JPH058206A - Manufacture of concrete structure - Google Patents

Abstract

PURPOSE:To provide compaction method of concrete whose slump value measured by a concrete slump measuring method displays at least a specific value and separation resistance is high by a vibrator whose number of vibrations and amplitude fall within specific ranges. CONSTITUTION:Concrete whose slump flow value measured by JIS A 1101 (concrete slamp measuring method) shows at least 50cm and separation resistance is high is compacted by a vibrator whose number of vibrations and amplitude fall within specific ranges. With this construction, since high fluidity and filling properties are improved and an environmental problem to separation control and noise are dissolved, it is obvious that manufacturing of a concrete structure makes a rapid improvement and application to not only engineering work and building but also the whole of concrete products requiring early strength is possible.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a concrete structure. More specifically, using high flow non-separable concrete showing a slump flow value of 50 cm or more, it is characterized by compaction by microvibration,
The present invention relates to a method for manufacturing a concrete structure such as civil engineering, construction, and concrete products that has excellent filling properties and surface aesthetics and that improves the environment against noise.

[0002]

2. Description of the Related Art For the durability and surface aesthetics of a concrete structure, it is important to densely fill the concrete. Generally, if the fluidity of concrete is increased, the filling property is improved. However, if the fluidity is only increased, material separation occurs, coarse aggregates are entangled with each other, and uniform concrete cannot be obtained, resulting in a decrease in strength.

Further, a vibrating machine is used for manufacturing concrete structures in order to densely fill the concrete. However, even if the concrete in a usual mixing area is compacted by the vibrating machine, the filling property is poor and the material is separated. It has problems such as large size and many surface bubbles.

[0004]

Means for Solving the Problems As a result of earnest research, the inventors of the present invention have achieved high flow and no material separation due to compaction of concrete in a specific mixing region by microvibration, good filling property, and formation of surface bubbles. It enables the production of reduced concrete structures.

That is, according to the present invention, the slump flow value measured by JIS A 1101 (concrete slump measurement method) is 50 cm.
Using the concrete showing the above and large separation resistance,
The present invention relates to a method for producing a concrete structure, which comprises compacting with a vibrator having a frequency of 30 to 800 vpm and an amplitude of 0.1 to 5 mm.

The vibrating machine used in the present invention has a vibration frequency of 30-80.
The vibration is 0 vpm and the amplitude is 0.1 to 5 mm, and a vibrator having an extremely low frequency is used as compared with general 3000 to 15000 vpm.

In the practice of the present invention, concrete having a slump flow value of 50 cm or more measured by JIS A 1101 (concrete slump measurement method) and having a large separation resistance,
More preferably blast furnace slag (SL), fly ash (F
A concrete composition containing one or two kinds of fine powder selected from A), cement (C), fine aggregate (S), and a high-performance water-reducing agent, which satisfies the following conditions (a) to (c): It is preferred to use the composition. By applying slight vibration to this concrete composition, the filling property is remarkably improved, and not only voids and surface bubbles of the concrete are reduced but also the initial strength of the concrete can be satisfied.

(A) SL / (S + SL) × 100 = 9 to 25% by volume (SL ratio) SL / C × 100 = 24 to 65% by weight (C mixing ratio) (C + SL) / (total concrete composition) × 100 = 14 to 22% by volume (C + SL ratio) (b) FA / (S + FA) × 100 = 20 to 40% by volume (FA ratio) FA / C × 100 = 45 to 85% by weight (C mixing ratio) ( C + FA) / (total concrete composition) × 100 = 18-27% by volume (C + FA ratio) (c) (SL + FA) / (S + SL + FA) × 100 = 9-38% by volume
(FA + SL ratio) (SL + FA) / C × 100 = 24-80% by weight (C mixing ratio) (C + SL + FA) / (total concrete composition) × 100 = 15-
25% by volume (C + SL + FA ratio) The above blast furnace slag and / or fly ash content is
If it is less than the above ranges (a) to (c), the separation resistance is lowered, and if it is more than the above range, the fluidity is lowered due to thickening.

