ES2283232A1 - Concrete pieces production involves adding recycled dry goods, where arid wet phase is arranged prior to phase of mixture of concrete components, which is arranged prior to phase of atmospheric storage - Google Patents

Abstract

The process involves adding recycled dry goods. An arid wet phase is arranged prior to a phase of mixture of concrete components, which is arranged prior to a phase of atmospheric storage. The phase of atmospheric storage is controlled before the phase of mixture of concrete components.

Description

Procedure for manufacturing parts of concrete.

The present invention refers to a procedure for the manufacture of concrete parts.

More in particular, the present invention makes reference to a procedure for the manufacture of parts of concrete.

With the term "recycled aggregate" is made reference, mainly, to aggregate from debris removal and demolition. However, the procedure according to the present invention is not necessarily limited to such application, It can also extend to aggregates obtained from slags metallurgical foundry, solid waste incinerator urban, and also other types of waste of a similar nature, including, for example, car tires. The concrete It is mainly composed of cement, water, coarse aggregate (more commonly called "aggregate" and fine aggregate or "sand."

The use of aggregate is known recycled in the manufacture of concrete, especially parts prefabricated In particular, such use has an impact remarkably favorable environmental because, when using arid Recycled waste disposal is used, as well as the environmental impact derived from the extraction of aggregate from a quarry.

However, it is also known that the concrete in which recycled aggregate is used loses properties, especially resistant properties, which make it difficult to use in structural applications. Interestingly, this decrease in structural properties (mainly compressive strength) It occurs even when the recycled aggregate is of good quality, for example, arid demolition that has passed various phases of removal of foreign materials (metals, plastic, wood, paper...). In short, with high percentages of utilization of recycled aggregate, compressive strength does not reach a value minimum of 150 kg / cm2, and is far from desirable 200 kg / cm2. The reason why this occurs, to date, does not It is well determined. Therefore, structural standards limit the use of recycled aggregate in concrete for structural use to 20% of the total aggregate of the concrete. This obviously limits the economic viability of the addition of recycled aggregate and its beneficial environmental impact.

The present invention discloses a procedure for the manufacture of concrete using a high percentage of recycled aggregate, even 100%, and that it has compression resistance characteristics that They even fit for structural applications.

In particular, the present invention gives know a procedure for the manufacture of concrete parts, of the type comprising the addition of recycled aggregate, characterized because it comprises a wetting phase of the aggregate immediately prior to a mixing phase of the concrete components, or well immediately prior to a storage phase in controlled atmosphere prior to said mixing phase of components.

Preferably, the recycled aggregate will present a wet layer that surrounds it during the addition phase.

Wetting can be advantageously achieved by a wash by immersion of the aggregate.

The controlled atmosphere can be obtained by aggregate storage in a closed enclosure, essentially dust free in environment.

In accordance with the present invention, a preferred objective to achieve is that a wet layer surrounds the aggregate at the time of its addition to the mixture of components of the concrete.

Surprisingly, during the tests made, it was discovered that the wetting of the recycled aggregate performed immediately before mixing meant a clear increase of the resistant properties of concrete, as well as its workability Since some of the recycled aggregates used during the tests they had undergone a washing phase prior to removal of unwanted materials and to a later air storage, according to known techniques, this resulted in First sight, remarkably surprising.

A possible hypothesis that explains the surprising result obtained by the invention is that by means of the pre-mixing washing is possible to clean the thin layer surrounding the recycled aggregate and that seems to be responsible for a significant decrease in the resistant properties of the final concrete, possibly due to procedures chemical-surface attack physicists who perform said fine aggregates on the surface of the recycled aggregate, releasing substances that are undesirable for concrete.

The controlled atmosphere essentially free of dust means storage of recycled aggregate in space closed, and not outdoors for a long time, since in this case a layer of fines would be created on the aggregate.

As a general rule, a production plant of concrete stones that include aggregate phases recycled from debris or waste products, may include additional phases of separation, treatment or storage prior to the realization of the mixture, provided that environmental dust conditions are controlled in those that perform these steps. In other cases, for example in which obtaining recycled aggregate and manufacturing concrete pieces are separated in space and time, they proceed more preferably to carry out the washing phase immediately before mixing, so that the aggregate grains are covered with a wet layer.

