DE1256136B - Building material mixes made from cement with aggregates and plastics - Google Patents

Description

f> EUT S CH E S

PATENT OFFICE

EDITORIAL

German class: 80 b -1/05

Number: 1 256 136

File number: W 41191 VI b / 80 b

Filing date: March 22, 1966

Opened on: December 7, 1967

It is known that some properties of concrete and mortar, e.g. B. the flexural strength and Abrasion resistance as well as the strength of the adhesion of fresh concrete and mortar to old concrete and Mortar, by adding aqueous dispersions of thermoplastics or dry, redispersible powders of such plastics to the building material mixtures of cement and aggregates can improve. The one from the previously known building material mixtures of cement, plastics and additives manufactured concrete and mortar, d. H. previously known so-called »plastic concrete« or "Plastic mortar", however, has the disadvantage that its strength values under the action of water fall below the values that concrete and mortar made without the use of plastics exhibits under the action of water. This drop in strength values is likely to be at least partially on emulsifiers and / or protective colloids, which necessarily with the plastics in the concrete and mortar are introduced. The addition of plastics also leads to a increased air entrainment, the increase in strength that can be achieved by adding the plastics counteracts.

The building material mixtures according to the invention from cement, plastics and aggregates result on the other hand, a concrete or mortar, in which the disadvantages described above are greatly reduced.

The building material mixtures according to the invention from. Cement, aggregates and 2 to 20 percent by weight, based on the weight of the cement, of plastic are characterized in that they contain 0.02 to 2 percent by weight, based on the weight of the plastic, gluconic acid and / or its derivatives contain.

The percentages given in the description and claims relate to ' Dry weights.

It is already known to add gluconic acid or its derivatives to plastic-free building material mixtures made from cement and aggregates in order to save mixing water and thereby increase the hardness and strength of the concrete or mortar. In these . ■ Known building material mixtures, however, had to use setting accelerators such as alkaline earth chlorides, ammonium chloride or alkaline earth lignin sulfonates in order to compensate for a delay in the setting speed caused by the gluconic acid or its derivatives. However, the use of such setting accelerators is often undesirable. Surprisingly, the building material mixtures according to the invention made of cement with aggregate
and plastics

Applicant:

Wacker-Chemie G. mb H.,
Munich 22, Prinzregentenstr. 22nd

Named as inventor:

Dr. Eduard Bergmeister,

Dr. Paul-Gerhard Kirst, Burghausen (Obb.)

In contrast to the previously known gluconic acids or their derivatives containing building material mixtures, building material mixtures do not contain any setting accelerators such as alkaline earth chlorides, ammonium chloride or alkaline earth lignin sulfonates; Building material mixtures according to the invention have rather whether or not containing a accelerators befriedi ₇ quietly short setting time and the concrete or mortar prepared from these building material mixtures having even without reducing the amount of mixing water high strength. In the mixtures according to the invention, the gluconic acid or its derivatives act primarily as air-entrainment agents.

The gluconic acid and / or its derivatives are preferably used in amounts of 0.05 to 1 percent by weight, based on the weight of the plastic.

It can be dl-, d- or 1-gluconic acid as gluconic acid be used. As their derivatives are gluconic acid-o-lactone, Gluconic acid-γ-lactone, alkali or alkaline earth salts are preferred. It can be mixtures of various gluconic acids and / or their derivatives can be used.

The cement can be the commercially available types of cement, such as Portland cement, iron Portland cement, Blast furnace cement, natural cement, molten cement or mixtures of these types of cement Act.

Anyone who is interested in the preparation of building material mixtures can be used as plastic Cement, plastics and aggregates are suitable. The plastic can thus be, for example, polymers of vinyl acetate to make copolymers of vinyl acetate with maleic acid esters, acrylic acid esters, Vinyl esters of aliphatic monocarboxylic acids with 3 to 18 carbon atoms and / or vinyl chloride, to polymers of vinyl chloride, to mixed poly-

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merisate of vinyl chloride with vinyl propionate, vinylidene chloride, acrylonitrile and / or acrylic acid ester ^ to polymers of acrylic acid esters and / or methyl acrylic acid esters or copolymers Act butadiene and styrene. ·.

Mixtures of different plastics can be used.

The plastics can be in the form of non-organic or anionic aqueous dispersions, which act as dispersants in addition to emulsifiers, optionally protective colloids, such as polyvinyl alcohol and polyvinylpyrrolidone or cellulose ethers, or in the form of, for example, prepared by drying such dispersions redispersible powders can be used.

It is advisable to add the gluconic acid and / or its derivatives to the plastics before mixing them Add cement and aggregates.

All those that are commonly used as additives in the can be used as aggregates Preparation of building material mixtures from cement and aggregates are used. Such aggregates are z. B. sand, gravel and / or lime. The aggregates are used in conventional proportions used by cement and aggregates.

