DE2414837A1 - Coating compsns., mastic and adhesives - comprising epoxy resin emulsion, hardener and cement - Google Patents

Abstract

Coating compsns. mastic or adhesives based on epoxy resins comprising (A) an epoxy emulsion, and (B) an equiv. amt. of hardener and a hydraulically-curing substance. Pref. the epoxy emulsion consists of 70-80 wt. % epoxy resin, 17-27 wt. % water and 3 wt. % emulsifier. Component (A) may additionally contain fillers, defoamers, pigments and/or methyl cellulose. The hydraulically curing substance may be alumina cement, Portland cement or gypsum. The hardener can be a polyamine, polyamide or ketimine. The compsn. provides for control of pot life and can be applied to non-absorbing substrates.

Description

Coating, filling and adhesive compounds based on epoxy resin Die The present invention relates to a coating, filling and adhesive composition Epoxy resin base.

Cold-curing epoxy systems have been known for a long time and have been used in an ever larger area of application in recent years. In general, glycidyl ethers (prepared from p, p-dioxydiphenylpropane (bisphenol A) or p, p-dioxydiphenylmethane (bisphenol F) by reaction with epichlorohydrin) are suitable as resin components and polyamines and polyamides as hardener components. The following reaction occurs as a typical addition reaction (US Pat. No. 2,444,333): In the past, versatile formulations could be created from this basic system. In addition to being used as paint and molding resin, these systems were also widely used as adhesives. By adding fillers and solvents, metal adhesives, construction adhesives, plastering compounds, coatings, insulation, etc.

For a long time only solutions of epoxy systems in paint solvents have been on the market for several years, emulsifiable resins and epoxy resin emulsions known.

These emulsions are best cured with polyamides.

Curing with ketimines should be mentioned as a special case.

These compounds have the advantage that their mode of action involves the presence of water presupposes (G.R. Somerville, Off.

Digest Federat. Soc. Point Technol. 37: 921 (1965)). The reaction proceeds according to the following scheme: The released polyamine in turn reacts with the polyepoxide.

With the epoxy emulsions alone, the area of application is very limited. So far, only epoxy mortar systems have been used for practical use, e.g. as a coating compound or injectable Paintings made. However, these systems are generally bound to highly absorbent substrates, as the emulsion water is sucked off must become. After the water has penetrated the subsoil and the system has set, this emulsion water acts with any remaining residual moisture as oppressive rising damp. If the surface is not porous and absorbent, so the temperatures must be so high that the water evaporates. However, it is Please note that the resin-hardener system reacts faster than the water evaporates. This reaction is also accelerated at high temperatures.

Another major disadvantage is that control over the end of the reaction resin with hardener is not possible because of the mixture Water content still makes it seem like they would still be workable, though the polymer reaction has ended. This effect is therefore often the cause of damage. After drying, part of the coating surface has solidified to form the subfloor, while the other part has no liability. For these reasons so far emulsified epoxy systems cannot prevail in practice.

It is therefore an object of the present invention to overcome these disadvantages to avoid, so to create a coating, filler and adhesive that in particular a control of the pot life enables and on non-absorbent substrates can be applied.

This object is achieved according to the invention in that it consists of one Component A, containing an epoxy emulsion and a component B, containing an equivalent amount of hardener and a hydraulically setting substance.

The reaction times should be optimized so that the hydrate ~ The setting process of the product runs parallel to the resin-hardener reaction or even a little faster, to be able to control it at any time to have.

According to the invention, a component A is used in water with the aid of Emulsifiers emulsified liquid epoxy resin (e.g. based on bisphenol A or bisphenol F) used. Component A can also contain defoamers, color pigments, fillers or contain methyl celluloses, which, however, are inert in this system.

Methyl celluloses play a crucial role in cement-based tile adhesives Role, as they are decisive for the water retention capacity. With strong suction Otherwise the hydraulic binder at the interface between the wall and the adhesive film would affect the substrates the water is withdrawn too quickly. One then receives the one that is familiar in the technical language "Scorching" effect, the adhesive strength suffers considerably and it comes to Wrong gluing.

