KR101617713B1 - Seismic Reinforcement Method of Unreinforced Masonry Structure using Masonry-Joint Embedded Reinforcement Steel and its Reinforcing Structure - Google Patents

Abstract

According to the seismic retrofitting method of the present invention, horizontally reinforcing steel is extended to an end portion of the outer wall on an outer wall of a building requiring seismic strengthening, a step of installing a fixing steel material surrounding the outer wall on an end of the outer wall, And fixing the outer wall with a fixing anchor.

Description

Technical Field [0001] The present invention relates to a seismic retrofitting method for reinforced concrete masonry,

The present invention relates to an anti-seismic reinforcement method and a reinforcement structure, and more particularly to an anti-seismic reinforcement method for a low-rise structure and a reinforcement structure thereof, and more particularly to an anti-seismic reinforcement method for a low- .

Recently, as the earthquake-resistant design standards for structures have been strengthened, a variety of seismic retrofitting methods have been developed and spread through the strengthening of the seismic reinforcement market such as school buildings and other government offices. However, the low-rise non- Technology development and reinforcement measures are insufficient. Since low-rise non-reinforced masonry buildings in Korea and abroad have weak structural performance compared to middle-level or higher-layer structures, they are subject to many damages such as cracks, conduction and collapse of sudden wall due to various natural disasters and aging each year (see Table 1 below).

    Generally, low-rise non-reinforced masonry buildings are mostly privately owned buildings, and it is not practical to reinforce them by applying existing seismic retrofitting methods, which require enormous cost.

    Therefore, it is urgent to develop a reinforcement method considering a combination of economical efficiency, construction performance, and structural stability for private low-rise un-reinforced masonry buildings. Through this, security for private buildings is secured, It is possible to minimize damage to property.

Examples of damages of low-rise reinforcement mast

On the other hand, seismic strengthening is a method for minimizing the expected damage at a minimum cost when it is judged that the seismic performance of a building to resist an earthquake is insufficient. For earthquake-proof reinforcement, concrete reinforcement work should be carried out after clearly predicting how the building will move during an earthquake while satisfying the conditions such as ① preventing collapse ② preserving function after earthquake ③ preserving asset value of buildings.

The seismic retrofitting method is mainly applied to the following cases. The above-mentioned non-reinforced mastication seismic strengthening method will mainly be applied to ①.

① Buildings built by the former Design Law, where seismic performance is insufficient ② New seismic performance enhancement is required to increase or reduce buildings or change their purpose ③ Reinforcement and reuse of damaged buildings

In addition, the above-mentioned seismic retrofitting method is carried out from the viewpoint of increasing the building strength (increasing the strength) and improving the deformability of the building (improving the ductility). The method of improving the ductility capacity includes lateral restraint of existing members, column reinforcement to change the collapse mechanism, and local reinforcement of the part where brittle fracture is expected. Unlike the ductility improvement method, the response correction factor (R) So that the intensity demand can be reduced.

However, due to the nature of the masonry that is constructed by stacking bricks one by one, it becomes very vulnerable to lateral loads if there is no method of securing such integrity as frame beams. Especially, when compared with reinforced concrete structure, masonry structure is known to be vulnerable to seismic load especially in the following cases: (1) out-of-plane deformation, (2) around the opening, especially at the upper corner, (3) joints with slabs, and (4) diagonal cracks in structural walls.

Korean Institute of Architects, "Improvement of seismic design system of buildings" 2008.11

Accordingly, the present invention aims to provide a seismic retrofitting method of a low-level non-reinforced masonry structure that maximizes preservation of masonry prototype after completion of the anti-seismic reinforcement work of an unreinforced masonry tank, and is excellent in workability and economy, and structurally stable.

Especially, we are going to provide an earthquake-proof reinforcement method which can solve the following matters.

- Ensure the structural performance that can sufficiently support the shear reinforcement of the wall as well as the out-of-plane deformation

- Ensure the bending reinforcement performance of the wall and minimize the occurrence of slip and line bending cracks

- Preserve the prototype as much as possible after completion of construction.

- Quantify the amount of reinforcement of horizontal reinforcement according to the scale of the building,

- Ensure settlement details applicable to buildings of various designs

- Additional reinforcement due to product damage and easy maintenance

According to the seismic retrofitting method of the present invention, horizontally reinforcing steel is extended to an end portion of the outer wall on an outer wall of a building requiring seismic strengthening, a step of installing a fixing steel material surrounding the outer wall on an end of the outer wall, And fixing the outer wall with a fixing anchor.

In the seismic retrofitting method of the present invention, the building is a masonry building, and the horizontal reinforcing bar 10 is to be buried in the outer wall. And anchoring holes to the outer wall to be inserted with the fixing anchor.

