JP3276080B2 - Fiber mixed high fluidity concrete - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to concrete having excellent fluidity in fresh properties and excellent strength, especially in flexural strength and flexural toughness, in hardened properties.

[0002]

2. Description of the Related Art High fluidity concrete having a slump flow of 50 cm or more is utilized for filling high-density reinforcing bars and narrow spaces where reinforcing bars cannot be disposed, utilizing its flow characteristics. Of these, in a narrow space where a reinforcing bar cannot be placed, high strength concrete is required to have sufficient strength and toughness because there is no reinforcing bar. Examples of application of high-fluidity concrete to such a non-arranged portion include, for example, joint adjustment concrete for bridges and repair concrete for repairing cross sections.

[0003] As a means for imparting strength and toughness in a hardened state to such high fluidity concrete, there is a reinforcing method by mixing short fibers.

[0004]

However, in a high fluidity concrete requiring a slump flow of 50 cm or more, if short fibers are mixed in an amount sufficient to expect tensile strength and toughness, in most cases, There is the problem that the fluidity is reduced and the self-filling performance is lost.

For example, when steel fiber or vinylon fiber is mixed in high fluidity concrete in such an amount that the reinforcing effect can be expected (0.1 to 2.0% by volume), the slump flow value decreases and the self-filling performance decreases. Will be lost. Therefore, when short fibers are mixed, the intended slump flow value must be ensured by increasing the unit water volume as compared with the case where no short fibers are mixed. Increasing the unit water volume not only decreases the durability of concrete, but also increases the unit cement amount to ensure strength, and raises the problem of not only raising costs but also causing temperature cracking. .

Therefore, the slump flow value is 50 cm.
As described above, in particular, when short fibers are mixed into a high-fluidity concrete of 60 cm or more to achieve high strength, various methods are required to achieve both high flowability in fresh properties and high strength in hardening properties. It was usually difficult and costly.
The present invention seeks to solve this problem.

[0007]

DISCLOSURE OF THE INVENTION The present inventors have developed a short fiber which is formed (processed) in a corrugated form, unlike a short fiber which is commonly used for fiber reinforced concrete and has a straight shape. In particular, it was found that the use of corrugated polypropylene short fibers can develop excellent strength, especially flexural strength and toughness, without significantly affecting the fresh properties of high-fluidity concrete. .

That is, according to the present invention, corrugated polypropylene short fibers are compounded as short fibers in high fluidity concrete having a slump flow value of 50 cm or more, in which water, cement, fine aggregate, coarse aggregate, short fibers and an admixture are mixed. It is intended to provide a fiber-mixed high-fluidity concrete characterized by the above. Here, the corrugated polypropylene short fibers are preferably subjected to a hydrophilic treatment, and the compounding amount thereof is preferably 0.1 to 2.0% by volume. This high fluidity concrete may further contain one or more of stone powder, blast furnace slag fine powder, silica fume, and fly ash as other admixtures, and a high-performance AE water reducing agent as an admixture. It is preferable to use a thickener to simultaneously exhibit high fluidity and resistance to material separation. This fiber-mixed high-fluidity concrete is suitable for filling narrow spaces in non-arranged portions, for example, adjustment joints of bridges and repairing sections.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention is characterized in that corrugated polypropylene short fibers are blended into high-fluidity concrete. The corrugated polypropylene short fibers used in the present invention are different from linear (straight) polypropylene short fibers in that they are formed into a corrugated shape.

Here, the straight polypropylene short fiber is defined as a fiber diameter and a fiber length suitable for blending with mortar or concrete, for example, a fiber diameter of 1000 to 90.
It refers to a straight (straight) polypropylene short fiber having a denier of 00 and a self-supporting shape having a fiber length of 5 to 60 mm (a self-supporting shape that does not bend even when supported at one end), but is used in the present invention. The corrugated polypropylene short fiber is a straight polypropylene short fiber formed into a corrugated shape, and the fiber diameter and fiber length after molding are the same as those of the straight type (however, the fiber length is corrugated). In this state, it refers to the length that measures the linear distance from one end to the other end).

