KR20210128158A - Rebar connector without eccentricity - Google Patents

Abstract

The present invention relates to a reinforcing bar connector without eccentricity which couples both sides of wing plates of a first and a second fixture each consisting of a reinforcing bar accommodation unit accommodating a reinforcing bar and wing plates on both ends thereof to transfer stress without eccentricity between connected reinforcing bars, absorb construction errors, and firmly connect reinforcing bars. The reinforcing bar connector without eccentricity is to connect a first reinforcing bar and a second reinforcing bar and comprises: a first fixture consisting of a reinforcing bar accommodation unit of a semicircular arc shape in which the first reinforcing bar is accommodated to be fixed and a pair of wing plates bent from both ends of the reinforcing bar accommodation unit; a second fixture provided on one end of the first fixture, and consisting of a reinforcing bar accommodation unit of a semicircular arc shape in which the second reinforcing bar is accommodated to be fixed and a pair of wing plates bent from both ends of the reinforcing bar accommodation unit; and a pair of coupling plates tightly attached to both sides of the wing plates of the first fixture and the wing plates of the second fixture to connect the wing plates to each other.

Description

Rebar connector without eccentricity

The present invention combines both sides of the wing plates of the first and second fixtures, each consisting of a reinforcing bar receiving part in which reinforcing bars are accommodated and wing plates at both ends, with a coupling plate, thereby allowing stress transmission without eccentricity between the reinforcing bars to be joined, while absorbing construction errors and It is about a non-eccentric reinforcing bar joint that can make a strong joint.

Rebar used in the construction of reinforced concrete structures has a length limitation due to problems such as transportation and loading. Therefore, the joint of reinforcing bars is essential.

Conventional reinforcing bar joint methods include overlap joint, pressure weld joint, mechanical joint, and the like.

Lap splice is to use the strength of adhesion with concrete to overlap the reinforcing bars to be joined for a certain length (Registration Patent No. 10-1039041). However, the overlap joint method has the lowest working precision and is applicable only to cast-in-place concrete. In addition, eccentricity of the reinforcing bars to be joined is inevitable, which is structurally disadvantageous.

Pressure welding is a joint method that melts and attaches reinforcing bars by applying heat by gas welding or arc welding, etc. in a state where the rebars to be joined are facing each other (Patent Publication No. 10-1999-0015019). However, the pressure welding method requires high working precision because the position of the reinforcing bars to be joined must exactly match. In addition, the reinforcing bar becomes brittle and deteriorates due to thermal effects during pressure welding. In addition, the pressure welding operation is greatly affected by the on-site environment such as weather and the skill level of the workers, so it is difficult to secure a homogeneous quality, and there is a risk of a fire accident due to the use of fire.

The mechanical joint is to mechanically connect the reinforcing bars to be joined by a coupler. However, the mechanical joint method is difficult to apply when the sizes of rebars to be joined are different, and if even a slight eccentricity occurs between rebars to be joined due to construction errors, it is difficult to couple the coupler.

In particular, in the case of forming a rebar cage by welding a plurality of reinforcing bars with a strip reinforcing bar at a factory, such as in the pre-fabricated Reinforced Concrete (PRC) method using reinforcing bars, the positions of the plurality of rebars are installed in a fixed state. It is not easy to fine-tune the position of the reinforcing bar, and when the rebar diameter is large, it is more difficult to fine-tune the rebar, so there is a limit to the connection by the coupler.

In order to solve the above problems, the present invention is to provide a non-eccentric reinforcing bar joint that can absorb construction errors while avoiding eccentricity between reinforcing bars to be joined during reinforcing bar splicing, and can be securely joined.

