JP2009215092A - Component of high-flow concrete, and method for producing high-flow concrete - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for producing high-flow concrete using recycled aggregate. <P>SOLUTION: The component of the high-flow concrete comprises recycled coarse aggregate as coarse aggregate and/or recycled fine aggregate as fine aggregate. The recycled coarse aggregate is adjusted so that it is in a saturated and surface-dried condition or in a water-containing condition having a surface moisture of 0.5% and satisfies the particle size distribution as shown below. The recycled fine aggregate is adjusted so that it is in a water-containing condition where the percentage of the moisture content to the absolute dry condition or water absorption is 0.1% or less and satisfies the particle size distribution as shown in the table. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a high-fluidity concrete having good fresh properties and hardenability, and more particularly to a constituent material of high-fluidity concrete using recycled aggregate as an aggregate and a method for producing high-fluidity concrete.

  High fluidity concrete is a concrete that has both high fluidity and moderate separation resistance and is excellent in self-filling properties, and its use is becoming widespread in various applications. The high fluidity concrete is mainly composed of aggregate, cement, water and fine powder material, and in its production, it has good fresh properties (fluidity) and curability properties (strength, durability, etc.). In order to obtain, manufacture is performed using the constituent material of the stable quality.

  On the other hand, most of the concrete lump generated when the concrete structure is demolished is reused for roadbed materials and the like, and there is almost no material used as concrete again. Therefore, even today, natural materials such as river gravel and crushed stone are often used as the constituent material of concrete. However, since the collection of such natural materials has various effects on the natural environment, from the viewpoint of effectively using resources and protecting the natural environment, the aggregate ( Attempts have been made to recycle it into concrete.

JP 2005-350303 A

However, the recycled aggregates as described above are unstable in quality due to the influence of the particle size and adhering mortar content (hardened cement paste), etc., so that they tend to affect the properties of concrete and make quality control difficult. It will be a thing.
In particular, it has been thought that it is impossible to use recycled aggregate as a raw material for high fluidity concrete such as one that needs to stably obtain good fresh and hardened properties.

  In view of the problems of the prior art, the present invention provides a high fluidity concrete component and a high fluidity concrete that can produce high fluidity concrete having good fresh properties and curing properties while using recycled aggregates. It is an object to provide a manufacturing method.

  As a result of intensive studies in view of the problems as described above, the present inventors have used regenerated aggregates (regenerated coarse aggregates and regenerated fine aggregates) whose particle size distribution and water content are adjusted to a predetermined range. The inventors have found that a high fluidity concrete in which good fresh properties and hardened properties are stably exhibited can be obtained, and the present invention has been completed here.

  That is, the constituent material of the high-fluidity concrete according to the present invention is a constituent material of high-fluidity concrete to which at least one of recycled coarse aggregate and recycled fine aggregate is added, and the recycled coarse aggregate to be added Is a surface dry saturated water state to a water content state having a surface water content of 0.5%, and is adjusted so as to satisfy the particle size distribution shown in Table 1 below. It is characterized in that it is in a dry state or a water content ratio of 0.1% or less with respect to the water absorption and is adjusted so as to satisfy the particle size distribution shown in Table 1 below.

  Further, in the constituent material of the high fluidity concrete according to the present invention, the mixing ratio of the recycled coarse aggregate is 25 to 100 parts by weight with respect to 100 parts by weight of the coarse aggregate, and the mixed fine aggregate is mixed. The rate is preferably 10 to 40 parts by weight with respect to 100 parts by weight of the fine aggregate.

  Moreover, the method for producing high-fluidity concrete according to the present invention is a method for producing high-fluidity concrete in which at least one of recycled coarse aggregate and recycled fine aggregate is added, and the recycled coarse aggregate to be added is added. The dry fine aggregate to be added is adjusted so as to satisfy the particle size distribution shown in Table 2 below, with respect to the dry dry state to the water absorption amount. The water content is adjusted so that the water content is 0.1% or less and the particle size distribution shown in Table 2 below is satisfied.

  According to the constituent material of the high-fluidity concrete having the above structure, the low-quality recycled aggregate (recycled coarse aggregate) having a large variation in quality such as the moisture content in the recycled aggregate and the water absorption due to the influence of the attached mortar. And recycled fine aggregates), it is possible to improve the quality variation by adjusting the particle size distribution and moisture content within the specified range, which is necessary when manufacturing high-fluidity concrete. Thus, it is possible to quantitatively grasp the amount of water to be added, and it is possible to stably and easily produce high-fluidity concrete having good fresh properties and curability.