For this reason, some formulations according to the invention (Tile adhesive and wall filler) methyl celluloses are used. Under the umbrella term Methyl celluloses is also understood to mean specially modified celluloses. In the formulations according to working examples 6) and 8) e.g. methylhydroxypropyl cellulose is used, which is delayed soluble.

The swelling only takes place from a pH value above 8. For this reason a portion of calcium hydroxide was also added to achieve rapid dissolution.

Component B contains the equivalent amount of hardener and one hydraulically setting material (e.g. cement or plaster).

Component B can also contain fillers, reactive thin-bodied Contains tar products and graphite.

After the two components have been mixed homogeneously, the following run Reactions from: 1. Hydraulic reaction: water with cement, gypsum 2. Polymer reaction: Epoxy resin with hardener The hydraulic reaction can be achieved by varying the amount of high-alumina cement and Portland cements vary in time so that the two reactions occur synchronously next to one another run here.

The following are the ingredients that make up component A and the Component B contain or may contain, described in more detail: Component A: a) Liquid epoxy resins based on bisphenol A and bisphenol F, including plasticized ones and types provided with reactive epoxy thinners; also with the help of solvents solid epoxy resins brought into solution.

b) emulsifiers polyoxypropylene glycol, highly ethoxylated fatty alcohols, highly ethoxylated castor oil, alkylaryl polyglycol ether, fatty acid polyglycol ester c) Defoaming agents isoamyl alcohol, nonyl alcohol, octyl alcohol, glycol, glycerine and sorbitol oleates or laurates d) fillers quartz sand, quartz flour, barite, Light spar, chalk, kaolin, soot, graphite, asbestos, fumed silica e) water f) Inorganic color pigments titanium dioxide, zinc sulfide, lithopone, iron oxides, etc.

g) methylcelluloses component B: a) hardeners polyamines, polyamides, Ketimine b) Hydraulically setting substances Cements (high-alumina cements, Portland cements), Plaster of paris c) Fillers as for component A d) Reactive, thin-bodied tar products. Stable Emulsions can be produced within the following limits: water 15 - 35 C / o emulsifier 3 - 6 epoxy resin 60 - 80 0% (epoxy equivalent 180 -200 drew Optimal Mixtures of water and resin have the following weight percentage limits: Epoxy resin 70 - 80% water 17 - 27% emulsifier 3 ovo The amount of resin: hardener is according to the Ratios of epoxide number to amine number always chosen to be equivalent. Because the amine number can be very different, a mixture cannot be specified here directly, especially since you often have to use hardener mixtures.

A mixture in general form cannot be defined because the Amine and epoxy resin equivalents are very variable.

A variation is easily manageable for one of ordinary skill in the art. However, the mixtures are determined not only by the equivalents, but by it it is more important to pay attention to the extent to which a workable mass is still possible by varying is attainable. Further details can be found in the exemplary embodiments.

According to the invention, water and defoamers are used to produce the emulsion and emulsifier submitted. The best are 15-20% water and 3% emulsifier. With the help of a fast-running stirrer, the liquid is then added Epoxy resin in the aqueous phase. A "water in resin" emulsion is obtained subsequent dilution with water, carried out with stirring, reverses the phase one, the resin-water emulsion is obtained.

The two components A and B can be simply Mix produce. The additives described above can be added to component A will. The component B is made by incorporating the fillers and the hydraulic setting substance in the liquid hardener. The mixture can be best prepared using a kneader or plane mixer.

In the case of the coating, leveling and adhesive compositions according to the invention the following must generally be observed. The response time setting must always depend on the the respective resin-hardener reaction. A pure resin-hardener reaction, without Emulsion water, however, cannot be used as this takes less time expires. As a result of the water-cement reaction, the system is depleted of water and thus increasing the reaction rate of the epoxy system. While the hydraulic Setting can be precisely determined by normalizing the cements, the polymer reaction must each have to be matched to the corresponding hardener reactivity. While the hydraulic Reaction is not influenced by the epoxy resin system - there were no serious ones Deviations found - is the epoxy reaction from the binding agent or amount of water, dependent (delay in reaction). The timing is therefore as follows Variables dependent: ratio of Portland cement: high alumina cement amount of water Hardener amount Hardener type The weight percentage limits for component A and the component B. are also variable. In any case, it is essential that equivalent amounts of resin and hardeners can be used. The water / cement factor can preferably be 0.5 - 0.7 lie.

