DE3731993A1 - Light-weight (breeze) concrete for construction - Google Patents

Abstract

The invention relates to a dense-microstructure light-weight concrete for construction on a pure mineral base and having a dry bulk density in the range from 600 to 850 kg/m<3>, which contains aggregates of low density whose surface was optionally subjected prior to use in concrete or mortar mixtures to a treatment with compounds forming silica, and also a process for the production thereof. The dry bulk density is, in particular, set by the use of treated aggregates of low density which were brought into contact with organosilicon compounds which are liquid at room temperature and form silica on hydrolysis.

Description

The invention relates to a structure-tight lightweight concrete on a purely mineral basis and a process for the same Manufacturing.

Structural lightweight concrete with limited thermal insulation capacity, depending on the strength and bulk density for load-bearing concrete components and concrete structures such as residential buildings, high-rise buildings, bridges, etc. are used according to Ullmann, Encyklopedia of technical Chemistry, 4th edition, volume 8, page 324 known. After the however, it is not known methods of the prior art possible to use a lightweight concrete with a density of less than To produce 850 kg / m³ on a purely mineral basis, which in its structure is as dense as normal concrete, which is about one Dry bulk density of 2300 kg / m³ and the same time can be used for constructional purposes. The so far known lightweight concrete on a purely mineral basis with a Dry bulk densities of less than 850 kg / m³ are not structure-tight. These so-called aggregate pores have besides the advantage of low weight and high thermal insulation major disadvantages. You can't use them statically use. Because the rebar is more or less exposed,  d. H. is not surrounded by protective concrete parts, are the rebars attacking atmospheric oxygen, Exposed to water and acid from the atmosphere, if you don't have the rebar before using it a protective coating made of cement paste, for example provides. Accordingly, a spiked Light concrete only as an intermediate layer between two normal concrete slabs be used and is not for visible surfaces suitable.

Structural lightweight concrete that is not structurally resilient is, can be by using special Additives or additives to concrete and mortar mixes produce with low density. For example can be used as low density aggregates pumice, expanded clay and expanded slate are used, such surcharges low density, however, have low grain compressive strength, so that such lightweight concrete only for extremely low loads are designed.

Lightweight concrete that is to be used directly for static purposes, accordingly, the requirement of structural density fulfill. Such structure-sealed lightweight concrete have a dry bulk density of far more than 850 kg / m³ and usually have a bad one Thermal conductivity. With the mere use of Light aggregates such as expanded clay or inflatable grinders can only that concrete strength can be achieved which is such a light aggregate as grain pressure resistance having. Therefore, according to the state of the art Lightweight concrete to increase the compressive strength with heavy aggregates, which have a higher grain pressure resistance had, for example quartz sand. Of course, this leads to the loss of the minor Weight and at the same time increases the thermal conductivity.

The object of the present invention was a structure-sealed lightweight construction concrete on pure to provide a mineral base, the one Dry bulk density of at most 850 kg / m³.

An essential task for a structure-tight lightweight construction concrete according to the present invention is that the tremendous lightness of the invention manufactured concrete using a conventional reinforcement methodology to new design (application) possibilities leads. Larger ones can be used here Spans and thinner designs can be realized.

In addition, despite the thin design, it remains the same Heat transfer coefficient (K value) reached shall be. The relationship between dry bulk density and thermal conductivity allows that at comparable Layer thickness greater thermal insulation achievable are.

A key feature of the present invention is that this lightweight construction concrete around a lightweight concrete with closed Structure must act. This enables this new one Material as lightweight construction concrete and as Use exposed concrete.

Another and also from the conventional designs differing task of the invention Concrete is a continuous one Diffusion transport, for example of condensation water, without any level of condensation. This is with the multitude of marketable systems only through complex constructions (e.g. sandwich Construction) in the context of the combination of different Materials possible.  

Another essential object of the present invention is a simple and straightforward To develop production as factory production, using essential parts of conventional systems should be and only partially through technological Changes require retrofitting.

Furthermore, the object of the present invention exists in that the concrete technology that has existed for decades and in particular the manufacture of the Construction lightweight concrete mixes on the construction site should be changed as little as possible.

