JP2010149402A - Manufacturing method of concrete composition and concrete molding - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a manufacturing method concrete composition capable of preparing the concrete composition of uniform slurry in a short time even if applied to the concrete composition of a low water/bonding agent ratio, and to provide a concrete molding of high compressive strength obtained thereby. <P>SOLUTION: The manufacturing method of the concrete composition with a water/bonding agent ratio of 0.2 or lower has: a first kneading step to knead 50-90 pts.mass of a bonding agent based on 100 pts.mass of the total amount of the bonding agent including cement in the concrete composition with water to prepare the slurry; and a second kneading step to knead after adding the residual quantity of the bonding agent to the slurry. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method for producing a concrete composition and a concrete molded body obtained by curing a concrete composition obtained by the production method, and more specifically, a molded article having a low water / binder ratio and a high strength. The present invention relates to a production method capable of easily adjusting a concrete composition to be obtained and a high-strength concrete molded body obtained thereby.

In recent years, with the increase in the number of buildings and the increase in the scale of bridges, a high-strength molded body made of cement concrete used for civil engineering structures is required. Conventionally, a concrete composition having a water / binder ratio of 0.4 to 0.7, that is, a binder content of about 71 mass% to 59 mass% in the total amount of water and binder is used. If necessary, fine aggregate, coarse aggregate, etc. are mixed and kneaded together to prepare a slurry-like concrete composition, which is placed and cured to obtain a molded body Yes. In such a case, a slurry-like concrete composition that can be placed within a few minutes after the start of kneading is obtained.
However, as a means for increasing the strength of the concrete molded body, if the water / binder ratio is lowered, the amount of powder increases, so that it takes time to prepare a uniform slurry-like concrete composition. Yes, this is aimed at improving efficiency by blending a water reducing agent.
In high-strength concrete, the water / binder ratio is reduced to increase the content of fine powders such as silica fume and limestone fine powder together with cement, but because the amount of powder is large and the bulk volume of the powder is large When a water / binding material ratio of 0.3 or less, particularly 0.2 or less, is prepared, water containing a water reducing agent is not uniformly distributed between the powders. It takes time, or even if kneaded for 10 minutes or more, it is a pre-stage of slurry formation, water does not penetrate into a part between each solid particle, and a pendular state that becomes a lump is not formed, so that a uniform slurry is not formed. There's a problem.

  As a method for preparing a high-strength concrete composition, for example, in order to obtain a high-strength concrete composition containing reinforcing fibers, a water reducing agent and reinforcing fibers are sequentially added to water, kneaded, and then cement is added. There has been proposed a method for producing a concrete composition in which a cement paste is prepared by kneading and preparing a cement paste, and then adding the cement paste to an empty kneaded aggregate mixture (see, for example, Patent Document 1). According to this method, the reinforcing fibers can be uniformly arranged in the concrete composition, but the water / binder ratio of the concrete composition described here is about 0.6 (60%), No consideration is given to increasing the strength by lowering the binder / binder ratio, and if this technology is applied to a composition having a low water / binder ratio, it will be uniform even after mixing with cement. There was a problem that a simple cement paste could not be obtained.

As another method for producing high-strength concrete, a method has been proposed in which cement, silica sand, water and a water reducing agent are mixed to prepare a cement paste, and then water and a retarder are added (for example, patents). Reference 2). In this method, water is added in two portions in order to ensure weighing accuracy, but in a composition with a low water / binder ratio, less water is added to the first stage mixture. However, there has been a problem that a uniform cement paste cannot be obtained, and none of these have led to an essential solution concerning the preparation of a concrete composition having a low water / binder ratio.
JP 11-320544 A JP 2004-123428 A

The object of the present invention made in consideration of the above problems is to prepare a uniform slurry-like concrete composition in a short time and with low energy even when applied to a concrete composition having a low water / binder ratio. An object of the present invention is to provide a method for producing a concrete composition capable of forming a compact having a high compressive strength.
A further object of the present invention is to provide a concrete compact having a low water / binder ratio and a high compressive strength, comprising the composition obtained by the method for producing a concrete composition.

