KR100980658B1 - Different material reinforcing bar for artificial structure - Google Patents

Abstract

The present invention relates to reinforcing bars for reinforcing rigidity of artificial structures. The present invention is formed in a straight line to form a rod, the core member (C) for maintaining a straight line by its rigidity; It is made of a different material from the core member (C), it is coupled to the outer peripheral surface of the core member (C) in the same body along the circumferential direction to form a straight line with the core member (C), and at the same time the core member (C) and a single body Reinforcement member (R) for reinforcing the rigidity of the core member (C); wherein, the reinforcing member (R) and the core member (C) is at least one made of a fiber reinforced polymer, the reinforcing member (R) ) Includes a carbon fiber reinforced polymer 12, a glass fiber reinforced polymer 16 and a binder 22 arranged on the outer circumferential surface of the core member (C), the carbon fiber reinforced polymer 12 and glass fiber reinforced Polymer 16 is characterized in that arranged in a cross state along the circumferential direction of the core member (C). The present invention is composed of a heterogeneous reinforcing member (R) and the core member (C) to provide a strong rigidity.

Structures, reinforcement, tensile, compression, polymer

Description

Heterogeneous reinforcement for artificial structures {DIFFERENT MATERIAL REINFORCING BAR FOR ARTIFICIAL STRUCTURE}

The present invention relates to reinforcing bars applied to artificial structures to reinforce the rigidity of artificial structures, and more particularly, to reinforcing bars used for artificial structures such as bridges and buildings by civil engineering or construction.

In particular, the present invention relates to a heterogeneous composite reinforcement for artificial structures having excellent rigidity by different materials.

In general, artificial structures such as bridges and buildings form frames using materials such as rebar and beams. These artificial structures are used in recent years to form a frame using rod-shaped FRP reinforcing bars (Fiber Reinforced Polymer) having high tensile strength, light weight, and corrosion resistance together with reinforcing bars or beams.

Such FRP reinforcing bars are manufactured by containing a fibrous material such as carbon fiber, glass fiber or aramid fiber in a base material mainly composed of a thermosetting resin. Thus, FRP rebar has high tensile strength, light weight and corrosion resistance. Of course, FRP rebar is also nonmagnetic due to its material properties.

FRP rebars as described above are used not only to compensate for the corrosiveness of the rebar but also to reinforce the tensile strength of the rebar. FRP rebar is also used in the construction of structures that require nonmagnetic materials, such as the tracks of maglev trains, due to their nonmagnetic properties.

These general FRP reinforcing bars are roughly classified into carbon fiber FRP reinforcing bars, glass fiber FRP reinforcing bars, or aramid fiber FRP reinforcing bars, and the most widely used among them are glass fiber FRP reinforcing bars. The reason why glass fiber FRP reinforcement is widely used is that glass fiber is the cheapest among three kinds of fibers (glass, carbon, aramid).

However, the glass fiber FRP reinforcing bar is cheaper, but the elastic modulus corresponds to about 1/10 of the steel (for example, reinforcing bar) or carbon fiber FRP reinforcing bar, there is a problem that the strength is weak compared to steel or carbon fiber FRP reinforcing bar. (Note: The modulus of elasticity is about 200,000 MPa for rebar, but 20,000 MPa for glass fiber FRP rebar)

In addition, the glass fiber FRP reinforcement has a problem that not only cracks due to the low elastic modulus but also the width of the cracks is very large, in addition, there is a problem that large sag occurs. In other words, the glass fiber FRP reinforcement is difficult to use as a general structural member.

Therefore, the glass fiber FRP reinforcement has caused a problem of changing the structural system due to its low rigidity (e.g., adopting a cable to prevent the deflection at the center of the span in the girder bridge).

Of course, it is also possible to design the structure using carbon fiber FRP reinforcement having superior rigidity than glass fiber FRP reinforcement. However, carbon fiber FRP reinforcement is limited because carbon fiber is too expensive.

