KR102188276B1 - The Method of Improving Seismic Performance of Columns by Buying Main Reinforcement and the Column Structure Strengthened - Google Patents

Abstract

The present invention forms grooves and holes on the outside of existing or new structures such as reinforced concrete columns of bridge alternations, bridge piers, and reinforced concrete columns in which the seismic design is not reflected, to embed and fix the main reinforcing bars, and then the strip reinforcement and the clip unit on the outer surface, and Enhancement of seismic performance of pillars by the purchase of main reinforcing bars that minimizes damage to life and property by exerting the seismic performance required in the event of an earthquake by reinforcing the finishing material and reinforced by it. It is about the column structure.
This includes the steps of fixing and installing a fixed H-beam rail at a predetermined distance to the existing pillar structure; After installing and installing a track running stand device that can be attached or detached from a dedicated grinder and a dedicated drilling machine to the fixed H-beam rail, the grooves and foundations at a certain width, depth, and interval on the outer surface and floor of the existing column structure. Forming a minor hole; Inserting and positioning the main reinforcing bar vertically in the groove groove and the hole of the foundation, and then filling and fixing the main reinforcing bar with an epoxy resin; Reinforcing strip reinforcing bars at equal intervals on the outer surface of the main reinforcing bars inserted and installed in the vertical state; Connecting and installing a clip unit to the band reinforcement and fixing it to the pillar; And coating a covering material on the outer surface of the column structure on which the band reinforcement is arranged.

Description

The Method of Improving Seismic Performance of Columns by Buying Main Reinforcement and the Column Structure Strengthened}

The present invention relates to a reinforcing method for improving seismic performance of a column by embedding cast reinforcing bars, and to a column structure reinforced thereby, and more particularly, to an existing bridge, such as a reinforced concrete column of a bridge building structure without seismic design, Or, after forming grooves and holes on the outside of the new structure to insert and fix the main reinforcing bar, reinforce the outer surface by wrapping it with a belt iron, clip unit, and finishing material to demonstrate the seismic performance required in the event of an earthquake (small and calm Nonghyeon). And a reinforcing method for improving the seismic performance of a column by embedding a main reinforcing bar that minimizes property damage, and to a column structure reinforced thereby.

In general, the abutment of bridges, bridge piers, and pillar structures of buildings are generally composed of plate-shaped or block-shaped structures and pillars that physically support the upper structures located at the top. It must be able to withstand the pressure sufficiently, and must be able to withstand the external force applied in the horizontal direction such as earthquake or wind pressure.

If the column cannot withstand it, it collapses, and the superstructures physically supported by it are also inevitable.

In particular, for reinforced concrete columns, seismic design against earthquakes is very important. To simultaneously resist bending moments caused by horizontal forces such as vertical axial forces and earthquake loads, wind loads, and driftwood impact loads transmitted from the upper structure. It consists of a composite structure with reinforcing bars.

In this reinforced concrete column structure, a plurality of axial reinforcement bars are installed extending to the base of the column in the vertical direction of the column to resist the bending moment caused by the above vertical and horizontal loads, and the transverse band reinforcement surrounding the main reinforcement is constant. It is installed at intervals.

In seismic design, these main reinforcing bars and band reinforcing bars are arranged by rational design, but in the case of columns that do not reflect the seismic design, seismic reinforcement of the vertical main reinforcing bars and the strip reinforcing bars is inevitable.

The reinforced concrete column structure reflecting the seismic design is a structure that resists earthquakes as a sufficient amount of main reinforcement and strip reinforcement are well placed in the plastic hinge section, which is called the fracture point of the column, when horizontal loads such as earthquake loads are applied, but the seismic design is reflected. If not, compression and buckling of the main reinforcement of the column occurs due to the detachment or detachment of the reinforcing bar, which causes destruction during an earthquake.

As a method for reinforcing the concrete column structure accordingly, several methods such as fiber reinforcement, steel plate reinforcement, and cross-sectional enlargement have already been applied in the field.

This is a type of wrapping the outside of the concrete pillar with one-way fiber sheet, fiber plate and steel plate, and concrete, and it is common to attach the fiber sheet to the concrete pillar using an epoxy resin.