The present inventors have found that the above-mentioned problems can be solved by adding a binder such as cement or silica fume in two steps in the preparation process of a cement concrete composition, particularly cement paste, and the present invention. completed.
That is, the configuration of the present invention is as follows.
<1> A method for producing a concrete composition having a water / binder ratio of 0.2 or less, wherein when the total amount of binders including cement contained in the concrete composition is 100 parts by mass, 50 of the binder 90 parts by mass of 90 parts by mass and water are kneaded to prepare a slurry, and a second kneading process for adding the remaining amount of the binder to the slurry and kneading. A method for producing a concrete composition.
<2> The method for producing a concrete composition according to <1>, wherein the concrete composition has a water / binder ratio of 0.05 to 0.15.

<3> The method for producing a concrete composition according to <1> or <2>, wherein a mixing ratio of water and the binder used in the first kneading step is 0.1 to 0.3.
<4> Any one of <1> to <3>, wherein the binder used in the first kneading step contains one or more selected from cement, silica fume, slag, limestone fine powder, and fly ash. The manufacturing method of the concrete composition as described in any one of.
<5> The concrete composition according to any one of <1> to <4>, wherein the first kneading step is a step of further mixing a fine aggregate and a water reducing agent into the binder and water. Production method.

<6> The production of the concrete composition according to any one of <1> to <5>, further including a third kneading step in which the coarse aggregate is added and kneaded after the second kneading step. Method.
<7> A concrete molded body having a compressive strength of 80 N / mm ² or more obtained by curing the concrete composition obtained by the method for producing a concrete composition according to any one of <1> to <6>.

Although the operation of the present invention is not clear, it is estimated as follows. In the manufacturing method of the concrete composition of the present invention, by adding a part of the binder such as cement and silica fume to the total amount of water first, the composition in the first mixing step includes water, the binder, The ratio of the water increases rapidly, water quickly penetrates into the gaps and the periphery of the powder in a short time, and becomes a uniform slurry-like mixture in a short time, and when the remaining binder is added thereto, the water once formed Compared to the above, since the powdery binder is added to the slurry having a high viscosity, the added binder is uniformly dispersed in the slurry without impairing the uniformity of the slurry. It is believed that a slurry with a low water / binder ratio can be prepared and a concrete composition suitable for placement can be obtained.
In addition, in order to be able to efficiently adjust the concrete composition suitable for placing in a short time, the entrainment air at the time of slurry preparation is reduced, and lump kneading that requires more time and energy for slurry preparation than this mode It is considered that the compression strength of the molded product obtained by curing this concrete composition is also improved.
In general, the lower the water / binder ratio is, the more difficult it is to prepare a uniform slurry mixture by kneading. Therefore, the production method of the present invention has a water binder ratio of 0.2 or less, particularly It can be said that the effect is remarkable when used for the preparation of a 0.15 concrete composition.

  In general, as a building material, a mortar is prepared by blending only fine aggregates without containing coarse aggregates with respect to a binder such as cement. In order to show the same or similar behavior in the kneading step if the composition contains a predetermined amount, the “concrete composition” in the present invention includes a mortar composition that does not contain coarse aggregate.

According to the present invention, even when applied to a concrete composition having a low water / binder ratio, specifically, a water / binder ratio of 0.2 or less, a uniform slurry-like concrete composition can be obtained in a short time. The manufacturing method of the concrete composition which can prepare a thing can be provided.
Moreover, by using the composition obtained by the method for producing a concrete composition of the present invention, a concrete molded body having a low water / binder ratio and a high compressive strength can be provided.

<Method for producing concrete composition>
The method for producing a concrete composition of the present invention is a method for producing a concrete composition having a water / binder ratio of 0.2 or less, wherein the total amount of the binder containing cement contained in the concrete composition is 100 parts by mass. A first kneading step in which 50 to 90 parts by mass of the binder and water are kneaded to adjust the slurry, and the remaining amount of the binder is added to the slurry and kneaded. And 2 kneading steps.
Hereinafter, the production method of the present invention will be described in detail.

