KR20120077431A - A fiber reinforced concrete for floor slab - Google Patents

Abstract

PURPOSE: A fiber-reinforced concrete for bottom slabs is provided to enhance constructability and structural durability by enhancing adhesive force and dispersibility within the cement paste. CONSTITUTION: A fiber-reinforced concrete for bottom slabs comprises binding materials which includes cement, water, aggregate and reinforcing fibers(100). The reinforcing fiber is composed of a plurality of filaments(S) and untied formed adhesion portions(130) which are located in both ends. The reinforcing fiber is composed of dual structural by including a linear portion(110) inside and an outer circumferential portion(120). The plurality of filaments which consists of the linear portion is made of basalt fiber. The filaments which consist of the outer circumferential portion are made of polyvinyl alcohol or polyamide. The reinforcing fiber has a loop on the surface by air-interlacing the linear portion with the outer circumferential portion.

Description

A Fiber Reinforced Concrete For Floor Slab}

The present invention relates to a fiber-reinforced concrete for floor slabs, which will be described in more detail. The coating of the shape of the fiber and the surface of the fiber provides excellent dispersibility in concrete and facilitates the construction of the floor slab. The present invention relates to a fiber-reinforced concrete for floor slabs that has excellent structural durability and prevents the reinforcing fibers from protruding from the floor slab surface, thereby preventing finishing and surface strength from falling.

In general, the floor slab is a structure that forms the bottom of the structure, such as factories, and serves to transfer the load of the upper floor slab to the ground of the lower floor slab. The floor slab is to be installed after mining the ground of the construction site, to install a joint (joint) rules on the outer periphery of the building (joint) and to reinforce the inside, and then to pour concrete cured. At this time, the floor slab top surface is to be finished to increase the surface strength and to increase the smoothness, using a hardner, surface reinforcing agent, urethane and the like.

Conventionally, in applying such a method, steel fiber is mixed (Steel Fiber Reinforced Concrete) is poured. Concrete incorporating these steel fibers has a high three-dimensional uniform reinforcement of the shear surface, and has a high load-bearing capacity, and can reduce the thickness of the floor slab and significantly less cracking than conventional concrete. In addition, since the process such as reinforcement and stormwater work is not necessary, only the floor compaction work needs to be carried out.

However, when the floor slab is constructed with concrete mixed with steel fibers, the specific gravity of the steel fiber is large, so that the dispersibility is not good. There is a problem such as lowering the strength, and in cold regions, there is a problem of lowering the temperature of the concrete that is not hardened and delaying the hardening of cement.

The present invention has been made to solve the above problems, and excellent in workability and structural durability, and prevents the occurrence of corrosion on the surface by preventing the reinforcement of the reinforcing fibers to the floor slab surface excellent surface strength and smoothness To provide fiber reinforced concrete for slab.

In the present invention as a means for achieving the above object is a reinforcement is composed of a plurality of filaments, particularly composed of a plurality of filaments, while presenting a fiber-reinforced concrete for the floor slab comprising a binder containing cement, water, aggregate The present invention provides a fiber reinforced concrete for floor slab to which fibers are added. The structure in which the loop is formed or the structure of the outer periphery is presented, and the dispersibility and adhesion are excellent, so that the construction of the floor slab is excellent, and the structural durability such as crack resistance is excellent due to the uniform dispersion. After the projection to the floor slab surface, this prevents the occurrence of corrosion, etc. floor slab island Present the reinforced concrete.

Fiber reinforced concrete for floor slab according to the present invention has the advantage of excellent dispersibility and adhesion in the cement paste based on the structural shape, such as loops by air entanglement added to the construction and structural durability.

In addition, the fiber reinforced concrete for the floor slab of the present invention has the advantage of excellent surface strength and smoothness by preventing the occurrence of corrosion on the surface by preventing the protrusion of the reinforcing fiber to the surface of the floor slab based on the material of the reinforcing fiber is added.

1 is a schematic view showing an embodiment of the fiber reinforced concrete for the floor slab of the present invention,
FIG. 2 is a perspective view showing a schematic diagram of air entanglement in a fiber having a double structure shown in FIG. 1;
Figure 3 is an exploded perspective view showing another embodiment of the fiber reinforced concrete for the floor slab of the present invention,
Figure 4 is a schematic diagram showing the fiber reinforced concrete for floor slab containing short fibers and reinforcing fibers,
Figure 5 is a schematic diagram showing the fiber reinforced concrete for floor slab containing steel fibers and reinforcing fibers.