For example, the known flame-retardant/semi-non-flammable seismic reinforcing fiber composite for concrete structures and concrete reinforcing method using the same (Registration Patent No. 10-1737554) as shown in FIG. 9 consists of fibers having an initial modulus of elasticity smaller than that of concrete, and the concrete surface A first slope formed of at least one of aramid filament, carbon filament, glass fiber filament, ultra-high molecular weight polyethylene fiber, and basalt fiber, It is woven including a second warp formed of synthetic fiber multifilament, which is arranged alternately with the first warp and is made of one or more of polyester and nylon, and a weft yarn which is formed of synthetic fiber multifilament, which is at least one of polyester and nylon. , The first inclination is 5000 ~ 20000d/5 ~ 20fila, T/M 50 ~ 80, the second inclination is 150 ~ 300d/48fila, the weft yarn is a seismic fiber consisting of 150 ~ 2000d / 40 ~ 96fila;

A resin applied to and impregnated with the seismic fiber;

Any one type of inorganic powder selected from aluminum hydroxide (Al(OH)3), magnesium hydroxide (Mg(OH)2), and calcium carbonate (CaCO3), and

The core component is aluminum hydroxide (Al(OH)3) and comprises aluminum hydroxide-melamine composite particles formed by bonding melamine to the surface of the aluminum hydroxide particles in the form of a shell, and is added to the resin to improve flame retardancy. The main is a non-toxic inorganic flame retardant;

It is sprayed on the concrete attachment surface of the earthquake-resistant fiber before the impregnated resin is hardened, and is located in a protruding form. It is hydrophilic and enables more solid attachment by hydrogen bonding with cement of the concrete structure. Sericite mineral powder which is made to increase the adhesion area to the surface;

Among the seismic fibers, a flame-retardant finishing material applied to the opposite side of the attachment surface attached to the surface of the concrete structure is applied in a thickness of 0.1 to 5 mm with respect to the seismic fiber, an epoxy resin, and an inorganic flame retardant. It includes, wherein the resin is provided with an epoxy resin, applied to and impregnated with the seismic fiber, and adheres the seismic fiber to the surface of the concrete structure, and serves to fix the inorganic flame retardant to the seismic fiber, and ,

An aramid strip is further provided, which is attached to concrete together with the earthquake-resistant flame-retardant composite member in a state arranged in multiple rows between the earthquake-resistant flame-retardant composite member and the surface of the concrete structure to reinforce the strength of the ductile earthquake-resistant flame-retardant composite member, and the The aramid strip has an initial modulus of elasticity that is smaller than that of concrete, so that the aramid fiber yarns are placed side by side in multiple rows to constrain the external volume expansion due to the destruction of concrete on the surface of the concrete in case of an earthquake, together with epoxy resin added with flame-retardant inorganic powder. Extruded and hardened by a pulltrusion process, and the flame-retardant inorganic powder contained in the aramid strip is one of aluminum hydroxide (Al(OH)3), magnesium hydroxide (Mg(OH)2), and calcium carbonate (CaCO3). Species, and the flame-retardant inorganic powder further includes aluminum hydroxide-melamine composite particles, and the core component of the composite particles is aluminum hydroxide (Al(OH)3), and melamine is in the form of a shell on the surface of the aluminum hydroxide particles. It is characterized in that it has a particle diameter of 100nm to 5㎛ made by combining.

In addition, as shown in Fig. 10, a known fiber sheet winding device for reinforcing a column structure (Registration Patent No. 10-0554276) includes a plurality of column frames 2 installed vertically at equal intervals on the outside of the column structure 100;

A guide device 6 mounted on one side of the moving rail part 62 installed to surround the outer side of the column structure 100 and being fitted to the support frame 2 to move up and down;

A driving device 50 coupled to the moving rail part 62 is provided on one side, and a cylinder device 58 capable of adjusting the length is provided on the other side to drive along the outer periphery of the column structure 100 ( 5) and;

Consisting of an impregnation tank 36 for impregnating the fiber sheet 340 into the resin, and a winding device 32 capable of winding the impregnated fiber sheet 340 around the outer periphery of the column structure, the cylinder device 58 A head 3 mounted on one end of the;

A control unit capable of controlling the operation of the holding frame 2, the guide device 6, the driving unit 5, and the head unit 3 by a processor input in advance;

However, the method of reinforcing concrete columns using a fiber sheet such as carbon fiber or aramid fiber has a problem that the effect of enhancing the load-bearing capacity of the column is excellent, while the effect of enhancing the flexibility in the transverse direction is weak.