The concrete composition to which the production method of the present invention is applied is a composition having a water / binder ratio of 0.2 or less, and contains at least water, cement, and other binders, depending on the purpose. Furthermore, it contains aggregates such as fine aggregates and coarse aggregates, and water reducing agents.
The water / binder ratio is required to be 0.2 or less, that is, the binder content in the total amount of water and binder is 83.3% by mass or more. 05 to 0.15, that is, the content of the binder in the total amount of water and the binder is in the range of 87% by mass to 95% by mass.
The binder in the present invention includes cement, which is a main component of concrete, and fine powders such as silica fume, slag and fly ash that are generally used together with cement.

  There is no restriction | limiting in particular in the cement used for the manufacturing method of the concrete composition of this invention, According to the objective, it can select suitably from various cements. As the cement, any known cement such as ordinary Portland cement, moderately hot Portland cement, and low heat Portland cement can be suitably used.

There is no restriction | limiting in particular also in the other binder used with cement, According to the use of the concrete composition prepared, a kind and usage-amount can be suitably selected from various cement and the binder used for concrete.
Specific examples of the binder other than cement that can be used in the present invention include slag such as blast furnace slag fine powder, limestone fine powder, fly ash, and silica fume.
In the present invention, the “binder” includes cement and other binder powder as an additive.

  In addition, the concrete composition may contain other components used in the concrete composition such as an aggregate, a water reducing agent, and a retarder depending on the purpose.

[First mixing step of adjusting the slurry by mixing 50 to 90 parts by mass of water and water when the total amount of the binder containing cement contained in the concrete composition is 100 parts by mass ]
The concrete composition used in the present invention is required to have a water / binder ratio of 0.2 or less. In the present invention, the amount of the binder expressed as “water / binder ratio” And based on the total amount of the above-mentioned binder other than cement.
In the first kneading step, first, 50 to 90 parts by mass of the entire binder is weighed out of the total amount of water, and this is added and kneaded.

  When the total amount of the binder is 100 parts by mass, it is necessary to add 50 parts by mass to 90 parts by mass, and from the viewpoint of efficiently and uniformly kneading, the first mixing step is performed. It is preferable to add as many binders as possible, and it is preferable to add 70 to 90 parts by mass. The ratio of the binder to be added at this time is appropriately selected depending on the physical properties and blending of the concrete composition to be prepared. From the viewpoint of efficiently forming a slurry-like mixture, the ratio of the mixture in the first kneading step is It is preferable to determine the addition ratio of the binder so that the water / binder ratio is 0.1 to 0.3.

Moreover, when the concrete composition to prepare contains an aggregate, it is preferable to mix | blend a fine aggregate among aggregates in a 1st kneading process.
As the fine aggregate used, known materials such as mountain sand and crushed sand can be used. It is preferable that the total amount of the coarse aggregate is added in the first kneading step.

From the viewpoint of efficiently making the mixture into a slurry, it is preferable to add a water reducing agent in the first kneading step.
As the water reducing agent, known ones can be appropriately selected. However, a surfactant selected from an AE water reducing agent mainly composed of lignin sulfonic acid or the like, a sulfonate of higher fatty acid, an oxycarboxylate, or the like as a main component. And water reducing agents.
As the addition amount of the water reducing agent, when the total amount of the binder used in the first kneading step is 100 parts by mass, it can be added in the range of 0 to 10 parts by mass.
When adding a water reducing agent, as long as it adds in a 1st kneading process, the time of addition is arbitrary, and you may add a part of water reducing agent in a 2nd kneading process.

By mixing water, a part of the binder and, if desired, a fine aggregate and a water reducing agent and mixing, the mixture starts from a pendulum state where water penetrates into a part between each solid particle and becomes a lump. It becomes a capillary state in which a uniform water film is formed on the powder surface by capillary action or the like, and further kneaded to become a slurry state with excellent fluidity.
A known mixer can be used as appropriate for the kneading.