Hereinafter, the configuration and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, the term or word used in the present specification and claims is based on the principle that the inventor can appropriately define the concept of the term in order to best describe the invention of his or her own. It should be interpreted as meanings and concepts corresponding to the technical idea of

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Fiber reinforced concrete for the floor slab of the present invention is composed of a binder containing cement, water, aggregate and a plurality of filaments, characterized in that it comprises a reinforcing fiber composed of the attachment portion of the shape released at both ends.

That is, as shown in Figure 1, the fiber reinforced concrete for the floor slab of the present invention is composed of a cement paste 21 including reinforcing fibers and water, cement, fine aggregate, coarse aggregate to form a floor slab 20 of a structure such as a factory. will be.

In the fiber-reinforced concrete for slab of the present invention, a binder including cement may selectively consider its blending ratio in consideration of strength expression, economical efficiency, and fluidity.

In addition, in the fiber-reinforced concrete for the floor slab of the present invention, the water may selectively consider its blending ratio in terms of strength and fluidity.

In addition, in the fiber reinforced concrete for the floor slab of the present invention, the aggregate and coarse aggregate may be selectively considered in consideration of its fluidity and material separation reduction aspect.

In particular, in the fiber reinforced concrete for the floor slab of the present invention, the advantages such as constructability, structural durability and ease of use are derived from the addition of reinforcing fibers. Hereinafter, the reinforcing fibers will be described.

The reinforcing fiber is composed of a plurality of filaments (S), as shown in Figures 1 and 3 and the attachment portion (130, 130a) of the shape of each filament is released at both ends is the attachment portion (130, 130a) In order to enhance the durability of the bottom slab 20 including the reinforcing fiber of the present invention by promoting the adhesion with the cement paste 21.

Meanwhile, in the present invention, the reinforcing fibers 100 and 100a of the two embodiments are presented, and a plurality of straight portions 110 and 110a and a plurality of straight portions 110 and 110a composed of a plurality of filaments S are provided at a central portion thereof. Attachment part configured to have a shape in which the filaments S are unwound at both ends of the outer periphery 120 and 120a and the straight portions 110 and 110a and the outer periphery 120 and 120a configured to surround the filament S. An embodiment consisting of 130 and 130a is provided.

First, as a first embodiment, the reinforcing fiber 100 is composed of a straight portion 110 composed of a plurality of filaments, the outer periphery 120 surrounding them and the attachment portion 130 at both ends thereof, as shown in FIG. As shown in FIG. 2, the straight portion 110 and the outer circumferential portion 120 each filament is formed by interlacing the straight portion 110 and the outer circumferential portion 120 formed by a plurality of filaments S. To entangle (S). That is, the fiber 100 thus produced forms a plurality of loops R on its surface, and the loops R improve the adhesion performance with the cement paste 21 to be described below.

In this case, the air line between the straight portion 110 and the outer circumferential portion 120 is not shown in the drawing, but may be formed by interlacing the straight portion 110 and the outer circumferential portion 120 without mutual distinction. As shown in FIG. 1, the straight line 110 and the outer circumferential portion 120 may be divided and entangled with each other.

Here, "air entanglement" refers to the air throttling device by supplying a matrix composed of a straight portion 110 and the outer peripheral portion 120 composed of a plurality of filaments (S) in the air entanglement by injecting high-pressure air It means to entangle the filament (S).

On the other hand, the reinforcing fiber 100 is more advantageous in adhesion and dispersibility that the loop (R) having a size of 0.01 ~ 2mm on the surface is formed of 100 ~ 1,000,000 per 1m length of the reinforcing fiber.

The filament constituting the reinforcing fiber 100 is characterized in that the basalt fiber.

The bazaar fibers are extracted from basalt, which is a natural mineral, and when the floor slab 20 is constructed by the fiber-reinforced concrete for the floor slab of the present invention based on high elasticity and high rigidity, prevents agglomeration between fibers based on high elasticity. The uniform distribution of the fiber makes it possible to prevent structural durability, especially surface strength and surface detachment, and to control the crack based on high rigidity and to strengthen the strength by holding firmly between different materials. Will be.