In addition, the “surface dry saturated state” in the present invention means a water content state of the regenerated aggregate as defined in JIS A 1110 (Coarse aggregate density and water absorption test method).
Further, the “surface water content” means the water content state of the regenerated aggregate as defined in JIS A 1125 (Aggregate water content test method and surface water content test method based on water content).
The “absolutely dry state” means a regenerated aggregate that has been dried to a constant mass at 105 ± 5 ° C. and cooled to room temperature in a desiccator according to JIS A 1109 (fine aggregate density and water absorption test method). It means the water content state.
Further, the “water absorption amount” in the present invention means a water amount corresponding to the difference in mass between the regenerated aggregates in the “surface dry saturated state” and the “absolutely dry state”.
Further, the “water content” means a moisture amount corresponding to the difference between the mass of the regenerated aggregate in the “absolutely dry state” and the mass of the regenerated aggregate before drying.

  As described above, according to the present invention, it is possible to produce high-fluidity concrete having good fresh properties and hardenability while using recycled aggregate as a constituent material.

  Hereinafter, embodiments of the present invention will be described.

  The constituent material of the high fluidity concrete according to the present embodiment includes a coarse aggregate and a fine aggregate as aggregates. Specifically, a part of the aggregate is constituted by using recycled aggregate. Hereinafter, aggregates other than recycled aggregates are referred to as normal aggregates (normal coarse aggregates and normal fine aggregates).

  The recycled aggregate is composed of recycled coarse aggregate and recycled fine aggregate. The regenerated aggregate is adjusted so as to be in a predetermined range of water content. Specifically, the moisture content of the regenerated coarse aggregate is adjusted so that it is in a dry dry saturated state or a water content state with a surface water ratio of 0.5%, and the regenerated fine aggregate is in an absolutely dry state or a water absorbing state. What was adjusted so that the ratio of the water content to the amount may be 0.1% or less is used.

  As described above, by adjusting the moisture content of the recycled aggregate within a predetermined range, it is possible to improve the variation of the moisture content in the high-fluidity concrete due to the influence of moisture present in the recycled aggregate. Can do.

  The recycled coarse aggregate and recycled fine aggregate are adjusted to have a predetermined particle size distribution. Specifically, recycled coarse aggregate and recycled fine aggregate adjusted to have a particle size distribution shown in Table 3 below are used.

  As described above, by adjusting the particle size distribution of the regenerated aggregate to a predetermined range, it is possible to improve the variation in water absorption due to the influence of the mortar adhering to the regenerated aggregate.

  Therefore, by using the recycled aggregate whose particle size distribution and water content are adjusted to a predetermined range as described above, the quality of the recycled aggregate that has been scattered before the adjustment is improved, and when producing a high fluidity concrete. It becomes possible to quantitatively grasp the amount of water required. Therefore, high-fluidity concrete having good fresh properties and curability can be stably and easily manufactured.

  The recycled aggregate can be used by mixing with ordinary aggregate. Specifically, at least one of the recycled coarse aggregate and the recycled fine aggregate can be used by mixing with ordinary aggregate.

It is preferable that the recycled coarse aggregate and the recycled fine aggregate are mixed and used at a predetermined ratio with respect to the normal coarse aggregate and the normal fine aggregate. Specifically, the recycled coarse aggregate is preferably mixed so as to be 25 to 100 parts by weight with respect to 100 parts by weight of the normal coarse aggregate, and more preferably the normal coarse aggregate 100. It is mixed so that it may become 35-67 weight part with respect to a weight part.
Further, the recycled fine aggregate is preferably mixed so as to be 10 to 40 parts by weight with respect to 100 parts by weight of the normal fine aggregate, and more preferably 100 parts by weight of the normal fine aggregate. On the other hand, it is mixed so that it may become 15-33 weight part.
By mixing and using ordinary aggregates and recycled aggregates at such a ratio, the fresh properties and hardenability properties of the high-fluidity concrete can be obtained more stably.