When the mixture kneaded in the mixer becomes a slurry state, the state of the mixture being kneaded is changed from a dumpling state (a state having no fluidity) to a fluid state, and the state is visually confirmed. be able to. Moreover, it can also confirm that the load current of the mixer used for kneading has passed the peak that it becomes a slurry state and fluidity | liquidity improves.
The time taken from the start of kneading to becoming a slurry is usually preferably from 15 seconds to 5 minutes, and more preferably from 15 seconds to 2 minutes.
Moreover, after becoming a slurry state, it is preferable to further mix for about 1 to 3 minutes in order to improve uniformity.

[Second mixing step in which the remaining amount of the binder is added to the slurry and mixed]
In this step, the remaining binder is added to the slurry-like mixture (mortar or cement paste) prepared in the first kneading step and further kneaded.
This step can be performed using the same mixer following the first kneading step. That is, after the first kneading step is completed, the mixer is temporarily stopped, and the remaining binder is added to the mixture in a slurry state to perform further kneading.
In this step, only the binder is added to the mixture in the slurry state, but the powder is quickly dispersed in the slurry by adding the powder to the slurry state already formed, A uniform concrete composition is formed. Immediately after the binder is added, a phen- cular state that is an aggregate is formed in the mixture. When kneaded for about 1 to 5 minutes, preferably about 1 to 3 minutes, a uniform slurry state is obtained. The load current once rises and then falls.
Even in the second kneading step, it is preferable to continue kneading for about 1 to 3 minutes after the slurry state is obtained.
Thus, a fluid concrete composition having a predetermined water / binder ratio can be produced in a short time.

In preparing the concrete composition of the present invention, known additives can be appropriately blended.
For example, reinforcing fibers such as carbon fibers and steel fibers may be added to the concrete composition for the purpose of improving strength, toughness, fire resistance, and the like.

  Other additives include, for example, surfactants such as anionic surfactants; organic components such as organic dyes and organic pigments; organic polymer compounds such as water-soluble polymers and water-insoluble fibrous materials, carbon Inorganic fine particles composed of inorganic compounds such as silica and titania, and the like can be included at any stage of production. Furthermore, it is also possible to use particles that have been combined with other materials or particles that have been surface-treated depending on the purpose.

In the concrete composition according to the present invention, in addition to the above essential components and the above-described additives, various additives that are usually blended in cementitious compositions, for example, air entraining agents, antifoaming agents, and the like are blended appropriately. be able to.
In the concrete composition, strength and physical properties can be adjusted by appropriately adjusting the weight ratio of various materials such as water, cement, admixture, aggregate, and chemical admixture.

Among the components other than the binder that can be used in combination with the concrete composition, the components preferably added in the first kneading step include the water reducing agent and fine aggregate. In addition, a water reducing agent and a part of fine aggregate can also be added in a 2nd kneading | mixing process.
Moreover, steel fiber, organic fiber, etc. are mentioned as a component preferable to add after completion | finish of a 2nd kneading | mixing process.

In the concrete composition, the fine aggregate and the coarse aggregate that are optionally used may be added in either the first kneading step or the second kneading step, and the first kneading step, the second kneading step, You may add after the kneading | mixing process of 2.
The fine aggregate and coarse aggregate may be added in the required total amount at once, or may be added in different steps by dividing them into 2 to 3 parts.
As an aspect of addition of fine aggregate and coarse aggregate, an aspect in which the total amount is added in the first mixing step, and an aspect in which the total amount is added in the second mixing step. A mode in which the total amount is added after the end of the first and second kneading steps, and further, a mode in which the coarse aggregate is divided into two, and each is added in the first kneading step and the second kneading step, A mode of adding each after the end of the second kneading step and the first and second kneading steps, and adding each after the end of the first kneading step and the first and second kneading steps Any aspect such as an aspect, an aspect in which the coarse aggregate is divided into three and each of them is added after the first kneading step, the second kneading step, and the first and second kneading steps. You may take
The quantity ratio when the fine aggregate and the coarse aggregate are divided into two and three is arbitrary.
These conditions may be appropriately selected according to the material used for the concrete composition and the physical properties of the target composition.
Among these, the fine aggregate is preferably added during the first kneading step, and the coarse aggregate is preferably added after the second kneading step, as described above.

