DE1816933C - Process for the production of epoxy polyadducts - Google Patents

Description

From British patent I 026 141 it is known to epoxy compounds of the general formula

CH ₁ -

-CH-H ₂ C-OOC-R ₁ -COO-R ₂ -OOC-R ₁ -COu · CH _{2 -CH}

CH,

in which the two acid _{radicals R 1} (CO—) _{2 are derived} from a dicarboxylic acid, e.g. phthalic anhydride, and the glycol radicals —OR ₂ O— are derived from ethylene glycol, propylene glycol or neopentyl glycol.

The heat resistance of the epoxy polyadducts. which are made from this intermediate product can is low. Following the example of the aforementioned British patent, an epoxy compound '5 made from 1 mole of glycol, 2 moles of phthalic anhydride and epichlorohydrin and this with maleic anhydride implemented. This polyadduct has a relatively low Martens heat.

From the German patent I 103 579 it is: o still known. Epoxy compounds that contain anthracene as a base (e.g. anthracene endosuccinic acid diglycidyl ester). to convert to polyadducts with conventional hardeners. This epoxy compound is obtained by reacting anthracene endosuccinic acid. their anhydride or their salts, e.g. B. alkali salts with haloepoxyalkanes. Epoxy polyadducts made from these starting materials show good thermal resistance: however, they have the following disadvantages:

1. Due to the high softening point of the epoxy compound based on anthracene endosuccinic acid the mixture with the so-called hardener can only be achieved by prolonged homogenization at an elevated temperature. This can easily lead to the fact that the crosslinking begins too quickly and the mixtures thermally decompose. In particular, the use of low-melting acid anhydrides and primary and secondary Amir> very difficult. 2. The polyadducts obtained from these mixtures are generally brittle at room temperature, so that their use is clear Limits are set.

The invention is based on the object. Develop and deploy epoxy compounds that Contain anthracene as a basic body and the easier and at lower temperatures with the implementation certain substances mixed and made into epoxy polyadducts with improved thermal and mechanical properties Properties can be processed that have a wide range of applications.

The invention relates to a process for the production of polyadducts with shaping by reacting an epoxy compound. the at least 2 epoxy groups in a molecule with one Contains anthiacene base with di- or polycarboxylic acids or their anhydrides, which is characterized. that as an epoxy compound of Diglycidyl ester of anthracene-endo-butanediol disuccinic acid monoester is used.

This ester has the following general formula:

HOOC-CH ₂ -CH ₂ -CO-CH ₂ ; CH, OC -CII ₂ -CH ₂ COOH

, · ■ o; ■!

Its melting point is 156 to 157 C. Fr. a theoretical acid value of 240.5. the calculated Molecular weight is 466. the IR spectrum shows no anhydride bands.

This epoxy compound is expediently prepared by reacting an alkali salt of this anthracne clo-hutanediol di-succinic acid monoester with haloepoxyalkanes , in particular with epichlorohydrin, according to known processes. The glycidyl esters obtained in this way are reacted in a manner known per se with the dicarboxylic or polycarboxylic acids or their anhydrides at elevated temperature with shaping to give insoluble polyadducts.

A particularly advantageous process for the preparation of the anthracene-endo-butanediol-di-succinic acid monoester. for which no protection is sought in the context of this invention, consists in the fact that succinic anhydride is reacted with anthracine-cndo-toutanediol in a ratio of 2: 1 in the presence of 1 percent by weight of PbO as a catalyst in the solvent (z. B. xylene). The reaction mixture is refluxed in xylene for 1 to 2 hours, preferably 1.5 hours. During the reaction, a precipitate separates out from the initially homogeneous solution. After the reaction mixture has cooled, the upper xylene phase is decanted off. The precipitate is taken up in acetone and the solution by filtration

fio freed from the catalyst. Stripping off the solvent gives the desired addition product in quantitative yield.