Here, the fact that the fiber is corrugated differs from the straight type shown in FIG. 1 in that the fiber is formed or processed so that the peaks and valleys are ideally repeated alternately at the same pitch as shown in FIG. This means that the shape of the waveform is maintained when no external stress is applied. For example,
An ideal shape is a wavy line obtained when a corrugated plate (corrugated plate) on which a wave of a constant pitch is formed is cut linearly along the direction of the wave, as shown in FIG. Assuming that the angle is θ ₁ , the inclination angle of adjacent valleys is θ ₂ , the pitch width between peaks is D ₁ , and the pitch width between valleys is D ₂ , θ ₁ ≒ θ
₂ , the wave in which the wave of D ₁ ≒ D ₂ is repeated in the same direction is an ideal shape. Therefore, although there are peaks and valleys, the short fibers have unidirectionality as a whole in the longitudinal direction. This is only an ideal shape. Even if the pitch is slightly deviated from this ideal shape, for example, if the pitch width is disturbed to some extent, or if the longitudinal direction is slightly changed in the middle (as if the whole was bent in the middle) State),
Alternatively, even if the peaks and valleys are not in the same plane and are twisted, those in which the peaks and valleys are repeatedly formed into a waveform are referred to as corrugated polypropylene short fibers according to the present invention. θ ₁ and θ ₂ are in the range of 90 to 160 ^° , D ₁ and D
₂ is preferably in the range of 5 to 10 mm.

When such corrugated polypropylene short fibers are mixed into a high-flow base concrete, the strength and toughness can be improved without significantly lowering the flowability of the base concrete. It has advantageous effects that are not found in vinyl fiber and vinylon fiber, and is superior in toughness and higher bending strength and shear strength than straight polypropylene short fiber. Although the reason is not clear, polypropylene short fibers are easy to adapt to high-fluidity concrete, and especially polypropylene short fibers that have been subjected to hydrophilic treatment disperse well in high-fluidity concrete. This is considered to be because the adhesion strength with concrete is higher than that of the concrete, and the generation of cracks is suppressed. Even if fine cracks are generated, the propagation of the cracks is prevented and the cracks are dispersed.

The base concrete containing the corrugated polypropylene short fibers has a slump flow of 50 cm or more, preferably 60 cm or more, and in some cases 65 cm.
Even in the case described above, there is no material separation, and it is possible to apply a high fluidity concrete in which materials are blended so as to have excellent self-filling properties.
Mortar that does not contain coarse aggregate can be used as a base, in addition to high-fluidity concrete containing coarse aggregate.
Of course, it is also possible to mix one or more other admixtures commonly used in high fluidity concrete, such as stone powder, blast furnace slag fine powder, silica fume, fly ash and the like.

In order to obtain such a high fluidity concrete, a high performance water reducing agent or a high performance AE water reducing agent is usually used as an admixture. A combination of a high performance AE water reducer and a thickener is preferred for good fiber dispersion. As the high-performance AE water reducing agent that can be used, various types such as naphthalene sulfonic acid salt type, polycarboxylic acid type, melamine sulfonic acid and amino sulfonic acid type can be applied, but polycarboxylic acid type is preferable. The amount of the high-performance AE water reducing agent to be added depends on its type, but it is 0.5 to cement (when adding fine powder such as stone powder or silica fume, to the amount of cement plus fine powder). ~ 5
What is necessary is just to mix | blend in the range of weight%. As a thickening agent, bio-gum such as welan gum is preferable, and the amount of addition is about 0.005 to 0.10% by weight, preferably about 0.01 to 0.05% by weight, based on the amount of water, and the amount of fluid is increased. Suitable viscosity can be provided without impairing the properties.

[0015]

EXAMPLE Based on a high-fluidity concrete with a slump flow value of 66 cm as a base, four types of short fibers A to D having the characteristic values shown in Table 1 were added to each of them in an amount of (1).
0.5 vol.%, (2) 1.0 vol.% And (3) 1.5 vol.% Were mixed, and the fresh property and the curable property were examined. Table 2
The composition of the base concrete and the composition of each fiber-concrete concrete are shown below. Mixing is 100L forced 2
Performed using an axial mixer.

C and D in Table 1 are polypropylene short fibers having the same diameter, length, tensile strength and specific gravity.
Has a straight (linear) shape, whereas D has a waveform. The corrugation of D fiber is
The height difference between the peaks and valleys is formed at approximately equal intervals of about 2 mm and the pitch width is about 6 mm, and the peaks and valleys repeat the height in substantially the same plane. Therefore, although there are peaks and valleys, the short fibers have a unidirectionality as a whole in the longitudinal direction, and none of them is bent in the middle. In addition,
The length 30 mm of the D fiber in Table 1 is a length that measures a linear distance from one end to the other end in a waveform state. The polypropylene short fibers C and D are both surface-treated so as to exhibit hydrophilicity.