In addition, by constructing the reinforcing fibers 100 by the basalt fiber, it is possible to solve the problem of surface durability degradation due to cost-effectiveness and corrosion of the finish by protruding to the surface when steel fibers are conventionally added.

In addition, since the reinforcing fiber 100 is composed of a filament composed of bazalt fibers, it has a coefficient of thermal expansion almost similar to that of aggregates, thereby preventing cracks due to temperature changes.

Meanwhile, when the reinforcing fiber 100 of the present invention is divided into a straight portion 110 and an outer circumferential portion 120, as shown in FIG. 1, the straight portion 110 has the same strength as that of the basalt fiber. And it is preferable to improve the strength and flexibility by using a high elastic filament (S), the outer periphery 120 is to use a hydrophilic yarn such as polyvinyl alcohol or polyamide for attachment to the cement paste 21 desirable. When using a hydrophilic yarn in this way, it is possible to increase the adhesion to the cement paste 21 by the hydrogen bonding is to improve the durability of the floor slab (20).

Single filament fineness (mono fineness) of the filament for manufacturing in the form of such air entanglement is 0.5 ~ 10 denier, the total fineness of the reinforcing fibers is preferably 100 ~ 5,000 denier. However, low mono fineness is advantageous. This is because the entanglement is loose when the mono fineness is too thick, and is easily released when blended.

Meanwhile, in the present invention, as shown in FIG. 3 as another embodiment, the reinforcing fiber 100a is presented, and the reinforcing fiber 100a includes a straight portion 100a composed of a plurality of filaments S, and a plurality of filaments. Consists of (S), it is composed of an outer circumferential portion (120a) of the shape woven while wrapping the straight portion (100a). The outer periphery 120a is to reinforce the tensile strength in the multi-direction in a state where the plurality of filaments (S) are formed by weaving in multiple directions while maintaining the linearity by the straight portion (110a) .

Therefore, the outer periphery 120a is a plurality of filaments (S) as shown in Figure 3 the filament (S) in the circumferential direction (X axis direction) and axial direction (Y axis direction), the circumference of the reinforcing fiber 100a It is produced by weaving each filament in four directions in a diagonal direction between the direction and the axial direction. The outer periphery 120a is formed by weaving the filaments in the multi-direction so that the fiber 100a is enhanced not only in the axial direction but also in the circumferential and diagonal directions, thereby improving the resistance performance due to external force in the multi-direction. Will be.

In addition, the outer periphery 120a is formed by weaving a plurality of filaments (S) in a multi-direction, the bending is formed on the surface of the outer periphery (120a) is improved adhesion to the cement paste 21 and eventually the bottom slab 20 ) Strength is reinforced.

Wherein the straight portion (100, 100a) is formed by a plurality of filaments (S) to be placed inside the outer periphery (120, 120a) to hold the shape (straightness) of the reinforcing fibers (100, 100a) It is to be possible to prevent the degradation of the dispersibility due to agglomeration between the fibers (100, 100a) based on the straight portion (110, 110a). In addition, by maintaining the linearity in the cement paste 21 based on the straight portions 110 and 110a, the tensile strength of the bottom slab 20 is reinforced.

In particular, the attachment portion (130, 130a) is to be configured to the filament (S) constituting the straight portion (110, 110a) and the outer periphery (120, 120a) loosened form to enhance the adhesive force with the cement paste 21 It can be. The attachment parts 130 and 130a may be formed by the straight parts 110 and 110a based on the cement particles constituting the cement paste 21 in a state where only the straight parts 110 and 110a and the outer peripheral parts 120 and 120a are formed. Attachment between the filaments (S) constituting each of the outer periphery (120, 120a) is loosened may be configured in the compounding process to expand the diameter, the straight portion (110, 110a) and the outer periphery before mixing Only the 120 and 120a may be configured in a shape in which the diameter of the filaments S is loosened at both ends of the reinforcing fibers 100 and 100a by cutting while vibrating at a slow speed in the matrix state. have. That is, by forming the attachment portions 130 and 130a, cement is filled between the gaps generated as the attachment between the filaments S becomes loose, thereby increasing the bonding force between the reinforcing fibers 100 and 100a and the cement paste 21. will be.