The above object is achieved by that one uses low-density supplements, one increased grain pressure resistance compared to the prior art have, especially by going to increase the grain compressive strength and the reduction of Water absorption capacity of the supplements with lower Density subjects it to a surface treatment.

The invention thus relates to Structural lightweight lightweight concrete on a mineral basis Base with a dry bulk density in the area from 600 to 850 kg / m³, the low density aggregates contains, the surface of which before use in concrete or mortar mixtures, if applicable, of a treatment subjected to compounds forming silica has been.

According to a preferred embodiment of the present Invention becomes a lightweight structural concrete on a purely mineral basis with a Dry bulk density in the range from 600 to 750 kg / m³ for Provided.  

Manufactured using the present invention Lightweight concrete has a very good nominal strength. A structure-proof lightweight concrete according to the invention should therefore be in the previously unknown Strength class of the lightweight concrete LBn 50 according to Ullmann, loc. cit. or LB-5 according to DIN 4219 Part 1 will. This division of strength classes becomes on the one hand by the density of the concrete and by determines the strength. Ullmann is the lowest known value a strength class of LBn 100 corresponding to a nominal strength of (100 kg / mm²) 10 N / mm², while according to DIN 4219 part 1 lightweight concrete up to class LB-8 which are only for unreinforced Components, here for walls according to DIN 1045 and for Facades and parapet elements are only allowed are burdened by their own loads and wind, d. H. with predominantly static loads.

One advantage of the concretes according to the invention is in particular in that due to the structural density in the reinforcement bars inserted completely in concrete are and therefore against direct effects are protected from the atmosphere. A pretreatment of the Reinforcing bars are therefore usually not required.

The low dry bulk densities according to the invention can adjusted in structural sealed concrete parts that you get surcharges in concrete and mortar mixes low density uses their surfaces if necessary, before use in concrete and mortar mixtures treatment with silica-forming Connections have been subjected. If known per se Low density aggregates such as pumice or expanded clay as such, d. H. without pretreatment  insufficient nominal strengths be obtained using an application of lightweight concrete allow for constructive construction. According to the invention however, such surcharges are used a special pretreatment to increase the Grain compressive strength and subjected to hydrophobization were. Without the pretreatment according to the invention it would be lower when using these supplements Density required, further surcharges with a high Grain compressive strength, such as adding quartz sand, however, which also causes the density of the finished Component is increased considerably.

To increase the grain pressure resistance and the hydrophobization the surcharges used according to the invention lower Density for the production of a structural sealed lightweight concrete the surcharges become lower Density therefore before placing in the concrete or Mortar mixture in liquid at room temperature, at Hydrolysis Organosilicon forming silica Immersion baths containing compounds introduced. Here are mainly due to the surface of the Aggregates taking place hydrolysis the surface pores largely filled out. This pretreatment increases the Grain compressive strength of the aggregates by about 20 to 30%. In addition, the water absorption capacity of the supplements reduced. This waterproofing is special therefore important to the mixing water requirement to change as little as possible. Commonly used Vacuum untreated low density aggregates literally water on, after the setting process and after is available. By the invention Procedure is achieved that the existing open  Pores only partially for the mixing water for the Capillary activity is available and cheaper Sieve line and the same proportion of binder the compressive strengths of the finished concrete parts rise.

According to a preferred embodiment of the present Invention has a lightweight structural lightweight concrete a nominal strength, d. H. Compressive strength of at least 5 N / mm².

Between dry bulk density and compressive strength there is naturally a connection. For example has a lightweight construction concrete according to the invention a dry bulk density of around 630 kg / m³ and a series strength 8.3 MPa after 7 days. To A series strength of approx. 12 MPa can last for 28 days be measured. According to the state of the art, it succeeded So far, only with lightweight concrete with a bulk density from 950 to about 1050 kg / m³ a strength of to produce about 12 MPa. In contrast is the Dry bulk density in the above example by approx. 40% reduced with the same strength. After DIN 4219 part 1 and 2 is an LB-8 for a bulk density defined from 800 to 1000 kg / m³. Accordingly, one should LB-6 with a bulk density class of 600 to 800 kg / m³ of a series strength of 8 MPa having. Since a lightweight concrete according to the invention drying (e.g. 106 ° C) a bulk density of 600 kg / m³, this is too LB-5 define. This means that the requirements the strength of such a lightweight construction concrete are far less than a heavier one Concrete. Accordingly, the series compressive strength is 6 MPa sufficient. The lightweight concrete according to the invention has however a much higher series pressure resistance.  

