DE2449211B2 - Mixture for the production of a cement-bound building material and its use - Google Patents

Description

In the invention of a mixture to Production of a cement-bound building material of the type mentioned in the preamble of claim 1 went out.

Concreted roads and other structures suffer considerable damage every year from the effects of frost and exposed to the effects of de-icing salts. Since the frost and de-icing salt damage for the most part by the penetration of water or saline solution into the cement mortar or concrete are caused, and there in particular the amount of water or salt solution absorbed by the capillaries Plays a role, a way was sought by excluding the coarse pore content, the absorption capacity to reduce the named materials for water and salt solutions and thus the by the Reduce the amount of water absorbed by capillaries as much as possible.

For the formation of frost damage, a water absorption of at least 7 percent by volume is required. The causes of damage lie in the ice crystallization pressure, the formation of cracks due to temperature fluctuations, the Salt crystallization pressure, the osmotic pressure etc. High quality portland cement mortar set and concrete can absorb 14 to 17 percent water by volume.

A method for improving the water resistance of cement plastic-based concrete has become known (DE-AS 10 99 925), in which the addition of dispersions of vinyl resins, especially polyvinyl acetate, for the mixture of cement and aggregates higher flexural strengths and better adhesion in the Causes dryness.

However, it has been observed that the basically waterproof concrete by adding polyvinyl acetate dispersion loses a significant amount of water resistance. Here is a copolymer of vinyl acetate-vinyl laurate bring an improvement.

Also known is a mortar base mixture (DE-AS 19 51 171) for the production of water-repellent, Breathable and highly adhesive insulating, laying and disposing mortars, which additives / on contains partially saponified polyvinyl acetate or vinyl acetate copolymers

In summary, it can be seen that when using the known methods and basic material mixtures, concretes are consistently obtained which, in addition to the gel pores, ie micropores of 2.5 × 10 ~ ⁸ cm in diameter and various other pores, above all have capillaries, which can be filled with water and for one ensure strong water transport in the cement stone. The frost resistance of these concretes is therefore naturally limited.

The invention specified in claim 1 is based on the object of a mixture of the above To create a genus that stands out in comparison to the conventional materials through an optimal tightness excels, d. H. their ability to absorb and store water and salt solutions in the long term Minimum is reduced.

This object is achieved according to the invention according to the characterizing part of claim 1 in Connection with its generic term. Advantageous developments of the invention emerge from the Features of claims 2 to 5.

When using the mixture according to the invention, a capillary-free, only inner crystalline gel pore is formed containing, cement-bound building material obtained.

In the gel pores, adsorption and chemisorption are predominant, and water transport can occur as a result these high forces no longer occur. According to the invention, concretes and mortars are thus for the first time without Air pores, d. H. without natural or artificially introduced macropores with high resistance to de-icing salt obtain.

The building material according to the invention can be produced by a liquid from water, a aqueous dispersion of the polymer plastic and the defoaming agent to form a premix Add cement and aggregates such as sand, gravel, grit and mix the whole thing intensively.

The polymerisation plastic can be a halogen-free homo- or copolymer, in particular an acrylate be. The defoaming agent can preferably be emulsion-stable and, for example, from a Mixture of fatty acid esters and higher hydrocarbons with carboxylic acid salts. Of the Defoaming agent content can be used for the purpose of achieving

^b0 an optimal density of the building material 0.2-4.0% by weight, based on the cement content.

Due to the composition according to the invention of the binder component, i. H. the definite ratio of Cement to water to polymer plastic too

⁶ "» Defoaming agent, it is possible for the first time to achieve a decisive reduction in the total porosity of mortar and concrete. The strong reduction or in some cases even elimination of the pores as well as voids and

Cavities, leads to cement-bound building materials of very high tightness, their total pore volume can be less than 8 volume% of the building material volume.

In addition, this composition causes a strong liquefaction (viscosity reduction) of the fresh concrete causes. A water-cement factor is therefore sufficient to set the required processing consistency (WZ) of less than 0.4, preferably 0.35. The WZ of 0.35 is practically the minimum required water content for the cement gel. Water volumes that exceed a WZ of 0.4 reduce the Quality and increase the percentage of voids in the concrete or mortar.

When hardening, the plastic dispersion immediately forms a plastic film on the surface and later in the body. It seals the mortar or concrete and also lowers the loss of water through evaporation The formation of capillaries is therefore greatly reduced. The plastic film is much less water-swellable, afs the known dispersion films and largely resistant to chemical degradation.

The building material according to the invention has a concrete watertightness. After five days of water storage Without a vacuum, the water absorption is 1.6 to 2.5% by volume, while it is with a good concrete conventional type has at least 9 vol .-%.

With the new cement-bound building material, the water absorption in a vacuum under water can be between 0.5 and 7.1 percent by volume of the building material volume, d. H. less than the gel pore volume of the Micropores of 0.0001-0.001 µ. In contrast, the water uptake in a vacuum under water is a normal mortar or concrete 12-20 percent by volume.

The new cement-bound building material has due to its minimal porosity compared to the conventional Mortar and concreting increase the strength, especially the flexural and compressive strength and an increased modulus of elasticity and an improved adhesive strength on the substrate. To the In addition, known cement mortars in layers of 2.5 cm and more must achieve good strength can be applied, whereas with the new building material also with coatings of 0.1 mm a good one Strength is achievable.

The building material according to the invention can be used as covering, structural and element concrete or mortar Find.

example 1

^{The damaged surface was milled 1 to 2 cm deep to a depth of approx. 30 m 2} on a worn concrete road with chipped areas, then a cement slurry according to the invention was applied in a layer thickness of 0/1 mm as a bonding bridge with lambskin wipers. The carriageway was then reprofiled with a cement mortar bound with Portland cement according to the invention in order to obtain a mortar resistant to frost and de-icing salt with high flexural and compressive strength. A vibrating beam was used for laying.