In addition, when the fiber sheet is attached to the surface of the pillar using a general epoxy resin, there is a problem that it is very cumbersome to remove air bubbles formed on the attachment surface during construction.

And, as shown in Fig. 11, a reinforcing method for improving the seismic resistance of a known concrete column, and a concrete column reinforced by it (Publication Patent 10-2004-0021018) is (1) a width 2 on the surface of the concrete column 20 A first reinforcing step of compressing and reinforcing by inserting and fixing the carbon fiber composite 30 and the epoxy resin after forming grooves in the vertical direction of 5 mm to 5 mm and 5 to 20 mm deep at regular intervals; And

(2) Secondary reinforcement to form a fabric reinforcement layer by winding a horizontal reinforced glass fiber fabric 10 impregnated with a vapor-permeable epoxy resin on the surface of the concrete column 20 reinforced in the first reinforcing step 2 to 5 times Steps; including.

However, this method of forming a groove on the surface of a concrete column, inserting and fixing the carbon fiber composite and epoxy resin, and then wrapping and reinforcing the horizontally reinforced glass fiber is very cumbersome and takes a long time to work, and it also has excellent load-bearing capacity enhancement effect. Increasing the flexibility in the transverse direction had a problem in that the enhancing effect was weak.

(1) Registered Patent No. 10-1737554 (1) Registered Patent No. 10-0554276 (1) Patent Publication No. 10-2004-0021018

The present invention is to solve the above problems, in detail, by forming grooves and holes on the outside of existing or new structures such as reinforced concrete columns of bridges, bridges, and reinforced concrete columns in which the intended seismic design is not reflected. After purchasing and fixing the main reinforcing bar, the outer surface is reinforced to wrap the strip reinforcing bar, the clip unit, and the finishing material to demonstrate the seismic performance required in case of an earthquake. An object thereof is to provide a reinforcing method for improving seismic performance of pillars by embedding and a pillar structure reinforced thereby.

In order to achieve this object, the present invention

(1) fixing and installing fixed H-beam rails at regular intervals on the existing pillar structure;

After installing and installing a track running stand device that can be attached or detached from a dedicated grinder and a dedicated drilling machine to the fixed H-beam rail, the grooves and foundations at a certain width, depth, and interval on the outer surface and floor of the existing column structure. Forming a minor hole;

Inserting and positioning the main reinforcing bar in a vertically upright state in the groove groove and the hole of the foundation, and then filling and fixing it with an epoxy resin;

Reinforcing strip reinforcing bars at equal intervals on the outer surface of the main reinforcing bars inserted and installed in the vertical state;

Connecting and installing a clip unit to the band reinforcement and fixing it to the pillar; And

There is a feature made in one piece, including the step of covering the outer surface of the column structure in which the band reinforcement is laid.

(2) In the above (1), the groove is formed in a longitudinal direction perpendicular to the outer surface of the plastic hinge section of the column structure, and a base hole is drilled in the lower portion of each groove.

(3) In the above (1), the coating material is characterized by using a finishing material such as mortar or epoxy.

(4) In the above (1), the lower portion of the main reinforcing bar has an extended fixing end.

(5) In the above (1), the clip unit is characterized in that it has an omega shape.

(6) According to the above (1), wherein the track operation stand device, a rail groove is formed in the upper center, the lower part is a base plate formed with a roller portion capable of running a track by connecting to a fixed H-beam rail;

The front is open, but the lower part is connected to the rail groove of the base plate so as to be movable forward and backward, and guide protrusions are formed on both inner surfaces, and a motor is provided with an elevating and descending transport shaft at the upper part. And a stand provided with a switch unit on the outside;

Elevating and descending fixtures that are built to be elevating and descending on the elevating and descending transport shafts of the stand, and equipped with a fixed base capable of attaching and detaching a dedicated grinder and a dedicated perforator and supplying power through several fixing screws on both sides of the front side; And

It has a feature consisting of; a hydraulic spring that is inserted and installed in the front inner side of the base plate to push the stand to the rear side.

(7) In the above (6), the roller part is provided with a wheel roller on the inner upper side, a separation prevention pin installed to enable width adjustment at the front and rear sides, and a locking piece formed in the front of the lower part. There is a feature that is equipped with a fixture.