On the other hand, there is a problem that the general FRP rebar as described above is strong in tension but weak in compression. Therefore, the FRP rebar is used only as a tension material, but not as a compression material.

The present invention was created to solve the conventional problems as described above, by permanently joining straight members made of heterogeneous materials having different rigidity due to the material properties of each other to form a single body, the rigidity of the dissimilar materials The purpose is to provide heterogeneous reinforcing reinforcement for artificial structures that can reinforce its stiffness strongly.
In particular, the straight members are arranged in the circumferential direction at the center and the outside of the center to form a bundle unitary by the binding member, and furthermore, the straight members arranged at the outside of the center are made of carbon fiber and glass fiber, thereby The purpose is to provide a heterogeneous reinforcement for artificial structures to reinforce the rigidity of the straight members arranged in the center in the cross-arrayed state.
Another object is to provide a heterogeneous reinforcement for artificial structures in which a straight member arranged at the center is made of any one of carbon fiber, metal, glass fiber or aramid fiber.
Another object of the present invention is to provide a heterogeneous composite reinforcement for an artificial structure having a cylindrical or flat member which is coupled to an outer side of a straight member arranged outside the center to strengthen the rigidity of these members.

Heterostructure composite reinforcement for artificial structures according to the present invention for achieving the above object, in the reinforcement to be applied to the artificial structure to reinforce the rigidity of the artificial structure, formed in a straight line to form a rod, by the self rigidity A core member for maintaining a straight line; A reinforcing member made of a different material from the core member and coupled to the outer peripheral surface of the core member in the same circumferential direction to form a straight line with the core member, and reinforcing the rigidity of the core member while forming a single body with the core member; And a reinforcing member and a core member, wherein at least one of the reinforcing members and the core member is made of a fiber reinforcing polymer, wherein the reinforcing member is arranged on an outer circumferential surface of the core member and comprises a carbon fiber reinforcing polymer having a main component; A glass fiber reinforcement polymer, which is arranged on the outer circumferential surface of the core member with the carbon fiber reinforcement polymer as the center, and comprises glass fiber as a main component; And a binder for binding the glass fiber reinforcement polymer and the carbon fiber reinforcement polymer together with the core member into a single unit in a bundle form, wherein the carbon fiber reinforcement polymer and the glass fiber reinforcement polymer are formed around the core member. Characterized in that arranged in the cross state along the circumferential direction.
The core member may be composed of any one of a carbon fiber reinforcing polymer having a carbon fiber as a main component, a reinforcing bar having compressive and tensile strength, a glass fiber reinforcing polymer having a glass fiber as a main component, or an aramid fiber reinforcing polymer having aramid fiber as a main component. .
The present invention may further include a rigid reinforcing member coupled to the outside of the reinforcing member to strengthen the rigidity of the reinforcing member.
The rigid reinforcing member, for example, the fitting pipe is integrally fixed to the reinforcing member in a state fitted to the outside of the reinforcing member; may be configured as a tape-like fiber reinforced polymer sheet attached to the outside of the reinforcing member It can consist of;

The heterogeneous composite reinforcement for artificial structures according to the present invention as described above, the reinforcing member consisting of a carbon fiber reinforcement polymer and a glass fiber reinforcement polymer is permanently coupled to the outer peripheral surface of the core member by a binder bundle together with the core member Since it forms a unitary form, the strength characteristics of each material are combined to provide strong rigidity.
In particular, the carbon fiber reinforcement polymer and glass fiber reinforcement polymer of the reinforcing member cross-arranged to complement each other's stiffness, thereby increasing the stiffness, and has the effect of further increasing the stiffness by the hardened binder. .
In addition, when the core member is composed of any one of carbon fiber reinforcement polymer, glass fiber reinforcement polymer or aramid fiber reinforcement polymer, since the core member and the reinforcing member can be composed only of fiber reinforcement polymers, the corrosion phenomenon can be prevented, and the core member When the reinforcing bar is configured to reinforce the elastic modulus and stiffness, not only can support more loads, but also prevent the occurrence of cracking due to the low modulus of elasticity of the fiber reinforcement polymer.
In addition, when the rigid reinforcing member consisting of a fitting pipe or fiber reinforced polymer sheet is installed on the outside of the reinforcing member, the rigid reinforcing member supports the outer circumferential surface of the reinforcing member, thereby further reinforcing the rigidity of the reinforcing member.