Accordingly, the compressive strength of the invention Lightweight concrete is disproportionately high.

According to a further embodiment of the present Invention has a lightweight structural lightweight concrete a thermal conductivity of less than 0.18 W / mK on.

Due to the structural tightness of the lightweight construction concrete according to the invention diffusion is opposed greatly reduced to a porous concrete, so that the extraordinarily low thermal conductivity figures are reached will.

A particular embodiment of the present invention consists of a lightweight structural concrete to provide that characterized is that you get lower than supplements Dense expanded clay or expanded slate is used, the Surface before use in concrete or mortar mixes treatment with silica-forming Connections are subject. That way the usual heavy surcharge saved are and thus the claimed according to the invention low dry bulk densities can be achieved. The Consolidation, d. H. the increase in grain pressure resistance can be especially with expanded clay or expanded slate can be achieved. Another essential phenomenon the consolidation is that with the ones mentioned below Solidification substances achievable hydrophobization of the Light supplements. This will when mixing the The mixing water does not get into the interior of the lightweight concrete Low density supplements are added, causing difficulties in the production of lightweight construction concrete would lead. This allows the residual space / cement value  be kept small, which is an additional Increasing the compressive strength and the tightness of the Construction lightweight concrete causes. With the help of the invention Process can have grain compressive strengths be increased by 20 to 30%. Even with supplements lower density, where an increase in grain crush strength cannot be observed is the Treatment of these aggregates with silica-forming Compounds advantageous because the water repellency Reduction in the mixing water requirement.

The dry bulk densities according to the invention are according to an embodiment of the present invention discontinued the use of low density aggregates. This means that the type and amount of surcharges used are made dependent on the desired dry bulk density. For example, if a Low density aggregate used as expanded slate which has a grain density of about 0.8 to 1.1 kg / m³, so can by the invention Increasing the grain pressure resistance further surcharges with low grain pressure resistance and in particular extremely low density ones can be used. Decisive for the amount to be used according to the invention low density supplements to be used is the dry bulk density claimed according to the invention.

As untreated in the sense of the present invention Low-density aggregates can contain foam glass granulate, Pumice, vermiculite, expanded clay, expanded slate, foam lava, Perlite, fly ash porite, fillite, gas concrete granulate and / or mineral fibers are used. As a matter of course also within the meaning of the present invention  these untreated, low-density aggregates are treated according to the method of the invention is an overlap of the untreated surcharges lower density with those of the treated supplements lower density possible. For example in a lightweight structural concrete according to the invention Expanded clay can be used Surface before using a treatment with silica forming compounds have been subjected is, in addition to untreated expanded clay. Of course is on compliance with the invention Boundary conditions, especially on the dry bulk density of the structure-sealed lightweight concrete.

The introduction of the low density aggregates into the Dipping baths happen, for example, in that brings the supplements directly into the immersion baths and let it stay a certain time until the desired one Grain compressive strength increased is. Naturally, it is also possible to apply the supplements low density with known spraying methods the organosilicon compounds in contact bring. With the known spraying methods are those that form during the hydrolysis of silicic acid Connections directly to the low density aggregates sprayed on conveyor belts or for example in trickle plants with the organosilicon compounds be brought into contact. Through contact the low density aggregates with the organosilicon Connections occurs directly on the surface Hydrolysis, in particular more or less "Water-containing" silicon dioxide (silica) is formed becomes. According to one embodiment of the present Invention are the low density supplements in liquid at room temperature, on hydrolysis silicic acid  forming, organosilicon compounds containing immersion baths. If necessary, these can organic or inorganic, more or less volatile solvents for organosilicon Connections included. For example, about 20% by weight Solutions of silanes in organic hydrocarbons such as naphtha or xylene commercially available. Such commercially available solutions can for example directly for the method according to the invention be used.