In addition, what is classified into the quality prescribed | regulated to JIS can be used as a reproduction | regeneration aggregate adjusted to the above particle size distribution and a water-containing state. Specifically, it is manufactured by crushing concrete waste, etc., and classified according to variations in quality such as water absorption, etc. Can be used in the order of recycled aggregate M for concrete defined in JIS A 5022 and recycled aggregate H for concrete defined in JIS A 5021 in this order.
In the present invention, it is possible to use a recycled aggregate having a quality equal to or higher than that of the above concrete aggregate L, and even with the lowest quality recycled aggregate, stable high-fluidity concrete having good fresh and hardened properties Can be manufactured. In addition, when a high-quality recycled aggregate is used, high-fluidity concrete having good fresh properties and curability can be stably and easily manufactured with a smaller amount of moisture.

  In addition, the normal aggregate is not particularly limited, for example, natural materials such as crushed stone, crushed sand, gravel, sand, and those artificially manufactured from blast furnace slag can be used, more Specifically, those satisfying the provisions of JIS A 5308 Annex 1 are preferably used. Since such normal aggregates have a stable quality such as the amount of water absorption, it is possible to quantitatively grasp the amount of water added to obtain good fresh properties and curable properties.

  Cement, an admixture, etc. are used as a constituent material of high fluidity concrete other than the said normal aggregate and recycled aggregate. Although it does not specifically limit as said cement, Preferably, blast furnace cement B type, fly ash cement C type, etc. can be used. According to such cement, alkali silica reaction can be suppressed.

  In addition, the admixture is not particularly limited, and a fine powder material or the like can be used. Preferably, air-dried fine limestone powder or fly ash can be used. According to such an admixture, fluidity suitable for high-fluidity concrete can be imparted. Moreover, when fly ash is used, the effect which suppresses alkali silica reaction other than the effect which provides fluidity | liquidity can also be acquired.

The constituent material, an alkali amount in the constituent materials 3.0 kg / m ³ or less, the chloride ion amount is blended so that 0.3 kg / m ³ or less. Specifically, with respect to 100 parts by weight of all the constituent materials, 33.1 to 44.1 parts by weight of coarse aggregate (normal coarse aggregate and regenerated coarse aggregate) and fine aggregate (normal fine aggregate) And regenerated fine aggregate) is 34.2 to 35.1 parts by weight, cement is 13.6 to 13.7 parts by weight, fine powder material is 10 to 13 parts by weight, and the admixture is 0.19 to 0.21 parts by weight. It is preferable to mix | blend so that it may become. By mix | blending in this way, deterioration of the concrete produced by alkali-aggregate reaction can be suppressed, and corrosion of the reinforcing bar at the time of using with a reinforcing bar etc. can be suppressed.

  Next, the manufacturing method of the high fluidity concrete which concerns on this invention is performed by adding water and an admixture to the above structural materials, and kneading. Specifically, the water cement ratio is adjusted according to the constituent materials such as cement and fine powder material. For example, kneading water and an admixture are added so that the water cement ratio is 45 to 55%. Done by mixing. The admixture is not particularly limited, but preferably a high performance AE water reducing agent or the like can be used. According to such a manufacturing method, both the fluidity and durability of the high fluidity concrete can be improved.

The obtained high fluidity concrete has good fresh properties and hardenability. Specifically, high-fluidity concrete having a slump flow of 60 to 70 cm and an age 28 day compressive strength of 42 to 47 N / mm ³ can be obtained.

The constituent material of the high fluidity concrete according to the present invention can be divided into several components, packed, and carried to the manufacturing site.
Specifically, the fine aggregate including the regenerated fine aggregate can be accommodated in a container together with a binder, a fine powder material, and the like as a pack material, and can be carried to the manufacturing site. The coarse aggregate containing can be stored in a container different from the fine aggregate containing the recycled fine aggregate to form a pack material, and can be carried to the manufacturing site.
By carrying in to a manufacturing site in such a form, each component can be carried in as a stable form, without having a bad influence on the fresh property and hardening property of high fluidity concrete.
Then, a pack material containing recycled fine aggregate, a pack material containing recycled coarse aggregate, and a predetermined amount of water and a water reducing agent are weighed and mixed to obtain a high fluidity concrete having good fresh and hardened properties. It becomes possible to manufacture stably and easily.

  Examples of the present invention will be described below.

