DE1154032B - Asphalt-like binder and coating compound for building purposes - Google Patents

Description

Asphalt-like binder and coating composition for building purposes. The invention refers to mixtures containing asphalt based on petroleum bitumina, which are particularly for use as a binding agent and covering material or paving for roads, Airfields, sidewalks and similar areas are suitable.

There is an increased need for a better and readily available one Material for building roads, airfields and the like, namely a material that for example better resistance to wear and tear, solvents and has heat and prevents sliding or skidding. It also exists a need for a cheap coating compound that can be applied to already completed cement or asphalt roads or storage areas can be applied to protect those caused by wear and tear, Rain and salts used for de-icing and cold caused destruction to decrease.

In addition, especially for asphalt runways for jet planes, a need for asphalt paving that has improved resistance to heat and solvents as heat and jet fuels possess asphalt surfaces attack easily. Cement and asphalt pavements and metal surfaces Roadways etc. leading over bridges tend to become dangerous after prolonged use to form smooth surfaces which, when wet, create a risk of slipping or skidding cause.

There are various types of requirements to meet the requirements just mentioned Mixtures have been suggested; however, the mixtures known hitherto for this purpose proved to be unsatisfactory or were too expensive for practical use. A mixture can also be used as a coating medium for pipeline pipes known from coal tar and polyepoxy resins. Trying to replace coal tar Using the increasingly available petroleum bitumen showed that this was the case Bitumen obtained from petroleum is not compatible with the epoxy resin.

It has now been discovered that these and other difficulties by the asphalt-like binders and coating compounds according to the invention for building purposes Can be turned off, which is a mixture of firstly a polyepoxide with more as a vicinal epoxy group, secondly a polyamide with amino hydrogen others consisting of the reaction product of a polybasic acid with at least 7 carbon atoms between the acid groups and an aliphatic polyamine, and thirdly, a bituminous material obtained from petroleum.

It is surprising that the presence of the polyamide with amino hydrogen a good compatibility of the components is achieved, so that excellent Binders for various mixtures or additives that are used as improved paving for roads, airfields, sidewalks and the like can find. The roads etc. made with these special mixtures show excellent durability, flexibility and resistance to Heat and solvents and also avoid the risk of slipping.

It has also been found that these mixtures are compatible Form films and coatings that, after hardening, are excellent on cement, asphalt, Wood and metal surfaces adhere. In addition, the coatings are resilient and tough and very resistant in all weather conditions. If the coating has small inert particles are added, these mixtures are excellent means of avoidance from sliding or skidding. The coating compounds are particularly suitable for highways and runways as they are easily applied to large areas and quickly can be cured without any particular curing conditions required; they are also useful for treating development of dock areas, floors in department stores, Sidewalks, tennis courts, ship decks, oil lines (pipelines) and the like other surfaces where durability and weather resistance are desired.

A particular advantage of the new asphalt-like binders and coating compounds lies in the fact that they can be hardened at low temperature and so no special devices for developing heat are required.

Many of these binders and coatings, especially those which have been produced from residual heating oils, or mixtures containing thinners, such as hydrocarbon nitriles, monoglycidyl derivatives and similar compounds, have a low viscosity and can be sprayed on or applied by brushing will.

The finding that the above-mentioned mixtures for these forms of expenditure are suitable, was surprising, as it was previously known that certain types of asphalt, like paving asphalt, are essentially incompatible with glycidyl polyethers. However, the mixtures according to the invention show excellent compatibility and form tough, homogeneous masses. It has also been found that the hardened Products have the above-mentioned improved properties, for example improved Flexibility, whereas the various asphalts alone in general form brittle products.

The bitumen material contained in the mixtures according to the invention is obtained from petroleum, for example asphalt, residual heating oils and the like. The binders preferably contain blown bitumen produced by the cracking process aromatic and catalytically or non-catalytically polymerized bitumen, in particular paving asphalt obtained by direct distillation. The aromatic petroleum asphalt can be improved in terms of their flexibility according to the invention and thereby the Use of these products, which are usually hard and brittle, be expanded.

A typical, preferably used, aromatic bitumen contains the bottom residues from the distillation of catalytically cracked gasoline. Normally have immediately distilled types of bitumen that are suitable for use as paving Particularly suitable are hardnesses of about 40 to about 300 and softening points within of the range from about 35 to 630 C. Blown bitumens are usually present in the presence or absence of catalysts produced by the fact that the bitumen at at elevated temperatures with an oxygen-containing gas, such as air. A typical one Asphalt can have a softening range between about 71 and about 1160 C and have a hardness within the range of about 5 to about 30.