An embodiment of the present invention exists in using immersion baths that

• (a) tetraalkylsilanes of the general formula (I) Si (OR¹) _nR² _mincluded, where
  R¹ for a methyl, ethyl, n-propyl, i-propyl, n-butyl, i-butyl, t-butyl or phenyl radical and
  R² for a methyl, ethyl, phenyl, vinyl or a methoxy, ethoxy, n-butyloxy, i-butyloxy, t-butyloxy or phenoxy stands and
  the sum ofn andm = 4 with the proviso that n = 2, 3 or 4, and / or
• (b) poly (dialkylsiloxanes) of the general formula (II) HO [Si (R¹) ₂-O-] _x-Include being
  R¹ has the meaning given above.

Organosilicon compounds are preferred used which correspond to the general formula (I),  where R¹ is an ethyl, n-propyl or i-propyl radical and R² represents an n-butyloxy radical.

The organosilicon compounds mentioned are already partially for the preservation of sandstones known. In weathered sandstones can go through those formed from silicic acid esters during hydrolysis Silica and the loosened grains of sand together again get connected.

In contrast, it was surprisingly found that the organosilicon compounds not as adhesion promoters serve, but on the one hand an increase in Grain compressive strength of low density aggregates and on the other hand, a hydrophobization of these supplements cause. A complete filling of the surface pores The low density supplements will in particular therefore not aimed, otherwise the adhesive strength the surcharges treated according to the invention low density with the other components of the concrete or mortar mixture can be negatively affected would.

Expanded clay and expanded slate are lower than aggregates Density has been known for a long time. Expandable slate, for example sold under the name Berwilit is a surcharge in lightweight concrete with high thermal insulation Properties and various strengths known up to quality class LB-300. The grain owns inside a very porous structure, the pores of which are self-contained. The surface is there from a sintered, dense and solid shell. Because of its special pore structure and firm Expanded slate grain has a relatively high outer skin Firmness on. Expandable slate is used in rotary kilns  heated to about 1200 ° C, the at the high Gases produced in the grain contribute to the temperature of the slate inflate at the same time as the surface fuses.

With the aid of the method according to the invention, the grain compressive strength of the individual grain increases by up to 20% increase. At the same time, the water absorption drops 30% by weight on average.

According to an embodiment of the present Invention can be used as low density aggregates, for example Foam glass granulate with a grain density from about 0.35 to 0.4 g / m³ and / or vermiculite a grain density of about 0.10 to 0.35 g / cm³ is used will. These low density supplements too can optionally the treatment according to the invention be subjected to organosilicon compounds. However, there is no measurable increase in Grain compressive strength is achieved, however, the surface hydrophobic, which means that the mixing water requirement can be regulated. So it is possible to be relative new raw material foam glass of a new use feed without pretreatment.

Under foam glass granulate in the sense of the present Invention is a solidified glass foam with airtight closed cells understood with a mixture different gases are filled. As a blowing agent at coke, magnesium carbonate are used for the production and calcium carbonate or also decomposable, organic compounds.

Vermiculite, d. H. to the montmorillonite-saponite group belonging magnesium aluminum silicates are as additives,  but not as surcharges for lightweight concrete known. Due to the open-pore structure of the vermiculite on the one hand and the low grain pressure resistance is, however, the manufacture of a structural seal Construction lightweight concrete on a purely mineral basis using this surcharge only not possible.

Those pretreated according to the present invention Low density supplements are known per se Concrete and mortar mixes for normal concrete added. Due to the special pore structure of the aggregates is the mixing water requirement compared to the conventional one Working in the construction industry practical unchanged.

Of course, in addition to the invention used supplements other known to those skilled in the art Surcharges and additives in the concrete and mortar mixes be introduced, such as from H. Weigler, S. Karl, lightweight steel concrete, manufacture, Property, execution, Bauverlag GmbH, Wiesbaden, or S. Karl, lightweight concrete foam concrete as construction lightweight concrete with reduced density, dissertation, Darmstadt 1979, can be seen.

Examples example 1

Expanded slate grain was made into a finished product by sieve immersion Mixture consisting of 50% silica ester (Steinfestiger OH, Wacker) and 50% monomeric silane (Dynasilan BH, Dynamit Nobel AG). The dwell time was 2 min. Then the knockdown was awarded  48 h at room temperature in an aluminum dish in the open air dried.