(8) In the above (6), a power supply terminal capable of receiving power from the fixture and a detachable groove are formed on both rear sides of the dedicated grinder and the dedicated perforator, and a predetermined width is formed on the outer surface and the bottom of the pillar structure. It is characterized by a vacuum suction port capable of self-suctioning and storing dust generated when forming a deep groove and a base hole.

As described above, the present invention is in detail, after embedding and fixing the main reinforcement by forming grooves and holes on the outside of existing or new structures such as reinforced concrete columns of bridges, bridges, and reinforced concrete columns in which the intended seismic design is not reflected. It has the effect of minimizing damage to people and property by exerting the required seismic performance in case of an earthquake by reinforcing the surface with band iron, omega clip unit and finishing material.

In addition, there is an effect that can be achieved quickly, easily and economically by using a stand device through a dedicated grinder and a perforator.

The present invention is not limited to the specific preferred embodiments described above, and any person having ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications Of course, such changes are within the scope of the claims.

1 is a flowchart for explaining a method of reinforcing seismic performance improvement of a column by embedding main reinforcement according to an embodiment of the present invention;
Figure 2 is a plan cross-sectional view showing a process for forming a reinforced column structure by the method of improving the seismic performance of the column by embedding the main reinforcement according to the present invention,
3 is a plan sectional view showing a column structure reinforced by a method for improving seismic performance of a column by embedding a main reinforcing bar, which is an embodiment of the present invention;
Figure 4 is a side view showing a process for forming a reinforced column structure by the method of improving the seismic performance of the column by embedding the main reinforcement according to an embodiment of the present invention;
5 is a side view showing a column structure reinforced by a method for improving seismic performance of a column by embedding main reinforcement according to an embodiment of the present invention;
6 is an exploded perspective view showing the main components used to form the reinforced column structure by the method of improving the seismic performance of the column by embedding the main reinforcement according to the present invention,
7 is an exploded perspective view showing an enlarged main component used to form a column structure reinforced by the method for improving the seismic performance of the column by embedding the main reinforcement according to the present invention,
8 is an enlarged side view showing a main component used to form a reinforced column structure by a method for improving seismic performance of a column by embedding a main reinforcement according to an embodiment of the present invention;
9 is a perspective view showing a conventional flame-retardant/semi-non-flammable seismic reinforcing fiber composite for concrete structures
10 is a perspective view showing a conventional fiber sheet winding device for reinforcing column structures,
11 is a plan cross-sectional view showing a reinforcing method for improving the seismic resistance of a conventional concrete column and a concrete column reinforced by it

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

For reference, when it is determined that a detailed description of known functions or configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof has been omitted.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators.

Therefore, it goes without saying that the definition should be made based on the contents throughout this specification.

The reinforcing method of improving the seismic performance of the pillar by embedding the main reinforcement of the present invention is a step of fixing and installing the fixed H-beam rail 140 to the existing pillar structure at regular intervals as shown in FIGS. 1 to 8 (S1) Wow, after connecting and installing a track operation stand device 200 capable of attaching and detaching the dedicated grinder 202 and the dedicated drilling machine 204 to the fixed H-beam rail 140 so that the track can be operated, the existing pillar structure 10 The step of forming the groove 12 and the base hole 14 at a predetermined width, depth and interval on the outer surface and the bottom of the (S2), and the groove 12 and the base hole 14 in the main reinforcement ( Step (S3) of filling and fixing the epoxy resin 150 after inserting 100) in a vertically upright state, and a strip reinforcing bar 110 on the outer surface of the main reinforcing bar 100 inserted and installed in the vertically upright state. The step of reinforcing at equal intervals (S4), the step of connecting and installing the clip unit 120 to the band reinforcement 110 and fixing it to the column structure 10 (S5), and the step of reinforcing the band reinforcement 110 It consists of a step (S6) of covering the covering material 150 on the outer surface of the pillar structure 10.

Here, the fixed H-beam rail 140 has anchor holes 144 that can be anchored to the floor at equal intervals.

Meanwhile, in the illustrated example, the fixed H-beam rail 140 is formed by connecting and combining two H-beams bent into a semicircular body to form a circular body, but the shape and number are not limited thereto.