Other preferred substances include high-boiling extracts of petroleum, such as those used in the extraction of petroleum by aromatic selective solvents are recovered, a.

For the production of these extracts one uses different ones, not reactive, highly polar solvents, such as. B. liquid SO2, phenol, cresylic acid, Furfural, dichloroethyl ether, nitrobenzene and similar compounds. The application the so-called double solvent process the mutually immiscible solvents, such as cresylic acid and propane, are used will, also provides suitable extracts. Particularly preferred are the Edeleanu and Furfural extracts from petroleum distillates. The extracts represent high-boiling substances represent, which are generally viscous liquids at ordinary temperatures up to tar-like substances can be. Extracts are preferred that have a boiling point of over 3000 C at 760 mm Hg.

Other preferred bitumen materials are residues of fuel oils, for example with a viscosity between 10 cSt at 370 C and about 1500 cSt at 370 C.

Suitable polyepoxides are disclosed in U.S. Patent 2,633,458.

Other examples are the epoxy compounds which can be used according to the invention, the epoxy-containing esters of polyethylenically unsaturated monocarboxylic acids, such as linseed oil containing epoxy groups, ethyl aeostearate, monoglycerides of tung oil obtained Fatty acids and similar compounds.

Another group contains diglycidyl esters of dibasic acids, such as diglycidyl phthalate.

Further compounds containing epoxy groups include those containing epoxy groups Esters of unsaturated monohydroalcohols and polycarboxylic acids, as well as those containing epoxy groups Esters of unsaturated alcohols and unsaturated carboxylic acids, containing epoxy groups Derivatives of polyethylenically unsaturated polycarboxylic acids, containing epoxy groups Polyester, which by reaction of an unsaturated polyhydroalcohol and / or unsaturated Polycarboxylic acids or anhydrides are formed, the polyester, which is produced by reaction of diethylene glycol with 2-cyclohexene-1,4-dicarboxylic acid, and similar compounds, in addition, polyethylenically unsaturated hydrocarbons containing epoxy groups, epoxy groups Polymers and copolymers of diolefins.

The polyepoxides particularly preferred according to the invention are glycidyl ethers, in particular the glycidyl ethers of polyhydrophenols, especially dihydrophenols, such as bisphenol A and polyhydroalcohols, especially those that have a molecular weight between 250 and 900. Those described in U.S. Patent 2,633,458 Polyethers A, B, C and D are good examples of such polyepoxides. Other examples are the polyglycidyl ethers of 1,1,2,2-tetrakis- (4-hydroxyphenyl) -ethane (with a Epoxy value of 0.45 equivalents / 100 g).

The polyamides contain the reaction product of a polybasic Acid with at least 7 carbon atoms between the acid groups and an aliphatic one Polyamine, the resulting product having at least one attached to an amino nitrogen atom has bonded hydrogen atom. Examples of the manufacture of these polyamides Polybasic acids used include 1, 10-decanedioic acid and 1,18-octadecanedioic acid and dimeric and trimeric fatty acids which polymerize drying by heating Oils can be produced under known conditions. To manufacture the polymeric acids, numerous drying oleic acids can find use, however those acids are preferred which have 16 to 24 carbon atoms, such as linoleic acid, linolenic acid, eleostearic acid and licanic acid.

The aliphatic polyamides used to make the polyamides can any Di-, Tri- or tetramines, for example ethylenediamine, Triethylenetetramine, tetraethylenepentamine, 1,4-diamine butane, 1,3-diamine butane, hexamethylene diamine, 3- (N-isopropylamino) propylamine, but preferably diethylenetriamine.

Particularly preferred polyamides are those that are different from aliphatic Polyamines containing no more than 12 carbon atoms and polymeric fatty acids, those by dimerization and trimerization of ethylenically unsaturated fatty acids with up to 24 carbon atoms, especially of fatty acid obtained from soybean oil arise, derive.

These polyamides preferably have a viscosity between 10 and 750 poise at 400 ° C., preferably 20 to 250 poise at 400 ° C. Preferred polyamides also have amine values of 50 to 450.

The amine value is the amount in mg of KOH that corresponds to the base content of 1 g Polyamide, determined by titration with HCI, is equivalent.

As already noted, the polyamides used according to the invention have at least 1 and preferably 2 or more hydrogen atoms bonded to amino nitrogen atoms.

One method of making such polyamides is in U.S. Patent 2,450,940 and U.S. Patent 2,695,908. It will be on those in these References disclosed manufacturing methods of polyamides.