<Concrete compact>
Although the concrete composition prepared by the production method of the present invention has a water binder ratio as low as 0.2 or less, it is in a uniform slurry state with excellent fluidity. The concrete molded body cured body of the present invention obtained by curing has a high compressive strength and achieves a compressive strength of 80 N / mm ² or more.
The compressive strength can be further improved by further reducing the water binder ratio, and the compressive strength of the concrete molded body of the present invention is preferably 100 N / mm ² or more, and more preferably 150 N / mm ² or more. It is.

  The concrete molded body of the present invention is prepared by kneading a concrete composition containing each of the essential components or various additives added according to the purpose into at least two steps by the method of the present invention. It can be manufactured by placing it on a frame and curing it.

  The concrete molded body of the present invention can be easily manufactured and has a high compressive strength because of its low water / binder ratio, so its application range includes structural materials such as buildings and piers, precast concrete molded bodies, etc. wide.

EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated further in detail, this invention is not restrict | limited to these description.
[Example 1]
(Preparation of concrete composition)
[Materials used]
Cement: Low heat Portland cement (Mitsubishi Materials Corporation) specific gravity 3.24
Admixture: Silica fume (manufactured by Elchem) Specific gravity 2.2
Water: Tap water Fine aggregate: Otsuki andesite crushed sand Specific gravity 2.6
Coarse aggregate: Otsuki-produced andesite crushed stone Max size 15mm Specific gravity 2.6
Water reducing agent: Tupole SSP (manufactured by Takemoto Yushi Co.) Addition amount: 5% by mass of total cement
A concrete composition having a unit water amount: 126 kg / m ³ and a water binder ratio of 0.11 is prepared. The coarse aggregate is added in such an amount that the bulk volume becomes 0.5 m ³ / m ³ . The amount of concrete kneaded was 80 L.

(First mixing process)
First, the total amount of water, the total amount of the admixture, 45.76 kg corresponding to 50% by mass of the combined material of cement and admixture, and 17.56 kg corresponding to 50% by mass of fine aggregate, coarse 29.72 kg corresponding to 50% by mass of the fine aggregate of the aggregate was put into a 100 L kneaded biaxial mixer and kneaded.
After kneading, a uniform slurry state was formed in 23 seconds.
(Second mixing process)
Thereafter, the mixer was temporarily stopped, the remaining 45.76 kg of the binder, the remaining fine aggregate 17.56, and the coarse aggregate 29.72 kg were put into the mixer and further kneaded. After 49 seconds, a uniform slurry state was obtained. A concrete composition was obtained.
That is, in the present embodiment, the kneading is the first kneading, adding half of the total amount of water + the total amount of the admixture + (binding material + coarse aggregate + fine aggregate), and the second kneading. , (Binder + Coarse Aggregate + Fine Aggregate) Each half amount was added.

At this time, the energy required for kneading was measured by measuring the load current applied to the mixer. FIG. 1 is a graph showing the load current applied to the preparation mixer when the concrete composition of Example 1 is mixed. It turns out that the composition of a slurry state can be obtained quickly by kneading in two steps.
The energy required to obtain a concrete composition in a uniform slurry state was 1611 A · sec.

  When the workability of the obtained concrete composition was measured, the amount of air was 2.7%, and the slump flow measured according to JIS A1101 (1998) was 67.5 × 62.5 (cm). Viscosity measured according to JIS R5201 (1997) is 34 seconds at 50 cm flow time, L flow initial value V1 is 2.4 m / s, and V2 is 2.7 m / s, which is suitable for placement. It was found to have fluidity.

