DE102005052817B3 - Concrete recipe for the production of sewage pipes, waste water pipes, and mains drainage pipes based on polycarboxylatether - Google Patents

Abstract

Claimed is the use of a blast furnace cement concrete recipe for the production of sewage pipes, waste water pipes, and mains drainage pipes. The recipe is based on polycarboxylatether, a hardening accelerator agent, rock grains and water. The recipe is self-sealing, is employed in shell forms and uses blast furnace cement Type CEM III/A.

Description

The The invention relates to the use of a concrete mixture for the production sewage pipes or sewer components.

At Concrete mixtures, in particular those for the production of sewage pipes and channel components, high demands are made. So should the concrete mixtures a the molding process and the component geometry appropriate processing consistency and one of the production technology corresponding early strength also for the use state have a high sulphate resistance.

So far it is the molded parts to be produced from the concrete mixture sewage pipes or sewer components in sewage treatment plants in which a very high resistance to sulfate attack is required is, is usually for the production of the concrete a cement with high sulphate resistance used, for example, CEM I 42.5 R-HS. This is due to the increased sulphate resistance the Portland cements, inter alia, on the limitation of Tricalciumaluminat content.

Prefers can also blast furnace cements as a binder for the production of a concrete be used with high sulfate resistance. In these blast furnace cements is based on the increased Sulphate resistance especially on the high slag sand content connected elevated Density of the mortar matrix. This will, if other concrete boundary conditions, for example by means of cements according to DIN 1164 with a slag sand content above 65% by mass achieved in cement.

The Production of concrete parts usually happens in the way that one Fresh concrete quantity earth-moist or in a plastic to soft consistency filled in molds and in the vibrating press process or with external and / or internal vibrators is compressed. While products from humidifier Concrete mix due to their green strength can be shut down immediately, have elements of plastic to soft concrete mix only after a hardening time strength of several hours (usually at least 8 hours) achieved, which allows to remove the mold. So complicated too and slim spatial Molds can be made of high quality, but should be preferred used such concrete mixtures with a softer consistency such as consistency class F6, or self-compacting concrete mixtures. When using correspondingly easily processable concrete mixtures, which advantageously has little jolting energy However, a much longer curing time is necessary to the required Ausschalfestigkeit to achieve. Show these concrete mixtures regularly one setting time to achieve the peel strength, which is well over 8 hours lies.

EP 1 547 987 A2 discloses a cement for creating hydrophobic components for very tall buildings or bridges. In DE 101 64 824 B4 For example, a binder mixture for refractory use is described. In the DE 298 25 081 U1 The disclosed binder composition finds use as a spray binder.

The Production, especially of large ones Components, often occurs in manufacturing halls, the seasonal temperature fluctuations only partially compensate. Ambient and fresh concrete temperatures at 10 ° C should therefore be taken into account.

to Acceleration of hardening can be a heat treatment (Fast curing) be provided the concrete mix. However, this treatment is costly and associated with high technical effort.

Also the above shaking the concrete mixture is with a high expenditure on machine technology and, in particular, due to the high use of vibrating energy and maintenance, with a high cost.

Compared with Portland cement of the same strength class blastfurnace cement has one lower early strength. A use of these cements for easily processable or self-compacting concrete mixtures, in particular with increased Requirements for early strength, includes Therefore, regularly. A reinforced heat treatment for shortening the hardening time includes on the one hand for cost reasons, on the other hand both for concrete technological reasons (ensuring the durability by Limitation of the concrete core temperature) as well as for structural reasons (cracking) regularly out.

to Production of concrete moldings would be both for already existing production sites, as well as for Investments beneficial to the vibration compression (shaking) and activities for quick hardening (Heat treatment) to be able to do without.

task The invention is to provide a concrete mixture available provide both a high early strength as well as having a high sulfate resistance.

A Another task is to use a concrete mix represent themselves in a manufacturing mold for the production of a concrete molding without the use of vibrating energy distributed and condensed.

It is also an object of the invention to provide a concrete mixture which develops a high early strength without the use of a heat treatment, preferably a compressive strength of at least 10 N / mm ² in the test age of 8 hours.

Finally is It is an object of the invention to provide a concrete mix provide for the production of sewage pipes or sewer components can be used.

to solution This object is the use of a concrete mixture according to claim 1 proposed.

It has been found according to the invention, that based on a binder in the form of a blastfurnace cement, the one with a condenser based on polycarboxylate ether is combined to create a concrete leaves, which meets the aforementioned requirements. It lies the Invention the surprising Recognition that a concrete mixture of the application according to Art self-compacting and thus without the use of vibrating energy compacted and early high-strength is. Thus, the concrete according to the application is extremely advantageous In particular also for use in a formwork form, in particular for the production of sewer pipes or sewer components.

self-compacting Although concrete mixtures are basically known. Unknown until now, however, was the application according to the application a self-compacting, early high-strength Concrete mixture based on blast furnace cement with high sulphate resistance. This is especially because blast furnace cements are extremely slow hardening, especially much slower than Portland cements. For the production However, a self-compacting concrete mix is the addition of a condenser, such as polycarboxylate, necessary. By the addition a condenser becomes the hardening time but still further increased, so that was previously refrained from self-compacting concrete mixtures to be used on the basis of a blast furnace cement according to the application.