The binders and coating compositions according to the invention can be obtained for example, by moving the components with or without the application of heat simply mixed together. If one or more of the components are thick liquids or solids is generally used, preferably before or during mixing warmed up.

There can be various solvents or diluents that can be used volatilize before or during curing, added to the preparation to facilitate the mixture; the use of such substances is general not desirable because it generally reduces the curing time of the finished Products is extended. Suitable solvents include hydrocarbons, such as xylene, benzene and similar compounds. In some cases it is useful to only liquid epoxides, such as glycidyl polyethers of liquid under normal conditions Polyhydro alcohols, to be used as a diluent, or monoglycidyl derivatives, such as butyl glycidyl ether, allyl glycidyl ether, etc., or other reactive compounds, such as nitriles, for example acrylonitrile, propiononitrile and similar compounds, to use.

The ratio of bituminous materials and polyepoxides used in the mixture can vary depending on the desired properties of the resulting product. Mixtures with the properties described above, unexpectedly found, such as good compatibility, excellent adhesion and improved coating properties, are obtained by at least 50/0 of the polyepoxide, preferably 15 to 85 percent by weight, based on the mixture of bitumen and polyepoxide, adds.

There should be at least 0.8 equivalents of polyamide per equivalent of Polyepoxyds be present. (A chemical equivalent in this case refers to to the amount of amine that is required, one amino hydrogen per epoxy group deliver.) Preferred are amounts of about 0.8 to 4 equivalents of polyamide per equivalent Polyepoxide, preferably from 3 to 3.5 equivalents. It can be a proportion, for example up to 50 percent by weight of the polyamide by other fabrics, as in any of the above-mentioned long-chain acids, or by polyamines or known hardening agents, such as polyacid anhydrides, alkali compounds, metal salts and similar substances will.

A type of mixture according to the invention is particularly preferred in the case of inert solid particles either for the production of road paving or added to impart excellent slip resistance to the coating are. These particles should be finely divided and preferably a size of 0.05 to 5 mm. Preferred substances are, for example, sand, more finely divided Gravel, finely divided mussels, crushed quartz, molten aluminum oxide particles, Sand, finely divided resin particles and similar compounds. Particularly preferred are minerals, especially silicon-containing substances such as sand and ground gravel. Mixtures of the different types of particles can also be used.

The amount of inert particles added to the mixture is at least 50 percent by weight of the total mixture of bituminous materials and polyepoxide, preferably 70 to 2000 percent by weight of the mixture.

The inert particles can be added to the mixture prior to its use will. This method is preferred when the mixture is used as a binder comes. The mixture of bituminous materials and polyepoxide can also be applied first and then the inert particles are added. When pulling over highways the mixture of bitumen and polyepoxide can be applied directly to the road surface applied and the inert particles, such as sand, then before hardening on this Cover to be sprinkled.

The particles can be used at will to accelerate the hardening process be heated. Aggregates heated to 65 to 2000 C are useful to reduce the Shorten the curing time of road substructures and coatings.

The coating compositions according to the invention can be applied to any surface but are particularly suitable for cement, asphalt, wood and Stole. When thick coatings or those containing large amounts of inert particles, are to be produced, the coating mass is best done with a spatula, a trowel, shovel] or a broom. The thickness of the coatings varies generally between 1.5 mm and about 12 mm.

Unless otherwise noted, they are used in the following examples mentioned parts by weight. Those marked with letters in the examples Polyether resins are described in U.S. Patent 2,633,458. The one in the Cement used in the examples was made from hydraulic cement (Portland cement), whose aggregates contain sand and water.

Example 1 This example illustrates the preparation and some of the Properties of a mixture, the polyether A, a liquid polyamide from ethylenediamine and dimeric linoleic acid, which contains amino hydrogen and a Viscosity from 80 to 120 poise at 400 C and a specific gravity of 0.97 and also a directly distilled one that can be used for paving streets Contains bitumen. Polyether A is a glycidyl polyether of bisphenol with an epoxy value of 0.50 equivalents! 100 g, a molecular weight of 350 and a viscosity of 150 poise at 250 C.

There are 12 percent by weight of polyether A and 52 percent by weight immediately distilled bitumen mixed together with heating. This mixture were made 36 percent by weight of a polyamide made from diethylenetriamine and dimeric linoleic acid was added and the coating compound obtained on a section of an asphalt highway, which had been treated by detergents, as a coating of about 1.5 mm Sprayed on thick. In a short time, the mixture hardened at normal temperature to a homogeneous, resilient, flexible, tough, solvent-resistant coating, which had good adhesion to cement.