The present invention according to a preferred embodiment relates to a non-eccentric reinforcing bar joint for joining a first reinforcing bar and a second reinforcing bar. a first fixture composed of a pair of wing plates each bent; a second fixture provided at one end of the first fixture and comprising a semi-circular arc-shaped reinforcing bar accommodating portion in which the second reinforcing bar is accommodated and fixed and a pair of wing plates bent at both ends of the reinforcing bar accommodating portion; And a pair of coupling plates in close contact with both surfaces of the wing plate of the first fixture and the wing plate of the second fixture; It provides a non-eccentric reinforcing bar joint, characterized in that consisting of.

The present invention according to another preferred embodiment provides a non-eccentric reinforcing bar joint, characterized in that the coupling plate is fixed to the wing plate by a fixing bolt.

The present invention according to another preferred embodiment provides a non-eccentric reinforcing bar joint, characterized in that the fixing bolt is a high-strength bolt and the coupling plate and the wing plate are fixed to each other by friction bonding.

The present invention according to another preferred embodiment provides a non-eccentric reinforcing bar joint, characterized in that the reinforcing bar accommodating part is filled with a welding flesh and a plug welding slot for fixing the reinforcing bar to the reinforcing bar accommodating part is formed.

The present invention according to another preferred embodiment is characterized in that the junction part of the wing plate and the reinforcing bar receiving part is formed to be round in an arc shape, so that the weld meat is filled between the reinforcing bar outer circumferential surface and a flare welding groove for fixing the reinforcing bar to the reinforcing bar receiving part is formed. It provides a non-eccentric reinforcing bar joint.

According to the present invention as described above, there are the following effects.

First, by mutually coupling both sides of the wing plates of the first and second fixtures, each consisting of a reinforcing bar receiving part in which reinforcing bars are accommodated and wing plates at both ends, with a coupling plate, the reinforcing bars to be joined are located on the same axis so that stress can be transmitted without eccentricity. Non-eccentric reinforcing bar joints can be provided.

Second, since it is possible to manufacture a fixture composed of a reinforcing bar accommodating part and a wing plate only by bending the steel plate, manufacturing is simple and manufacturing cost can be reduced.

Third, the construction error can be absorbed by adjusting the size of the bolt fastening hole of the fixing bolt for combining the coupling plate and the wing plate. can be joined.

Fourth, if the first and second fixtures are respectively fixed to the ends of the first and second reinforcing bars before reinforcing reinforcement, the reinforcing bar joint can be completed quickly and simply simply by coupling the coupling plate to the wing plate.

1 is a perspective view showing an eccentric reinforcing bar joint of the present invention.
Fig. 2 is a perspective view showing an embodiment of a fixture;
3 and 4 is a view showing a reinforcing bar joint process using the present invention non-eccentric reinforcing bar joint.
Figure 5 is a perspective view showing a state in which the reinforcing bar is coupled to the fixture by plug welding.
Figure 6 is a perspective view showing a state in which the reinforcing bar is coupled to the fixture by flare welding.
7 is a cross-sectional view showing a state in which the reinforcing bar is coupled to the fixture by plug welding and flare welding.

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

1 is a perspective view showing the present invention non-eccentric reinforcing bar joint, Figure 2 is a perspective view showing an embodiment of the fixture, Figures 3 and 4 is a view showing a reinforcing bar joint process using the present invention non-eccentric reinforcing bar joint .

1 to 4, the non-eccentric reinforcing bar joint of the present invention is for joining the first reinforcing bar 1a and the second reinforcing bar 1b, and the first reinforcing bar 1a is accommodated and fixed in a semicircle. A first fixture (20a) comprising an arc-shaped reinforcing bar receiving portion (21a) and a pair of wing plates (22a) each bent at both ends of the reinforcing bar receiving portion (21a); It is provided at one end of the first fixture 20a and is bent at both ends of the semi-circular arc-shaped reinforcing bar accommodating part 21b and the reinforcing bar accommodating part 21b in which the second reinforcing bar 1b is accommodated and fixed, respectively. a second fixture 20b consisting of a pair of wing plates 22b; And a pair of coupling plates 23 in close contact with both surfaces of the wing plate 22a of the first fixture 20a and the wing plate 22b of the second fixture 20b; It is characterized in that it is composed of

The present invention absorbs construction errors while avoiding eccentricity between the first reinforcing bars 1a and the second reinforcing bars 1b to be joined when the first reinforcing bar 1a and the second reinforcing bar 1b are connected in the longitudinal direction, This is to provide a non-eccentric reinforcing bar joint that can be joined securely.

