DE2222573A1 - Mortar - contg a polyester,a catalyst and a filler - Google Patents

Abstract

The polyester contains a highly flexible copolymer and an an essentially rigid copolymer, the former having low visc. and being present in wt. ratio 2:1 to 5:1 w.r.t. rigid copolymer; and the mortar compsn. undergoing shrinkage, on curing, of not more than 1 vol.%. Pref. the initial viscosity of the flexible polymer is 6 cP.

Description

Mortar compound, particularly for use in road construction. The invention relates to polyester-containing compounds for use as mortar in road construction, in construction of bridges and runways and for similar purposes.

US Pat. No. 3,008,387 describes a compound for road surfaces and the like containing a polyester blend and a filler such as quartz. The polyester part is made up of a larger part of a normally rigid polyester formed together with a smaller proportion of a flexible polyester.

In contrast, the invention is based on the surprising finding from that an improved mortar mass is obtained, which also becomes blocks can be poured when you get into the mortar Incorporates polyester, which consists mainly of a flexible polyester of low viscosity.

Accordingly, the mortar composition according to the invention contains: a) a highly flexible one Polyester copolymer of low viscosity, that is, with a viscosity of less than about 6 cP, b) a substantially rigid polyester copolymer, the em / Components a) and b) in a weight ratio of 2 to 5 to 1, preferably about 4 to 1 are present, c) a redox catalyst system, d) a filler, wherein the mixture shows a shrinkage of no more than 1% by volume on setting.

This mortar mass can be factory-made under easily controllable Pour conditions to form a block of about 15 cm thick. The blocks show a high degree surface abrasion resistance, as well as a noticeable resilience. Because the blocks can also be cured under precisely controlled conditions the Control the degree of cure so that there is no need to place the mixture in place and place - often under unfavorable, wet and cold environmental conditions and harden.

The polyester copolymers of the mortar mass can be prepared according to known methods Win procedure. The highly flexible copolymers are preferably converted by reaction made of the following ingredients: 1) a polyol of the general formula HO - X - OH or X (OH) 3 in which X represents a straight chain of 4 to 6 methylene groups, which optionally by an ether oxygen atom or in the presence of 6 methylene groups is interrupted by a maximum of 2 ether oxygen atoms, 2) one Ethylenically unsaturated acid, 3) an acid, and 4) an ethylenically unsaturated one aromatic hydrocarbon or aliphatic ester, where component 3) in a proportion of 1.5 to 3 moles per mole of component 2) is used. The bn essential stare Copolymers are made by reacting 1,2-propylene glycol, Maleic acid, another acid and an ethylenically unsaturated aromatic Hydrocarbon or an aliphatic ester produced.

Component 1) is preferably diethylene glycol, but can also Be triethylene glycol or hexamethylene glycol. Ingredient 2) can be maleic acid, Citraconic acid or itaconic acid.

Component 3) is preferably phthalic acid, a halophthalic acid or a hydrogenated phthalic acid, either alone or together with one long-chain dicarboxylic acid such as sebacic or adipic acid or a long-chain fatty acid such as lauric or stearic acid. The component 4) is preferably styrene, methyl styrene, Divinylbenzene or another ethylenically unsaturated monomer such as methyl methacrylate or acrylate. Anhydrides of the specified acids can also be used. The highly flexible polyester is preferably made by first having a Polyester from components 1), 2) and 3) forms, component 1) in one small excess of, for example, up to 10% over that for the esterification of the Components 2) and 3) required amount is available; the implementation takes place under Reflux conditions to obtain a product whose viscosity is less than 5 cP. This polyester is then included in component 4).

To form the substantially rigid polyester, it is preferred the glycol and maleic acid react with one another in practically equimolar amounts and then take up the product obtained in styrene.

The actual mix is conveniently made by adding the both styrene solutions and addition of a small amount of polymerization inhibitor, for example, from tertiary butylcatechol.

The redox catalyst system is preferably a benzoyl peroxide and Tertiary amine system or a cobalt naphthenate-containing catalyst system or a mixture of a naphthenate or linoresinate of another polyvalent metal as an activator and methyl ethyl ketone peroxide or any other hydroperoxide as a catalyst.