The alkali salts of the product can be obtained directly by neutralizing the acetone solution with ent speaking aqueous liquor and subsequent Ab pulling the solvent to dryness can be obtained. To represent the preliminary products are appropriately used potassium or sodium salts.

The product obtained here has an acid number of 240 and a calculated molecular weight of 468. That corresponds to a compound of the chemical constitution given above. That determined The molecular weight of the potassium salts of the product is 543, which corresponds to the calculated molecular weight of the ester. The elemental analysis of the potassium salt gives the following values:

Carbon:

found .... 56.64 calculated ... 57.57%.
Hydrogen:

found .... 4.77. calculated ... 4.43%.

In contrast to the procedure just described, according to which the acidic ester in the presence of Basic catalysts is prepared in a solvent, is obtained when using acidic catalysts the T. 'trahydrofuran derivatives of anthracenendobutanediol. Oligoester and unreacted succinic anhydride. Melt condensations in acidic environments without a catalyst according to British patent specification 1,026,141 also do not provide a uniform environment Product, but a mixture of the tetrahydrofuran derivative of anthracene-endo-butanediol. Oligoester and unreacted succinic anhydride.

In the process according to the invention, the epoxy compounds are reacted with di- or polycarboxylic acids or their anhydrides. It is useful to use anhydrides of polybasic carboxylic acids. such as B. Isooctenylbernsfinsäureanhydric ¹ succinic anhydride, phthalic anhydride, maleic anhydride, etc. In addition, tertiary amines and Lewis acids can be used for catalytic hardening.

Moldings that have been produced by the method of the invention are characterized by a unique combination of good mechanical and thermal properties. Despite the high Hardness, they are not brittle. As is their thermal behavior, characterized by their dimensional stability in the warmth according to Martens, above average the new products are subject to considerable technical progress.

The process according to the invention results in considerably lower processing temperatures (about 80 C) than with the corresponding known epoxy compounds with anthracene as the base. For example, the above-mentioned known, Epoxy compounds obtained from anthracene-endo-succinic acid are a processing temperature of about 140 C. The casting process can if used the epoxy compounds mentioned according to the invention take place much more precisely and more slowly. Without the casting mixture prematurely segregating or gelling. Due to the slow course of the crosslinking reaction an excessively large temperature gradient cannot develop, even with larger shaped bodies.

In table (2) various properties of the polyadducts according to the invention (I) are the corresponding Properties of a known polyadduct based on 2,2-bis (4-oxyphenyl) propane (Bisphenol A) (II) compared. The flexural strength and impact strength of product (I) are important higher than of product (II). It follows that product (I) is an unusual combination has good mechanical and thermal properties.

P ^; Comparison of the polyadducts according to the invention with corresponding products according to British patent specification 1,026,141 shows the superiority of the new plastics. Is z. B. an Epoxidvei bond that has been prepared from 1 mole of glycol, 2 moles of phthalic anhydride and epichlorohydrin according to the example of the British patent, cured with maleic anhydride, a polyadduct with a Martens heat of 52 "C, while a corresponding polyadduct according to the Invention has a Mar'ens heat of 85 "C. Is. Anhydride in a corresponding comparative experiment Bernsteinsäur used as a curing agent, so polyadduct according to the invention has a Martens temperature of 52 ⁰ C, during which is the polyadduct from the Epoxidharzvorprodukt according to British patent specification below room temperature.

The mechanical properties of the epoxy polyadducts produced by the process according to the invention are superior to those mentioned above. The latter are so brittle that corresponding Measurements were not possible.

The polyadducts according to the invention are suitable as casting, impregnating and laminating resins. especially in the electrot &. hnik; Components of binders, especially from adhesives and synthetic resin mortars. Components of coating compounds. especially in Construction. Paint raw materials for the production of particularly chemical-resistant paints and as components solvent-free paint systems. Casting compounds, among other things in mold and tool making. Foams. You can use known additives such. B. fillers, dyes, plasticizers, in the usual for this purpose Quantities included.