In the seismic strengthening method of the present invention, the step of injecting a chemical binder such as a bond into the line eye and the anchor hole may be performed so as to improve the adhesion performance between the horizontal reinforcing bar, the fixing anchor and the outer wall, .

In the seismic retrofitting method of the present invention, the outer wall may intersect with each other in two directions, and the fixing hardware may be installed in an 'a' -shaped section at the intersection of the outer walls.

In the seismic retrofitting method of the present invention, the two intersecting outer walls are a masonry and a reinforced concrete structure, and the horizontal reinforcing bars are connected across the masonry concrete structure and the masonry tile. At the end of the reinforcing concrete structure, So that the pulling strength of the horizontal reinforcing bars can be improved.

In the seismic retrofitting method of the present invention, the outer wall is a wall constituting the opening of the masonry tank, and the fixing iron and the fixing anchor may be installed on the left and right sides of the outer wall of the opening.

The present invention's advanced steel structure comprises a horizontally reinforcing steel reinforced by a reinforced concrete reinforced concrete which is embedded in a reinforced concrete wall of an outer wall of a building requiring seismic strengthening and extends to an end of the outer wall, a fixing steel material installed at an end of the outer wall, As shown in FIG.

According to the present invention, it is possible to maximize the preservation of the mooring prototype after completion of the reinforcement work by introducing the buried type reinforcement system instead of the surface exposure type, and it is possible to fully cope with the out-of-plane deformation as well as the shear reinforcement of the wall, It can be applied to buildings of various designs regardless of design, and it is easy to change the amount of horizontal reinforcing bars and specifications, settlement hardware specifications according to the required strength of buildings, and it is advantageous that additional reinforcement and maintenance are easy have.

The seismic retrofitting method according to the present invention can be utilized as a low-cost seismic retrofitting method for a private low-floor non-reinforced masonry building, a simple seismic retrofitting method for a small public building that can be utilized as a seismic- It can be utilized as a reinforcement method for masonry modern buildings, and can be used as a reinforcement method of a ramen structural wall in which conduction is a concern, and can be utilized as an emergency reinforcement method in various structural types together with additional reinforcement details.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view explaining a mooring-resistant seismic strengthening method according to the present invention; Fig.
2 is a perspective view explaining an opening reinforcing method of the mooring-resistant seismic strengthening method of the present invention.
Figure 3a is a detailed view of the masonry edge joint;
Figure 3b is a detailed view of the RC column-masonry connection.
3C is a detailed view of the fixture opening fixing portion;
FIG. 3D is a detailed view of another fixing portion of the coarse aperture.

Hereinafter, preferred embodiments of the seismic retrofitting method and the reinforcement structure of the present invention will be described with reference to the accompanying drawings.

1 is a conceptual perspective view showing an embodiment of the seismic retrofitting method and reinforcing structure thereof according to the present invention.

As can be seen schematically in FIG. 1, the seismic retrofitting method of the present invention and its reinforcing structure have the following features.

First, it is possible to reinforce the seismic performance of the low-rise non-reinforced masonry building (however, it is not limited to the low-rise masonry building, and the reinforcement method of the present invention and other structures to which the principle of the reinforcing structure can be applied, As well as to the < RTI ID = 0.0 &

Secondly, a reinforcing material (reinforcing bars, steel wires, wires, etc.) 10 is embedded in the eye of the mooring line in the horizontal direction to prevent shear reinforcement of the wall and the outer stooling wall from being transmitted in the out-

Third, fixation hardware 20, 21 having a predetermined detail for reinforcing the wall bending strength is installed at the corners and openings at the same time as fixing the horizontal reinforcement (reinforcing bars, steel wires, wires, etc.)

Fourthly, in order to stably move the fixing hardware 20 and 21, a metal fixture is fixed to the lower foundation and the upper beam with the fixing anchor 30,

Fifth, the embedding portion of the horizontal stiffener (reinforcing bar, steel wire, wire, etc.) (10) is finished with a mortar or an adhesive of the same color as the existing line,

Sixth, end fittings (20, 21) are finished with mortar finish, stainless steel cover, painting.

In the moorment-reinforced earthquake-proofing method of the present invention, the stationary still life 20 is attached to the corner of the portion where the wall 1 meets the wall 1 as shown in Fig. The stationary fixed object 20 extends in the height direction of the building along the longitudinal direction of the corner of the portion where the wall and the wall meet, and restrains the wall. On the other hand, the upper fixture 20 is configured to surround each wall in the longitudinal direction of each of the two walls abutting against each other. Therefore, the fixing fixture 20 has a cross-sectional shape of 'b'.