<Materials used>
-Normal coarse aggregate: According to JIS A 5005.
-Normal fine aggregate: According to JIS A 5308 Annex 1.
-Recycled coarse aggregate: Recycled aggregate L for concrete defined in JIS A 5023 Annex 1 (quality described in Table 4 below).
Recycled fine aggregate: Recycled aggregate L for concrete as defined in JIS A 5023 Annex 1 (quality described in Table 4 below).
・ Sand: According to JIS A 5308 Annex 1.
・ Cement: Blast furnace type B ・ Admixture: Limestone fine powder (density 2.7 g / cm ³ )
・ Water (tap water)

<Adjustment of particle size distribution of recycled aggregate>
The regenerated coarse aggregate and regenerated fine aggregate were adjusted using a predetermined sieve so as to have the particle size distribution shown in Table 5 below.

Example 1
While using the said normal coarse aggregate and the said sand and using the said reproduction | regeneration coarse aggregate adjusted so that it may become the particle size distribution 1 shown in the said Table 5 as a reproduction | regeneration aggregate, it is highly fluid by the mixing | blending shown in the following Table 6 Concrete was prepared.

(Example 2)
While using the said normal coarse aggregate and the said sand, using the said reproduction | regeneration fine aggregate adjusted so that it may become the particle size distribution 2 shown in the said Table 5 as a reproduction | regeneration aggregate, it is highly fluid by the mixing | blending shown in the following Table 6 Concrete was prepared.

(Example 3)
While using the said normal coarse aggregate and the said sand, it becomes the said reproduction | regeneration coarse aggregate adjusted so that it may become the particle size distribution 1 shown in the said Table 5 as a reproduction aggregate, and the particle size distribution 2 shown in the said Table 5. Using the recycled fine aggregate adjusted to the above, high fluidity concrete was prepared with the composition shown in Table 6 below.

(Reference Example 1)
While using the said normal coarse aggregate and the said sand, the high fluidity concrete was adjusted with the mixing | blending shown in following Table 6. FIG.

(Comparative Example 1)
Using the recycled coarse aggregate adjusted to have the particle size distribution 1 shown in Table 5 and the recycled fine aggregate adjusted to have the particle size distribution 3 shown in Table 5, the composition shown in Table 6 below is used. The high fluidity concrete was adjusted.

<Evaluation method>
Evaluation is performed using the slump flow specified in JIS A 1150 as an evaluation standard for fresh properties (fluidity), and compression strength of 28 days of age specified in JIS A 1114 is used as an evaluation criterion for curable properties. And evaluated. The results are shown in Table 7 below.

  As shown in Table 7, in Comparative Example 1, slump flow and age 28 days compressive strength as in Reference Example 1 (that is, conventional high-fluidity concrete using only ordinary aggregates) are not obtained. On the other hand, in Examples 1-3, it is recognized that the slump flow and age 28 day compressive strength equivalent to Reference Example 1 are obtained.

  As described above, according to the constituent material of high-fluidity concrete and the method for producing high-fluidity concrete according to the present invention, the particle size distribution and moisture content of recycled aggregate (recycled coarse aggregate and recycled fine aggregate) are within a predetermined range. It is possible to improve the variation in quality of recycled aggregates by adjusting to, and high flow with good fresh and hardened properties even for low quality recycled aggregates with large quality variations. It can be used as a constituent material for concrete.

Claims (3)

It is a constituent material of high-fluidity concrete to which at least one of recycled coarse aggregate and recycled fine aggregate is added,
The regenerated coarse aggregate to be added is a surface-dried saturated state to a water-containing state having a surface water content of 0.5% and adjusted to satisfy the particle size distribution shown in Table 1 below.
The regenerated fine aggregate to be added is in an absolutely dry state or a water content state in which the ratio of the water content to the water absorption is 0.1% or less, and is adjusted so as to satisfy the particle size distribution shown in Table 1 below. A constituent material of high fluidity concrete.

  The mixing ratio of the recycled coarse aggregate is 25 to 100 parts by weight with respect to 100 parts by weight of the coarse aggregate, and the mixing ratio of the recycled fine aggregate is 10 to 10 parts by weight with respect to 100 parts by weight of the fine aggregate. The constituent material of high-fluidity concrete according to claim 1, characterized in that it is 40 parts by weight. A method for producing high-fluidity concrete comprising at least one of recycled coarse aggregate and recycled fine aggregate,
The regenerated coarse aggregate to be added is adjusted so as to satisfy the particle size distribution shown in Table 2 below in a water-containing state with a surface dry saturated state to a surface water ratio of 0.5%,
The regenerated fine aggregate to be added is adjusted so as to satisfy the particle size distribution shown in Table 2 below in a completely dry state or a water content ratio of water content to water absorption of 0.1% or more. Manufacturing method of high fluidity concrete.