

If this mixture is heated to 125 ° C. for 15 hours, the result is a cheesy gel in which the glyceryl phthalate resin is used as a gel alongside unpolymerized epoxy resin seems to be present.

For the production of the acidic polyesters of low molecular weight A wide variety of polyhydric alcohols can be used, such as. B.

Glycerin, pentaerythritol and the like as examples of non-polymerizable ones Dicarboxylic acids that can be used to produce the polyesters are named for example: succinic acid, adipic acid, sebacic acid, phthalic acid, Isophthalic acid, terephthalic acid or chlorinated phthalic acids. If necessary, can the anhydrides of these acids can also be used with the same effect. if dicarboxylic acids are spoken of in the description and claims, they include also always understand the anhydrides.

The epoxy resins are polyether derivatives of organic polyvalent ones Phenols with epoxy groups and are z. In U.S. Patents 2,324,483 and 2,444,333 and in British Patent Nos. 518 057 and 579 698. Most of these epoxy resins are resin-like reaction products between Epihalohydrins, e.g. B. epichlorohydrin, and a phenol with at least two phenolic Hydroxyl groups. such as B. bis (4-oxyphenyl) dimethyl methane, also known as bis (oxyphenyl) -2,2-propane referred to as. U.S. Patents 2,494,295, 2,500,600, and 2,519,130 are further examples of epoxy resins as described for performing of the method according to the invention can be used.

The strongly acidic, non-polymerizable polyesters of lower Molecular weights can be produced in a number of known ways. For education strongly acidic polyester it is necessary to put the dicarboxylic acid or its anhydride in apply equivalent excess over the polyhydric alcohol. So it is z. B. advantageous in the case of a dihydric alcohol, for every mole of the dihydric alcohol 1.1 to 2.0, preferably 1.5 to 2.0 mol of the dicarboxylic acid to be used. Becomes a trihydric alcohol, for example glycerine, is used, it is advisable to for each mole of glycerol 2.2 to 3, preferably 2.5 to 3 moles of dicarboxylic acid, for example Phthalic acid or its anhydride. With tetravalent alcohols such as pentaerythritol, it is advantageous to use 3.3 to 4.0 moles of the dibasic acid per mole of tetravalent To apply alcohol.

An acid number of the polyester of over 200 is generally due to Heating a mixture of the polyhydric alcohol and the dicarboxylic acid or their Anhydride in the appropriate molar quantities conditions to 150 to 250 "C during reached a period of 1 to 3 hours. The reaction is preferably so led that the acid number is in the desired range and most of the hydroxyl groups are esterified, so that strongly acidic polyesters of low molecular weight are formed, which can be processed together with the epoxy resins.

The ratio of polyester to epoxy resin can vary depending on the desired Purpose of use, the type of polyester used and the type of applied Epoxy resin vary within wide limits.

In general, the acidic polyesters are used in amounts from 5 to 70% 0 / o of the total weight of epoxy resin and acid polyester used. The real one Quantity ratio depends on the specific acidic used in the individual case Polyesters and epoxy resins. The polyesters and the epoxy resins are preferred used in such proportions that in the mixture about 0.8 to 1.2 There are carboxyl group equivalents of the polyester for each epoxy equivalent.

The way the acidic polyester and epoxy resins are combined can of course be modified and does not present any particular difficulty.

In general, the polyester resin is heated, optionally epoxy resin heated until it becomes liquid is also added to the liquid polyester resin and then the mixture with stirring to higher temperatures, for example 80 to 150 "C or higher, heated until a homogeneous mixture has formed. By further heating to higher temperatures, for example to 100 to 200 "C, the homogeneous, still liquid mass poured into a mold becomes a solid casting cured without any noticeable shrinkage occurring and without any substantial Amounts of by-products, such as water, are formed. The reaction between the Epoxy resin and the acidic polyester can also be made by cooling the liquid homogeneous Mass can be interrupted to room temperature, with a meltable, soluble Resin is obtained as an intermediate product with good shelf life.

The cure rate will be as is known. through increase the temperature and the length of the heating time. Partly converted product can be used for casting, pressing, for the production of laminates, be used for covering surfaces or for adhesive purposes, if necessary in the form of solutions.

By subsequent heating of the partially converted, precondensed Product, it is converted into the insoluble, infusible, hardened state.

In order to better illustrate the invention and its practical implementation, some examples are given below. All parts given are parts by weight.

Example 1 An acidic polyester "A" is made by heating for 30 minutes from 592 g (4.0 moles) of phthalic anhydride and 143 g (1.05 moles) of pentaerythritol to 175 up to 210 "C in the usual way, up to the acid number about 336 and the neutralization equivalent 167 is.

This polyester is made together with two epoxy resins, where Epoxy resin 1 has an epoxy equivalent of 300 to 375 and an esterification equivalent 105, epoxy resin II an epoxy equivalent 450 to 525 and an esterification equivalent von 130 has produced castings in the proportions shown in Table 1.

Table 1 Sample parts acid parts parts No. Polyester A Epoxy resin I Epoxy resin II 9 30 70 10 20-80 The castings are heated to 125 "C for 15 hours and an additional 1.5 hours to 150" C in each case. The castings obtained consist of yellow-brown resins which are hard and tough at 150 "C and very hard and insensitive to impact at room temperature.

A precondensed resin is made by heating for 1 minute for 30 Parts of the pentaerythritol phthalic acid polyester with 70 parts of epoxy resin I to 120 to 125 "C. The product obtained has an acid number of 74.8, which indicates that the acid groups have reacted to 26%. The curing time for a film is at 200 "C for 40 seconds.

