KR20230100448A - Locking Device of One-touch Coupler for Connecting Reinforcing Rods - Google Patents

Abstract

The present invention relates to a reinforcing bar locking device of a one-touch coupler for reinforcing bar jointing that can secure the stability of a building by satisfying a residual strain of 0.3 mm or less. A plurality of coupler housings in which an inlet into which reinforcing bars are inserted is formed, a tapered portion having an inner diameter gradually increasing from the inlet toward the opposite side of the inlet, and a first screw thread formed on an inner circumferential surface or an outer circumferential surface of the other end; a joint member that is disposed between the plurality of coupler housings and has a second screw thread formed on an outer circumferential surface or an inner circumferential surface of both ends of the coupler housing and coupled with the first screw thread of the coupler housing to connect the plurality of coupler housings to each other; A plurality of locking grooves are inserted into the inside of the coupler housing, and the outer surface is formed inclined at an angle corresponding to the taper part of the coupler housing to be in close contact with the taper part, and a plurality of locking grooves supported while the nodes of the reinforcing bar are caught on the inner surface along the longitudinal direction A plurality of pyeonche arranged at regular intervals; And, a compression spring disposed between one end of the pyeonche and the joint member to elastically support the pyeonche with respect to the joint member; including, the locking groove of the pyeonche has a shape corresponding to the node of the reinforcing bar, and the node of the reinforcing bar It is characterized by being arranged at a 1/n pitch (where n is an integer of 2 or more) of the pitch (P ₀ ) of.

Description

Rebar locking device of one-touch coupler for rebar joint to minimize residual strain {Locking Device of One-touch Coupler for Connecting Reinforcing Rods}

The present invention relates to a one-touch coupler for joining reinforcing bars, and more particularly, by forming the shape of the grooves of the one-touch coupler body to match the shape of the nodes of the reinforcing bars by inserting and connecting both ends of the reinforcing bars to minimize the amount of residual strain. It relates to a rebar locking device for a one-touch coupler for rebar jointing.

The reinforcing bar joint refers to a case in which two reinforcing bars are connected and used because the length of the reinforcing bar is short.

One-touch coupler is a type of coupler that can firmly connect two reinforcing bars simply by simply inserting reinforcing bars into both ends of the coupler without processing the ends of the reinforcing bars. A typical one-touch coupler is composed of a housing, a body, a spring, a joint, etc., and when a tensile force is applied to both ends of the reinforcing bar, the unit is pulled along the inclined surface and fastened in the form of biting the reinforcing bar.

Therefore, since the one-touch coupler is a fastening method using the initial slip of the reinforcing bar, it is a fastening method in a form inevitably accompanied by residual deformation.

In the case of a one-touch coupler, it has excellent stability compared to a double joint and excellent workability compared to a screw-type coupler (easy to construct and drastically shorten the construction time). There are very big downsides.

When a large load such as an earthquake is applied to a building, it is difficult to secure the stability of the building due to such initial slip. In October 2020, in the "Quality Control Guidelines" of the Ministry of Land, Infrastructure and Transport, in the case of mechanical reinforcing bars, the regulations were amended to ensure that the residual strain is less than 0.3 mm.

Therefore, there is an urgent need to develop a one-touch coupler capable of suppressing the increase in residual strain due to initial slip while maintaining the advantages of the existing one-touch coupler.

For reference, the amount of residual strain refers to a constant load (90 to 95% of the yield point of the standard reinforcing bar standard) compared to the state in which no load is applied (initial state) after mechanical rebar jointing (screw-type coupler joint or one-touch coupler joint). It means the amount of deformation when the load is removed after being applied to it.

In general, structures such as buildings must return to their original state when a load is removed after an external load is applied.

In reinforcing bar joints, the deformation amount is measured after various tests such as low cycle fatigue test, static capacity test, high stress cyclic strength test, and high cycle fatigue test are performed, and the residual deformation amount is limited to 0.3mm (0.2mm for high cycle fatigue test). are doing

Korean Registered Patent No. 04622901 (registered on December 8, 2004) Korean Registered Patent No. 10-1003302 (registered on December 16, 2010)

An object of the present invention is to have high structural strength and excellent workability and at the same time satisfy the residual strain amount of 0.3 mm or less to secure the stability of the building. Reinforcing bars of one-touch coupler for reinforcing bar jointing that optimize the shape and spacing of the rebar restraints It is to provide a locking device.

In order to achieve the above object, the reinforcing bar locking device of the one-touch coupler for reinforcing bar jointing according to the present invention has an entrance into which reinforcing bars are inserted at one end, and a tapered portion whose inner diameter gradually increases from the entrance to the opposite side of the entrance is formed. a plurality of coupler housings having a first screw thread formed on an inner circumferential surface or an outer circumferential surface of the other end; a joint member that is disposed between the plurality of coupler housings and has a second screw thread formed on an outer circumferential surface or an inner circumferential surface of both ends of the coupler housing and coupled with the first screw thread of the coupler housing to connect the plurality of coupler housings to each other; A plurality of locking grooves are inserted into the inside of the coupler housing, and the outer surface is formed inclined at an angle corresponding to the taper part of the coupler housing to be in close contact with the taper part, and a plurality of locking grooves supported while the nodes of the reinforcing bar are caught on the inner surface along the longitudinal direction A plurality of pyeonche arranged at regular intervals; And, a compression spring disposed between one end of the pyeonche and the joint member to elastically support the pyeonche with respect to the joint member; including, the locking groove of the pyeonche has a shape corresponding to the node of the reinforcing bar, and the node of the reinforcing bar It is characterized by being arranged at a 1/n pitch of the pitch (where n is an integer of 2 or more).