The filler can be any filler material which has good abrasion resistance. Melted and calcined ones are particularly valuable Clays, silicic acids or silicates. So much filler peat should be added in each case be that the mass gets the consistency of a stiff paste, which is spatula and let it condense. Because of the good wetting properties and the low viscosity of mixes for it is the filler particles or aggregates possible to incorporate so much filler that die.fertige mass 80 wt.% and above contains fillers.

(Aggregates) The liquid mortar mass preferably contains coarse Aggregates Preferably, the minimum average particle size is the coarse Aggregates at about 0.6 cm, i.e. a particle size which is the same as that of the aggregates in known resinous mortars. The best wise Aggregates have an average particle size of 0.9 cm. The maximum particle size depends on the intended use of the mortar mass, the aggregates can be made from a large number of inorganic or organic, natural or synthetic Fabrics are selected. Preference is given to aggregates that do not have a lamellar structure own; for cost reasons and because of the convenient accessibility, this is called Criggion Green designated material is particularly preferred.

The proportion of aggregates in the mortar can be between about 30 and 100 Vol, X, preferably up to about 75% by volume.

A block made from the mortar composition according to the invention can embed themselves in a mortar, which is advantageous alkali-resistant is good, shows good resistance to abrasion from traffic and good bond strength owns with concrete. It is best to use the same mortar that the block is made of is made, but the mortar can be made with the help of any unsaturated polyester or epoxy resin.

Typically, the polyester resin can consist of a single resin or consist of a resin mixture. A typical universal polyester resin can be achieved by a known reaction of one mole of fumaric acid or maleic anhydride and one mole of phthalic anhydride with 2.2 moles of 1,2 propylene glycol, wherein finally diluted with styrene to the desired concentration, usually around 65% will.

Following the addition of suitable hardeners, the resin is subject to one free radical induced vinyl polymerization at room temperature or elevated Temperatures, resulting in a hard, somewhat brittle solid. The flexibility and compliance of such a resin can be increased by replacing one Part of the acids given above by an aliphatic saturated dicarboxylic acid, in which the carboxyl radicals are separated from one another by three or more methylene groups are, for example, glutaric or adipic acid, andS or by replacing part of the Glycols specified above by longer-chain diols, for example 1, 4-butanediol, 1,5-pentanediol or glycol ethers, for example diethylene and dipropylene glycols. A certain Flexibility can also be achieved in that the aromatic phthalic acid in the reaction mixture by a hydrogenated derivative like tetrahydrophthalic anhydride.

Such modified resins are called flexibilized polyester resins designated. The functionality can be reduced if you have a monobasic or a dibasic acid, preferably a long chain acid such as for example Tall oil or coconut oil is used. Preferred epoxy resins are flexible resins, which cure to the desired epoxy resin component of the mortar. Preferred flexible resins include Shell Epikote 871, CIBA GY 292, DOW DER 732, Proctor & Gamble Flexibiliser 151.

Preferred hardeners include: primary and secondary aliphatic, cycloaliphatic, aromatic or heterocyclic aralkyl or alkaryl polyamines, Polyaminoamides, polysulfides, polymercaptans or aniline-formaldehyde resins.

The use of a plasticizer is beneficial for hard, tough resins; suitable agents include: esters, chlorinated paraffins, high-boiling oils, Polysulphides, pine oils, benzyl alcohol, low molecular weight polymers based on styrene, Coal tar, furfuryl alcohol and coumarone / indene resins.

Hydraulic cements of sufficient strength including such hydraulic cements modified by polymers or reinforced by fibers can be used as mortar. Other suitable mortars are based of polyurethanes, furans or cold-setting phenols. An inventive Mortar mass can be used to embed a block made of natural or artificial stone is made, for example, of granite, acap t slag, or air-dried calcined bricks or hydraulic cements including hydraulic cements, which are modified by plastics or epoxy resins.

The mortar mass and the blocks according to the invention are particularly preferred used for making expansion joints for roads; compare the essay by Goodman in the Journal of the Institution of Iighway Engineers, May 1971. The blocks are preferably placed in gaps about 11 cm deep.