In addition, the fixing hardware 20 and the wall 1 are connected to each other by an anchor 30 passing through the fixing hardware. The adhesion force between the fixture 20 and the wall can be enhanced. Optionally, a separate chemical bonding means may be added between the fixture hardware 20 and the wall.

In the masonry wall, a horizontal joint 2 is formed between the brick and the brick, and the horizontal reinforcing bar 10 can be inserted into the horizontal joint. The horizontal reinforcing bars 10 can be horizontally embedded in the wall 1 and the wall 1, respectively, and one end thereof extends to the fixing metal member 20.

In summary, in the mooring earthquake-proof reinforcement method according to the present invention, a fixing steel piece extending in the longitudinal direction of the building between the masonry wall 1 and the wall 1 and having a cross- And an anchor 30 is inserted between the wall 1 and the fixing hardware 20 in order to strengthen the binding force between the walls 1 and 1 and the fixing hardware 20. The wall 1 and the wall 20, After the horizontal reinforcing bar 10 is inserted into each horizontal joint 2 of the fixing bracket 1, the horizontal reinforcing bar 10 is extended to the fixing steel bracket 20 to be restrained to the fixing bracket 20. As a result, it is possible to prevent or minimize the out-of-plane deformation of the wall without substantially changing the external shape of the existing building. Since the cross-sectional shape of the fixture can be freely selected as described below, deformation can be performed with various details, It is possible to actively cope with a change in the cross section of the member. In addition, the necessary reinforcement strength can be freely changed through adjustment of the horizontal reinforcement amount.

The horizontal reinforcing steel bar 10 may be straightly connected to the fixing steel member 20 as shown in FIGS. 3A and 3C, but may be curved as shown in FIGS. 3B and 3D. When the connecting portion between the horizontal reinforcing bar 10 and the fixing steel bracket 20 is curved as described above, the area of confinement with the outer wall 1 and the column 3 of the horizontal reinforcing bar 10 increases, The bonding strength of the joint portion can be increased by increasing the integral with the columnar body 1 or the column 3.

Also, as shown in FIG. 3A, the horizontal reinforcing bars 10 are installed on the outer walls which are generally in contact with each other, and the fixing hardware 20 also covers the outer wall 1 which is in contact with them, and thus has a "B" shaped cross section as described above. However, as in the reinforcement of the openings, if necessary, the horizontal reinforcing steel bars may be installed only on one of the outer walls and the fixing hardware may be mounted (see FIGS. 2 and 3). In addition, as shown in FIG. 3B, when reinforcing between one outer wall 1 and the column 3, in particular, reinforcement between the outer wall of the masonry tank and the concrete column 3, is required, tensile bars are already laid in the concrete column In addition, the horizontal rebar 10 may not be required, and the fixture may also be installed in only one direction. The reason for this is that the seismic retrofitting method of the present invention is intended to supplement the seismic performance of the masonry having low resistance to seismic force. In the cross section where the masonry and RC columns are joined, the RC columns will already exhibit seismic strengthening performance The horizontal reinforcing bar 10 is inserted into the outer wall 1 and the straight fixing steel piece 20 is arranged between the RC column 3 and the outer wall 1 and then the anchor 30 is used So that the fixture 20 and the RC column 3 are integrated. Particularly, in the case of such a cross section, the integral behavior of the connection between the RC column 3 and the outer wall 1 is important. As described above, the horizontal reinforcing bar 10 is curved at one end, The strength against the pullout force is improved and the strength of the joint between the RC column 3 and the outer wall 1 can be improved. Also in FIG. 3D, the fixing steel wire 21 is provided in a straight shape on the outer wall 1 of the opening portion. In this case also, since the horizontal reinforcing steel bar 10 is curved at one end, the behavior against the pulling force applied to the horizontal reinforcing steel bar 10 Can be excellent.

1, the outer wall of the masonry tank is provided with a heat insulating material 4 and an inner wall 5, and the horizontal reinforcing bar 10 is provided on the outer side of the heat insulating material 4 and the inner wall 5 And is installed in the outer wall (1).

As shown in FIG. 2, the seismic retrofitting method of the present invention can be applied to the openings of the mooring troughs. In the opening provided in the openings, a straight fixation iron (the left end of the opening in FIG. 2) Shaped fixture iron (the one end on the right side of the opening of Fig. 2). That is, an 'a' -shaped fixture can be used to wrap two cross-sections (X-directional members and Y-directional members) which basically meet with each other. However, in the case of reinforcing only one- Is used.

