KR101328045B1 - Reinforced concrete composite columns using precast high-performance fiber-reinforced cement - Google Patents

Abstract

The reinforced concrete composite column method using the precast high-performance fiber cement composite is located in the weak part of the plastic hinge generation section, which is a risk section of the column when subjected to lateral load such as the earthquake load by using the precast block using the high-performance fiber cement composite. Reinforce the reinforcing bars, install the formwork, and install the post-casting concrete to connect integrally. According to the reinforced concrete composite column method using the precast high-performance fiber cement composite structure, the construction cost is reduced by constructing the high-toughness fiber cement composite which is relatively expensive compared to the general concrete at the optimal position, which is the risk section of column bending. At the same time, it has a high toughness bending performance that can cope with external forces such as seismic force, and has the advantage of shortening the air and increasing work efficiency by constructing using a precast block manufactured in advance.

Description

Reinforced concrete composite column method using precast high-performance fiber cement composite {REINFORCED CONCRETE COMPOSITE COLUMNS USING PRECAST HIGH-PERFORMANCE FIBER-REINFORCED CEMENT}

The present invention relates to a reinforced concrete composite column method using a precast high-performance fiber cement composite, more specifically, to prevent bending cracks and fractures by using high-performance precast fiber cement at the end face of bending failure of construction civil engineering columns and piers. The present invention relates to a composite column method for improving flexural strength and deformation capacity.

Recently, tsunamis caused by large earthquakes in northeastern Japan have caused the greatest damage ever. Accordingly, interest in earthquakes in Korea is increasing, and various methods of seismic measures of domestic civil engineering structures are being discussed.

In order to improve the seismic measures for building civil engineering structures, the stiffness of major bearing members should be improved. To improve such stiffness, not only the strength of axial pressure, bending and shear strength, but also the flexural ductility and shear stiffness The same deformability must be improved together.

In the case of reinforced concrete structures, as is well known, concrete has high compressive strength and thus is strong in compressive force, but tensile strength is only about 8 to 15% of compressive strength, and thus has a very weak problem in tensile strength. Therefore, this problem is solved by reinforcing steel bars in the concrete.

Fig. 1A shows the bending moment diagram for the pillar which is the main structural member of the building frame structure. As shown, in the case of the pillar used in the building shown in (A) of Figure 1a it can be seen that the bending moment due to the 휭 load is concentrated on the upper and lower portions of the pillar, as shown in (B) of Figure 1a In the case of the bridge piers used in the bridge, it can be seen that the bending moment is concentrated in the lower part of the column.

Therefore, when an earthquake occurs and an external force is applied by horizontal seismic waves, bending cracks and breakages are concentrated at the top and bottom of the column having a large bending moment or at the bottom of the piers, resulting in plastic hinge, thereby reaching end local bending failure. As such, when the stress is concentrated and destroyed in the pillar, as shown in FIG. 1B (A), the pillar is concentrated at the lower end of the pillar near the point where the pillar and the base are connected.

However, conventional conventional reinforced concrete structures cannot overcome the end local bending failure due to the bending moment concentrated at the bottom of the column due to the transverse load. In particular, in the case of a general concrete structure, if a certain stress is exceeded, the concrete is crushed to bear no stress at all, so the damage caused to the entire building.

In order to overcome this problem, there are suggested reinforcing methods such as increasing the reinforced concrete cross section, reinforcing steel sheet, fiber, etc., or reinforcing structures due to mortar spraying and prestressed steel wire. There is a method of applying high toughness concrete having tensile strength.

High toughness concrete has a tensile strain of 100 to 1000 times that of ordinary concrete by incorporating fibers such as PVA or PP to reinforce the disadvantages of concrete with very low flexural or tensile strength. It means concrete having toughness.

High toughness concrete, as shown on the right side of Figure 1b, when the load is applied to the column in the horizontal direction to induce the micro-cracking behavior so that the bending cracks and fractures are not concentrated in the bending danger section just above the junction of the pillar and the foundation It is configured to improve the resistance to warping in the whole. That is, the toughness of the high toughness concrete itself improves the horizontal strength and horizontal deformation capacity of the column in the horizontal load.