The process object of the present invention allows to obtain concrete with a compressive strength equal to or greater than 15 MPa, or even equal to or greater than 20 MPa, which They are characterized because they present a percentage of recycled aggregate over the total aggregate greater than 20%, preferably equal to or greater than 30%, more preferably equal to or greater than 50%, even more preferably equal to or greater than 80% and even more preferably equal to or greater than 95%.

To obtain an increase in the resistance of the concrete with recycled aggregate, is highly preferred, according to tests performed, that the recycled aggregate used is essentially free of particles less than 4 mm in diameter, of face to avoid the retraction of concrete. For similar reasons, more preferably, the sand used will not come from recycling.

In addition, according to the tests performed by the inventors, obtaining a concrete with recycled aggregate of very high strength requires the addition of an additive superfluidifying Preferably, this will be combined with a adding a maximum of 0.65 kg of water per kg of cement from the mixture. More preferably, the amount of water per kg of cement is It will be between 0.49 kg and 0.65 kg.

In a particular embodiment, the procedure object of the present invention comprises an air wash of the recycled aggregate and density separation of aggregate recycling.

The procedure may also include phases separation of the recycled aggregate by particle diameter, which will allow a parameterization of concrete properties manufactured and a better use of recycling.

In a preferred mode, the concrete made according to the present invention it can be presented in block form, for which the procedure may include kneading phases of the mixing, molding and demolding of it.

For a better understanding of the invention, attached by way of explanatory example but not limiting, some Examples of embodiment of the present invention and tests made.

Figure 1 shows a scheme of a possible performance of the procedure according to the present invention.

Figure 2 shows a possible scheme realization of an industrial installation that carries out a procedure according to the present invention.

The realization and results of some laboratory examples carried out during The process of the invention.

Used materials Cements

For laboratory examples, it was used EMC type cement II / B-M (P-V-L) 32.5N.

       \ vskip1.000000 \ baselineskip
    

Sand Arena R

The "Arena R" is a recycled sand. He granulometry analysis was carried out according to UNE-En 933-1: 1997: aggregate washing and subsequent dry sieving. As a result, it was determined that the% of retention accumulated by sieve 0.5 was only one 68.6% The water absorption capacity was 9.1%, determined according to UNE-EN 1097-6: 2000.

Arena P

Sand P is a crushing limestone sand. From according to the granulometry tests performed according to the aforementioned conditions, the% of retained accumulated by the 0.5 sieve was 80%. The water absorption capacity was 1.8%, according to UNE-EN 1097-6: 2000.

Recycled arid

The recycled aggregate used in the tests was an aggregate from debris. The classification of Constituents of coarse aggregate were carried out following the project of prEN standard 933-11.

one

The acid soluble sulfate content of recycled aggregate was 0.63% and sulfur of 0.875%, determined both according to the UNE-EN standard 1744-1: 1998. No organic matter was detected that It could affect the setting. Potential reactivity alkali-silica was negative, determined by following the UNE 146508 standard.

The aggregate absorption capacity, determined according to UNE-EN 1097-6: 2000 it was, approximately 5.8% or less for the fraction greater than 4 mm and greater than 9.5% for the remaining fraction.

As a consequence, said fraction was removed fine of recycled aggregate less than 4 mm for the realization of tests, through sieve.

Additive

To all the dosages of added superfluous additive, in particular Glenium C 355 (Additive Highly effective water reducer, superplasticizer and hardening accelerator) in the amount of 80 grams per 8,800 grams of cement.

Dosages

\hskip0.9cm

Dosificación R1

 \ hskip0.9cm 

R1 dosage

2

There was a significant decrease in fluidity in the time interval between kneading and Final manufacturing of the 6 specimens.

\hskip0.9cm

Dosificación R2

 \ hskip0.9cm 

R2 dosage

3

The dosage R2 was prepared in the same way to the dosage R1.

\hskip0.9cm

Dosificación R3

 \ hskip0.9cm 

R3 dosage

4

The R3 dosage was prepared differently to the dosage R1.