Hereinafter, referring to the heterogeneous reinforcement composite for artificial structure according to the present invention with reference to the accompanying drawings as follows, Figure 1 is a perspective view of the heterogeneous reinforcement for artificial structure according to an embodiment of the present invention.

As shown, the heterostructure reinforcement for artificial structures according to an embodiment of the present invention is formed long in a straight line as shown. This heterogeneous composite reinforcement is composed of a core member (C) provided in the center, and a reinforcing member (R) provided on the outside of the core member (C) as shown.

The core member C is vertically embedded in the interior of the reinforcing member R as shown in the enlarged view "A" in the drawing, and is formed in a straight line to substantially form a rod. This core member (C) maintains a straight line by its rigidity.

The reinforcing member R is coupled to the outer circumferential surface of the core member C in the same circumferential direction as shown in the enlarged view "A" to form a substantially straight line with the core member (C). The reinforcing member (R) substantially expands the cross-sectional area of the core member (C) while forming a single body with the core member (C) as shown in an enlarged view. Therefore, the core member C is reinforced with rigidity by the reinforcing member R. This reinforcing member (R) is made of a material different from the core member (C).

Here, at least one of the above-described core member (C) and the reinforcing member (R) is formed of a fiber reinforced polymer. That is, at least one of the core member C and the reinforcing member R is made of FRP containing fibers.

On the other hand, the enlarged view "A" is composed of the core member (C) as the main component of the carbon fiber and the expensive carbon fiber reinforcement polymer (12) having excellent elastic modulus, and the reinforcing member (R) as the main component It is shown that the low-cost glass fiber reinforced polymer 16 having an excellent modulus of elasticity. That is, the core member C is composed of expensive carbon fiber FRP, and the reinforcing member R is composed of low cost glass fiber FRP.

In addition, the enlarged view "B" is composed of the core member (C) made of steel as a main component of low-cost rebar 14 having excellent compression and tensile strength, and the reinforcing member (R) is glass fiber reinforced polymer (16) It shows what was comprised by fiber FRP. In other words, the core member (C) is composed of a low-cost rebar 14, the reinforcing member (R) is composed of glass fiber FRP more expensive than the reinforcing bar (14).

On the other hand, when the core member (C) and the reinforcing member (R) as described above and expensive and low cost can be configured inexpensive heterogeneous composite reinforcement according to an embodiment of the present invention.

Here, as described above, the glass fiber reinforcement polymer 16 bonded to the outer circumferential surface of the core member C made of the carbon fiber reinforcement polymer 12 or the reinforcing bars 14 is the core member C by a mold not shown. Combined in a single body. At this time, the glass fiber reinforcement polymer 16 is injected into the mold in the liquid state and then hardened on the outer circumferential surface of the core member (C) and is bonded to the outer circumferential surface of the core member (C) in the same manner. Thus, the glass fiber reinforced polymer 16 forms a single body with the core member (C). That is, the glass fiber reinforced polymer 16 forms a single body with the core member C by insert injection.

Core member (C) is substantially expanded in cross-sectional area as shown enlarged as the glass fiber reinforcement polymer 16 is bonded to the outer peripheral surface by the above-described method. Therefore, the core member (C) is strengthened as the glass fiber reinforcement polymer (16) forms the same and firmly supports the outer peripheral surface. Of course, since the core member (C) is reinforced by the glass fiber reinforced polymer 16, the overall rigidity of the heterogeneous composite reinforcement according to the embodiment of the present invention is enhanced.