However, there is a problem in applying the high toughness concrete according to the prior art as described above.

First, in order to increase the toughness of the structural member, it is possible to use a high toughness fiber cement composite over the entire height of the pillar, which is the main structural member, but since the manufacturing cost of the high toughness fiber cement composite is very expensive, the high toughness fiber cement composite is used throughout the column. To use is inefficient and there is a problem that raises the construction cost.

In addition, when the high toughness fiber cement composite is placed on-site, general concrete and the high toughness fiber cement composite must be separately installed, and the high toughness fiber cement composite in the field is complicated in construction procedure, and there is a problem of lowering the construction efficiency. .

The present invention is to solve such a conventional problem, it is an object of the present invention to provide a method capable of efficiently applying a high toughness fiber cement composite to a column.

Another object of the present invention is to provide a high toughness fiber cement composite to the precast concrete construction.

According to a feature of the present invention for achieving the above object, the reinforced concrete composite column method using the precast high-performance fiber cement composite of the present invention applies a precast block composed of a high-performance fiber cement composite to a part of the pillar, In a construction method of manufacturing a column by post-casting concrete to a precast block, the installation position of the precast block preferably corresponds to a bending risk cross section position where a bending moment is concentrated.

It is preferable that the installation position of the precast block of this invention is the junction point of a pillar and a foundation concrete.

The height of the precast block of the present invention is preferably at least the effective depth of the column cross section or the height of the plastic hinge of the column.

The minimum height (Hpc) of the precast block of the present invention is at least [Equation 1]

It is preferable that it is more than the value computed by.

The present invention provides a block manufacturing step of manufacturing a precast block using a fiber cement composite; A block construction step of installing the precast block on the ground of a construction site; A reinforcing bar construction step for reinforcing bar in the precast block; A formwork installation step of installing formwork on the precast block and the constructed rebar; Concrete placing step of pouring concrete to the formwork; And after curing the concrete, it is preferable to include a formwork demoulding step of demolding the formwork.

The block construction step of the present invention preferably includes a prestress application step of applying prestress to the precast block.

Reinforcing bar construction of the present invention preferably comprises a step of connecting the fixed coupler to the precast block to apply a prestress, and connecting the fixed coupler with the main reinforcing bar.

Block manufacturing step of the present invention preferably comprises the step of forming a cast iron reinforcing ball is inserted into the precast block.

The reinforcing bar construction step of the present invention preferably includes a step of connecting the connection coupler to the main reinforcing bar inserted into the precast block and connecting with the upper main reinforcing bar.

Block manufacturing step of the present invention preferably comprises a cast iron reinforcing step of integrally constructing by inserting the cast iron in the precast block.

The block manufacturing step of the present invention preferably includes a rib forming step of forming a rib in the precast block.

Formwork installation step of the present invention preferably comprises a spacer mounting step for forming a space for injecting mortar between the formwork and the base concrete.

The block construction step of the present invention preferably includes a step of forming a joint recessed in the base concrete, and seating the precast block on the joint.

Formwork installation step of the present invention preferably comprises the step of pouring mortar between the precast block and the base concrete.

Another embodiment of the reinforced concrete composite column using the precast high performance fiber cement composite of the present invention is a precast block composed of fiber cement composite and having an effective height having flexural strength and high toughness flexural deformation capacity against a lateral load acting on a column. It is preferable to prepare the column by installing at the junction of the pillar and the foundation concrete, fixing the precast block with the foundation concrete by a connecting connector, and post-installing the concrete to the precast block.

The minimum height of the precast block of the present invention is preferably at least equal to the effective depth of the column cross section or the height of the plastic hinge of the column.

In the present invention, after fixing the precast block to the foundation concrete, it is preferable to apply prestress to the precast block.

The connection connector of the present invention preferably includes a first connector connected to the base concrete, and a second connector provided on the precast block and connected to the first connector.

The first connector of the present invention includes a bolt connection part inserted into the foundation concrete and a bolt part connected to the bolt connection part, and the second connector is provided in the precast block, and a nut part connected to the first connector. And a support portion for fixing the nut portion to the precast block.

Precast block using the fiber cement composite of the present invention is preferably by the above method.