(Manufacture of concrete moldings)
The obtained concrete composition was placed in a mold having a diameter of 100 mm and a height of 200 mm, and subjected to standard water curing to obtain a concrete molded body having a material age of 28 days. When the compressive strength of the obtained concrete compact was measured according to JIS R 5201, it was 155.1 N / mm ² , and it was confirmed to be a high-strength compact. Further, when the same molded body was cured by steam curing at 90 ° C. for 3 days, the compressive strength was 259.4 N / mm ² , and it was confirmed that a molded body having high strength could be obtained by steam curing. .

[Comparative Example 1]
A concrete composition was prepared using the same amount of the same material used in Example 1. For the adjustment, the same mixer as used in Example 1 was used. All materials were put into the mixer and mixed in one step to prepare the concrete composition of Comparative Example 1.
FIG. 2 is a graph showing the load current applied to the prepared mixer when the concrete composition of Comparative Example 1 is kneaded. It can be seen that one-step kneading takes about 1.5 times longer to obtain a uniform slurry composition than in Example 1.
The energy required to obtain a concrete composition in a uniform slurry state is 2252 A · second, which indicates that more energy is required than in Example 1.

  When the workability of the obtained concrete composition was measured in the same manner as in Example 1, the air content was 2.3%, the slump flow was 62.5 × 63.5 (cm), and the viscosity was The initial flow rate V1 was 4.9 m / s and the flow rate V2 was 2.7 m / s for 37 seconds at a flow time of 50 cm. It was found that the fluidity was comparable to that in Example 1.

(Manufacture of concrete moldings)
The obtained concrete composition was placed in the same mold as in Example 1 and subjected to standard water curing to obtain a concrete compact with a material age of 28 days. When the compressive strength of the obtained concrete compact was measured, it was 161.8 N / mm ² , and it was confirmed to be a high-strength compact. Moreover, when the same molded body was cured by steam curing at 90 ° C. for 3 days, the compressive strength was 252.7 N / mm ² , and it was confirmed that a molded body having high strength could be obtained by steam curing. .
From the comparison between Example 1 and Comparative Example 1, according to the production method of Example 1, using a concrete composition having a low water / binder ratio, a molded article having excellent compressive strength equivalent to that of a conventional product is obtained. It can be seen that it can be manufactured in a shorter time and with lower energy.

[Example 2]
(Preparation of concrete composition)
[Materials used]
Cement: Silica fume cement (Mitsubishi Materials Corporation) specific gravity 3.08
Water: Tap water Fine aggregate: Oyama, Yamanashi Prefecture Andesite crushed sand Density 2.61 Water absorption 2.48
Water reducing agent: Tupole SSP (manufactured by Takemoto Yushi Co., Ltd.)
A concrete composition in which the unit water amount is 162 kg / m ³ and the water binder ratio is 0.10 is prepared.

Of the above composition, cement as a binder is divided into two equal parts, and in the same manner as in Example 1, half amounts are added in each of the first kneading step and the second kneading step, and a concrete composition is added. Adjusted.
The time required to obtain a uniform slurry state mixture in the first kneading step was measured and found to be 45 seconds. In the second kneading step, it was necessary to obtain a uniform slurry state composition. The time was 75 seconds, and the time required to obtain a uniform concrete composition was 120 seconds.

About the workability of the obtained concrete composition, it carried out similarly to Example 1, and measured air quantity and slump flow. The results are shown in Table 1 below.
Further, the obtained concrete composition was cured by standard water curing and steam curing under the same conditions as in Example 1, to obtain a concrete composition, and the compression strength of the molded body was measured.

[Comparative Example 2]
A concrete composition was prepared using the same amount of the same material used in Example 2. For the adjustment, the same mixer as that used in Example 1 was used. All materials were put into the mixer and mixed in one step to prepare the concrete composition of Comparative Example 2.
In Comparative Example 2, the mixing time required to obtain a uniform concrete composition was 150 seconds.
The concrete composition obtained in Comparative Example 2 was evaluated in the same manner as in Example 1. The results are listed in Table 1 below.