In addition, in forming the attachment portions 130 and 130a, it is reasonable to manufacture the non-attachment between the straight portions 110 and 110a of the fiber and the filaments S constituting the outer peripheral portions 120 and 120a. In order to easily form the attachment portions 130 and 130a by forming the non-attachment between each filament (S). Thus, even if the filament (S) between the non-attachment, the friction force between each filament (S) acts to a certain degree of adhesion occurs, it is not a problem to maintain the shape of the reinforcing fibers (100, 100a).

In addition, as shown in FIG. 3, the coating layer 140a including a polyhydric alcohol ester lubricant, a nonionic surfactant, and an antistatic agent may be further applied to the outer peripheral portion 120a. By coating the coating layer 140a on the surface of the fiber 100a, the dispersibility of the fiber 100a is greatly improved in the cement paste 21.

Preferably in the present invention, the coating layer 140a is blended with 40 to 50% by weight of a polyhydric alcohol ester lubricant, 30 to 40% by weight of a nonionic surfactant, and 10 to 30% by weight of an antistatic agent to apply the coating layer 140a. It is reasonable.

In addition, the coating layer (140a) is preferably 0.5 to 3% by weight relative to the total weight of the fiber (100a), if outside the above range can be reduced the effect of improving the dispersibility and adhesion.

In the above, the coating layer 140a is shown only on the outer circumferential portion 120a of the reinforcing fiber 100a shown in FIG. 3, but it is obvious that the coating layer may be configured in the case of the reinforcing fiber 100 according to another embodiment.

Such reinforcing fibers preferably contain more than 0.1 and 1.0% or less based on the unit volume of fiber reinforced concrete for floor slabs. If the content of the fiber is 0.1% or less with respect to the unit volume of the fiber reinforced concrete for floor slab, it does not satisfy the criteria of structural durability such as the equivalent bending strength ratio, and also disadvantages in terms of crack control. In addition, when the fiber exceeds 1.0% agglomeration occurs during the construction of the floor slab, the dispersibility is lowered, it is also disadvantageous in terms of strength.

Meanwhile, in the present invention, it is preferable to set the slump of the concrete which is not hardened to 80 to 230 mm in the process of mixing the fiber reinforced concrete for the floor slab, and more preferably, the slump to 80 mm. This is the same as described in the prior art, when mixing the fiber reinforced concrete for the floor slab by mixing the conventional steel fibers to fit the slump to 230mm or more based on problems such as agglomeration. It becomes weak and a problem of non-uniform distribution occurs and eventually the durability of the floor slab 20 will fall. However, in the present invention, by mixing the reinforcing fibers (100, 100a) composed of the basalt fibers, etc., and mixes the concrete, even if the slump is adjusted to 80 mm, which is a general slump, no agglomeration occurs, and the like, the viscosity and the material of the fiber, etc. Geometry can be uniformly distributed, thereby improving the durability of the floor slab.

On the other hand, the diameter of the reinforcing fibers (100, 100a) is possible up to 0.02mm ~ 10mm, more preferably limited to 0.1mm ~ 2.0mm. If less than 0.1mm, it did not show a big difference from the monofilament, it is difficult to manufacture because a large number of filaments can not be used even in the air entanglement, it is difficult to express the structural performance in the floor slab low tensile strength. On the contrary, when the diameter exceeds 2.0 mm, the air entanglement is difficult and the double layer is formed in the cement paste, which is structurally disadvantageous.

In addition, the reinforcing fibers (100, 100a) is preferably limited to the length of 10 to 200mm, if less than 10mm the reinforcing fibers (100, 100a) expresses the effect on the strength expression and crack control in concrete Insignificant to do, the reinforcing fibers (100, 100a) itself can be released in the concrete all the double structure of the fiber is not maintained, the problem may occur, and the reinforcing fibers (100, 100a) is 200mm If it exceeds the agglomeration occurs between the reinforcing fibers (100, 100a) there is a problem that the dispersibility is lowered.

Meanwhile, the present invention includes the reinforcing fiber 100 in the cement paste 21 including water, cement-containing binder, fine aggregate, and coarse aggregate in constructing the fiber reinforced concrete for the floor slab as shown in FIG. 4. In addition, an example in which short fibers 150 are further included is provided.

As shown in FIG. 4, the short fiber 150 included in the present embodiment is also coated with a coating layer 151 including a polyhydric alcohol ester lubricant, a nonionic surfactant, and an antistatic agent on the surface thereof, thereby providing a cement paste 21. It is reasonable to improve dispersibility within.