The present invention non-eccentric reinforcing bar joint (2) is a first fixture (20a) to which the first reinforcing bar (1a) is fixed, and a second fixture (20b) to which the second reinforcing bar (1b) is fixed, and the first fixture (20a) and the first fixture (20a) 2 It is composed of a coupling plate 23 interconnecting the fixture (20b).

The first fixture 20a and the second fixture 20b have the same shape.

The first fixture 20a and the second fixture 20b are a pair of wings integrally bent at both ends of the reinforcing bar accommodating parts 21a and 21b and the reinforcing bar accommodating parts 21a and 21b of the semi-circular arc shape, respectively. It is composed of plates 22a and 22b.

Hereinafter, the first reinforcing bar 1a and/or the second reinforcing bar 1b are referred to as reinforcing bars 1a and 1b, and the first fixture 20a and/or the second fixture 20b are referred to as fixtures 20a and 20b. decide to do

The reinforcing bar accommodating portions 21a and 21b are portions into which a part of the reinforcing bars 1a and 1b are inserted and accommodated, and the reinforcing bars 1a and 1b are rounded to a shape and size corresponding to the outer circumferential surface and can be bent into a semicircular arc shape. .

The reinforcing bars 1a and 1b may be fixed in the reinforcing bar accommodating portions 21a and 21b by welding.

The wing plates 22a and 22b are respectively bent at both ends of the reinforcing bar accommodating portions 21a and 21b to form a pair.

The wing plates 22a and 22b may be integrally formed with the reinforcing bar accommodating portions 21a and 21b.

That is, the first fixture (20a) and the second fixture (20b) can be formed integrally with the reinforcing bar accommodating parts (21a, 21b) and the wing plates (22a, 22b) by bending the center of the rectangular steel plate in a semi-circular arc shape. have.

Therefore, since the fasteners 20a and 20b can be manufactured only by bending the steel plate, the manufacturing is very simple and the manufacturing cost can be reduced.

The coupling plate 23 is in close contact with the wing plate 22a of the first fixture 20a and the wing plate 22b of the second fixture 20b, the first fixture 20a and the second fixture 20b interconnect

That is, the first fixture 20a and the second fixture 20b may be joined by connecting the wing plates 22a and 22b with the coupling plate 23 .

The stress of the reinforcing bars 1a and 1b is smoothly transferred through the coupling plate 23 connecting the first fixture 20a and the second fixture 20b.

Therefore, the same structural performance can be exhibited in tension and compression.

The coupling plate 23 is provided with a pair so that a pair of wing plates (22a, 22b) positioned at both ends of the reinforcing bar accommodating parts (21a, 21b) can be coupled, respectively.

In addition, the coupling plate 23 may be provided on both front and rear surfaces of each wing plate 22a and 22b so that eccentricity does not occur when stress is transmitted by the coupling plate 23 .

The first fixture 20a and the second fixture 20b are formed in the same shape.

Accordingly, the first fixture 20a and the second fixture 20b are fixed to the coupling plate 23, and the reinforcing bar receiving portions 21a and 21b are positioned on the same axis. Therefore, the first reinforcing bar 1a and the second reinforcing bar 1b to be joined can also be joined without eccentricity on the same axis.

A reinforcing bar splicing process using the non-eccentric reinforcing bar joint of the present invention will be described with reference to FIGS. 3 and 4 .