Example 3
(Preparation of concrete composition)
[Materials used]
Cement: Silica fume cement (Mitsubishi Materials Corporation) specific gravity 3.08
Water: Tap water Fine aggregate: Oyama, Yamanashi Prefecture Andesite crushed sand Density 2.61 Water absorption 2.48
Water reducing agent: Tupole SSP (manufactured by Takemoto Yushi Co., Ltd.)
A concrete composition having a unit water amount of 149 kg / m ³ and a water binder ratio of 0.09 is prepared.

Of the above composition, cement as a binder is divided into two equal parts, and in the same manner as in Example 1, half amounts are added in each of the first kneading step and the second kneading step, and a concrete composition is added. Adjusted.
The time required to obtain a uniform slurry state mixture in the first kneading step was measured to be 51 seconds, and it was required to obtain a uniform slurry state composition in the second kneading step. The time was 84 seconds, and the time required to obtain a uniform concrete composition was 135 seconds.

About the workability of the obtained concrete composition, it carried out similarly to Example 1, and measured air quantity and slump flow. The results are shown in Table 1 below.
Further, the obtained concrete composition was cured by standard water curing and steam curing under the same conditions as in Example 1, to obtain a concrete composition, and the compression strength of the molded body was measured.

[Comparative Example 3]
A concrete composition was prepared using the same amount of the same material used in Example 3. For the adjustment, the same mixer as that used in Example 1 was used. All materials were put into the mixer and mixed in one step to prepare the concrete composition of Comparative Example 3.
In Comparative Example 3, the mixing time required to obtain a uniform concrete composition was 180 seconds.
The concrete composition obtained in Comparative Example 3 was evaluated in the same manner as in Example 1. The results are listed in Table 1 below.

As is apparent from Table 1, the concrete compositions obtained by the production methods of Examples 2 and 3 were able to obtain a uniform concrete composition in a shorter time and with lower energy than the comparative examples. Further, the comparison between Example 2 and Comparative Example 2 and Example 3 and Comparative Example 3 shows that the concrete composition obtained by the production method of the present invention has a small amount of air, thereby reducing the amount of air during preparation of the composition. It was confirmed that the amount of entrainment was small.
Further, the molded product obtained by curing the concrete composition obtained by the production method of the present invention is a standard underwater curing compared to the molded product obtained by curing the concrete composition obtained by the comparative example, It can be seen that all of the steam-cured ones have higher compressive strength.

It is a graph which shows the load electric current concerning a preparation mixer at the time of knead | mixing the concrete composition of Example 1. FIG. It is a graph which shows the load electric current concerning a preparation mixer at the time of knead | mixing the concrete composition of the comparative example 1.

Claims (7)

  A method for producing a concrete composition having a water / binder ratio of 0.2 or less, wherein when the total amount of binder containing cement contained in the concrete composition is 100 parts by mass, from 50 parts by mass of the binder A concrete composition comprising a first kneading step for preparing a slurry by kneading 90 parts by mass and water, and a second kneading step for adding the remaining amount of the binder to the slurry and kneading. Manufacturing method.   The method for producing a concrete composition according to claim 1, wherein a water / binder ratio of the concrete composition is 0.05 to 0.15.   The method for producing a concrete composition according to claim 1 or 2, wherein a mixing ratio of water and binder used in the first kneading step is 0.1 to 0.3.   The binder used in the first kneading step contains at least one selected from cement, silica fume, slag, fine limestone powder, and fly ash. A method for producing a concrete composition.   The method for producing a concrete composition according to any one of claims 1 to 4, wherein the first kneading step is a step of further mixing a fine aggregate and a water reducing agent into the binder and water. .   The method for producing a concrete composition according to any one of claims 1 to 4, further comprising a third kneading step of adding and mixing coarse aggregate after the second kneading step. . A concrete molded body having a compressive strength of 80 N / mm ² or more obtained by curing a concrete composition obtained by the method for producing a concrete composition according to any one of claims 1 to 6.

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