Precast block using the fiber cement composite of the present invention is formed in a polygonal or circular shape, the inner center of the hollow penetrating up and down is formed, the main reinforcement ball is formed in the periphery of the hollow or the main reinforcement is arranged inside the hollow periphery It is preferable that a part of protrudes.

The fiber cement composite of the present invention preferably includes synthetic fibers or steel fibers such as PVA (Polyvinyl alcohol) or PP (Polypropyline) fibers.

It is preferable to include the upper core part which protrudes upward or the lower core part which protrude below at the periphery of the hollow of this invention.

Preferably, the upper core portion or the lower core portion of the present invention includes a friction portion.

The fiber cement composite of the present invention is preferably UHPC (Ultra High Performance Concrete), FRC (Steel Fiber Reinforced Concrete), HPFRC (High Performance Fiber Reinforced Cementitious Composites), or ECC (Engineered Cementitious Composites).

According to the reinforced concrete composite column method using the precast high performance fiber cement composite according to the present invention, the construction cost is reduced by constructing the high performance fiber cement composite which is relatively expensive compared to general concrete at an optimal position, and at the same time, such as seismic force It has the advantage of shortening the air and increasing the work efficiency by constructing using a precast block that has a pre-fabricated block, and has increased bending strength against high external force and high toughness deformation ability.

Figure 1a is a conceptual diagram showing the stress distribution by the external force in the general column.
Figure 1b is a schematic cross-sectional view showing the crack distribution in the column using a common column and high performance fiber cement composite.
Figure 2a is a view showing a precast block is not reinforcement cast iron used in reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 2b is a view showing a precast block reinforcement cast iron used in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 3a is a view showing a precast block with ribs formed without reinforcing cast iron used in reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 3b is a view showing a precast block in which the cast iron is used in the reinforced concrete composite pillar method using the precast high-performance fiber cement composite according to the present invention is ribbed.
Figure 4 is a cross-sectional view showing the basic concrete and precast block of the reinforced concrete composite column method using a precast high performance fiber cement composite according to the present invention.
Figure 5 is a cross-sectional view showing the step of connecting the base concrete and the precast block in the reinforced concrete composite pillar method using a precast high-performance fiber cement composite according to the present invention.
Figure 6a is a cross-sectional view showing the step of connecting the precast block and the reinforcing bar in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 6b is a cross-sectional view showing the step of connecting the precast block and the reinforcing bar when the prestress is applied in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 7a is a cross-sectional view showing the process of installing the formwork in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 7b is a cross-sectional view showing a process of installing the formwork when pre-stressed in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
8 is a view showing a state in which the formwork is installed in the reinforced concrete composite pillar method using a precast high-performance fiber cement composite according to the present invention.
9 is a cross-sectional view showing a process of pouring mortar in a reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
10 is a cross-sectional view showing a process of pouring concrete in a reinforced concrete composite pillar method using a precast high-performance fiber cement composite according to the present invention.
11 is a cross-sectional view showing a state in which the formwork is removed in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
12 is a cross-sectional view showing a process of forming a foundation concrete to which the precast block is reinforced with reinforcement in the reinforced concrete composite pillar method using a precast high-performance fiber cement composite according to the present invention.
Figure 13 is a cross-sectional view showing a process of connecting the pre-cast reinforcement cast steel reinforcement in the reinforced concrete composite pillar method using a precast high-performance fiber cement composite according to the present invention to the base concrete.
Figure 14a is a cross-sectional view showing a process of connecting the upper cast iron with the cast steel of the precast block in the reinforced concrete composite column method using a precast high-performance fiber cement composite according to the present invention.
Figure 14b is a cross-sectional view showing a process of applying the prestress in the reinforced concrete composite column method using the precast high-performance fiber cement composite according to the present invention and connecting the upper cast bar with the cast bar of the precast block.
15 is a partial perspective view showing another embodiment of the reinforced concrete composite pillar method using a precast high performance fiber cement composite according to the present invention.
16 is a cross-sectional view of FIG. 15.
17A to 17C are perspective views illustrating various embodiments of a precast block of a reinforced concrete composite pillar method using a precast high performance fiber cement composite according to the present invention.
FIG. 18 is a view for explaining the plastic hinge height of the column calculated in the nonlinear bending analysis model of the cantilever column used to obtain the minimum height of the precast block of the present invention. FIG.