On the other hand, the heterogeneous composite reinforcement shown in the above-mentioned enlarged view "A" is composed of a glass fiber reinforced polymer 16 of the core member (C), and the reinforcing member (R) of the carbon fiber reinforced polymer (12), as described above It can also be configured as. And, the heterogeneous reinforcement composite reinforcement shown in the enlarged view "B" is composed of a carbon fiber reinforcement polymer (12) unlike the above-mentioned reinforcing member (R) coupled to the outer peripheral surface of the core member (C) consisting of reinforcing bars 14 It may be.

On the other hand, the heterogeneous reinforcing reinforcement shown in the enlarged view "A" and "B" is elastic because the carbon fiber reinforcement polymer 12 or reinforcing bar 14 is embedded in the center, the glass fiber reinforcement polymer 16 is coupled to the outside The coefficient is greatly increased. Therefore, it can support more load when used in artificial structures. In particular, the glass fiber reinforcement polymer 16 is reinforced with an elastic modulus by the carbon fiber reinforcement polymer 12 or the reinforcing bars 14, and at the same time, the rigidity is strengthened, as well as preventing the occurrence of cracks due to the rigid reinforcement The width of can be prevented from being formed large.

On the other hand, the heterogeneous reinforcement reinforcement is shown in the above-described enlarged view "B" can be used as a compression material because of the reinforcing bar 14 in the center because of the characteristics of the reinforcing bar (14). In addition, since the reinforcing bar 14 is wrapped by the glass fiber reinforced polymer 16, the corrosion resistance of the reinforcing bar 14 is improved.

The heterogeneous composite reinforcement according to the embodiment of the present invention as described above may be coupled to the outside of the reinforcing member (R) to further strengthen the rigidity of the reinforcing member (R); That is, the glass fiber reinforced polymer 16 of the aforementioned reinforcing member (R) may be provided with a rigid reinforcing member on the outside. Of course, the glass fiber reinforced polymer 16 is strengthened by the rigid reinforcing member.

Here, the above-mentioned rigid reinforcing member, for example, as the fitting tube 24 which is integrally fixed to the reinforcing member (R) in a state fitted to the outside of the reinforcing member (R) as shown in the enlarged view "B" in the drawing. Can be configured. At this time, the fitting pipe 26 is preferably composed of a plastic coating or steel pipe. Therefore, the reinforcing member R is strengthened as the fitting pipe 24 supports the outer circumferential surface.

Alternatively, the rigid reinforcing member may be constituted by, for example, a tape-reinforced polymer sheet 26 attached to the outside of the reinforcing member R as shown in the enlarged view "C" in the drawing. At this time, the fiber reinforced polymer sheet 26 is integrally attached to the outside of the reinforcing member (R) by the adhesive. Therefore, the reinforcing member R is reinforced with rigidity as the fiber reinforced polymer sheet 26 supports the outer circumferential surface.

In conclusion, the heterogeneous composite reinforcing reinforcement according to an embodiment of the present invention has a core member (C) and a reinforcing member (R) made of dissimilar materials to expand the cross-sectional area and at the same time have disadvantages of each other (e.g., elastic modulus or compressive force or tensile force, manufacturing cost, etc.). ), The stiffness of each other doubles and the stiffness is greatly strengthened. Therefore, the dissimilar composite reinforcement reinforcement according to the embodiment of the present invention can support a load having many beams.

On the other hand, Figure 2 is attached is a perspective view of a heterogeneous composite reinforcement for artificial structures according to another embodiment of the present invention, as shown is a heterogeneous composite reinforcement for artificial structures according to another embodiment is a plurality of fiber reinforcement polymer (14, 16) ) That is, the heterogeneous reinforcing reinforcement according to another embodiment is composed of bundles of fiber reinforcing polymers (14, 16).