Production of the diglycidyl ester of the anthracenendo-butanediol-di-amber-nsäurc-monocster

133.6 g anthracene-endo-biitanediol (0.5 mol). 100 g Succinic anhydride (1.0 mole). 2.33 g PbO as

4c catalyst (1.0 percent by weight) and 500 ml of xylene are refluxed for 1.5 hours in a 1 l two-necked flask equipped with a stirrer and attached reflux condenser. During the reaction, a precipitate forms from the initially homogeneous solution. After the reaction mixture has cooled, the upper xylene phase is decanted off. The precipitate is taken up in acetone and the solution is freed from the catalyst by filtration. The solution is evaporated to T ^r ockne. Yield: 223.7 g of white product from anthracene-cndo-butanediol-di-bcrnstcinsäurc-monocster.

200 g anthracene-endo-butanediol-di-succinic acid monocystcr are dissolved in 1 l of acetone and the solution neutralized with 5% KOH against Phcnolphthalcin. After the solvent has been stripped off, the potassium salt is obtained. Yield: 240 g.

To illustrate the Fpoxidverbindung 90 g potassium salt of Example 2, for 16 hours at 120 ° C / 15Torr be has been thoroughly dried, cooked mil 210 ml of epichlorohydrin for 48 hours at 140 ^c C bath temperature with vigorous stirring. After cooling, 250 ml of ethyl chloride are added to the suspension and the solution of the epoxy compound is centrifuged off from the salt. After the excess epichlorohydrin and ethylene chloride have been distilled off, the pale yellow resinous epoxy compound remains with a yield of 97.5 g. The epoxy compound has an epoxidation of 2.9 mAquiU / g.

B e i s ρ i e

For preparing the moldings of the epoxy compound is heated to 8Q ¹ C and mixed with the hardener. After homogenization, the mixture is ready for casting.

The epoxy compounds can contain about 80 to 120%, preferably 90% of the stoichiometric amount of hardener, calculated on the epoxy content of the epoxy compound to be used according to the invention, are converted to insoluble polyadducts.

Mixtures of the epoxy compound and various hardeners are listed in Table 1 and the amount of hardener in g / g epoxy compound as well as ■ the processing conditions for these mixtures has been specified.

table

Processing conditions for polyadducts based on disuccinic acid-anlhiticen-endo-butan

diolester

Epoxy value: 2.9 meq / g; Hardener: succinic anhydride (BSA), phthalic anhydride (PSA) and maleic anhydride (MSA); Pre-curing: 2 hours at 120 ⁵ C.

llairians l'rter salary
J! G hardening
temperaiur
(C) Curing time
th) BSA
PPE
MSA 0.262
0.387
0.255 180
180
210 22nd
22nd
22nd

table

Comparison of the thermal and mechanical properties of polyadducts (I) according to the invention with those of one known polyadducts based on 2,2-bis- (4-oxyphenyl) -propane (bisphenol A) (II)

characteristic
dimension

Test specification Polyaddukl 1 according to the invention

BSA PSA

MSA

Pol> adduki Il

high quality

Comparative product

of the trade

BSA

Martens heat ( ^G C) ...
Ball indentation hardness (kp / cnr)
Impact strength

(kp ■ cm / cm ² )

Flexural strength (kp / cirr).
Deflection (mm) ....

DIN 53 462 DIN 53 456

DIN 53 453 DIN 53 452 DIN 53 452

51 1365

16.6 1710 4.0 70
1515

11.9
1560
2.4

85 1565

16.0 1610 3.9

64 950

810 5.6

Claims (1)

Claim: Process for the production of polyadducts with shaping by reacting an epoxy compound, the at least two epoxy groups in a molecule with an anthracene backbone contains, with di- or polycarboxylic acids or their anhydrides, characterized in that the epoxy compound of the diglycidyl ester of anthracene-endo-butanediol di-succinic acid monoester is used.