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

2 to 18 show a preferred embodiment of the reinforced concrete composite pillar method using a precast high performance fiber cement composite according to the present invention.

2A to 3B show precast blocks 10 and 20 for use in the process of the present invention. The precast blocks 10 and 20 are composed of a high performance fiber cement composite.

The high performance fiber cement composite means that the fiber cement composite has a higher tensile strength than ordinary concrete by incorporating synthetic fibers or steel fibers such as polyvinyl alcohol (PVA) or polypropyline (PP), and deforms and strengthens after cracking.

For example, the high performance fiber cement applied to the present invention may be composed of Ultra High Performance Concrete (UHPC), Steel Fiber Reinforced Concrete (SFRC), High Performance Fiber Reinforced Cementitious Composites (HPFRC) or Engineered Cementitious Composites (ECC). .

In addition, the precast blocks 10 and 20 are preferably installed at the lower portion of the pillar, that is, the point where the pillar and the ground contact.

The point where the pillar and the base are in contact is the portion where the local bending failure occurs at the end when the horizontal force is applied, the stress is concentrated by the large bending moment, and the plastic hinge is generated. Therefore, in the method of the present invention, the precast blocks 10 and 20 are installed at the intersections of the pillars and the foundation where the stress is concentrated.

Similarly, since the point where the column and the upper slab contact each other is a point where a large bending moment with respect to the horizontal force is generated, the precast blocks 10 and 20 may be installed at the junction point where the maneuver and the upper slab contact each other.

More specifically, the installation position of the precast block corresponds to the position where the stress is concentrated in the pillar, and the minimum height of the precast block is a high toughness bending ability ability against the bending moment generated by the transverse load It is preferable to correspond to more than the effective height of the columnar cross section that may have.

The precast blocks 10 and 20 are formed in a substantially rectangular shape, and are precast concrete blocks as preformed products in a manufacturing plant. In addition, the hollow 11 may be formed in the precast blocks 10 and 20 so that the post-cast concrete may be poured into the hollow 11 later.

In addition, the shapes of the precast blocks 10 and 20 are not limited to rectangles, and may be configured in various forms such as cylinders.

The precast blocks 10 and 20 may be formed in two types. The precast block shown in FIG. 2A is a first type precast block 10, which is a precast concrete block manufactured by only shearing reinforcement in the block. The first type precast block 10 is formed with a plurality of cast iron balls 13 penetrating the upper and lower surfaces of the block in the precast manufacturing process. Then, at a construction site, the main reinforcing bars are placed in the main reinforcing bar 13 and are integrally constructed.

The precast block shown in FIG. 2B is a second type precast block 20, which is a block fabricated by shearing both the reinforcing bars and the main bars. A part 15 of the main reinforcing bars arranged in the second type precast block 20 protrudes to the upper surface of the block 20 and is connected to other reinforcing bars at the construction site.

The precast block shown in FIGS. 3A and 3B shows a block in which ribs 21 are formed in the blocks 10 and 20. The rib 21 is to increase the bonding force with the concrete post-installed on the precast blocks (10, 20).

The precast blocks 10 and 20 have a block minimum height Hpc of a high performance fiber cement composite to have a substantial high toughness effect throughout the column. That is, the block minimum height (Hpc) means a substantial height that can exhibit the maximum bending toughness effect for the bending moment generated by the lateral load when applying the high performance fiber cement composite to a portion of the column.

As shown in FIG. 18, the block minimum height Hpc is a plastic hinge generated in the column support portion where the nonlinear bending curvature increases rapidly due to bending cracking and fracture as the load increases in the horizontally loaded reinforced concrete cantilever column. As a representation of the height, the theoretical nonlinear bending model of the reinforced concrete cantilever column can be used to predict the generated plastic hinge height L _p .