The variation resin / hardener to the hydraulic system could theoretically be carried out in every proportion. A ratio of 40: 60 parts is favorable up to 60: 40 parts.

The water / cement factor was found to be optimal at 0.6.

The ratio of Portland cement PZ 450: high-alumina cement is dependent the desired reaction time or processing time of the product. The limits of variation were in relation to reaction times of 50-180 minutes from 2: 1 to 10: 1, portland cement to high alumina cement.

The times or conditions shift with the respective water content.

Further features and advantages of the invention emerge from the.

following description of exemplary embodiments: 1) Tile adhesive for bonding ceramic tiles to the wall: epoxy emulsion: water 15.00 Wt. °,; ó polyoxypropylene glycol 4.00 "liquid epoxy resin 71.00 II (equivalent: 190) Defoamer 0.30 Water 9.70 "1 100.00 wt. °, b component A epoxy emulsion 19.00% by weight water 13.20 methyl cellulose 0.70 asbestos fiber 1.20 Quartz sand 65.90 100.00% by weight component B Amide hardener 28.40% by weight gO (amine equivalent: 180) Portland cement 450 F 46.40 high-alumina cement 5.60 quartz sand 19.30 pyrogenic Silicic acid 0.30 100.00% by weight Mixing ratio: 2 parts A: 1 part B With the obtained, Ceramic wall tiles and heavy floor tiles can be easily applied with a notched trowel and extremely heavy, smooth, non-absorbent stone slabs glued to a wall (cement) will. All tiles were only pressed once and not fixed any further, e.g. by wedges. Slipping was not found in any case. Detonation search t resulted in tears from the substrate or the tile material at application thicknesses of the adhesive with a layer thickness of 2 - 3 mm. Due to the good wetting properties Full-surface adhesion can be detected even after exposure times of 20 minutes. The adhesive sets after 1 hour at 200 ° C.

2) Floor leveling compound: Epoxy-epoxy emulsion, water 15.00% by weight polyoxypropylene glycol 4.00 epoxy resin (equivalent = 190) 71.00 defoamer 0.30 water 9.70 100.00 wt Component A epoxy emulsion 14.00% by weight water 8.00 quartz sand 0.06 - 0.2 mm 50.00 Quartz flour 2,500 mesh 27.00 Paraffin oil 1.00 100.00% by weight Component B amine hardener 15.60% by weight (amine equivalent 90-95) Portland cement 450 F 42.00 Fondu Lafarge 25.00 (Alumina cement) Quartz sand 0.06 - 0.2 mm 17.40 100.00% by weight Mixing ratio: 3 parts A: 1 part B This filler is a relatively light one spatulable Material that is suitable for filling all stable, solid substrates is. Because of the pronounced adhesive properties, it can even be used on metal be filled. The application thickness can range from mm to several centimeters take place.

3) Floor leveling compound, antistatic: component A epoxy emulsion as in example 2 14.00% by weight water 8.00 "carbon black 3.00 quartz sand 0.06-0.2 mm 50.00 Quartz flour 2,500 mesh 25.00 "100.00 wt.% Mix ratio and component B are analogous to example 2.

It is a filler with the same properties, as described under Example 2. The only difference is that through Adding soot to the bleeder resistance to 106 - 107 ohm (surface resistance measurement, Electrode spacing 50 cm, voltage 100 V, layer thickness 5 mm). the Putty can preferably be used where prefabricated and wood construction Mastic asphalt screed or other insulation is not earthed.