Example 2 1480 g (10 mol) of phthalic anhydride and 330 g (3.6 mol) Glycerin are in the usual way in a reaction vessel with a mechanical Stirrer and an air-cooled reflux column is gradually increased Heated to 190 "C and then to 190-206" C for 1/2 hour. The aqueous distillate formed is collected and removed. The resin "B" obtained has an acid number of 354, corresponding to an acid equivalent weight of 158.

Since the epoxy resin 1 has an epoxy equivalent of 300 to 375 (340 on average) and the acidic polyester B has an equivalent weight of 158 (calculated on the basis that a carboxyl group reacts with an epoxy group in the reaction) according to the following formula the following calculation can be made: epoxy resin 340 680in acidic polyester B ................. 158 3201o 498 1000in The preferred ratio of the reactants is around the equivalent point, ie 30 to 330 / o acid polyester B.

Example 3 An acidic polyester "C" is made by heating for 2 hours from 438 grams (3.0 moles) of adipic acid and 92 grams (1.0 moles) of glycerin to 190 to 210 "C in produced in an inert atmosphere. The polyester C has an acid number of 390. This acidic polyester and an epoxy resin III with epoxy equivalent 905 to 985 become dissolved in acetone in a weight ratio of 20:80, so that the solution 20% Contains solids. A paper tape covered with mica is then made with this solution impregnated and coated. The production of such mica paper is closer in the U.S. Patent 2,549,880. The tape obtained becomes the wrapping used by stator bars at 150 "C and a pressure of 7 kg / cm2 for several hours are compressed to allow the reaction between the epoxy resin and the acidic polyester C can take place. The insulation obtained is heat-hardened, tough and tight and has excellent dielectric strength.

Is the reaction mixture of epoxy resin 1 and an acidic polyester heated for a short time and then quenched before gelatinization occurs Pre-condensed resins are obtained, which can be used as surface coatings, adhesives and binders suitable. This procedure is described in detail below.

30 to 33 parts of the acidic polyester B and 70 to 67 parts of the epoxy resin I are preheated to 100 to 120 "C, mixed with stirring to form a homogeneous mass and then heated to 120 to 130 "C for 20 to 30 minutes. The reaction is slightly exothermic, so that a slight cooling is required for large batches. At the end of the response time the viscous product is poured onto a clean surface to allow the mixture cool quickly and freeze the reaction. In this way they become thermosetting Mixtures obtained that cure at 2000 C as a film in 80 to 195 seconds. the Curing times depend on the temperature at which the precondensation takes place, of the length of time during which the precondensation is carried out and of the percentage of the acidic glycerolphthalic acid polyester.

The resin compositions according to the invention can be used in a wide variety of ways Use for purposes. So z. B. useful solutions of the unimplemented Mixtures of the acidic polyester and the epoxy resins or of precondensed resins with a wide variety of low-boiling solvents, such as acetone, Cyclohexanol, methyl ethyl ketone and the like, produce, to which aromatic diluents, such as benzene or toluene can be given. Solutions of mixtures of resins or of precondensed resins can be used for surface coatings, as adhesives, for impregnating various flat structures such as fabric, paper, asbestos or Mica can be used. Laminates can be removed by treating the fabric with the solution of a mixture of the epoxy resin and the acidic polyester or of precondensed resins from these substances with evaporation of the solvent, Laying the sheets on top of one another and pressing for sufficiently long curing times produce under heat and pressure.

In these cases temperatures from 150 to 200 "C applied for 1/4 to 6 hours.

Furthermore, a wide variety of pressed pieces can be used a mixture of the resins or precondensed resins from the resin mixture Addition of conventional fillers at elevated temperatures. The fillers can optionally be in a solution of the mixture of resins or of precondensed Resins are introduced.

The solvent is then evaporated. It comes up with the resins coated filler material.

Suitable fillers are: titanium dioxide, the most varied Clays, iron oxides, carbon, graphite or asbestos fibers. The precondensed resins, d. H. a partially condensed mixture of the acid polyester and an epoxy resin such as Epoxy Resin I exhibits shear strengths in excess of 140 kg / cm2 if the resin is used as an adhesive for steel or with copper oxide and copper coated steel surfaces is used. Furthermore, the precondensed resins with success for gluing a wide variety of surfaces including cracked ones Glass surfaces are used.

A wide variety of types can be made from magnetic materials of magnets when they are fixed with the resin composition according to the invention Pieces are pressed which, according to tests, have a separation strength of 42 kg / cm2. This value is well above that of corresponding pieces made with phenolic resins or Mixtures of other polymerizable substances and unsaturated alkyd resins as binders can be achieved. In the latter two cases, release strengths are generally under 7 kg, sometimes even as low as 1.75 kg / cm2, are available.

Claims (4)

PATENT CLAIMS: 1. Thermosetting, plastic molding, adhesive and coating compound based on epoxy resins and polyesters containing more than one epoxy group containing epoxy resin based on polyhydric phenols and a low molecular weight one Polyester from a trihydric or tetravalent alcohol with an equivalent excess a non-polymerizable dicarboxylic acid with an acid number above 200. 2. Heat-curable, plastic molding, adhesive and coating mass according to Claim 1, containing a polyester composed of 1 mole of glycerol and 2.2 to 3 moles of adipic acid or phthalic anhydride. 3. Heat-curable, plastic molding, adhesive and coating mass according to Claim 1, containing a polyester of 1 mol of pentaerythritol and 3.3 to 4 mol Phthalic anhydride. 4. Thermosetting, plastic molding, adhesive and coating mass according to Claims 1 to 3, containing the polyester in an amount of 5 to 70 percent by weight, based on the weight of epoxy resin and polyester. ~~~~~~~~ Considered References: French Patent No. 962 846; Belgian patent specification No. 497 540.