The known defoamers, in particular those based on organopolysiloxanes, in particular of dimethylpolysiloxanes end-blocked by trimethylsiloxy groups, optionally in a mixture with pyrogenic silicon dioxide generated in the gas phase, in amounts up to 1 percent by weight, based on the dry weight of the plastic.

It has been shown that concrete and mortar from the ■ building material mixtures according to the invention are essential have higher flexural and compressive strength than concrete and mortar made from building material mixtures that apart from cement and aggregates only contain gluconic acid or its derivatives or only plastics. This also applies if defoamers are also used. It is particularly noteworthy at Concrete and mortar from the building material mixtures according to the invention also take place with wet storage strong increase in strength within 3 days after adding the mixing water. Also wise Concrete and mortar from the building material mixtures according to the invention on old concrete, mortar, asbestos cement and other mineral substrates or on ceramic substrates a higher bond strength on as concrete and mortar from building material mixtures of cement, plastic and aggregates, the Does not contain gluconic acid or its derivatives.

The building material mixtures according to the invention can be used for all purposes in which building material mixtures made of cement, plastic and aggregates can be used. This includes manufacturing of screeds, industrial floors, adhesive bridges for the connection of old concrete with new concrete, the production of moldings in civil engineering, the filling of unwanted holes and cracks in Old concrete as well as the use as cement plaster mixes.

example 1

100 g of a commercially available 50 weight percent aqueous dispersion of a copolymer of 50 weight percent ethyl acrylate, 10 weight percent methyl acrylate, 20 weight percent methyl methacrylate and 20 weight percent ethyl methacrylate are mixed first with 0.2 g of gluconic acid <5-lactone and then with 175 g of water. The mixture obtained in this way is divided into a mixture of 500 g Portland cement PZ 275 (cf. DIN regulation 1164 of December 1958, § 1), 500 g standard sand I (fine) (see DIN regulation cited § 8) and 1000 g standard sand II (coarse) (see quoted DIN regulation § 8) thoroughly mixed in. The test specimens are otherwise produced as described in the cited DIN regulation § 25. The storage of the specimens is carried out at 2O ⁰ C and at a relative humidity of 65 weight percent (standard atmosphere) or under water. The strength values given in the following tables were carried out with the devices described in the above DIN regulation § 16 and § 17, as specified in the same DIN regulation § 25.

Table I.

Additive to cement, sand and water *)

Air void content in percent by volume Bending tensile strength in kp / cm ^a
after 28 days of storage

in standard climate I under water

Compressive strength in kp / cm ²
after 28 days of storage

in standard climate I under water

No addition

Plastic alone

Plastic + gluconic acid lactone

*) Total amount of water 225 g each.

4.6 15.0 10.8 67.3

86.3

113.6

73

56.3

81.6

398
296
373

440
223
368

Example 2

1. 200 g of a commercially available 50 weight percent aqueous dispersion of a copolymer of 50 percent by weight vinyl acetate, 25 percent by weight of vinyl laurate and 25 percent by weight of vinyl chloride are initially added at 0.6 g Gluconic acid-o-lactone and then with 0.8 g of an im Commercially available 20 weight percent aqueous emulsion of a mixture of 93 weight percent Dimethylpolysiloxane end-blocked by trimethylsiloxy groups with 350cSt / 25 ° C and 7 percent by weight pyrogenic silicon dioxide produced in the gas phase is mixed as a defoamer.

II. 150 g of the mixture thus obtained are mixed with 300 g of water. With the thus obtained diluted Dispersion (a) and, for comparison with water (b) without additives, with one as above described, but diluted dispersion prepared without the use of a gluconic acid derivative (c) and with water (d), containing 0.12 g of gluconic acid-δ-lactone, each is Portland cement

PZ 275 to a pulp with standard rigidity [cf. DIN regulation 1164 of December 1958, § 24b), 1] touched upon. Then the start and end of the solidification of the mixtures, as in the. mentioned DIN regulation §24b), 2 and 3, described.

Table Ha

g liquid, Freezing Solidification necessary beginning end Fluid to the speed achievement the 210 minutes 230 minutes Standard rigidity 130 minutes 160 minutes a 77.5 180 minutes 210 minutes / b 76.5 over 8 hours over 8 hours C. 78 .. d 72

III. 100 g of the mixture of plastic dispersion, gluconic acid derivative and defoamer prepared as described under I are mixed with 175 g of water. With the diluted dispersion (a ') thus obtained and for comparison with 225 g of water φ') without addition, 225 g of water (c '), containing a total of 0.04 percent by weight, based on the weight of the cement, of gluconic acid-o- lactone, and with a dispersion (d ') of 100 g of that described under I.