Further, the compaction according to the present invention means that the vibration frequency is 30 to 800 vpm and the amplitude is 0.1 to 5 mm. Generally, vibration compaction of concrete is performed at 3000 to 15000 vpm (3000 to 10000 vpm even in high slump), but the filling property is not sufficient. In comparison with these, the present invention has a high fluidity, so that the filling property is remarkable in an extremely low speed range of 30 to 800 vpm. However, if the frequency is 30 vpm or less, the filling property is not sufficient, and if it is 800 vpm or more, the separation resistance decreases. Looking at the filling efficiency from the amplitude, the frequency is 30 to 10
In the case of 0 vpm, the amplitude is preferably 3 to 5 mm, which is relatively large. When the amplitude is 5 mm or more, vibration noise with the form is generated. When the frequency is 100 to 800 vpm, 0.1 to 3 mm is preferable, and
If it is less than 1 mm, sufficient filling property cannot be obtained. Therefore, for vibration compaction, a region with a vibration frequency of 30 to 800 vpm and an amplitude of 0.1 to 5 mm is effective.

The method of using the vibrator is not particularly limited, and a commonly used method, for example, a method of directly attaching it to a mold material or a form, or a method of attaching it to a form stand such as a table vibrator is used. Can be mentioned. According to the method of the present invention, as compared with the noise (110 to 130 dB) generated during general vibration compaction, extremely quiet (75-90 dB)
Therefore, the environment for noise is improved.

The high-performance water-reducing agent used in the present invention is one or two of naphthalene, aniline sulfonate or melamine, phenol methylol or sulfonate.
One or more formaldehyde monocondensates or cocondensates, for example, naphthalene sulfonate formalin condensate [for example, Mighty 150; manufactured by Kao Corporation], melamine sulfonate formalin condensate [for example, Mighty 15
0V-2; manufactured by Kao Co., Ltd.], phenol sulfonate formalin condensate (for example, Patent No. 1097647), phenol sulfanilate formalin co-condensate (for example, JP-A-1).
-113419), a phenol melamine methylolated sulfonate cocondensate (for example, JP-A-56-13674) and the like are used.

The amount of the high-performance water-reducing agent added is 1.5 in terms of effective content with respect to cement and blast furnace slag and / or fly ash.
It is preferably added in an amount of up to 5.0%, and it can be used as long as it has high fluidity. The concrete structure of the present invention includes civil engineering, building structures and concrete products, for example, vibration compaction products such as box culverts, segments, and road products, and pile products such as piles, poles, and fume pipes. It is not limited.

The blast furnace slag and fly ash used in the present invention are fly ash specified in JIS A 6201 and blast furnace slag having a plane value of 4000-10000 cm ² / g and are not particularly limited. The concrete composition of the present invention can be used in combination with various admixtures (agents).

[0014]

EXAMPLES The present invention will be described below with reference to examples, but the present invention is not limited to these examples. Example 1 Table 1 shows the composition of the high flow non-separation concrete used in the test. Table 2 shows the slump flow value and separation resistance. Table 3 shows the results of the separation resistance of concrete and the surface aesthetics of hardened concrete when the vibration conditions of the vibrator were changed.

[0015]

[Table 1]

[0016]

[Table 2]

[0017]

[Table 3]

The concrete materials and symbols used in the examples are shown below.・ Cement (C) ； Chuo Cement Company Specific gravity ＝ 3.16 ・ Water (W) ； Tap water / fine aggregate (S) ； Kinokawa product river sand Specific gravity ＝ 2.57 FM ＝
2.89 ・ Coarse aggregate (G); Takarazuka crushed stone Specific gravity ＝ 2.60 FM ＝
6.57 ・ Blast furnace slag (SL); NKK company specific gravity = 2.9 Blaine value = 8000 cm ² / g ・ Fly ash (FA); Kansai Electric Power Company specific gravity = 2.3 ・ Water-soluble polymer; Methylcellulose [High Metroz MC
90SH30000: Shin-Etsu Chemical Co., Ltd.] ・ High-performance water reducing agent; naphthalene sulfonate formalin condensate [Mighty 150: Kao Co., Ltd.] ・ (A) = fine aggregate (S) + coarse aggregate ( G). The vibrator used in the example was a variable type of a table vibrator (1000 W), and was subjected to vibration compaction for 15 seconds. The evaluation method is shown below. -Noise measurement: Measurement was performed using a sound level meter [Model S-15, manufactured by Rion Co., Ltd.] at a location 2 m away from the mounting portion of the vibrator.・ The slump flow value is the slump flow value according to JIS A 1101.・ For the separation resistance, concrete was packed in a cylinder form of φ15 cm × 30 cm, the settlement value (mm) of coarse aggregate was measured from the surface, and the following evaluation categories were based on the average value. ○: 2 mm or less, ×: 2 mm or more ・ Surface appearance: Number of bubbles on the concrete surface after hardening (3 mm
The above) was measured and it was set as the following evaluation categories. Number of bubbles per 200 m ² , ○: none, △: 1 to 5, ×: 5 or more. -For the compressive strength, a specimen with a diameter of 10 cm x 20 cm was prepared, steam-cured, and the strength after 24 hours was measured. The compression strength measurement method was in accordance with JIS A 1108. The steam curing conditions were as follows: standing at 20 ° C. for 2 hours, then raising the temperature to 65 ° C. at a heating rate of 20 ° C. per hour, holding for 4 hours, and then naturally cooling. From the results of Table 3, the concrete structure according to the present invention is slightly vibrated as compared with the comparative example.
That is, it can be seen that when the amplitude is 30 to 800 vpm and the amplitude is 0.1 to 5 mm, the effect of excellent separation resistance and surface aesthetics is exhibited.
In addition, since the filling property is excellent, it can be seen that the compressive strength is higher than that of the comparative product.