The short fiber 150 is also composed of a monofilament or a plurality of filaments, characterized in that the filament is a basalt fiber.

On the other hand, in the case of the short fiber 150, if the length is long, the occurrence frequency of the aggregation phenomenon is high, it is reasonable that the short fiber 150 has a shorter length than the reinforcing fiber 100.

The long length of the reinforcing fiber 100 in the cement paste 21 is maintained in the shape of the straight portion 110, the aggregation does not occur, the strength of the bottom slab 20 is reinforced, the outer peripheral portion 120 And the cement paste 21 and the adhesion force are increased based on the attachment portion 130, and in particular, the macro cracks in the cement paste 21 can be controlled.

In addition, the short fibers 150 are short, the coating layer 151 is formed on the surface to improve the dispersibility, the agglomeration is prevented due to the relatively short length, the reinforcing fibers 100 in the cement paste 21 By controlling the micro-cracks which cannot be controlled, eventually, cracks of various shapes and sizes in the bottom slab 20 are controlled to improve their durability.

In another embodiment, the reinforcing fiber 100 is included in the cement paste 21 including water, cement-containing binder, fine aggregate, and coarse aggregate in constructing the fiber reinforced concrete for floor slab. An example is provided in which 160 is further included. This is to reinforce the portion of the steel fiber 160 is insufficient to reinforce the bending toughness in the cement paste 21 only by the reinforcing fiber 100, as shown in FIG. In addition, by incorporating the steel fiber 160 into the reinforcing fiber 100 is to solve the problem of lowering the dispersibility due to the specific gravity that can be caused by the steel fiber (160).

In this way, the reinforcing fiber 100 in the cement paste 21 is maintained in the shape of the straight portion 110 so that no aggregation occurs and the strength of the bottom slab 20 is reinforced, and the outer periphery 120 and the attachment portion are The adhesion force with the cement paste 21 is increased at 130, and in particular, the crack can be controlled due to the improvement of the adhesion force in the cement paste 21. In addition, by partially mixing the steel fiber 160 to prevent dispersibility deterioration due to specific gravity, and to strengthen the flexural toughness based on the rigidity greater than the reinforcing fiber 100 to improve the durability of the bottom slab 20 eventually.

4 and 5 illustrate an example in which the reinforcing fiber 100 is included in the fiber reinforced concrete for the floor slab, it is obvious that the reinforcing fiber 100a may be included as another embodiment.

100, 110a: reinforcing fiber 110, 110a: straight part
120, 120a: outer circumference 130, 130a: attachment

Claims (9)

Fiber-reinforced concrete for floor slab, comprising a reinforcing fiber composed of a binder, water, aggregate and a plurality of filaments containing cement, the attachment portion of the shape is released at both ends.
The method of claim 1,
The reinforcing fiber is a fiber reinforced concrete floor slab, characterized in that composed of a double structure of the inner peripheral portion surrounding the straight portion and the straight portion.
The method of claim 2,
The filament constituting the straight portion is composed of a basalt fiber, the filament constituting the outer periphery is fiber reinforced concrete for floor slab, characterized in that composed of polyvinyl alcohol or polyamide.
The method of claim 2,
The reinforcing fiber is a fiber reinforced concrete floor slab, characterized in that the straight portion and the outer peripheral edges are mutually air-interlocked loop is formed on the surface.
The method of claim 1,
The surface of the reinforcing fiber fiber reinforced concrete for floor slab, characterized in that the coating layer further comprises a polyhydric alcohol ester lubricant, nonionic surfactant and antistatic agent.
The method of claim 1,
The reinforcing fibers are fiber reinforced concrete for floor slabs, characterized in that the compounding is more than 0.1% and 1.0% or less relative to the concrete unit volume.
The method of claim 1,
The reinforcing fiber has a diameter of 0.1mm to 2.0mm, the length of the fiber reinforced concrete floor slab, characterized in that 10 to 200mm.
The method of claim 1,
Fiber-reinforced concrete for floor slabs, characterized in that the slump is formulated from 80 to 230mm.
The method of claim 1,
Fiber-reinforced concrete for floor slabs, characterized in that it further comprises short fibers or steel fibers composed of multifilament or short filament.

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