4) Floor coating: component A epoxy emulsion as in the example 2 14.00% by weight water 8.00 " Paraffin oil 1.00 wt. 9b, quartz flour 2.500 17.00 Quartz sand 0.06 - 0.2 mm 30.00 Quartz sand 0.4 - 0.7 mm 30.00 100.00% by weight component B Amine hardener 15.60% by weight (amine equivalent = 90-95) toluene 4.00 Portland cement 41.00 Alumina cement 25.00 "Quartz sand 0.06 - 0.2 mm 14.40" 100.00 wt.

Mixing ratio: 3 parts A: 1 part B This mass can also contain quartz sand the grain size 0.6-1.2 mm can be added. Color pigments can also be used for coloring can be added.

The floor coating is an epoxy mortar with quartz sand aggregates can be processed. This mortar has a special application in factories as utility screed.

By incorporating cement, the coefficient of expansion became more than that Concrete adapted so that stress cracking and chipping from the substrate are less possible is.

5) Isolating agent: component A water 16.60% by weight Polyoxypropylene glycol 8.00% by weight epoxy resin 75.00 (epoxy resin equivalent = 190) defoamer 0.40 100.00 % By weight of component B amine hardener 30.00% by weight (amine equivalent = 90-95) amine hardener 3.00 (amine equivalent = 35-40) liquid tar product 47.00 "portland cement 14.00 Alumina cement 6.00 "100.00% by weight Mixing ratio: 1 part A: 1.5 parts B Component A is an epoxy emulsion produced according to the invention. However, no additional filler is added here, as this agent mainly used as an additive in conventional leveling compounds. The isolating agent however, alone cures according to the reaction scheme like the other formulations the end. Only the aggregates are missing, but they are missing when using cement leveling compounds (ready-made) are available.

This product becomes a mixed cement floor filler added. Additions 5 - 15 56 to the finished leveling compound. By adding this By means of the Strength, elasticity, bond to the substrate and the water resistance is greatly improved.

6) Wall filler (epoxy gypsum): component A epoxy resin emulsion 60% 45.00 wt / o methyl cellulose 0.70 "calcium hydroxide 0.29" retarder for Gypsum 0.01 "Zinc sulfide 1.00" Talc 3.00 2 Quartz flour 50.00 "100.00% by weight component B Amine hardener 45.00% by weight (amine equivalent: 120) Alabaster gypsum 55.00 "100.00% by weight Mixing ratio: 3 parts A: 1 part B epoxy resin emulsion 60% water 12.00 weight o / o Poloxypropylene glycol 3.00 "epoxy 60.00" (epoxy equivalent: 190) water 25.00 100.00 wt.% 7) Wall filler (epoxy gypsum): component A epoxy resin emulsion 70 ion 70% 45.00% by weight methyl cellulose 0.50 "calcium hydroxide 0.29 retarder 0.01 zinc sulfide 1.00 talc 3.00 quartz powder 50.20 100.00 wt. As component B amine hardener 42.00% by weight (amine equivalent: 120) alabaster gypsum 58.00 100.00% by weight Mixing ratio: 2 A: 1 B epoxy resin emulsion 70% water 12.00% by weight polyoxypropylene glycol 3.00 Epoxy resin 70.00 "(epoxy resin equivalent: 190) Water 15.00 100.00% by weight Instead of gray Cement white cement can also be used.

8) Wall filler (epoxy / cement): component A epoxy resin emulsion 20.50 wt / o, water 12.00 methyl cellulose 0.60 asbestos fibers 1.00 "quartz sand 0.06 - 0.2 mm 29.00 quartz powder 2500 mesh 36.90 100.00% by weight component B amine hardener 29.50 % By weight (amine equivalent: 120) toluene 1.00 "Portland cement 69.50" 100.00 Mixing ratio: 3 parts A: 1 part B epoxy resin emulsion analogous to Example 1.