The pyeonche may be made of a pair of two. In addition, the pyeonche may be composed of two or more.

Between the tapered portion of the coupler housing and the outer surface of the pair body, the guide protrusion and the guide protrusion are inserted and guided so that the pair can move only in the longitudinal direction without moving in the circumferential direction so that the guide groove extends along the longitudinal direction can be formed

The reinforcing bar locking device of the one-touch coupler for reinforcing bar jointing of the present invention protrudes between both ends of the two pieces on both sides of the tapered portion of the coupler housing, and the rib of the reinforcing bar can be accommodated between the two pieces while contacting both ends of the piece. At the same time as forming a space there may be a gap holding protrusion for preventing the body from being separated from the outside of the coupler housing.

In addition, as the rib of the reinforcing bar is inserted at a position corresponding to the gap maintaining protrusion in the inlet portion of the coupler housing, two positioning grooves for determining the insertion direction of the reinforcing bar may be formed spaced apart at an interval of 180 degrees.

When the nodes of the reinforcing bars are formed in a spiral shape, the locking groove formed in the pyeonche is formed in a spiral shape corresponding to the nodes of the reinforcing bars.

According to the present invention, the locking groove of the knitting body has a shape corresponding to the node of the reinforcing bar and is arranged at a 1/n pitch (where n is an integer of 2 or more) of the pitch of the node of the reinforcing bar. In this way, if the locking groove of the knitting body has a shape that matches the shape of the node of the reinforcing bar and is formed with a pitch of 1/n of the pitch of the node of the reinforcing bar, the node of the reinforcing bar is accurately inserted into the locking groove of the knitting body and fixed Even if strong tensile force is applied to the reinforcing bar, the occurrence of initial slip can be minimized and the residual strain can be maintained below 0.3mm.

1 is an exploded cross-sectional view showing a reinforcing bar locking device of a one-touch coupler for reinforcing bars according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the reinforcing bar locking device of the one-touch coupler for reinforcing bars shown in FIG.
3a and 3b are views showing the shapes of various reinforcing bars.
Figure 4 is a cross-sectional view showing the form of the unit body of the reinforcing bar locking device of the one-touch coupler for reinforcing bars shown in FIG.
Figure 5 is a perspective view showing the shape of the pyeonche shown in Figure 4;
6 is a cross-sectional view of a coupler housing of the one-touch coupler for reinforcing bars shown in FIG. 1;
7 is a front view of a coupler housing of the one-touch coupler for reinforcing bars shown in FIG. 1;

Referring to the accompanying drawings, a reinforcing bar locking device of a one-touch coupler for reinforcing bars for minimizing residual strain according to an embodiment of the present invention will be described in detail. Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention. Like reference numbers have been used for like elements throughout the description of each figure. In the accompanying drawings, the dimensions of the structures are shown enlarged than actual for clarity of the present invention, or reduced than actual in order to understand the schematic configuration.

Also, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. Meanwhile, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 to 7 show a one-touch coupler for rebar jointing according to an embodiment of the present invention, and the one-touch coupler for rebar joint connects two coupler housings 10 and two coupler housings 10 in a pair. The joint member 20, which is installed inside each coupler housing 10 and adheres to the outer surface of the reinforcing bar 1 inserted into the coupler housing 10 to firmly restrain the node 2 of the reinforcing bar 1 A compression spring 40 that is disposed between one end of the unit 30 and the joint member 20 of the two units 30 and elastically supports the unit 30 with respect to the joint member 20 include

The coupler housing 10 is made of a hollow cylindrical tube made of a high-strength metal material. At one end of the coupler housing 10, an inlet into which the reinforcing bar 1 is inserted is formed to be open to the outside, and a tapered portion 11 whose inner diameter gradually increases from the inlet to the opposite side of the inlet is formed, and the other end A first thread 12 for connection with the joint member 20 is formed on the inner or outer circumferential surface of the part. In this embodiment, the first screw thread 12 has a female screw structure formed on the inner circumferential surface of the rear end of the coupler housing 10, but may be formed in a male screw structure on the outer circumferential surface of the rear end of the coupler housing 10 differently.

In this embodiment, two coupler housings 10 are arranged symmetrically at 180 degrees with the joint member 20 interposed therebetween to connect the two reinforcing bars 1 in a straight line, but otherwise, the joint member 20 is ' It is in the form of + 'shape' or 'a' so that three or four coupler housings 10 may be simultaneously connected to one joint member 20 to connect three or four reinforcing bars 1 at the same time.