Composition of the cement slurry:

Portland cement 200 parts by weight

Water 20 parts by weight

Polyacrylate dispersion

(50% in water) 100 parts by weight

Emulsion stable

Defoaming agents

0.1 part by weight

320.1 parts by weight Composition of the cement mortar:

Portland cement 200 parts by weight

Water 20 parts by weight of polyacrylate dispersion

(50% in water) 100 parts by weight of emulsion stable

ίο Defoaming agent 0.1 part by weight of quartz sand

(Grain size 0/5 mm) 600 parts by weight

920.1 parts by weight

A test specimen was produced from the mortar mixture obtained, and the tightness measurement was carried out carried it cheat

the water-cement factor 0.35

the cement content / m ³ 533 kg

the density 2.3 kg / 1 the water absorption in vacuo

under water (AV) 2.7 vol%

From this the tightness was calculated dme follows d = 100-AV = 100-2.7 = 97.3%

Example 2

A mix of

Portland cement
Sand, grain size 0/3 mm
Grit, grain size 3/6 mm
Grit, grain size 6/16 mm
Chippings, grain size 16/25 mm

350 parts by weight 560 parts by weight 260 parts by weight 440 parts by weight 600 parts by weight 2210 parts by weight

was made with a liquid

water

Polyacrylate dispersion,
50% in water
Emulsion stable
Defoaming agents

105 parts by weight

34.98 parts by weight 0.02 part by weight

140.0 parts by weight

combined and mixed in a compulsory mixer. The concrete mix obtained was with a pavement concrete machine in a layer thickness of 5 cm on an already existing concrete sub-layer of a bridge applied and compacted in the usual way. It was

■> o a concrete covering with a very high resistance to frost and de-icing salt as well as a high flexural strength and compressive strength. From the obtained concrete mix In addition, a test specimen was produced and the following properties were determined on it:

Water-cement factor 0.35

Cement content per m ³ 350 kg

Volume weight 2.35 kg / l

Water absorption in vacuum

under water (AV) 10.10% by volume

Tightness d = 100-AV 89.9%

Proportion of spherical pores with

a diameter of less than 0.3 mm 2.61% by volume

example
A mix of

Portland cement

Sand, grain size 0/4 mm

300 parts by weight 680 parts by weight

Gravel, grain size 8/16 mm
Gravel, grain size 16/32 mm

was made with a liquid

water

Polyacrylate dispersion
50% in water
Emulsion stable
Defoaming agent

660 parts by weight
660 parts by weight

91 parts by weight
58.5 parts by weight
1.5 parts by weight

After that, a liquid was made from:

combined and mixed intensively in a compulsory mixer. The concrete mix thus obtained was pressed with pressure through pipes into a prepared formwork and with a Compacted vibrator A water-, liquid- and gas-tight concrete molding was obtained with a high Chemical resistance, which is ideal for protective structures against toxic liquids, vapors or gases suitable

A test specimen was also made from the concrete mix produced, and the following was made on this Properties determined:

Water-cement factor 0.4 Cement content per m ³ 300 kg Volume weight 2.45 kg / l Water absorption in a vacuum under water (AV) 7.9% by volume Tightness d = 100 - AV 92.1%

Example 4
A premix was made from:

Portland cement
Sand, grain size 0.3 mm
Chippings, grain size 3 / fi mm
Grit, grain size 6/16 mm
Chippings, grain size 16/25 mm

350 parts by weight 560 parts by weight 260 parts by weight 440 parts by weight 600 parts by weight 2210 parts by weight

water

Air entraining agent!

Polyacrylate dispersion

(50% in water)

Emulsion stable

Defoaming agent

105 parts by weight
0.5 parts by weight

34.8 parts by weight

0.2 part by weight
140.5 weight units

prepared, initially the air entraining agent dispersed in water and then stirred in the polyacrylate dispersion and the defoaming agent became. The solid part mixture was then mixed with the liquid in a compulsory mixer

The concrete mixture obtained was applied in a pavement concrete machine in a layer thickness of 5 cm already existing concrete sub-layer of a bridge was applied and compacted in the usual way a concrete pavement with very high resistance to frost and de-icing salt as well as high flexural and compressive strength obtain.

A test specimen was also produced from the concrete mix obtained, and the following test specimens were used on it Properties determined:

Water-cement factor 0.35 Cement content per m ³ 350.0 kg Volume weight 2.38 kg / l Water absorption in vacuum under water (AV) 11.70% by volume Tightness d = 100-AV 88.30% Percentage of air pores with a diameter less than 0.3 mm 3.10% by volume

Claims (5)

Patent claims: 1. Made of cement, aggregates, a polymer plastic and water existing mixture for the production of a cement-bound building material with optimal tightness, which is capillary-free in the bound form and next to a minimum of Macropores contains only gel pores, characterized in that these, based on the Amount of cement, 4.8-40% by weight of a cement-compatible homopolymer or copolymer Acrylate 33-40% by weight water 0.001-4.0% by weight of a defoaming agent contains 2. Mixture according to claim 1, characterized in that the defoaming agent is a mixture from fatty acid esters and higher hydrocarbons with carboxylic acid salts. 3. Mixture according to claims 1 and 2, characterized in that it contains 0.2-4.0% by weight Contains defoaming agent. 4. Cement-bound building material produced from the mixture according to claim 1, characterized in that that its total content of cement-dependent gel pores and the minimum of macropores is less than 8 percent by volume of the building material volume. 5. Use of the building material according to claim 4 as covering, structural and element concrete or -mortar.