To test the resistance of the coating to solvents was fueled over the coating twice a day for jet aircraft sprayed. Even after 6 weeks of such treatment, there was no difference in condition to remember the pavement. Unmodified asphalt softened after one similar duration of treatment or use and began to dissolve.

Also metal plates (steel and aluminum) and cement plates or surfaces, that had been coated with the above mixture remained through jet fuels unattacked.

Example 2 With heating, 12 percent by weight of polyethers A and 52 percent by weight of immediately distilled bitumen mixed together. Thereupon 36 percent by weight of that of ethylenediamine and dimeric linoleic acid were added to the mixture Polyamide produced (see Example 1) added. This mixture was stirred and then applied to smooth cement in an amount of approximately 0.55 kg / m². The coating hardened to form a resilient, tough, flexible coating.

A similar attempt was made before the coating was complete had hardened, sand was strewn on it.

The resulting coating was hard and had good sliding properties. Spin resistance and good flexibility.

By varying the amount of polyamide from 10 to 20%, similar ones become Get results.

Example 3 This example illustrates the production of a thick one Street paving or a thick coating.

There was 12 weight percent polyether A and 52 weight percent one immediately distilled bitumen mixed with heating and on it 36 percent by weight of a liquid polyamide from a dimeric, soybean oil obtained fatty acid and diethylenetriamine containing amino hydrogen and a viscosity of 80 to 150 poise at 400 C added and one of the total mixture equal amount of crushed quartz added. After the mixture is completely put together it was applied in an amount of 5.5 kg / m² to a cement surface using a spatula and / or trowels applied. After a smooth layer was applied, was another amount of crushed quartz sprinkled over the surface and covered with one Lawn roller rolled in to get a firmer paving material. After the Once the hardening process is complete, the excess sand is brushed away. on Cement surfaces treated in this way exhibited good slip resistance or spin and good weather resistance.

Example 4 This example illustrates the manufacture and and some the properties of a mixture of polyether D and a polyamide of ethylenediamine, which contains amino hydrogen, and dimeric linoleic acid with a viscosity of 80 to 120 poise at 400 C and a low-viscosity, fast-hardening asphalt. Polyether D is the glycidic ether of bisphenol with an epoxy value of 0.20 equivalents' 100 g, a molecular weight of 900 and a melting point of 700 C.

Polyether D was in a solvent of 90 parts of xylene and 10 parts of Cellosolve dissolved in 700 / one concentration. The above-mentioned polyamide from ethylenediamine and dimeric linoleic acid became one in the same solvent 850 / 'own solution dissolved. 15 percent by weight of the polyether D solution, 15 percent by weight the polyamide solution and 70 percent by weight of a medium-hard cut bitumen with a viscosity of 100 to 200 SSF were mixed with one another at 600 C with heating. The resulting mixture was poured onto a section of a cement highway, which had previously been cleaned with hydrochloric acid, applied. The coating had a 1.5 mm thick. The mixture hardened after a short time at normal temperature to a hard, tough, solvent-resistant coating.

Example 5 The mixture prepared according to the preceding example was on an asphalt highway that had previously been treated with cleaning solution had been. applied. The coating was 1.5 mm thick. Before the hardening process When it was completely gone, sand was sprinkled over the coating.

The resulting coating or paving hardened a tough, resilient film that prevented sliding or skidding.

Example 6 There were 40 parts of polyether A with 60 parts of trimer Linoleic acid heated to a precondensation product. Thereupon this precondensate the polyamide described in Example 1 and a medium-hard cut asphalt with a viscosity of 100 to 200 SSF at 600 C. The components were in the following proportions are present: 23.6% average hardening asphalt fraction 21.3% Polyamide 22.0% polyether A 33.10 / 0 trimeric linoleic acid This mixture was stirred and 100 percent by weight of sand was added. Then this mixture became Applied as a thick coating on cement blocks and before the hardening process is complete had run, sand strewn over it. The result was a tough, resilient, solvent-resistant Coating that offered good resistance to sliding or skidding.

Example 7 Polyether A, that described in Example 1, was obtained Polyamide, an asphalt with a viscosity of 705 cSt at 600 C and a 12 carbons primary amine containing per molecule mixed with one another with heating. the individual components were present in the following proportions: 360/0 polyether A 30 ovo Bitumen 20% polyamide 14 0 / o Ct2 primary amine This mixture was stirred and then applied to an asphalt road in an amount of approximately 0.55kg / sqm. Sand was then sprinkled over the coating before the hardening process was complete was lost. Curing resulted in a hard, tough, resilient coating with sliding resistance.