When using an expanded slate grain with the Grit 8/25 (corresponding to a sieve line from 8 to 25 mm grain diameter) could increase the Compressive strength of the single grain from 9.3 to 11.1 N / mm² can be achieved. At the same time, water absorption decreased of the individual grain from 19.3 to 13.8% by weight. It could thus an increase in grain pressure resistance of 20% and achieved a 30% reduction in water absorption will.

The water absorption was carried out on 200 g batches of oven-dry aggregate (1 h, 106 ° C.) by storing them in tap water for one hour and pouring them out onto a matt damp pleated filter, diameter 240 mm (Schleicher-Schull) until the end of a drop formation. The water absorption (W) was determined according to equation (1)

m ¹ = dry surcharge in g
m ² = filter paper wet in g
m ³ = additive moist and filter paper moist.

Example 2

It became a test piece of lightweight construction concrete under the use of

-35.7 parts by weight of Portland cement 35 F,
-32.5 parts by weight expanded clay 2/4, pretreated analogously to Example 1,
- 13.8 parts by weight of vermiculite 0/2,
- 6.9 parts by weight of Helapor® 0/1 (expanded calcite, dolomite),
- 5.8 parts by weight of Fillite ® (fly ash)
- 5.0 parts by weight of electrostatic precipitator and
- 0.3 parts by weight of condenser

produced.

With a water-cement value (W / Z value) of 1.26 a dry bulk density after 28 days at 800 kg / m³ certainly.

Example 3

It became a test piece of lightweight construction concrete under the use of

-35.7 parts by weight of Portland cement 45 F,
-32.5 parts by weight expanded clay 2/4, treated analogously to example 1,
-13.8 parts by weight of vermiculite 0.2,
- 6.9 parts by weight of Helapor® 0/1,
- 5.0 parts by weight of electrostatic precipitator ash,
- 0.3 parts by weight of condenser and
- 5.8 parts by weight of Promaxon® P 60 (expanded Na-Al silicate)

produced.

With a W / Z value of 1.51, one became after 28 days Obtain dry bulk density of 840 kg / m³.

Example 4

It became a test piece of lightweight construction concrete under the use of

-26.8 parts by weight of Portland cement 35 F,
7.11 parts by weight expanded clay 2/4, treated analogously to Example 1,
- 9.14 parts by weight of vermiculite 0/2,
- 9.14 parts by weight of Helapor® 0/1,
- 5.0 parts by weight of electrostatic precipitator ash,
- 0.3 parts by weight of condenser,
- 5.14 parts by weight of Promaxon® P 60 and
-37.37 parts by weight of expanded slate 4/8

produced.

A dry bulk density was obtained at a W / Z value of 2.8 after 28 days of 750 kg / m³.

Example 5

It became a test piece of lightweight construction concrete under the use of

-22.0 parts by weight of Portland cement 45 F
-16.0 parts by weight of ZWS ash from Firmal Lurgi (whirl sintered ash),
- 3.2 parts by weight of vermiculite 3/6,
- 0.7 parts by weight of Savemix® C 100, (melanin-formaldehyde resin)
- 7.8 parts by weight of Fillite®,
-15.0 parts by weight of foam glass 4/10,
-11.8 parts by weight of foam glass 0/1 and
-11.02 parts by weight of alumina cement

produced.

At a W / Z value of 1.39 a dry seal was used obtained from 690 kg / m³.

Example 6

It became a test piece of lightweight construction concrete under the use of

-42.6 parts by weight of Portland cement 45 F,
-16.7 parts by weight of fly ash,
-15.7 parts by weight of foam glass 4/8,
-13.0 parts by weight of foam glass 05/1,
- 8.3 parts by weight of foam glass 03/05,
- 3.7 parts by weight of vermiculite 2/3,
- 0.4 parts by weight of condenser and
-40.0 parts by weight of mixing water

produced.

After 7 days the compressive strength was 8.0 MPa be determined. After 28 days the dry bulk density was 650 kg / m³ and the thermal conductivity 0.15 W / mK at 10 ° C mean temperature in the dry state.