Essential for the Invention was the realization that self-compacting concretes Base of a blast furnace cement can then be created if next to a condenser additionally a solidification / hardening accelerator is added.

Such Solidification / hardening accelerator (BE) are well known in concrete technology, but they do lead a "shadowy existence" and hardly come for use. This is due in particular to the fact that solidification / hardening accelerators often Have chlorides that attack the steel reinforcement of a concrete. For steel and prestressed concrete are allowed therefore, chloride does not generally have solidification / hardening accelerators be used. Other disadvantages of a previous use of solidification / hardening accelerators were a possible Reduction of the final strength of the concrete and a solidification delay instead an acceleration with only a small incorrect dosage.

Surprised has now been found that in the application according to the application the negative effects of a solidification / hardening accelerator in one Concrete not or only to a significantly reduced extent to bear come when this concrete based on blast furnace cement and further polycarboxylate ether as a concrete liquefier having.

Basically any hardening or solidification accelerator (BE) according to the state of Technique are used. For example, a hardening accelerator based on silicate, aluminate (for example sodium aluminate), carbonate, Nitrate (for example, sodium or calcium nitrate), formate, amine, Hydroxide and / or sulfate (especially aluminum sulfate) used become. It can For example, salts of organic acids, such as carboxylic acids used For example, basic sodium, calcium or aluminum salts.

Especially a hardening accelerator may be preferred based on calcium compounds, in particular based on organic calcium compounds be used. In one embodiment, a hardening accelerator based on the calcium salt of an organic acid used. After a embodiment becomes a hardening accelerator of the type Centrament Rapid (brand of MC-Bauchemie Müller GmbH & Co. KG, Bottrop) used.

Next Solidification / hardening accelerator and polycarboxylate ether may be the concrete mixture for the application according to the application have further concrete admixtures, for example, at least one of following concrete admixtures: air entrainers, retarders, stabilizers, Chromate reducer, injection aid, foaming agent, sealant and / or recycling aids. For example, the concrete mix also other concrete liquefiers / superplasticizers exhibit.

at The binder in the form of a blast furnace cement may in principle be any blast furnace cement, for example according to DIN 1164 or according to general building inspectorate approval, act, preferred However, a blast furnace cement of the type CEM III / A is used a blast furnace cement with high sulphate resistance (HS) may preferably be used can be used (according to DIN 1164 Part 10).

Of the Blast furnace cement may preferably be one having a low effective Alkaline content (NA) (according to DIN 1164-10).

To a preferred embodiment a blast furnace cement of strength class 52.5 is used.

The Concrete mixture may contain any aggregates. Both aggregates it can be natural or industrially produced granular Material or mixtures thereof. It can be rough and / or fine and / or finest aggregates be used.

When another component, the concrete mixture, for example, one or contain several additives.

To an embodiment the concrete mixture contains coal fly ash as an additive.

To a further preferred embodiment the concrete mixture contains silica fume as an additive, preferably Microsilica.

To an advantageous embodiment the concrete mix has an equivalent Water cement value in the range of 0.2 to 0.45, more preferably in the range of 0.25 to 0.45 (according to DIN EN 206-1 / DIN 1045-2).

Based on a m ³ (cubic meter) compacted fresh concrete this may include, for example, the following proportions of components:
Blast furnace cement, for example 200 to 700 kg, so for example 300 to 600 kg, 300 to 550 kg or 350 to 550 kg.

additives can for example, in proportions up to 400 kg, so for example in proportions up to 300 or 50 to 200 kg. This can hard coal fly ash For example, in proportions up to 200 kg, so for example in shares from 50 to 150 kg. Microsilica, which prefers in shape of microsilica slurry may, for example, in proportions up to 80 kg, so for example in proportions of 20 to 60 kg added be.

additive can For example, in proportions of 2 to 50 kg, so for example also present in proportions of 10 to 30 kg in concrete. It can Polycarboxylatether for example in proportions of 2 to 20 kg, So for example, in shares of 2 to 15 kg or in shares from 5 to 15 kg. Solidification / hardening accelerators can be used, for example in proportions of 2 to 20 kg, so for example in shares from 2 to 15 kg or from 5 to 15 kg.

Gesteinkörnung can be present in concrete, for example, in proportions of 1300 to 1900 kg, that is, for example, in proportions of 1500 to 1800 kg or 1500 to 1700 kg. The aggregate may preferably be present in several fractions, for example in a fraction of 0 to 2 mm (0/2 mm) and in a further fraction of 2 to 8 mm (2/8 mm). In a fraction 0/2 mm, for example, shares of 500 to 800 kg and in a fraction 2/8 mm, for example, shares 800 to 1100 kg.