Example 2 An example of concrete composition and concrete physical properties of high flow non-separable concrete for concrete structures requiring initial strength, particularly concrete products will be shown.
Table 4 shows the concrete composition containing blast furnace slag as fine powder. Table 5 shows the concrete composition containing fly ash as fine powder. Table 6 shows the concrete composition containing blast furnace slag and fly ash as fine powder.

[0020]

[Table 4]

[0021]

[Table 5]

[0022]

[Table 6]

The test method was carried out according to Example 1, and Tables 7 to
Figure 9 shows the results of slump flow after concrete preparation, separation resistance and concrete physical properties after vibration. Example 2
The vibration conditions were as follows: the vibration frequency was 300 vpm and the amplitude was 2 mm. Table 7
From the results of ~ 9, the concrete structure according to the present invention,
It can be seen that the separation resistance is excellent with a high fluidity (slump flow value) of 50 cm or more.

[0024]

[Table 7]

[0025]

[Table 8]

[0026]

[Table 9]

Example 3 Table 10 shows the contents of the high-performance water reducing agent and the comparative water reducing agent used in the examples of the present invention. Table 11 shows the measurement results of the properties of concrete containing various water reducing agents.

[0028]

[Table 10]

[0029]

[Table 11]

From the above results, when the high-performance water reducing agent according to the present invention is used, when the addition amount is 1.5 to 5.0% by weight, the slump flow value shows a high fluidity of 50 cm or more, and the filling property and the separation resistance. It can be seen that the property is good.

[0031]

According to the present invention, high fluidity and improved filling property,
It is clear that the production of concrete structures will be dramatically improved by eliminating environmental problems related to segregation control and noise, and not only for civil engineering and construction, but also for general concrete products that require early strength. It can be applied.

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Claims (3)

[Claims] 1. A concrete having a slump flow value of 50 cm or more and a large separation resistance measured by JIS A 1101 (concrete slump measurement method) and having a frequency of 30 to 80.
A method for producing a concrete structure, which comprises compacting with a vibrator having an amplitude of 0.1 to 5 mm at 0 vpm. 2. A concrete composition containing, as essential components, cement (C), fine aggregate (S) and a high-performance water reducing agent, which are one or two selected from blast furnace slag (SL) and fly ash (FA). The method for producing a concrete structure according to claim 1, wherein the following conditions (a) to (c) are satisfied. (a) SL / (S + SL) × 100 = 9 to 25% by volume (SL ratio) SL / C × 100 = 24 to 65% by weight (C mixing ratio) (C + SL) / (total concrete composition) × 100 = 14 to 22% by volume (C + SL ratio) (b) FA / (S + FA) x 100 = 20 to 40% by volume (FA ratio) FA / C × 100 = 45 to 85% by weight (C mixing ratio) (C + FA) / (Total concrete composition) x 100 = 18 to 27 volume% (C + FA ratio) (c) (SL + FA) / (S + SL + FA) x 100 = 9 to 38 volume%
(FA + SL ratio) (SL + FA) / C × 100 = 24-80% by weight (C mixing ratio) (C + SL + FA) / (total concrete composition) × 100 = 15-
25% by volume (C + SL + FA ratio) 3. As the high-performance water reducing agent, one or two selected from naphthalene, aniline sulfonated compounds or melamine, phenol methylolated compounds or sulfonated compounds.
The method for producing a concrete structure according to claim 1 or 2, wherein a monocondensate or a cocondensate of at least one formaldehyde is used.