The above experiment was repeated, with the modification that the original one Mixture 200 parts by weight of sand were added. This mixture was put over on it Spread cement and gave a hard coating with sliding resistance.

Example 8 This example illustrates the preparation and some of the Properties of a mixture, the polyether A, a polyamide according to Example 1 and Contained residual heating oil.

15 percent by weight of polyether A with 65 percent by weight became industrial extracted fuel oil mixed with the following properties: Density, O API (DIN 51 757) .. 8.0 Flash Point, PMCC. 820 C pour point. . 1.70 C viscosity, ............ cSt 370 sulfur content, percent by weight. 1.84 coal residue, weight percent. 19.0 20 percent by weight of the polyamide described in Example 1 was then added added.

This mixture was then put on a section of an asphalt road sprayed on as a coating approximately 1.5 mm thick. One sprinkled over the surface, before hardening was complete, 30 mesh aluminum oxide. It resulted in a hard, tough, weather-resistant coating with sliding resistance.

By replacing the above-mentioned residual heating oil with another one Light fuel oil with the following properties gave similar results: density, O API (DIN 51757) .. 17.0 flash point, PMCC. . 800 C pour point. 230 C viscosity, cSt .................... 52 sulfur content, weight percent .. 1.64 coal residue, Weight percent 9.0 Example 9 This example illustrates the manufacture and some the properties of a mixture, polyether A, a mixture of ethylenediamine and dimeric, Polyamide produced from soybean oil fatty acid according to Example 1 and contained an Edeleanu extract from petroleum distillates.

It became approximately 15 weight percent Polyether A with 65 weight percent of an extract from petroleum distillate mixed with the following properties: Density, O API (DIN 51 757). . . 5.8 Flash Point, Coc ........ 2130C viscosity, SSU at 990 C. 96.1 aniline point ................... ...... 270 C acid number (TAN-C) (ASTM D 664-54) 1.1 Iodine Number. . 69 There were 20 percent by weight of the example 1 described polyamide added. This mixture was then added at 200 percent by weight Aggregate of crushed gravel heated to 1200 C and placed on a prepared Road substructure applied and rolled in. After rolling in, the road was left rest until hardened. The resulting road surface was tough, flexible, and resilient against heat and solvents and offered good resistance to sliding or skidding.

Claims (8)

PATENT CLAIMS: 1. Asphalt-like binder and coating compound for building purposes, characterized in that it is a) a polyepoxide with more than one vicinal epoxy group, b) a polyamide which has amino hydrogen and preferably a reaction product of an aliphatic polyamine with a polybasic acid which has at least 7 carbon atoms between the acid groups, and c) Contains bitumen derived from petroleum. 2. Binder and coating composition according to claim 1, characterized in that that the bitumen substances are residual heating oils. 3. Binder and coating composition according to claim 1 and 2, characterized in that that the polyepoxide is a glycidyl polyether of a polyhydrophenol having a molecular weight is from 250 to 900. 4. Binder and coating composition according to claim 1 to 3, characterized in that that the polyamide consists of an aliphatic polyamine with a content of no more than 12 carbon atoms and polymeric fatty acids obtained by dimerization or Trimerization of ethylenically unsaturated fatty acids with a content of up to 24 carbon atoms are obtained. 5. Binder and coating composition according to claim 1 to 4, characterized in that that the polyepoxide in an amount of 15 to 85 percent by weight, based on the Mixture of the bituminous materials and the polyepoxide is included. 6. Binder and coating composition according to claim 1 to 5, characterized in that that the polyamide in amounts of 0.8 to 4 equivalents, preferably 3 to 3.5 equivalents is contained per equivalent of polyepoxide. 7. Binder and coating composition according to claim 1 to 6, characterized in that that there are also inert solid particles in an amount of at least 50 percent by weight, based on the total mixture of bituminous materials and polyepoxide. 8. Process for the production of an asphalt-like binder and Coating agent according to Claims 1 to 7, characterized in that a) a polyepoxide with more than one vicinal epoxy group, b) an amino hydrogen containing polyamide (from a polybasic acid, the at least 7 carbon atoms between the acid groups and an aliphatic polyamine) and c) bitumen materials obtained from petroleum mixed together and reacts. Publications considered: prospectus of Schering A. G., Berlin-West, October 1957, on Versamide, pp. 1, 3, 6, 7, 8; Company prospectus General Mills on Versamide Polyamide, Lesius, 1957, page 4, Table IV, pages 6 and 7. Table V.