ία 50 weight percent aqueous plastic dispersion, 0.7 g of the defoamer emulsion described under I and 175 g of water and in each case that described in Example 1 Portland cement-sand mixture », v / ie in DIN regulation 1164 of December 1958, §25 described, under determination of the slump test specimens produced and their flexural strength and compressive strength after 3 and 28 days at 28 ° C and a relative humidity of 65 percent by weight (Standard climate) or determined under water.

Table Hb

Air pores Slump Flexural strength in kp / cm ² under 28 days under Compressive strength in kp / cm under 28 days under Fluid salary in 3 days water standard water 3 days water standard water speed Volume cm standard 61 climate 86 standard 302 climate 476 percent 17.0 climate 55 117 73 climate 306 457 440 a ' 4.8 11.3 75 56 67 80 308 283 398 454 b ' 4.6 11.3 44 41 78 69 323 172 401 313 c ' 6.2 17.2 54 96 278 322 d ' 5.4 48 192

Example 3

35

100 g of a commercially available 50 weight percent aqueous dispersion of a copolymer of 60 weight percent styrene and 40 weight percent butadiene are mixed first with 0.2 g of sodium gluconate and then with 175 g of water. From the mixture thus obtained and the cement-sand mixture described in Example 1, test specimens are produced, as indicated in Example 1, and these specimens are tested. _{The compressive strength 'is about 10 ° / 0} after storage in a standard climate as well as after storage in water, the flexural strength after storage in a standard climate 10 ° / ₀ , after storage under water 15 ° / ₀ higher than the corresponding values, which are achieved with the polystyrene-butadiene dispersion without the addition of sodium gluconate.

Example 4

55

100 g of a commercially available 50% strength by weight aqueous dispersion of polyvinyl acetate which is plasticized with 8% by weight, based on the weight of the polyvinyl acetate, of di-n-butyl phthalate are mixed first with 0.3 g of calcium gluconate and then with 175 g of water. As indicated in Example 1, test specimens are produced from the mixture thus obtained and the cement-sand mixture described in Example 1, and these specimens are tested for their flexural strength. The flexural tensile strength after storage in a standard climate is 14 ° / ₀ , after storage under water 9 ° / ₀ higher than the corresponding values achieved with the polyvinyl acetate dispersion without the addition of calcium gluconate.

Example 5

100 g of a commercially available redispersible plastic powder, produced by spray drying a plasticizer-free polyvinyl acetate dispersion are mixed with 0.3 g of gluconic acid-o-lactone. 50 g of the mixture thus obtained are first mixed with the cement-sand mixture described in Example 1 and then mixed thoroughly with 225 g of water. The ones mentioned in Example 1 Test specimens produced in accordance with DIN regulations show a significant improvement in the strength properties with respect to the strength properties of test specimens, which in the manner described above, but without the use of a gluconic acid derivative.

Example 6

100 g of a commercially available 50 percent strength by weight aqueous dispersion of a copolymer from 40 percent by weight vinyl chloride and 60 percent by weight vinyl propionate are 0.3 g Gluconic acid-o-lactone mixed. One part by weight of this mixture is initially mixed with 2 parts by weight Water and then in a mixture of 8 parts by weight of Portland cement PZ 275 and 45 parts of sand with the Grain size 1 to 7 mm mixed in according to the grading curve B according to DIN 1045. The mixture thus obtained is spread out on an old concrete slab and left to harden for 4 days. The screed produced in this way is tested by dropping a 20 kg steel ball from a height of 2 m. The screed will

not damaged while doing the same test as described above, but without With the use of a gluconic acid derivative, screed is detached from the base and in several parts splintered.

Claims (6)

Patent claims: 1. Building material mixtures of cement, aggregates and 2 to 20 percent by weight, based on the weight of the cement, in terms of plastic, characterized by being 0.02 to 2 percent by weight, based on the weight of the plastic, of uluconic acid and / or its Contain derivatives. 2. Building material mixtures according to claim 1, characterized in that they are 0.05 to 1 percent by weight Gluconic acid-o-lactone, alkali and / or Contain alkaline earth salts of gluconic acid. 3. Building material mixtures according to claim 1 and 2; characterized in that it is made of plastic Polymers of vinyl acetate and / or copolymers of vinyl acetate with acrylic acid esters, Maleic acid esters, vinyl esters of aliphatic monocarboxylic acids with 3 to 18 carbon atoms and / or vinyl chloride. 4. Building material mixtures according to claim 1 and 2, characterized in that they are made of plastic Polymers of vinyl chloride with vinyl propionate, vinylidene chloride, acrylonitrile and / or acrylic acid ^ contain esters. 5. Building material mixtures according to claim 1 and 2, characterized in that they are made of plastic Contain copolymers of styrene and butadiene. 6. Building material mixtures according to claim 1 and 2, characterized in that they are made of plastic Contain copolymers of acrylic acid esters and methacrylic acid esters. 709 707/516 11.67 O Bundesdruckerei Berlin