9) EP mortar: Formulation structure component A epoxy emulsion 14.0 % By weight (as in Example 1) water 8.00 quartz sand 1.2-1.8 mm 25.00 quartz sand 0.7 - 1.2 mm 25.00 quartz sand 0.06 - 0.2 mm 25.40 fumed silica 1.90% by weight pigment dispenser 0.20 paraffin oil 0.50 100.00% by weight component B ketimine hardener 4.00% by weight (amine equivalent: 100) amine hardener 11.10 (amine equivalent: 105) amine hardener 3.00 (amine equivalent: 105) cement PZ 450 F 57.00 Fondu Lafarge 10.00 quartz sand 0.06 - 0.2 mm 14.90 100.00% by weight Mixing ratio: 3, parts A: 1 part B The mortar is easy to apply with a smoothing trowel or trowel.

The processing time is approx. 2 hours. In the hardener component a ketine hardener was incorporated. This ketiminl reacts harder however in this one Fall (with water) much faster than a reaction with humidity, because the decomposition into amine and ketone occurs immediately. Through the hydrolysis of the ketimine In addition to the hardening effect, a very good spreadability of the prepared Dimensions.

The invention brings about the known masses and methods numerous advantages: a) Control of the pot life by the better recognizable setting process of the hydraulically setting reaction partner are misplaced respectively.

Wrong gluing is no longer possible.

b) Non-absorbent surfaces Also on non-absorbent surfaces Bonding and filling are possible because the emulsion water is chemically bound will. The emulsifier works even on oily surfaces perfect liability is possible.

c) Improvement of the water resistance through the combination of epoxy resin / cement you get much better water resistance. For tile adhesives and fillers were 30 - 50 56 lower water absorption compared to conventional, purely cement-bound Systems.

d) Improvement of the corrosion resistance It could be increased here Resistance to chemicals can be found in every single component alone does not have.

e) Heat resistance The heat resistance was increased by adding cement significantly increased by epoxy resin systems in the construction sector. This is especially true in shower rooms and hot water containers are an advantage.

f) Resistance to temperature changes Through the addition of the cement the coefficient of thermal expansion shifted towards concrete. This is special Advantageous for coatings outdoors and in workshops and for screed repairs. A flaking of coatings due to strong temperature fluctuations and thereby changing expansion of the materials is thus prevented.

g) Elasticity, flexural strength and compressive strength By adding 5 - 10% of the isolating agent (see example 5) to normal self-leveling floor leveling compounds a strong increase in flexural tensile strength and compressive strength could be determined. (Bending tensile strength + 15 - 20 °, b, compressive strength + 30 - 35%.). By adding The epoxy resin emulsion or when using the finished epoxy fillers increases the hardness and abrasion resistance.

Claims (8)

Claims 1. Coating, leveling and adhesive based on epoxy resin, thereby characterized in that it consists of a component A containing an epoxy emulsion and a component B containing an equivalent amount of hardener and one hydraulic setting substance. 2. Coating, leveling and adhesive composition according to claim 1, characterized characterized in that the epoxy emulsion consists of 70-80% by weight of epoxy resin, 17-27 Ges.56 Water and 3 wt.% Emulsifier. 3. Coating, leveling and adhesive composition according to claim 1 or 2, characterized in that component A additionally contains fillers and / or defoamers and / or color pigments and / or methyl celluloses and / or acetylene black. 4. Coating, leveling and adhesive composition according to one of the claims 1-3, characterized in that component B also contains fillers and / or contains reactive, thin-bodied tar products. 5. Coating, leveling and adhesive composition according to one of the claims 1 - 4, characterized in that as hydraulically setting substances, high-alumina cements, Portland cements or plaster of paris can be used. 6. Coating, leveling and adhesive composition according to one of the claims 1-5, characterized in that the weight ratio water / hydraulically setting Substance = 0.6. 7. Coating, leveling and adhesive composition according to one of the claims 1 - 6, characterized in that the ratio resin - hardener / hydraulically setting Substance 40: 60 parts by weight to 60: 40 parts by weight. 8. A method for producing the epoxy emulsion according to any one of the claims 1 - 7, characterized in that 15-20 56 water, 3 56 emulsifier and the defoamer put in front, then the liquid with vigorous stirring Epoxy resin is added and finally the resulting water-in-resin emulsion by dilution is converted into a resin-in-water emulsion with water while stirring.