First, as shown in FIG. 3, the first fixture 20a and the second fixture 20b are the ends of the first reinforcing bar 1a and the second reinforcing bar 1b before each reinforcing bar 1a, 1b. It can be fixed to

After reinforcing the reinforcing bars 1a and 1b in a state in which the fixtures 20a and 20b are fixed, the coupling plate 23 is coupled to the first fixture 20a and the second fixture 20b as shown in FIG. The connection of the reinforcing bars 1a, 1b can be completed only by connecting them.

As shown in FIG. 4 , the coupling plate 23 may be fixed to the wing plates 22a and 22b by fixing bolts 24 .

The coupling plate 23 and the wing plates 22a and 22b may be coupled to each other by fixing bolts 24 .

To this end, bolt fastening holes 221 and 231 are formed at positions corresponding to each other in the wing plates 22a and 22b and the coupling plate 23, respectively.

In order to fasten the fixing bolt 24, the bolt fastening holes 221 and 231 formed in the wing plates 22a, 22b and the coupling plate 23 have manufacturing errors, fastening easiness, and the reinforcing bars 1a and 1b to be joined. It is preferable to form slightly larger than the diameter of the fixing bolt 24 in consideration of fine adjustment and the like.

Since the first reinforcing bar 1a and the second reinforcing bar 1b can be installed by fixing the first fixture 20a and the second fixture 20b in advance, respectively, when the reinforcing bars 1a and 1b are joined, the fixing bolts 24 ), the joint can be completed only by fastening.

Therefore, the reinforcing bar (1a, 1b) joint operation is very quick and simple.

The fixing bolt 24 may be configured such that the coupling plate 23 and the wing plates 22a and 22b are fixed to each other by friction bonding with a high-strength bolt.

Normal bolts transmit stress by acupressure between the bolt hole and the bolt. In this case, there is a possibility of shear failure of the bolt, and the stress concentration around the bolt is large, so it is vulnerable to cyclic stress. In addition, when the direction of stress is changed due to the clearance between the bolt fastening holes (221, 231) and the fixing bolt (24), confusion such as slip occurs between the wing plates (22a, 22b) and the coupling plate (23). can happen

Therefore, by using a high-strength bolt as the fixing bolt 24, the coupling plate 23 and the wing plate 22a, 22b can be mutually fixed by friction bonding of the high-force bolt.

The high-strength bolt transmits stress by friction generated between the coupling plate 23 and the wing plates 22a and 22b, which are joined using a strong tightening force. Therefore, loosening of the nut does not occur, the local stress concentration is small, so it is strong against repeated stresses, and the fatigue strength is high. In addition, even if the direction of the stress is changed, there is no confusion, so that the tensile force and the compressive force can be stably transmitted.

The high-strength bolt may use a TS bolt (Torque Shear Bolt) whose tip is shear-ruptured when a predetermined tightening force is reached so as to secure a constant tightening force.

5 is a perspective view showing a state in which the reinforcing bar is coupled to the fixture by plug welding.

As shown in FIG. 5, the reinforcing bar accommodating portions 21a and 21b are filled with welding flesh W, and a plug welding slot 211 for fixing the reinforcing bars 1a and 1b to the reinforcing bar accommodating portions 21a, 21b is provided. can be formed.

A plug welding slot 211 may be formed through the center of the reinforcing bar accommodating portions 21a and 21b in order to be able to fix the fixtures 20a and 20b to the ends of the reinforcing bars 1a and 1b connected to each other by welding, respectively. have.

Accordingly, the reinforcing bars 1a and 1b are inserted into the reinforcing bar accommodating portions 21a and 21b, and then the reinforcing bars 1a and 1b are brought into close contact with the inner peripheral surfaces of the reinforcing bar accommodating portions 21a and 21b. And by filling the welding flesh (W) in the plug welding slot (211) portion can be firmly fixed to the reinforcing bars (1a, 1b) to the reinforcing bar accommodating portions (21a, 21b).

The plug welding slot 211 is preferably formed in a long hole with a long length in the longitudinal direction of the reinforcing bars 1a and 1b to be joined, so as to secure a sufficient welding length.