Construction order number fair Explanatory diagram One - Groove grooves
- Chipping of hardware fixture
- drill hole for anchor installation

2 - Surface dust removal
- Bond injection with line eye and anchor mounting part

3 - Horizontal Rebar Installation
- Installation of steel fixation anchor

4 - Installation of corners and openings
- Fusing part welded or bolted joint
Parallel construction with No. 3

5 - Finishing of wall reinforcement
- Fixed hardware finishing

Table 2 exemplifies the construction sequence of the non-reinforced mooring-resistant seismic strengthening method according to the present invention. It should be noted that the above serial numbers (1 to 5) represent an exemplary sequence and are not necessarily limited to the above sequence.

The step 1 is a preparation step in which the horizontally-reinforced steel bars 10 are grooved in the eye to be buried, chipping the hardware fixing part to be fixed, and holes for anchors to be inserted for easy anchoring . Next, in step 2, the horizontal reinforcing bar 10 and the anchors 30 and 31 are attached to the line eye and the anchor mounting part in an auxiliary manner so as to improve adhesion performance to the outer wall 1 and the fixing hardware 20 and 21, Of a chemical binder. Next, the step 3 is a step of installing the horizontal reinforcing bar and the anchor on the outer wall, and the anchor may be performed in parallel with the fourth step of installing the fixing hardware 20 and 21. Finally, the area where the horizontal reinforcing bars and fixing hardware are installed is finished with mortar or the like in order to make the appearance more beautiful.

An important consideration in securing the seismic performance of such a masonry building is to prevent conduction (out-of-plane deformation) of the wall, which is the most deadly in masonry. It is difficult to resist as a masonry wall that is vulnerable to bending stress (tensile force) by causing a force to act on the wall in the vertical direction, not in the direction of the wall, thereby causing rapid collapse of the whole building.

In order to prevent conduction of the wall, it is important to minimize the wall surface area and maximize the wall thickness, as well as to ensure the integrity of the walls and walls that meet with each other. In the present invention, by the fixing hardware 20, The integrity of the wall can be greatly improved. In addition, in the present invention, the anchoring fixture 30 can improve the adhesion performance of the fixture hardware 20, 21 between the wall and fixture hardware, which is more advantageous for preventing the wall from falling. In addition, in the present invention, the chemical bonding agent such as a bond is injected into the anchor mounting portion, so that the integrity between the wall-to-wall and the wall-to-fix can be further increased.

On the other hand, the opening in the masonry building is also vulnerable to the vertical load at the top, and when the lateral force is applied, a tilted crack is generated in the corner portion, which is gradually enlarged. However, according to the present invention, since the vertical fixing hardware 21 installed on the right and left sides of the opening can transmit the vertical load of the upper opening to the left and right wall surfaces and the lower side, it is possible to overcome the weakness of the seam tightness of the miter opening. In the same way, the enhancement of the integrity of the fixing fixture 21 and the miter openings greatly affects the reinforcing performance, and the fixing performance of the fixing hardware 21 is greatly increased by the anchor fixing portion 31.

In addition, according to the present invention, the fixation hardware 20 and 21 can be expected to have an improved integration with the mooring structure by the horizontal reinforcing bar 10 buried through the joint of the wall. As a result, the present invention can exhibit triple reinforcing performance.

While the present invention has been particularly shown and described with reference to certain preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It should be understood that various changes and modifications may be made by those skilled in the art. In addition, the accompanying drawings are shown not to scale but to partially enlarge and reduce in order to explain the technical idea of the present invention.

1: outer wall
10: Horizontal rebar
20, 21: Fixed hardware
30, 31: Anchor

Claims (7)

A step 1 of extending a horizontally reinforcing steel bar to an end of the outer wall on an outer wall of a building requiring earthquake-proof reinforcement,
A step 2 of setting a fixing metal material surrounding the outer wall on an end of the outer wall,
And fixing the fixing hardware and the outer wall with a fixing anchor,
Wherein the outer wall intersects with each other in two directions, and the fixing hardware is provided in a section where the outer walls cross each other,
Wherein the crossing two outer walls are a masonry and a reinforced concrete structure and the horizontal reinforcing bars are connected across the reinforcing concrete structure and the masonry so that the horizontal reinforcing bars are bent toward the fixing hardware at the ends of the reinforcing concrete structure So that the pulling strength of the horizontal reinforcing bars is improved. The method according to claim 1,
The building is a masonry building,
As a preparation step before the step 1,
A step 1-1 of grooving the horizontal reinforcement bars 10 to be buried in the outer wall,
A step 1-2 of chipping the position where the fixing hardware is installed,
The method according to any one of claims 1 to 3, further comprising a step (1-3) of anchoring the anchor holes to the outer wall to be inserted with the fixing anchor. 3. The method of claim 2,
A step of injecting a chemical bonding agent such as a bond into the line eye and the anchor hole so as to improve the adhesion performance between the horizontal reinforcing bar and the fixing anchor and the outer wall in the line eye portion and the gutter- 1 to 4; delete delete delete delete

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