In other words, according to the site situation, it is possible to form a circular body by connecting and combining a plurality of bent H beams, and a plurality of H beams are connected to form a straight section and a bent section so that it can be applied to a pillar structure 10 such as a square face. Because it can be achieved in combination.

In addition, the groove 12 is formed in a vertical longitudinal direction on the outer surface of the plastic hinge section P of the column structure 10, and a foundation hole 14 is provided under each groove 12.

On the other hand, the groove 12 and the base hole 14 are formed on the outer surface of the plastic hinge section P of the column structure 10 as much as the diameter and installation distance of the vertical main reinforcing bar 110 determined by the seismic design. It is not limited to the width, depth, and spacing shape as in the illustrated example.

In addition, the covering material 150 may be made of a finishing material such as mortar or epoxy.

In addition, the lower portion of the main reinforcement 100 is formed with an extended fixing end 112.

As in the illustrated example, the extended fixing end 112 is formed in an upper and lower light shape, but is not limited to this shape.

In addition, the clip unit 120 is formed in an omega shape in the illustrated example, but is not limited to this shape.

In addition, the track running stand device 200, a rail groove 211 is formed in the upper center, and fixing holes for inserting and fixing adjustment pins 212 for adjusting the depth of the groove 12 on both sides ( 213) is formed, and a base plate 210 having a roller part 214 that is connected to a fixed H-beam rail 140 and can be operated on a track at the bottom thereof,

The front is open, but the lower part is connected to the rail groove 212 of the base plate 210 so as to be movable forward and backward, and guide protrusions 222 are formed in the vertical longitudinal direction on both inner sides, and the upper part A motor 226 having a rising and falling transfer shaft 224 at the bottom is provided, and a stand 220 provided with a switch 228 on the outside,

It is built to be raised and lowered on the lifting and lowering transfer shaft 224 of the stand 220, and a dedicated grinder 202 and a dedicated perforator 204 are attached and detached through fixing screws 232 on both sides of the front side. A lifting and descending fixture 230 provided with a fixture 234 capable of supplying,

It consists of a hydraulic cylinder 240 that is inserted and installed inside the front of the base plate 210 to push the stand 220 to the rear side.

Here, the roller part 214 is provided with a wheel roller 215 on the inner upper side, and a separation prevention pin 216 installed to enable width adjustment at the front and rear sides of the lower part, and a protrusion formed in the lower front ( A locking fixture 218 is provided at 217.

In addition, power supply terminals 206a, 206b and detachable grooves 208a, 208b capable of receiving power from the fixing table 234 on both rear sides of the dedicated grinder 202 and the dedicated perforator 204 A vacuum suction port 209 capable of self-suctioning and storing dust generated when the groove 102 and the base hole 104 of a predetermined width and depth are formed on the outer surface and the bottom of the column structure 10 Each is provided.

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

2 to 8 of the accompanying drawings show a first embodiment according to the present invention, and as shown therein, in actual use, first fixed H-beam rails at a predetermined interval on the floor surface adjacent to the existing pillar structure 10 ( 140) can be fixedly installed through anchors.

Subsequently, it is sufficient to connect the track running stand device 200 on the fixed H-beam rail 140.

That is, after the roller unit 214 provided in the lower part of the track running stand device 200 and the separation prevention pin 216 are spaced apart so that the wheel roller 218 can be placed on the top of the fixed H-beam rail 140 , Again, the gap between the separation prevention pins 216 can be narrowed.

And, the track operation stand device 200 connected in this way is fixed to the fixed H-beam rail 100 through the locking fixture 218, and the track operation stand device 200 can be moved to the depth intended by the operator. After inserting the adjustment pin 212 into the fixing hole 213 of the base plate 210 so that it is possible to press the operation button (not shown) of the dedicated grinder 202 located in the switch unit 228.

Then, the dedicated grinder 202 rotates at high speed, and the dedicated grinder 202 rotating at such a high speed is grooved on the outer surface of the column structure 10 that abuts by a motor 226 that continuously repeats forward and reverse rotation. (12) is formed by cutting.

At this time, the cutting depth is made as much as the distance at which the track running stand device 200, which is projected in the direction of the column structure 10 by the hydraulic spring 240, contacts the adjustment pin 212, and the cutting length consisting of up and down is It includes the plastic hinge section (P) determined by the seismic design.

In addition, dust generated in the cutting process is suction-cleaned by a vacuum suction port 209a integrally formed in the dedicated grinder 202.