The following is an example recipe for a concrete mix: CEM III / A 52.5 N-HS / NA: 450 kg Coal fly ash: 100 kg Mikrosilikaslurry: 40 kg polycarboxylatether: 8 kg Solidification / Hardening Accelerator (Ca salt of an organic acid): 9 kg Rock Grain (0/2 mm): 643 kg Aggregate (2/8 mm): 965 kg

water is added to the above formulation in an amount that the equivalent Water-cement value of the above mixture is 0.3.

For example, with respect to the water-mixed concrete mix, it may include the following proportions of components, each in mass%:
Blast furnace cement, for example, 10 to 35%, that is, for example, 15 to 25% or 17 to 21%.

additives can for example, in shares up to 15%, so for example, in Shares to 10 or 3 to 9%. This can hard coal fly ash for example, in shares up to 10%, that is, for example, in shares from 2 to 6%. Microsilica, which is preferred in the form of Microsilica slurry may be added, for example, in proportions to 5, so for example be added in proportions of 2 to 4%.

additive can for example in proportions of 0.1 to 3%, ie for example also present in proportions of 0.3 to 2% or 0.4 to 1.5% in concrete. In this case, polycarboxylate, for example, in proportions of 0.1 up to 1.5%, for example in proportions of 0.1 to 1% or in proportions of 0.1 to 0.7% or 0.2 to 0.4%. Solidification / hardening accelerator can for example, in proportions of 0.1 to 1.5%, that is, for example also in units of 0.1 to 1% or in units of 0.1 to 0.8 % or 0.3 to 0.5%.

Rock Grain Can in concrete, for example, in proportions of 40 to 85%, so for example are also present in proportions of 60 to 80% or 65 to 75%. In a fraction 0/2 mm can for example, shares of 22 to 32% and in a fraction 2/8 For example, be present shares of 35 to 47%.

In the following, another example formulation, in each case given in% by mass, for a concrete mixture is named: CEM III / A 52.5 N-HS / NA: 19.3% Coal fly ash: 4% Mikrosilikaslurry: 2% polycarboxylatether: 0.3% Solidification / Hardening Accelerator (Ca salt of an organic acid): 0.4% Rock Grain (0/2 mm): 27% Aggregate (2/8 mm): 41% Water: 6%

Also with this recipe leads the addition of water to an equivalent Water-cement value of 0.3.

According to the invention has proved that the concrete in the set condition an excellent Surface quality possesses. The surfaces are smooth and high-strength, so that the concrete, for example, also used for visible surfaces can be.

Furthermore, the concrete has excellent early high strength. Thus, the compressive strength of the concrete in the test age of 8 hours is at least 10 N / mm ² , for example in the range of 10 to 22 N / mm ² or 14 to 18 N / mm ² , for example 16 N / mm ² (according to DIN EN 12390-3).

Finally, it has been found that in the case of concrete, the early strength even in Frischbetontempe temperatures of 10 ° C and ambient temperatures of 8 ° C is guaranteed (according to DIN 12390-3).

at The concrete mixture becomes a processing behavior (slump flow rate) of the fresh concrete in the range of 700 mm to 850 mm over a minimum period 30 to 50 minutes (according to DAfStb guideline Self-compacting Concrete, 'SVB directive').

It It has been found that, based on the concrete mixture, molded parts, which are produced in formwork forms, excellently created can be.

there the concrete mixture is self-compacting, so that it can without the Application of vibrating energy compacted. Furthermore, the concrete mixture reaches without an additional Hot or steam treatment a high early strength.

It It has been proven that the concrete mix is excellent for Production of sewer pipes or duct components are used can. The use of the concrete mix for the production of sewer pipes or channel components are in molds in which the concrete is filled; the concrete mix behaves there self-leveling and self-compacting. After a maximum of 8 hours The concrete component can be removed from the mold, as it is to this Time has already reached a sufficient strength.

Claims (8)

Using one of the blast furnace cement components, condenser based on polycarboxylate ether, hardening accelerator, aggregate and Water containing mixture as self-compacting concrete mix for the production of sewage pipes or channel components in formwork forms. Use according to claim 1 with a blast furnace cement of type CEM III / A. Use according to claim 1 with a blast furnace cement with high sulphate resistance according to DIN 1164. Use according to claim 1 with a blast furnace cement with low effective alkali content according to DIN 1164. Use according to claim 1 with a blast furnace cement the strength class 52.5. Use according to claim 1 with a further component in the form of hard coal fly ash. Use according to claim 1 with a further component in the form of silica fume, preferably microsilica. Use according to claim 1 with an equivalent Water-cement ratio in the range of 0.25 to 0.45.