When unmolding the dosing specimens R1 to R3 at the age of 1 day a large amount of retraction cracks.

Dosages R4 to R6

The three dosages mentioned above were repeated using recycled coarse aggregate and sand crushing limestone "sand P", but pre-wetting the samples so that a fine Moisture layer surrounds the aggregate grains. The consumption of materials per m3 of concrete change slightly due to the higher density of limestone sand in relation to recycled sand. The manufactured concretes were identified as R4, R5 and R6

\hskip0.9cm

Dosificación R4

 \ hskip0.9cm 

R4 dosage

5

       \ vskip1.000000 \ baselineskip
    

\hskip0.9cm

Dosificación R5

 \ hskip0.9cm 

R5 dosage

6

       \ newpage
    

\hskip0.9cm

Dosificación R6

 \ hskip0.9cm 

R6 dosage

7

R7 and R8 dosages

In dosages 7 and 8 a part of the coarse aggregate recycled by a limestone gravel that We had in the laboratory. The objective was to adjust the particle size of the aggregates once the sand used is very fine.

\hskip1.1cm

Dosificación R7

 \ hskip1.1cm 

R7 dosage

8

       \ vskip1.000000 \ baselineskip
    

\hskip1.1cm

Dosificación R8

 \ hskip1.1cm 

R8 dosage

9

It was observed that the granulometry adjustment of the aggregates, achieved with the introduction of gravel, had no no influence on the compressive strength nor on the "finish" of concrete. Therefore it was decided to follow the study using only recycled coarse aggregate and aggregate fine "sand P".

       \ newpage
    

Dosages R9 to R11

\hskip0.9cm

Dosificación R9

 \ hskip0.9cm 

R9 dosage

10

       \ vskip1.000000 \ baselineskip
    

\hskip0.9cm

Dosificación R10

 \ hskip0.9cm 

R10 dosage

eleven

       \ vskip1.000000 \ baselineskip
    

\hskip0.9cm

Dosificación R11

 \ hskip0.9cm 

R11 dosage

12

       \ vskip1.000000 \ baselineskip
    

\hskip0.9cm

Dosificación C3 Hormigón de referencia con áridos convencionales

 \ hskip0.9cm 

Dosage C3 Reference concrete with conventional aggregates

13

Compressive strength of concrete

The compressive strength of concrete studied has been determined in 15 cm cylindrical specimens diameter and 30 cm high, manufactured in accordance with the UNE standard 83301: 1991 and tested at the age of 7 days according to the UNE standard 83304: 1984.

The following table shows the average resistance of three test pieces tested for each dosage.

14

Discussion of results

From the comparison of the results of the concretes R1 to R3 with R4 to R6 it follows that the technique of humidification not only solves cracking problems referenced, but there is also a notable increase in the resistance.

Notable, more notable resistances are observed still when considering the recycled nature of the aggregate (aggregate thick).

In the evaluation of the different Dosages should also be taken into account that it is recommended the amount of aggregate consumed per m3 is the highest possible, in order to obtain a favorable environmental effect. As a consequence it also follows that it is preferred that the amount of water in the concrete per kg of cement must be preferably less than 0.65 kg. For the same reason, it turns out preference is given to the addition of the superfluorizer.

Figure 1 shows a block diagram of a possible industrial process according to the present invention.

As seen in Figure 1, a possible industrial process by process plants, according to the present invention may comprise a supply or collection (1) of aggregate recycling. Subsequently, unwanted elements are separated of aggregate, for example by sand (2), or by density (3), and finally a water immersion wash (4) and a subsequent grain selection (5) by sizes.

The selected grain can be stored by granulometry (5), (5 '' (, (5 '' '), and taken (6' ') to the phase of mixture or dosage (6) or it can be taken directly, wet, at dosage (6), such that a layer is formed wet around the recycled aggregate.

After dosing, phases are performed kneading post (7), molding (8), demolding (9), ripening, quality control and tinting (10) and storage and / or distribution (eleven).

Figure 2 shows a possible scheme of concrete parts manufacturing plant according to a procedure according to the present invention.

The plant consists of a process zone initial (100), a recycled aggregate treatment zone (101) and a concrete plant (102).