The vertical groove 12 of a certain depth on the outer surface of the column structure 10 by continuously repeating the cutting operation of the groove 12 while moving the track running stand device 200 from the fixed H-beam rail 140 Can be formed at equal intervals.

Then, after dismantling the dedicated grinder 202, fixing the dedicated perforator 204 to the lifting and lowering fixture 230, a base hole 14 having a predetermined depth was formed on the bottom of the groove 12. Just form it.

That is, after moving the track running stand device 200 on the fixed H-beam rail 140 so that the dedicated perforator 204 is positioned in the groove 12 to be drilled for the base hole 14, lock Fixing through the fixture 218, and pressing the dedicated perforator 204 operation button (not shown) located in the switch unit 228.

Then, the dedicated perforator 204 rotates at high speed, and at the same time, the motor 226 rotates the up and down transfer shaft 224 forward to lower the up and down fixture 230 in which the dedicated perforator 202 is fixedly installed.

Also at this time, the dust generated in this drilling process is suction-cleaned by the vacuum suction port 209b integrally formed in the dedicated drilling machine 204.

On the other hand, the depth of the base hole 14 is made by the preset operating time of the motor 226 or the descending point value of the lifting and descending fixture 230 that descends along the lifting and descending transport shaft 224. You lose.

Then, after inserting the main reinforcing bar 16 in each groove 12, it is sufficient to fill the epoxy resin 17 and cure.

Here, the lower part of the main reinforcing bar 16 is formed with an extended fixing end 112 that has an upper and lower beam, so that the frictional force of the main reinforcing bar 16 is increased, and the bonding force with the surrounding structures is improved, so that the foundation part It improves the adhesion ability of the wand.

And, the belt reinforcement 130 is laid at equal intervals on the outer surface of the main reinforcing bar 16, and fixed to the column structure 10 using a clip unit 120 to the belt reinforcing bar 110, and the belt reinforcing bar A covering material 150 such as mortar or epoxy may be coated on the outer surface of the columnar structure 10 on which (110) is laid.

The effects of the present invention are examined through experimental analysis.

Experiment outline

1.1 Purpose of experiment

In the case of reinforcement by embedding main reinforcement for the pier column of the bridge or the column structure of the building, especially the piloti-type building column structure, which did not reflect the seismic design, the structural behavior characteristics of the reinforced concrete column during earthquake were analyzed experimentally.

For the members to be compared, it was assumed that the seismic design concept was not introduced at the design stage, and the deep restraining reinforcement could not be placed.

In this experiment, reinforced concrete columns that did not reflect such seismic design were subjected to reinforcement as in the present invention, and their performance was compared and evaluated.

1.2 Cross-section design of specimen

The overall shape of the specimen is in the form of a circular column, and a reduced model was designed as a base and a column for the experiment.

The foundation part was made of reinforced concrete with a size of 1,200 X 600 X 600 (mm), and the column part was made of reinforced concrete with a diameter of 400 mm and a height of 1,250 mm.

1.3 Preparation of specimen

A total of two specimens produced and tested in this experiment were placed and cured indoors.

After pouring, the cured specimens were reinforced as indicated in the patent.

The identification numbers of the two specimens were CN-0-0 and CR-8-100-A, and the seismic design was not reflected in CN-0-0.

In other words, it is a general specimen of no reinforcement in the case of no deep constraining reinforcement, and CR-10-100-A is a specimen manufactured according to the contents of the present invention.

In this experiment, after calculating the plastic hinge section, the dangerous section was calculated as a 500mm section from the junction, and reinforcement for this section was performed as in the present invention.

The meaning of the number located in the middle of the specimen name means the diameter of the band reinforcement used, and the unit is mm.

The last number refers to the distance (mm) of the reinforced band reinforcement within the danger section.

[Figure 1] below is a view of each specimen.

[Figure 1] Front view of specimen

2. Experiment method

2.1 Seismic performance test

In general, experiments to understand seismic behavior characteristics and seismic performance of piers are largely divided into Shaking Table Test, Pseudo-Dynamic Test, and Quasi-Static Test.

In this experiment, a quasi-static experiment was performed in consideration of the available equipment.

The quasi-static test is the most common test method to obtain a structure's supply capability curve by loading a structure with repeated horizontal loads in the transverse direction.