The heterogeneous reinforcing reinforcement according to another embodiment of the present invention has a core member C made of glass fiber reinforcement polymer 16 disposed in the center thereof, as shown in an enlarged view "D" in the drawing, and the outer peripheral surface of the core member C. A reinforcing member (R) made of carbon and glass fiber reinforcement polymers 12 and 16 is disposed along the circumferential direction. At this time, the carbon and glass fiber reinforcement polymers 12 and 16 of the reinforcing member R are arranged in a cross state along the circumferential direction with respect to the core member C made of the glass fiber reinforcement polymer 16 as shown in an enlarged view. do. This heterogeneous composite muscle has a corrosion resistance because the core member (C) and the reinforcing member (R) is made of a glass fiber reinforced polymer (16) and a carbon fiber reinforced polymer (12).

This reinforcing member (R) can be bound in the same body by the binder 22 as shown in the enlarged view "D". At this time, the binder 22 is preferably a thermosetting resin that is molded as shown while being cured from the liquid phase to the solid phase by a mold not shown. Such a binder 22 not only permanently binds the reinforcing member R and the core member C while being hardened, but also supports the reinforcing member R while forming a solid phase to strengthen the rigidity of the reinforcing member R.

In addition, the reinforcing member (R) may be provided with a rigid reinforcing member on the outer circumferential surface to strengthen the rigidity. This rigid reinforcing member may be composed of, for example, a fitting tube 24 such as a plastic coating or steel pipe on the outer circumferential surface of the binder 22 as shown in the enlarged view "D". Alternatively, the rigid reinforcing member may be composed of, for example, a fiber reinforced polymer sheet 26 taped to the outer circumferential surface of the reinforcing member R as shown in the enlarged view "E". This rigid reinforcing member is coupled to the outside of the reinforcing member (R) to reinforce the rigidity of the reinforcing member (R).

Here, the above-mentioned binder 22 can be omitted when the rigid reinforcing member is composed of a steel pipe as described above. That is, the binder 22 may be omitted when the outer circumferential surface of the reinforcing member R is wrapped by the steel pipe. This is because the steel pipe very firmly supports the reinforcing member R by the material property. However, the binder 22 is preferably provided with a steel pipe as shown to enlarge so as to double the rigidity of the reinforcing member (R). As such, when the binder 22 and the steel pipe are provided together, the heterogeneous reinforcing reinforcement according to another embodiment of the present invention as shown in the drawing is greatly improved in tensile and compressive strength.

On the other hand, the glass and carbon fiber reinforcement polymer (16, 12) of the core member (C) and the reinforcing member (R) described above is preferably twisted so as to improve the bonding force between each other. That is, the core member (C) and the reinforcing member (R) is preferably formed twisted in a twisted form. As such, when the twist is formed, the heterogeneous reinforcing reinforcement according to another embodiment of the present invention not only improves the bonding force between the members but also strengthens the tensile strength more strongly.

On the other hand, the core member (C) described above is carbon fiber reinforced polymer (12) or aramid fiber reinforced polymer instead of glass fiber reinforced polymer (16) to ensure corrosion resistance while ensuring a stronger rigidity than glass fiber reinforced polymer (16) It can be configured as. Alternatively, the core member C may be applied to the reinforcing bar 14 described above instead of the glass fiber reinforced polymer 16. That is, the heterogeneous reinforcing reinforcing bars shown in FIG. 2 may be disposed with reinforcing bars 14 in the center, and carbon and glass fiber reinforcing polymers 12 and 16 may be arranged in a crossing state around the reinforcing bars 14. In this configuration, the heterogeneous reinforcement heterogeneous reinforcement according to another embodiment of the present invention is greatly enhanced in compressive strength. Of course, the reinforcement 14 is strengthened tensile strength due to the carbon and glass fiber reinforced polymers (12, 16). Therefore, the heterogeneous reinforcing reinforcing bars configured as described above can be used for both compression and tension. And crack generation of the glass fiber reinforced polymers 12 and 16.

On the other hand, the mixing ratio, that is, the quantity or thickness of the carbon and glass fiber reinforced polymers 12 and 16 described above, is determined by the set elastic modulus. That is, when the elastic modulus is adjusted upward, the thickness or quantity of carbon or glass fiber reinforced polymers 12 and 16 may be increased. For example, in order to improve the modulus of elasticity, the carbon fiber reinforcement polymer 12 or the reinforcing bars 14 used as the core member C may be formed to be very thick or may be composed of multiple bundles.

