KR20140137598A - Seismic retrofit method for reinforcing partition wall of mansory - Google Patents

Abstract

The present invention provides a seismic retrofit method for the partition wall of a masonry tank, which reinforces the partition wall of masonry tank, using a linear reinforcing member, an end connection unit, and a throttle connection unit. According to an embodiment of the present invention, the method comprises the steps of processing a base surface by removing paint applied on the surface of the partition wall of a masonry to be reinforced and roughly processing the surface; installing end connection units in the beam and the slab of the partition wall of a masonry tank respectively and then coupling an end coupler to each end connection unit; installing the linear reinforcing member by screw-combining linear member couplers to both ends of the linear reinforcing member respectively and then connecting the end couplers and the linear member couplers to fixing sockets; and placing non-shrink mortar or concrete so that the linear reinforcing member can be completely embedded into and integrated with the partition wall.

Description

{Seismic retrofit method for reinforced partition wall of mansory}

The present invention relates to a seismic strengthening method for a masonry partition wall, and more particularly, to a seismic strengthening method of a masonry partition wall reinforcing a masonry partition wall using a reinforcing linear member, an end connecting means and a throat connecting means.

The reinforced concrete structure has a structure in which the space is horizontally divided through the slab and the plane is vertically divided using the wall, based on the rament frame which is made of the column and the beam which are in contact with the beam. The slab is a cast concrete structure that is formed integrally with columns and beams when they are constructed. However, the wall is constructed by using a brick or concrete block during the construction of the frame after the completion of the frame, and usually functions as a partition wall separating the thread from the thread without supporting the load.

A slight gap is created between the wall and the column and between the beam and the beam, and the gap is filled with mortar. Therefore, the partition wall is not integrated with the frame, so it is very weak against the lateral force acting in the in-plane or out-of-plane direction. Therefore, if an earthquake occurs, the casualty damage in the building is very likely to be caused by conduction or collapse of the masonry partition wall.

As a background art of the present invention, Korean Patent Registration No. 10-1027393 discloses a bidirectional and unidirectional anti-seize wall seismic reinforcement method in which a plurality of eye bolt through holes and wire rope through holes are formed on the upper surface of a slab of a building located on both sides of a bottom wall The upper fixture steel material corresponding to the position of the lower fixture hardware installed on the slab is disposed on the slab formed on the upper end of the masonry wall or in the direction of extension of the masonry wall on the side of the masonry wall The eye bolts are inserted into the eye bolt through holes of the upper fixing hardware and the lower fixing hardware provided respectively in the slab and the beam, and the eye bolts are connected to each other by using wire ropes. Thereby restricting the masonry wall in the transverse direction, and the upper fixing iron and the lower fixing iron The wire is alternately up and down the rope through hole presenting a two-way jojeokbyeok seismic strengthening method comprising the step of longitudinally constrain the wire rope as jojeokbyeok extension direction.

However, the above background art has a problem in that it is difficult to densely reinforce the wall walls and the wire rope is tensioned by using the eye bolts, which can not be used for connecting the deformed steel bar or deformed steel bar.

Korean Patent Registration No. 10-1079318

An object of the present invention is to provide a method of reinforcing seismic partitioning walls of a mooring compartment wall by reinforcing the mooring compartment wall by using reinforcing linear members, end connecting means and throat connecting means.

According to a preferred embodiment of the present invention,

A base surface treatment step of peeling the paint applied to the surface of the mosaic partition wall to be reinforced and roughening the surface;

A step of installing end connectors on the beams and slabs of the masonry partition walls to be reinforced and fastening the end couplers to the respective end connectors;

Attaching a linear member coupler to both end portions of the reinforcing linear member and connecting the end portion coupler and the linear member coupler to the fixed socket to install the reinforcing linear member;

Casting the shrink-free mortar or concrete so that the reinforcing linear member is completely embedded and integrally formed with the partition wall.

The method further includes the steps of: locating and intersecting the intersecting axes intersecting the reinforcing linear members located on the inner and outer sides of the mooring compartment wall to selectively form the wall holes;

Inserting a male coupler and a male coupler of a rotatizing coupler into a wall hole,

And a female flange cover plate and a water-side flange cover plate are installed on the male coupler and the male coupler, respectively, to grip the reinforcing linear member.