Horizontal load is loaded in a displacement control method using a hydraulic actuator as shown in [Fig. 2] below, and the increment of the load is generally selected as a multiple of the yield displacement or a multiple of the drift ratio of the pier.

In this experiment, the displacement control method using the drift ratio was used.

[Figure 2] Schematic diagram of quasi-static test method

2.2 Lateral load loading method and experimental parameters

)로 정하였다.In the lateral force displacement control of the actuator, a load was applied to the maximum range that the maximum displacement can be used, which is 150mm, and when the main reinforcing bar of the pier yielded, the displacement was adjusted to the yield displacement (

).

=22mm이며 결과에 따른 Drift Level(

)은, 0.25%(5.5mm), 0.5%(11mm), 0.75%(16.5mm), 1.0%(22mm), 1.5%(33mm), 2.0%(44mm), 2.5%(55mm), 3.0%(66mm), 4.0%(88mm), 5.0%(110mm)이다.The yield displacement of the specimen used in this experiment is the experimental result.

=22mm, and the Drift Level (

) Is 0.25%(5.5mm), 0.5%(11mm), 0.75%(16.5mm), 1.0%(22mm), 1.5%(33mm), 2.0%(44mm), 2.5%(55mm), 3.0%( 66mm), 4.0% (88mm), 5.0% (110mm).

In order to prevent sudden destruction of the pier at the beginning of loading, the displacement was increased by 0.25% up to the first 1.0%, 0.5% after 1.0%, and the pier increased by 1.0% from 3.0%, and the control load of the same displacement was repeatedly loaded. And confirmed the seismic performance of the pier.

There are a total of two specimens, and the classification is a total of two such as a non-reinforced general specimen and the present invention specimen.

The classification of the specimens is shown in [Table 1] below.

Classification of specimen Specimen Concrete strength
(MPa) Band reinforcement Remark Reinforcement Diameter (mm) Thickness (mm) CN-0-0 24 X - - - CR-8-100-A 24 ○ 8 100 Patent application details

3. Analysis of experimental results

3.1 CN-0-0 specimen

This specimen is an unreinforced specimen that does not reflect the seismic design.

The bending behavior was shown up to the maximum load of 10.96 tons, and after the drift level 2.5%, the concrete cover of the plastic hinge section fell off by more than 70%, and severe buckling began to occur after the main reinforcement was exposed.

After the drift level of 3.0%, deep constraining concrete destruction occurred, and the lateral constraining ability rapidly decreased.

Slip phenomenon of the main reinforcing bar occurred in the displacement after this, and buckling was observed in quite a number of sections.

[Fig. 3] below is during the experiment, and [Fig. 4] is after the end of the experiment. It can be seen that the column main reinforcement is compressed and bucked in the plastic hinge area of the joint, and the column is destroyed.

[Figure 3] Destruction of CN-0-0 specimen during experiment

[Figure 4] Destruction of CN-0-0 specimen after experiment

3.2 CR-8-100-A specimen

As the test body of the present invention, [Fig. 5] shows the state of destruction during the experiment, and [Fig. 6] shows the appearance after the end of the experiment.

Compared to the specimen without seismic reinforcement, the maximum load received by the specimen increased by 20%, and bending behavior occurred at 12.22ton.

In addition, after receiving the maximum load at the drift level of 1.5% (displacement 33mm), it begins to yield and shows a very high energy absorption rate until the end of the experiment.

In particular, even after the maximum load, the main reinforcing bars are not buckling due to the deep constraining effect of the reinforcing bars as shown in [Fig. 6], so it is possible to prevent sudden destruction of the columns during an earthquake. It was experimentally confirmed that there is an enhancement effect.