The minimum block height (Hpc) is used to be greater than or equal to the larger value between the plastic hinge height (L) and the effective depth (D) of the cross section of the column calculated from the nonlinear bending analysis model of the cantilever column. Equation 1

High performance fiber cement at the point where the bending crack and the bending fracture occurs at the bending danger section caused by the external force by satisfying the minimum height (Hpc) of the high performance fiber cement composite precast block calculated using Equation 1 above. The precast block is made to be provided.

Hereinafter, a process of constructing a composite pillar using the precast block manufactured as described above will be described in detail.

First, the construction procedure of the first type precast block 10 will be described.

The foundation concrete construction step is performed to form the foundation concrete 30 on which the column is to be constructed. The foundation concrete 30 may be constructed in the form of general foundation concrete in which the pillar is installed, and the foundation concrete 30 has a joint recess recessed therein to increase bonding force with the first type precast block 10. (31) is constructed.

The joint part 31 is formed to correspond to the first type precast block 10, and the first type precast block 10 is seated on the joint part 31 to form a connection structure between the pillar and the base concrete. Stiffness can be improved.

The lower cast iron 33 extending upward to the foundation concrete 30 is arranged. In addition, the lower main reinforcing bar 33 is inserted into the main reinforcing bar hole 13 formed in the first type precast block 10 to perform a block connecting step.

In the block connecting step, a first type precast block 10 is connected to the lower main reinforcing bar 33, and a connecting coupler 41 or a fixed coupler 43 is connected to an upper surface of the first type precast block 10. Connect.

The connecting coupler 41 is used to connect the upper main reinforcing bar 35 to the lower main reinforcing bar 33. In addition, the fixing coupler 43 is like a wedge, and is used to fix the lower main reinforcing bar 33 to the first type precast block 10 to introduce prestress.

In FIG. 6A, a state in which a general upper reinforcing bar 35 is connected to the lower main reinforcing bar 33 is illustrated. As shown in the drawing, the end of the lower main reinforcing bar 33 protruding to the upper surface of the first type precast block 10 and the one end of the upper main reinforcing bar 35 are connected using the connection coupler 41.

6B shows a state in which the upper main reinforcing bar 35 is connected to the lower main reinforcing bar 33 when the prestress is introduced. As shown in the drawing, after tensioning by connecting the cable to the end of the lower main reinforcing bar 33 protruding to the upper surface of the first type precast block 10, by connecting and fixing the fixing coupler 43, such as a wedge, the first Prestress can be applied to the type precast block 10.

Prestress is applied to the first type precast block 10 and the fixed coupler 43 is connected to the lower main reinforcing bar 33 to fix the first precast block 10, and then the upper main reinforcing bar 35 is connected to the fixed coupler 43.

When the first type precast block 10 is connected to the base concrete 30 and the main reinforcing bars 33 and 35, the shear reinforcing bars 37 are connected to the main reinforcing bars 33 and 35. Then, the formwork is installed when the reinforcement of all the basic rebars is completed.

7A and 7B illustrate a process of installing formwork on the completed reinforcing bar structure. As shown in Figure 7a, a plurality of divided formwork 50 is sequentially stacked and connected from the bottom of the reinforcing structure.

The formwork 50 positioned at the lowermost part of the formwork 50 may be installed spaced apart from the ground by a separate spacer 51. That is, a constant space 53 is formed between the lower end of the bottom formwork 50 and the ground, so that mortar can be poured into the space 53. The mortar is to fill a gap between the first type precast block 10 and the foundation concrete 30.

In addition, a separate support 57 is connected to the formwork 50 to support the formwork 50 by the support 57.

FIG. 7B shows the process of installing the formwork 50 in the case of introducing prestress. Even when the prestress is introduced, the formwork 50 is installed in the same manner as a general formwork installation process.

When the formwork 50 is completed, the mortar 59 is injected into the space 53 at the bottom of the formwork 50 as shown in FIG. 9. The mortar 59 injected into the space 53 is for coupling the first type precast block 10 and the foundation ground 30 and the high performance fiber cement composite constituting the first type precast block 10. It is preferable that it consists of.

When the pouring of the mortar (59) is completed, after curing the mortar (59) for a certain period of time, as shown in FIG. 10, the concrete is poured into the form (50).