In addition, the core member (C) and the reinforcing member (R) described above may be composed of an aramid fiber reinforced polymer having at least one of the high strength. Since the aramid fiber reinforced polymer has a high strength, it is preferable to be used as a substitute for the carbon fiber reinforced polymer (12). Since such aramid fiber reinforcing polymer is easily understood by those skilled in the art, a detailed description thereof will be omitted.

In addition, the aforementioned reinforcing member (R) may be formed ribs, protrusions or sand-mounted irregularities on the surface of the outer peripheral surface. Thus, when configuring the outer peripheral surface of the reinforcing member (R) can improve the adhesion of the reinforcing member (R) to the concrete.

Since the above embodiments are merely illustrative of preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

1 is a perspective view of a heterogeneous composite reinforcement for an artificial structure according to an embodiment of the present invention; And

Figure 2 is a perspective view of a heterogeneous composite reinforcement for artificial structures according to another embodiment of the present invention.

<Description of Major Symbols in Drawing>

12: carbon fiber reinforced polymer

14: rebar

16: glass fiber reinforced polymer

22: binder

24: fitting tube

26: fiber reinforced polymer sheet

C: Core member

R: Reinforcing member

Claims (18)

In the reinforcing bar is applied to the artificial structure to reinforce the rigidity of the artificial structure, Core member (C) is formed long in a straight line in the form of a rod, maintaining a straight line by its own rigidity; And It is made of a different material from the core member (C), is coupled to the same body along the circumferential direction to the outer peripheral surface of the core member (C) to form a straight line with the core member (C), and at the same time the core member (C) and a single body It includes; reinforcing member (R) for reinforcing the rigidity of the core member (C); At least one of the reinforcing member (R) and the core member (C) is made of a fiber reinforced polymer, The reinforcing member (R), A carbon fiber reinforcing polymer (12) arranged on the outer circumferential surface of the core member (C), the carbon fiber as a main component; A glass fiber reinforcement polymer (16) arranged along the core member (C) along with the carbon fiber reinforcement polymer (12) and arranged on the outer circumferential surface of the core member (C); And And a binder 22 for binding the glass fiber reinforcement polymer 16 and the carbon fiber reinforcement polymer 12 together with the core member C into a single unit in a bundle form. The carbon fiber reinforcement polymer 12 and the glass fiber reinforcement polymer 16 is a heterogeneous composite composite for the artificial structure, characterized in that arranged in a cross state along the circumferential direction of the core member (C) around the core member (C) Rebar. The method of claim 1, The core member (C) is a heterogeneous composite reinforcement for an artificial structure, characterized in that the carbon fiber reinforcement polymer (12) as the main component. The method of claim 1, The core member (C) is a reinforcing bar composite reinforcement for artificial structure, characterized in that; The method of claim 1, The core member (C) is a glass fiber reinforcement polymer (16) mainly composed of glass fibers; heterogeneous composite reinforcement for artificial structures, characterized in that the. The method of claim 1, Said core member (C) is an aramid fiber reinforcement polymer having aramid fibers as a main component; heterogeneous composite reinforcement for artificial structures, characterized in that the. delete delete delete delete delete delete delete delete The method according to any one of claims 1 to 5, Heterogeneous composite reinforcement for artificial structures further comprising; a rigid reinforcing member coupled to the outside of the reinforcing member (R) to strengthen the rigidity of the reinforcing member (R). The method of claim 14, wherein the rigid reinforcing member, Heterogeneous composite composite reinforcement for artificial structure, characterized in that; fitting tube (24) integrally fixed to the reinforcing member (R) in a state fitted to the outside of the reinforcing member (R). The method of claim 14, wherein the rigid reinforcing member, Heterogeneous composite reinforcement for artificial structures, characterized in that the; reinforcing member (R) tape-shaped fiber reinforced polymer sheet (26) attached to the outside. delete delete

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