The following examples are intended to explain the invention in more detail serve: Example 1 100 g of a commercially available flexible polyester with a viscosity of about 2 cP (made from diethylene glycol, maleic acid and phthalic acid) in In the form of a styrene solution containing 60% by weight, 53 g of a commercially available, essentially rigid polyester (made from 1,2 ^ propylene glycol and maleic acid together with phthalic anhydride) in the form of a styrene solution containing 70% by weight mixed, with 1.75 g of a 10% dimethylaniline solution in styrene 1 g of a 1% tertiary butylcatechol solution in styrene and 3 ml of a 10% paraffin solution in styrene were added. The product was an easily processable liquid polyester blend, which are combined with the following ingredients that have already been mixed together was: 890 g finely divided clay 175 g silica (0.190 mm clear mass width) 10 g of benzoyl peroxide as a catalyst A paste-like mortar mass was obtained, which hardened into a rigid block whose shrinkage was less than 1 % By volume. This trestle was made into a Street joint embedded and formed a road sleeper with good abrasion resistance.

Example 2 The liquid polyester mortar of Example 1 was made with added to a previously prepared mixture of the following ingredients: 890 g fine slag 175 g silica (particle size below 0.190 mm lighter Mesh size) 10 g benzoyl peroxide as a catalyst (20% active ingredients in one inert carrier) 490 g of Criggion Green A mass was obtained which, as a mortar was suitable for anchoring a road sleeper in a concrete road surface.

Example 3 The procedure of Example 2 was repeated except that the Premix contained 300 g of Criggion Green.

Example 4 Example 2 was repeated, but with a premix Was used which contained 700 g of Criggion Green.

Example 5 The procedure of Example 2 was followed using a Repeated premix containing 925 g of Criggion Green.

Example 6 The mass of Example 4 was poured into two 5 cm cubes, which has a density of about 2.56 g / cm3 and a compressive strength of 1050 kg / cm2 exhibited. Cast cubes of a similar composition but without rough ones Aggregates had a density of about 2.48 g / cm² and a compressive strength of 1,100 kg / cm², which shows that the presence of the coarse aggregates is mechanical Properties of the set mortar not affected.

Example 7 A mortar mass was prepared according to the instructions of Example 1 produced and used to use a granite block as a threshold in a Embed road surface. The embedding was possible even at temperatures up to Slightly duII it down to 0 ° C and within 24 hours the traffic was able to cross the threshold created in this way again without impairment flow.

Example 8 The procedure of Example 7 was repeated, wherein however, a block made from an epoxy resin mortar was used which contained the following ingredients: 100 parts CIBA GY 250 20 parts chlorinated biphenyls 15 parts Laromin C 260 13 parts Laromin C 252 10 parts benzyl alcohol 5 parts of phenol The same results were obtained.

Examples 9 and 10 A polyester-based mortar composition was made from Bakelite 19273 and 0.2% by weight dimethylaniline, 2% benzoyl peroxide as a catalyst and finely divided Alag made as a filler.

A mortar mass based on epoxy resin was made from 100 g of CIBA GY 250 and 20 g chlorinated biphenylene, 15 g Laromin C 260, 13 g C 252, 10 g benzyl alcohol and 5 g of phenol prepared. Tests were done by removing blocks from the hardened Mixture of example 1 embedded in a street column and with the neighboring ones Walls of the column were joined using the mortar given above. The distance between a side surface of the respective block and the column wall was about 2.5 cm. In both cases the blocks could easily be made using the Fix mortar masses so that usable road sleepers were obtained.

Claims (8)

Claims 1. Mortar, especially for use in road construction, which a polyester, a catalyst suitable for this and a filler wherein the polyester is a highly flexible copolymer and a substantially rigid one Contains copolymer, characterized in that 'the highly flexible copolymer low Has viscosity and in a weight fraction of 2 to 5: 1, based on weight of the substantially rigid copolymer, is present; the mortar mass upon curing shows a shrinkage of not more than 1 vol.%. 2. mortar mass according to claim 1, characterized in that the highly flexible Copolymers has an initial viscosity of less than 6 cP. 3. Mortar mass according to claims 1 or 2, characterized in that that the weight ratio of highly flexible copolymers to essentially rigid Copolymers is about 1: 4. 4. mortar mass according to claims 1 to 3, characterized in that that the filler content based on the mortar mass is about 80%. 5. Block of hardened mortar mass according to claims 1 to 4. 6. Block according to claim 5, characterized in that it has a strength has up to about 15 cm. 7. Street expansion joint or the like, characterized in that it contains a mortar mass according to claims 1 to 4. 8. street expansion ruge or the like, characterized in that it contains a block according to claims 5 or 6.