In addition, the male coupler and the male coupler are joined together by a coupling between a shoulder formed on the inner surface of the cylindrical coupling portion having the slit and the engagement groove formed in the engagement pin, thereby preventing separation and preventing mutual rotation.

According to the seismic strengthening method of the masonry partition wall of the present invention, the reinforcing linear member provided on the masonry partition wall can be joined before and after the wall through the rotatating coupler as the throttling connecting means. Also, the reinforcement linear member can be installed in a tense manner through the fixed socket, which is the end connecting means, and the coupler of each function, so that the strength of the mooring compartment wall can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view of the mooring compartment wall at the base stage in accordance with the invention; Fig.
Fig. 2A is a front view showing a state in which an end connecting unit and a reinforcing linear member are installed on a mooring partition wall according to the present invention; Fig.
Figure 2b is a cross-sectional side view of Figure 2a.
FIG. 3A is an installation perspective view of an end connecting unit according to the present invention; FIG.
3B is an exploded perspective view of the end connecting unit according to the present invention.
3C is an exploded sectional view of Fig. 3B. Fig.
4A is a view showing an installation state of a throttle joint unit applied to the present invention.
Fig. 4B is an assembled state of the throttle joint unit applied to the present invention. Fig.
5A is an exploded front view of a throttle joint unit applied to the present invention.
FIG. 5B is an exploded perspective view of a throttle joint unit applied to the present invention; FIG.
FIGS. 6 and 7 are various reinforced constructional views of a masonry partition wall to which a thrust fastening unit according to the present invention is applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

First, as shown in Fig. 1, there is a surface treatment step of peeling the paint applied to the surface of the masonry tank partition wall 1 and roughening the surface.

Next, as shown in Figs. 2 and 3, the beam 4 of the mooring bulkhead 1 to be reinforced and the respective end joints 10 included in the end connecting unit are installed in the slab 2, The end coupler 12 is fastened.

As shown in FIGS. 3B and 3C, the end connector 10 is formed in a cylindrical shape with a predetermined depth of a female screw 10a at one end of its inner circumferential surface. The end coupler 12 functions to connect the fixed socket 16 to be described later to the end connector 10. The end coupler 12 has an annular groove 12a which is inserted into the coupler coupling hole 161 of the fixed socket 16 at one end and is coupled to the groove jaw 162 at its one end, And a male screw 12b coupled to the male screw 10a.

The linear member coupler 13 is screwed to both ends of the reinforcing linear member 14 and then the end member coupler 12 and the linear member coupler 13 are connected to the fixed socket 16, The linear member 14 is installed as shown in Fig.

The linear member coupler 13 has an annular groove 13a which is inserted into the coupler coupling hole 161 of the fixed socket 16 at one end and is coupled to the groove jaw 162 at one end and has a reinforcing linear member 14 A screw hole 13b is formed to be engaged with the male screw on the end side of the screw hole 13b.

The fixed socket 16 is connected to the end connector 10 via an end coupler 12 to maintain the linear member 14 at a constant angle. The fixed socket 16 has a structure in which it is split and assembled into a pair. The fixed socket 16 includes a pair of split bodies 16a and 16a having a semicircular coupler engagement hole 161 formed in each of the three directions and one or more semicircular groove 162 formed in each coupler engagement hole 161 . Therefore, the coupler coupling holes 161 are formed at three places. One coupler coupling hole 161 is used for coupling with the end coupler 12 and the remaining two coupler coupling holes 161 are used for coupling with the linear member coupler 13. [ The coupler coupling hole 161 used for coupling with the end coupler 12 is formed in a vertical direction and two coupler coupling holes 161 connected to the linear member coupler 13 are connected to the reinforcing linear member 14, As shown in FIG.

At this time, the pair of split bodies 16a and 16a can be assembled and disassembled by screwing the bolts 17 and the nuts 18 inserted into the fastening holes 163.

Then, shrink-free mortar or concrete is laid so that the reinforcing linear members 14 are completely embedded and integrated with the partition wall 1.