Example 7

It became a test piece of lightweight construction concrete under use

-34.5 parts by weight of Portland cement 45 F,
-18.5 parts by weight fly ash,
-13.0 parts by weight of foam glass 4/8,
-10.5 parts by weight of foam glass 05/1,
- 7.0 parts by weight of foam glass 03/05,
- 0.3 parts by weight of condenser and
-23.0 parts by weight of mixing water

produced.

After a day, the compressive strength was 8.0 MPa. After 28 days, the Dry bulk density 642 kg / m³. The thermal conductivity at 10 ° C mean temperature when dry 0.156 W / mK.

Claims (16)

1. Structural lightweight lightweight concrete on pure mineral base with a dry bulk density in the area from 600 to 850 kg / m³, including surcharges lower Density, the surface of which may be before Use in concrete or mortar mixes of a treatment subjected to compounds forming silica have been. 2. Structural lightweight lightweight concrete according to claim 1 with a dry bulk density in the range of 600 up to 750 kg / m³. 3. Structural lightweight lightweight concrete according to claims 1 and 2 with a nominal strength of at least 5 N / mm². 4. Structural lightweight lightweight concrete according to claims 1 to 3 with a heat transfer coefficient of less than 0.18 W / mK. 5. Structural lightweight lightweight concrete according to claims 1 to 4, characterized in that the dry bulk density by using supplements lower Density is set. 6. Structural lightweight lightweight concrete according to the Claims 1 to 5, characterized in that one Low density aggregates are used, their surfaces before use in concrete and mortar mixtures Subjected to treatment with silica-forming compounds  are lower, in addition to untreated supplements Density. 7. Structural lightweight lightweight concrete according to the claims 1 to 5, characterized in that as Supplements of low density expanded clay or expanded slate used, the surfaces of which are used in concrete or mortar mixtures of a treatment with silica are subject to forming compounds. 8. Structural lightweight lightweight concrete according to Claims 1 to 6, characterized in that one as untreated low-density foam glass granulate aggregates, Pumice, vermiculite, expanded clay, expanded slate, Foam lava, perlite, fly ash porite, fillite, Gas concrete granulate and / or mineral fibers are used. 9. Process for the production of lightweight structural concrete according to claims 1 to 8, characterized characterized in that low-density supplements were proposed use in concrete and mortar mixes with Room temperature liquid, on hydrolysis silicic acid forming organosilicon compounds in Brings contact. 10. The method according to claim 9, characterized in that the supplements are brought into immersion baths, the organosilicon that forms during the hydrolysis of silicic acid Compounds optionally in an inert Contain solvents. 11. The method according to claims 9 to 10, characterized characterized in that organosilicon compounds used that  

• (a) tetraalkylsilanes of the general formula (I) Si (OR¹) _nR² _mincluded, where
  R¹ for a methyl, ethyl, n-propyl, i-propyl, n-butyl, i-butyl, t-butyl or phenyl radical and
  R² for a methyl, ethyl, phenyl, vinyl or a methoxy, ethoxy, n-butyloxy, i-butyloxy, t-butyloxy or phenoxy stands and
  the sum ofn andm = 4 with the proviso that n = 2, 3 or 4, and / or
• (b) poly (dialkylsiloxanes) of the general formula (II) HO [Si (R¹) ₂-O-] _x-Include being
  R¹ has the meaning given above.

12. The method according to claim 11, characterized in that one uses organosilicon compounds which correspond to the general formula (I), wherein R¹ is an ethyl, n-propyl or i-propyl radical and
R² represents an n-butyloxy radical. 13. The method according to claims 9 to 12, characterized in that as low-density supplements Expanded clay and / or expanded slate treated. 14. The method according to claims 9 to 13, characterized in that the treated supplements are lower  Density, if necessary, along with other supplements low density, in particular foam glass granulate and / or Vermiculite in concrete and mortar mixes. 15. The method according to claims 9 to 14, characterized in that the low density supplements in known concrete mixes in addition to known ones Introduces additives. 16. The method according to claims 9 to 15, characterized in that the dry bulk density by the Use the treated low density aggregates and, if necessary, by using additional surcharges with low density.