In the initial process zone (100) you can including a crusher (103) and a sieve (104) for separation of, for example, fractions of recycled aggregate 0-10 mm, 10-30 mm and 30-60 mm The three fractions carry processes slightly different. The finest fraction (0-10) it passes to a trommel (105) that separates the fraction. Grains more small (0-5) pass through a clinquer sensor (106) to remove dust / sand and move to an aggregate storage for "other uses" (107). The thickest part, having passed by a vacuum cleaner (108) and by a water wash (110) that eliminates additionally powder (110) passes to an aggregate doser (112) recycled with granulometry "5-10".

The intermediate fraction 10-30 mm it passes through a second trommel (113), passing the fraction that is excessively thick (20-30 mm) of accumulation of recycled aggregate for other uses. The granolometric fraction considered more useful for concrete production (10-20 mm) passes through a densimetric table (114), in which eliminates dust (114 ') and rejections such as wood, plastics and by a washing machine by immersion (115) in which new Rejections and dust remains on the surface and is separated. The fraction "10-20" (116) is this way transferred to another dispenser (117).

The thickest fraction 30-60 mm recycled aggregate can undergo immersion washing (118) to separate dust and rejections, by an elimination table (119) rejection manual (wood, plastics, metals ...), for a metal extractor, and a part of the obtained, after passing said mill cycles (121) and (122) gives rise to a fraction 0-30 mm of recycled concrete for all types of use.

The concrete area (102) in addition to the two recycled aggregate dosers (112), (117) cited, can have a sand dispenser (123) from extraction, cement (124), water (125) and additive (126) passing the components to a mixer-mixer (126) and from there to a mold (128) or to a concrete mixer truck (129) for site service.

While the invention has been described with respect to preferred embodiments, these should not be considered limiting the invention, which will be defined by the interpretation broader of the following claims.

Claims (17)

1. Procedure for the manufacture of concrete parts, of the type comprising the addition of recycled aggregate, characterized in that it comprises a wetting phase of the aggregate immediately prior to a mixing phase of the concrete components, or immediately preceding a phase of storage in controlled atmosphere prior to the mentioned phase of mixing of components. 2. Method according to claim 1, characterized in that the wetting comprises an immersion wash of the aggregate. 3. Method according to claim 1 or 2, characterized in that the aggregate has a wet layer that surrounds it at the time of its addition to the mixture of components. Method according to any one of claims 1 to 3, characterized in that said phase of storage in controlled atmosphere consists of storage in an essentially dust-free enclosure in an environment and closed to the outside. 5. Method according to any one of claims 1 to 4, characterized in that the recycled aggregate used in the mixing phase is essentially free of particles smaller than 0.4 mm in diameter. Method according to any one of claims 1 to 5, characterized in that the mixing phase comprises the addition of a superfluidifying additive. Method according to any one of claims 1 to 6, characterized in that the mixing phase comprises the addition of a maximum of 0.65 kg of water per kg of cement. Method according to claim 7, characterized in that the mixing phase comprises the addition of between 0.49 and 0.65 kg of water per kg of cement. 9. Method according to any of claims 1 to 8, characterized in that the sand added in the mixing phase does not proceed from recycling. Method according to any one of claims 1 to 9, characterized in that more than 20% of the aggregate used is recycled aggregate. 11. Method according to claim 10, characterized in that more than 50% of the aggregate used is recycled aggregate. 12. Method according to claim 11, characterized in that more than 80% of the aggregate is recycled aggregate. 13. Method according to claim 12, characterized in that more than 95% of the aggregate is recycled aggregate. 14. Method according to any of claims 1 to 13, characterized in that it comprises the following phases prior to wetting:

-

Washed by recycled aggregate air

-

Separation by density of the aggregate recycling.

15. Method according to any of claims 1 to 14, characterized in that it comprises a phase of separation of the recycled aggregate by particle diameter. 16. Method according to any of claims 1 to 15, characterized in that it comprises, after the mixing phase, subsequent kneading, molding and demoulding phases of the mixture. 17. Method according to any of claims 1 to 16, characterized in that the aggregate used is aggregate from debris.