Concrete poured into the formwork 50 is poured into the hollow 11 of the first type precast block 10 and is cured integrally with the first type precast block 10. After the concrete is poured in the formwork 50 and cured for a predetermined period, the construction is completed by removing the formwork 50.

12 to 14B illustrate a process of constructing the second type precast block 20. The second type precast block 20 is a block in which the main reinforcing bar is further included, and a process of connecting the main reinforcing bar reinforced to the precast block 20 and the main reinforcing bar reinforcing the foundation concrete 30 are further included.

That is, as shown in FIG. 13, the main reinforcing bar protruding from the lower portion of the second type precast block 20 and the main reinforcing bar reinforcing the base concrete 30 are connected to each other by the connection coupler 41. Then, the main reinforcing bar and the column reinforcing bar protruding upward of the second type precast block 20 are connected to each other by the connection coupler 41.

When all the main reinforcing bars are reinforced to the second type precast block 20, shear reinforcing bars are installed, and after the formwork is installed as described above, the construction is completed by pouring concrete into the formwork.

Even when prestress is applied to the second type precast block 20, as described above, the second type precast block 20 is fixed to the foundation concrete 30, and then the cable is used. Prestress can be applied by tensioning the main reinforcing bar of the type 2 precast block 20 and fixing by the fixed coupler 43.

15 and 16 illustrate a process in which the precast blocks 10 and 20 used in the method according to the present invention are installed in the foundation concrete 30 in which the joint 31 is not formed.

As shown, when the joint 31 is not installed in the foundation concrete 30, a separate connection connector 60 is provided to improve the fixing force between the pillar and the foundation.

The connecting connector 60 includes a first connector 61 such as a bolt connected to the foundation concrete, and a second connector 63 such as a nut provided in the precast blocks 10 and 20.

The first connector 61 includes a bolt connection part 61c inserted into the foundation concrete 30 and integrally formed, and a bolt part 61b connected to the bolt connection part 61c. The bolt connection portion 61c is integrally formed with the foundation concrete 30 during the construction of the foundation concrete 30.

The second connector 63 is integrally formed in the manufacturing process of the precast blocks 10 and 20. The second connector 63 includes a nut portion 63n to which the first connector 61 is connected, and a support portion 63s for fixing the nut portion 63n to the precast blocks 10 and 20. Include.

Therefore, after connecting the bolt portion 61b of the first connector 61 to the bolt connection portion 61c, the nut portion 63n of the second connector 63 is connected to the bolt portion 61b. The precast blocks 10 and 20 can be firmly connected to the ground.

17A-17C show various forms of precast blocks used in the process of the present invention. The precast block of the present invention may be formed in various forms according to the column shape, and is not limited to the block shape described in the present invention.

As shown in FIG. 17A, a separate upper core part 110 protruding upward may be formed at the center of the precast block 100. The upper core part 110 is to improve the coupling force between the precast block 100 and the column body installed on the upper portion of the block, and is installed for the purpose of other internal piping and the like.

The upper core part 110 may be formed according to the shape of the precast block 100 or may be separately formed. An outer surface of the upper core part 110 may be formed with a separate friction portion 113 protruding along the circumference of the upper core part 110. Coupling force between the precast block and the pillar body may be further increased by the friction part 113.

17B illustrates a state in which a separate lower core part 120 protruding downward from the center of the precast block 100 is formed. The lower core portion 120 is to improve the bonding force between the base concrete and the precast block. The lower core part 120 may also be provided with a friction part 113.

FIG. 17C illustrates a state in which the precast block 100 is formed at an upper core portion 110 and an lower core portion 120 formed at an upper portion thereof.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. will be.