In the meantime, the present invention further includes a step of locating an intersecting axis where the reinforcing linear member 14 located on the inner and outer sides of the mooring partition wall 1 intersects with the mooring partition wall 1 and selectively drilling to form the wall hole 1a . This is done before the reinforcement linear member 14 is installed.

Then, the female coupler 30a and the male coupler 30b of the rotatable coupler 30, which are throttling connecting units, are inserted into the wall hole 1a and are coupled to each other as shown in Fig.

5A and 5B, the female coupler 30a includes a cylindrical insertion portion 311a at the center thereof, a cylindrical coupling portion 311 having a slit 311b opened at a predetermined interval and a predetermined depth from the distal end thereof at regular intervals on the outer peripheral surface thereof, A locking protrusion 312 formed on the inner circumferential surface of the insertion hole 311a of the coupling portion 311 and a semicircular hole 313a formed at the end of the cylindrical coupling portion 311 in the direction perpendicular to the longitudinal direction of the cylindrical coupling portion 311 And has a female flange 313. And a female flange cover plate 314 having the same shape as the female flange 313 and bolted to the female flange 313.

Therefore, the outer diameter of the section corresponding to the length of the slit 311b can be forcibly extended by the male coupler 30b by the slit 311b. At this time, the latching jaw 312 is positioned within the section where the slit 311b exists. The radius of the semicircular hole 313a is configured to be the same as the radius of the reinforcing linear member 14. [

The male coupler 30b includes an engaging pin 321 rotatably inserted into the cylindrical engaging portion 311 and an engaging pin 321 formed on the outer circumferential surface of the engaging pin 321 to be engaged with the engaging protrusion 312 of the female coupler 30a An engagement groove 322 for inhibiting the reverse movement of the engagement pin 321 and a water side flange 323 formed at the rear end of the engagement pin 321 and having a semicircular hole 323a in a direction perpendicular to the longitudinal direction of the engagement pin. Further, a water-side flange cover plate 324 having the same shape as the water-side flange 323 and bolt-connected to the water-side flange is provided.

At this time, the outer diameter of the coupling pin 321 is equal to or slightly smaller than the inner diameter of the inlet hole 311a of the female coupler 30a.

6, the reinforcing linear member 14 may be arranged diagonally or vertically as shown in FIG. 7 by using the male coupler 30a and the male coupler 30b of the rotating coupling 30 described above, The present construction method can be applied.

As described above, according to the present invention, the reinforcing linear member 14 provided on the masonry partitioning wall 1 can be joined before and after the wall through the rotatable coupler 30, which is a throttling connecting means. Also, the reinforcement linear member can be installed in a tense manner through the fixed socket 16, which is the end connecting means, and the coupler of each function, thereby enhancing the strength of the mooring compartment wall.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: end connector
12: End coupler
14: Linear member for reinforcement
30: Rotating coupler
30a: female coupler
30b: Coupler

Claims (3)

A base surface treatment step of peeling the paint applied to the surface of the mosaic partition wall 1 to be reinforced and roughening the surface;
Installing end connectors 10 on the beams and slabs of the masonry bulkhead 1 and fastening the end couplers 12 to the end connectors 10;
The linear member coupler 13 is screwed to both ends of the reinforcing linear member 14 and then the end member coupler 12 and the linear member coupler 13 are connected to the fixed socket 16, 14);
Pouring the non-shrinkable mortar or concrete so that the reinforcing linear member (14) is completely embedded and integrated with the partition wall (1). The method according to claim 1,
Locating and intersecting the crossing axis intersecting the reinforcing linear member located on the inner and outer sides of the mason room partition wall (1) to selectively form the wall hole (1a);
Inserting the male coupler (30a) and the male coupler (30b) of the rotating coupling (30) into the wall hole (1a) and connecting them;
Further comprising a step of holding the reinforcing linear member (14) by providing the female flange cover plate (314) and the water side flange cover plate (324) to the male coupler (30a) and the male coupler (30b) Seismic strengthening method of masonry partition wall. 3. The method of claim 2,
The male coupler 30a and the male coupler 30b are joined by a coupling between a shoulder 312 formed on the inner surface of the cylindrical coupling portion 311 having the slit 311b and a coupling groove 322 formed in the coupling pin 321 To prevent separation and mutual rotation of the masonry partition wall.

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