Since a sufficient welding length can be secured by the plug welding as described above, the reinforcing bars 1a and 1b can be firmly fixed to the fixtures 20a and 20b.

6 is a perspective view showing a state in which the reinforcing bar is coupled to the fixture by flare welding, and FIG. 7 is a cross-sectional view showing the state in which the reinforcing bar is coupled to the fixture by plug welding and flare welding.

6 and 7, the junction of the wing plates 22a, 22b and the reinforcing bar accommodating portions 21a, 21b is formed to be round in an arc shape and welded between the outer peripheral surfaces of the reinforcing bars 1a, 1b. The flesh W is filled to form a flare welding groove 212 for fixing the reinforcing bars 1a and 1b to the reinforcing bar accommodating portions 21a and 21b.

In the case of manufacturing the fixtures 20a and 20b by bending the steel plate, the bent portion between the reinforcing bar accommodating portions 21a and 21b and the wing plates 22a and 22b can be formed to be round in an arc shape.

A flare welding groove 212, which is a constant space, is formed on both sides of the reinforcing bars 1a and 1b by the rounded bends in this way.

By using the flare welding groove 212 to fill the welding rib (W) in the flare welding groove 212, the reinforcing bar 1a, 1b by flare welding (Flare Groove Welding) reinforcing bar receiving portion (21a, 21b) ) can be fixed in

As shown in FIG. 7 , by combining plug welding and flare welding in some cases, the reinforcing bars 1a and 1b stress may be smoothly transferred to the fixtures 20a and 20b.

1a: 1st reinforcing bar
1b: second reinforcing bar
2: Non-eccentric rebar joint
20a: first fixture
20b: second fixture
21a, 21b: rebar receiving part
211: plug welding slot
212: flare welding groove
22a, 22b: wing plate
221: bolt fastener
23: coupling plate
231: bolt fastener
24: fixing bolt
W: Weld

Claims (5)

It relates to a non-eccentric reinforcing bar joint (2) for joining the first reinforcing bar (1a) and the second reinforcing bar (1b),
A first fixture comprising a semi-circular arc-shaped reinforcing bar accommodating portion 21a in which the first reinforcing bar 1a is accommodated and fixed, and a pair of wing plates 22a bent at both ends of the reinforcing bar accommodating portion 21a, respectively. (20a);
A semi-circular arc-shaped reinforcing bar accommodating part 21b provided at one end of the first fixture 20a and fixed to which the second reinforcing bar 1b is accommodated and bent at both ends of the reinforcing bar accommodating part 21b, respectively. a second fixture 20b consisting of a pair of wing plates 22b; and
A pair of coupling plates 23 in close contact with both surfaces of the wing plate 22a of the first fixture 20a and the wing plate 22b of the second fixture 20b; Non-eccentric reinforcing bar joint, characterized in that consisting of.
In claim 1,
The coupling plate 23 is a non-eccentric reinforcing bar joint, characterized in that it is fixed to the wing plate (22a, 22b) by a fixing bolt (24).
In claim 2,
The fixing bolt 24 is a non-eccentric reinforcement joint, characterized in that the coupling plate 23 and the wing plate (22a, 22b) are fixed to each other by friction bonding with a high-strength bolt.
In claim 1,
The reinforcing bar accommodating parts (21a, 21b) are filled with a welding rib (W) to form a plug welding slot 211 for fixing the reinforcing bars (1a, 1b) to the reinforcing bar accommodating parts (21a, 21b). Non-eccentricity, characterized in that rebar joint.
In claim 1,
The junction of the wing plate (22a, 22b) and the reinforcing bar accommodating parts (21a, 21b) is formed to be round in a circular arc shape, and the welding rib (W) is filled between the outer peripheral surfaces of the reinforcing bars (1a, 1b) to fill the reinforcing bars (1a, 1b). ) Non-eccentric reinforcing bar joint, characterized in that the flare welding groove 212 for fixing the reinforcing bar receiving portion (21a, 21b) is formed.

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