Description of the Related Art [0002]
10, 20, 100: precast block 11: hollow
13: cast iron ball 21: rib
41: connection coupler 43: fixed coupler

Claims (25)

In the construction method of applying a precast block composed of a high-performance fiber cement composite to a part of the column body, and post-casting concrete to the precast block to produce a column,
A block manufacturing step of manufacturing a precast block using the fiber cement composite;
A block construction step of installing the precast block so as to correspond to a bending risk cross section position where a bending moment is concentrated at a junction point of a pillar and a foundation concrete;
A reinforcing bar construction step for reinforcing bar in the precast block;
A formwork installation step of installing formwork on the precast block and the constructed rebar;
Concrete placing step of pouring concrete into the formwork; And
After curing the concrete, formwork demoulding step of demolding the formwork
Reinforced concrete composite column method using precast high performance fiber cement composite.
delete The method of claim 1,
The height of the precast block
At least the effective depth of the cross section or the plastic hinge height of the column
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 3,
The minimum height Hpc of the precast block is at least
[Equation 1]

Is greater than or equal to the value
Reinforced concrete composite column method using precast high performance fiber cement composite.
delete The method of claim 1,
The block construction step
And applying a prestress to the precast block.
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method according to claim 6,
The rebar construction step
Connecting the fixed coupler to the precast block to apply prestress, and connecting the fixed coupler to the main reinforcing bar.
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The block manufacturing step
Forming a cast iron ball into which the cast steel is inserted into the precast block;
Reinforced concrete composite column method using precast high performance fiber cement composite.
9. The method of claim 8,
The rebar construction step
And connecting a coupling coupler to a main reinforcing bar inserted into the precast block to connect with the upper main reinforcing bar.
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The block manufacturing step
Inserting a cast iron reinforcement in the precast block including the construction of the main reinforcing bar construction
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The block manufacturing step
A rib forming step of forming a rib in the precast block;
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The formwork installation step
A spacer mounting step for forming a space for injecting mortar between the formwork and the foundation concrete;
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The block construction step
Forming a joint recessed inwardly in the foundation concrete, and seating the precast block on the joint;
Reinforced concrete composite column method using precast high performance fiber cement composite.
The method of claim 1,
The formwork installation step
Pouring mortar between the precast block and the foundation concrete;
Reinforced concrete composite column method using precast high performance fiber cement composite.
A precast block composed of a fiber cement composite and having an effective height with flexural strength and high toughness flexural deformation capacity for lateral loads acting on the pillar is installed at the junction of the pillar and the foundation concrete,
The precast block is fixed to the foundation concrete by a connecting connector,
Post-casting concrete to the precast block to produce a column
Reinforced concrete composite column method using precast high performance fiber cement composite.
16. The method of claim 15,
The height of the precast block
At least the effective depth of the cross section or the plastic hinge height of the column
Reinforced concrete composite column method using precast high performance fiber cement composite.
16. The method of claim 15,
After fixing the precast block to the foundation concrete, prestress is applied to the precast block
Reinforced concrete composite column method using precast high performance fiber cement composite.
16. The method of claim 15,
The connecting connector
A first connector connected to the foundation concrete;
A second connector provided in the precast block and connected to the first connector;
Reinforced concrete composite column method using precast high performance fiber cement composite.
19. The method of claim 18,
The first connector includes a bolt connecting portion inserted into the foundation concrete, a bolt connected to the bolt connecting portion,
The second connector includes a nut part provided in the precast block, the nut part connected to the first connector, and a support part fixing the nut part to the precast block.
Reinforced concrete composite column method using precast high performance fiber cement composite.
Used in the process according to any one of claims 1, 3, 4, 6-19.
Precast block using fiber cement composite.
21. The method of claim 20,
It is formed in a polygonal or circular shape, a hollow penetrating up and down is formed in the inner center, the main reinforcement ball is formed in the circumference of the hollow or a part of the main reinforcing bar is protruded in the circumference of the hollow
Precast block using fiber cement composite.
21. The method of claim 20,
The fiber cement composite is
Containing synthetic or steel fibers such as polyvinyl alcohol (PVA) or polypropyline (PP) fibers
Precast block using fiber cement composite.
The method of claim 21,
The circumference of the hollow includes an upper core portion projecting upward or a lower core portion projecting downward
Precast block using fiber cement composite.
24. The method of claim 23,
The upper core portion or the lower core portion
Including friction part
Precast block using fiber cement composite.
21. The method of claim 20,
The fiber cement composite is
Ultra High Performance Concrete (UHPC), Steel Fiber Reinforced Concrete (SFRC), High Performance Fiber Reinforced Cementitious Composites (HPFRC), or Engineered Cementitious Composites (ECC).
Precast block using fiber cement composite.

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