The materials used in the formulations in Table 2 are as follows. Cement: ordinary Portland cement Sand: mountain sand Gravel: crushed stone High-performance AE water reducing agent: SP8S (polycarboxylic acid-based standard type) manufactured by NMB Corporation Thickener: Welan gum (manufactured by Sansei Co., Ltd.)

Table 3 shows the fresh properties (measured values of slump flow and air amount) of each high fluidity concrete. Table 3 shows the hardening properties (compressed strength, bending strength, flexural modulus in bending toughness test, and measured values of shear strength in shear strength test) of each high fluidity concrete in Table 3.

[0019]

[Table 1]

[0020]

[Table 2]

[0021]

[Table 3]

[0022]

[Table 4]

From the results shown in Table 3, it can be seen that the slump flow of the A-type and B-type concretes in which steel fibers or vinylon fibers are mixed into the base high-fluidity concrete is greatly reduced in accordance with the mixing amount. In the A system containing steel fiber, the mixing amount of steel fiber is 1.5% by volume A-3.
In the figure, a fiber ball in which the fibers were in a dumpling shape was observed. Similarly, fiber balls were also observed in B-2 and B-3 in which vinylon fibers were mixed at 1.0% by volume or more.
Therefore, it can be seen that even if an attempt is made to reinforce the high fluidity concrete with the fibers A and B, the fluidity is reduced, and the original characteristics of the high fluidity concrete are deteriorated.

On the other hand, in the systems C and D in which the polypropylene fibers were mixed, even if both were mixed up to 1.0% by volume, substantially the same slump flow value as the base concrete was maintained, and the slump flow value was 1.5. Even when the volume% is mixed, the slump flow value does not decrease much and a sufficient high fluidity can be maintained. In these C-1 to C-3 and D-1 to C-3, no fiber ball was formed at all. Therefore, it is clear that polypropylene staple fiber shows good dispersibility in high-fluidity concrete, which cannot be obtained with steel fiber or vinylon fiber. The dispersibility is not worse than that of the straight type.

On the other hand, as can be seen from the results in Table 4, regarding the hardening properties, the D-type high-fluidity concrete mixed with corrugated polypropylene short fibers is harder than the A-type high-flowability concrete containing steel fibers. The physical properties are equivalent, and it can be seen that the flexural strength and flexural toughness are greatly improved as compared with those of the B type containing vinylon fiber and the C type containing straight polypropylene fiber.

[0026]

As described above, according to the present invention,
It is possible to obtain concrete with improved flexural strength in hardened properties without lowering the flow characteristics inherent in high-fluidity concrete. Therefore, the high-fluidity concrete containing corrugated polypropylene short fibers according to the present invention can be filled in narrow gaps and voids and can exhibit sufficient strength, particularly bending strength, even in a non-arranged location, so that the joint concrete for a bridge can be adjusted. And excellent effect as repair concrete at the time of section restoration.

[Brief description of the drawings]

FIG. 1 is a plan view showing a shape example of a straight polypropylene short fiber.

FIG. 2 is a plan view showing a shape example of corrugated polypropylene short fibers.

────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoshinobu Shinda 2-9-1-1, Tobita-Shi, Chofu-shi, Tokyo Kashima Construction Co., Ltd. (56) References JP-A 2000-302494 (JP, A) ( 58) Field surveyed (Int.Cl. ⁷ , DB name) C04B 16/06 C04B 28/02

Claims (3)

(57) [Claims] 1. A slump flow value of 5 containing water, cement, fine aggregate, coarse aggregate, short fibers and a high-performance AE water reducing agent.
A high-fluidity concrete mixed with fibers, wherein corrugated polypropylene short fibers are blended as the short fibers in a high-fluidity concrete of 0 cm or more. 2. Water, cement, fine aggregate, coarse aggregate, short fiber
Slump containing fiber, high-performance AE water reducer and thickener
In high fluidity concrete with a flow value of 50 cm or more,
A corrugated polypropylene short fiber is blended as the short fiber.
Fiber-mixed high-fluidity concrete characterized by the fact that: 3. Stone powder, blast furnace slag fine powder, silica fume
And one or more of fly ash
The fiber-mixed high-fluidity concrete according to claim 1 or 2, which is produced .