[Figure 5] Destruction of CR-8-100-A specimen during experiment

[Figure 6] Destruction of CR-8-100-A specimen after experiment

S1: Fixed H beam installation step
S2: Groove groove and base hole formation step
S3: Main reinforcing bar insertion and installation step
S4: The step of reinforcing the belt reinforcement
S5: Fixture installation step
S6: Covering step
P: plastic hinge section
10: column structure 12: groove groove
14: base hole
100: main reinforcement 112: extended fixing end
110: band reinforcement
120: Clip unit 122: Omega type clip unit
130: covering material
140: fixed H beam rail 142: hole
150: epoxy resin
200: track operation stand device 201: handle
202: dedicated grinder
204: dedicated perforator 207: cover
206a,206b: power supply terminal
208a, 208b: detachable groove 209: vacuum inlet
210: base plate 211: rail groove
212: adjustment pin 213: fixing hole
214: roller part 215: wheel roller
216: departure prevention pin 217: protruding piece
218: locking fixture
220: stand 222: guide protrusion
224: up/down feed shaft 226: motor
228: control switch part
230: lifting, lowering fixture 232: fixing screw
234: fixture 236: power supply terminal
240: hydraulic spring

Claims (8)

The steps of fixing and installing the rail, the step of cutting and trimming the outer surface and the floor of the existing pillar structure after connecting and installing a track operation stand device capable of attaching and detaching a dedicated grinder and a dedicated perforator to the rail so that it can be operated on a track, and Installing a vertical stiffener on the outer surface and the bottom of the structure, filling and fixing it with an epoxy resin, distributing a horizontal stiffener to the outer surface of the vertical stiffener, and covering the outer surface of the existing pillar structure with a covering material. In the seismic performance improvement reinforcement method of the existing pillar made by
The rail is a fixed H-beam rail that is fixedly installed at regular intervals on the existing pillar structure;
Groove grooves and foundation holes are formed on the outer surface and bottom of the existing column structure at a predetermined width, depth, and interval, but the groove is formed in a longitudinal direction perpendicular to the outer surface of the plastic hinge section of the column structure. The lower part is made by perforating the base hole;
The vertical stiffener is a main reinforcing bar of a predetermined diameter inserted in a vertically standing state into the groove groove and the base hole;
The horizontal stiffener is a band reinforcement of a predetermined diameter that is laid at equal intervals on the outer surface of the main reinforcing bar inserted and installed in the vertical state;
The reinforcing method for improving the seismic performance of the pillar by embedding the main reinforcing bar, characterized in that the band reinforcement is connected and installed by a clip unit and fixed to the pillar. Groove grooves and foundation holes formed at predetermined widths, depths, and intervals on the outer surface and bottom of the existing pillar structure;
Joo reinforcement placed vertically in the groove and the hole of the foundation;
An epoxy resin that is filled in the groove groove and the base hole into which the main reinforcing bar is inserted to fix the main reinforcing bar;
Band reinforcement reinforced at equal intervals up and down on the outer surface of the main reinforcing bar inserted in the vertical state;
A clip unit fixing the band reinforcement to the column; And
The reinforcing structure for improving the seismic performance of the pillar by embedding the main reinforcement, characterized in that it comprises a covering material coated with a certain thickness on the outer surface of the pillar structure in which the reinforcing bar is laid. delete delete delete According to claim 1, The track running stand device, a rail groove is formed in the upper center, the lower part is a base plate formed with a roller part which is capable of running a track by connecting to a fixed H-beam rail;
The front is open, but the lower part is connected to the rail groove of the base plate so as to be movable forward and backward, and guide protrusions are formed on both inner surfaces, and a motor is provided with an elevating and descending transport shaft at the upper part. And a stand provided with a switch unit on the outside;
Elevating and descending fixtures that are built to be elevating and descending on the elevating and descending transport shafts of the stand, and equipped with a fixed base capable of attaching and detaching a dedicated grinder and a dedicated perforator and supplying power through several fixing screws on both sides of the front side; And
A method for improving seismic performance of pillars by embedding main reinforcing bars, comprising: a hydraulic spring inserted into the front inner side of the base plate to push the stand toward the rear side. The method of claim 6, wherein the roller part is provided with a wheel roller on the inner upper side, a separation prevention pin installed to enable width adjustment at the front and rear sides, and a locking fixture provided on a protrusion formed in the front of the lower part. Reinforcing method for improving seismic performance of columns by embedding main reinforcing bars, characterized in that The method of claim 6, wherein a power supply terminal capable of receiving power from the fixing table and a detachable groove are formed on both rear surfaces of the dedicated grinder and the dedicated perforator, and grooves having a predetermined width and depth are formed on the outer surface and the bottom of the pillar structure. A reinforcing method for improving seismic performance of pillars by embedding main reinforcing bars, characterized in that a vacuum suction port capable of self-suctioning and storing dust generated when forming grooves and foundation holes is provided.

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