The joint member 20 has a substantially cylindrical or circular ring shape and is disposed between the plurality of coupler housings 10 . A second screw thread 22 helically coupled to the first screw thread 12 of the coupler housing 10 is formed on the outer or inner circumferential surface of both ends of the joint member 20 to connect the plurality of coupler housings 10 to each other. . That is, the coupler housing 10 is connected to the joint member 20 by screwing the first screw thread 12 of each coupler housing 10 to the second screw thread 22 of the joint member 20 .

The pyeonche 30 is located in the tapered portion 11 of the coupler housing 10 and serves to firmly restrain the node 2 of the reinforcing bar 1. To this end, the outer surface of the knit body 30 is formed inclined at an angle corresponding to the taper portion 11 of the coupler housing 10 and at the same time is curved in the circumferential direction to be in close contact with the tapered portion 11, and the reinforcing bar 1 on the inner surface ) A plurality of locking grooves 31 supported by the joint 2 are arranged at regular intervals along the longitudinal direction. Each piece of the pair body 30 is made of an approximately semi-conical shape so that the two members 30 correspond to the shape (approximately conical) of the tapered portion 11 of the coupler housing 10.

In this way, since the plurality of locking grooves 31 in which the nodes 2 of the reinforcing bars 1 are inserted and restrained are arranged along the longitudinal direction in the knit body 30, the reinforcing bars 1 are inside the coupler housing 10 In the inserted and restrained state, when tensile force is applied to the reinforcing bar 1 in the axial direction outward, the node 2 of the reinforcing bar 1 is caught in the locking groove 31 of the unit 30, and the unit 30 is coupled to the coupler housing It is pressed to the outside of (10). At this time, since the tapered portion 12 becomes narrower toward the outside in the axial direction, the members 30 act as a wedge, so that the reinforcing bar 1 does not fall out and almost from the inside of the coupler housing 10 It is immobile and firmly restrained.

The locking groove 31 of the knit body 30 has a shape corresponding to the node 2 of the reinforcing bar 1, and at the same time, the pitch of the locking groove 31 (P ₁ ) is the node 2 of the reinforcing bar 1 ) of a pitch (P ₀ ) of 1/n pitch (where n is an integer greater than or equal to 2, in this embodiment, 1/2 pitch). In this way, while the locking groove 31 of the knitting body 30 has a shape matching the shape of the node 2 of the reinforcing bar 1, the pitch of the node 2 of the reinforcing bar 1 (P ₀ ) When formed with a 1/n pitch, as shown in FIG. 2, the node 2 of the reinforcing bar 1 is accurately inserted into the locking groove 31 of the unit 30 to be in a fixed state, so the reinforcing bar 1 Even if a strong tensile force is applied to it, it is possible to minimize the occurrence of initial slip and keep the residual strain at 0.3 mm or less.

In the existing knitting body 30, the groove for restraining the node 2 of the reinforcing bar 1 is a simple triangular gear tooth or ratchet gear regardless of the shape and pitch of the node 2 of the reinforcing bar 1 Ratchet gear) has a structure in which irregularities in the form of gear teeth are arranged at regular intervals, and when a tensile force is applied to the reinforcing bar (1), the residual strain exceeds 0.3 mm due to the initial slip.

For reference, referring to Figures 3a and 3b, two ribs 3 are formed to extend along the longitudinal direction at 180 degree intervals on the outer surface of the reinforcing bar 1, and between each rib 3 in the transverse direction. A plurality of nodes 2 extending are arranged at a constant pitch (P ₀ ) along the longitudinal direction. Node 2 of the reinforcing bar 1 may have a protrusion extending along the circumferential direction as shown in FIG. 3A. At this time, as shown in (A) of FIG. 3A, the nodes 2 arranged on both sides of the two ribs 3 may be arranged in the same position, but as shown in (B) The nodes 2 arranged on both sides of the two ribs 3 may be arranged to have a phase difference by 1/2 pitch, that is, 1/2 pitch by each other.

Alternatively, as shown in FIG. 3B, the node 2 of the reinforcing bar 1 may be formed in a spiral shape. Of course, even when the node 2 is made of a spiral, the nodes 2 on both sides of the rib 3 may be arranged at the same position, but arranged to have a phase difference by 1/2 pitch (1/2 P ₀ ) It could be.

The locking groove 31 of the knit body 30 is the shape, size and pitch of the node 2 of the reinforcing bar 1 shown in FIGS. 3A and 3B, or the node of the known standard standard reinforcing bar 1 (2) It is formed in a shape and size corresponding to the shape and size, and the pitch (P ₁ ) of each locking groove 31 is 1/2 pitch of the pitch (P ₀ ) of the node 2 of the reinforcing bar (1) is formed with

As described above, the reason for arranging the intervals of the locking grooves 31 of the knitting body 30 at 1/2 pitch intervals of the nodes 2 of the reinforcing bars 1 is that shown in (B) of FIG. Even if the nodes 2 arranged on both sides of the reinforcing bar 1 are alternately arranged by 1/2 pitch, the nodes on both sides of the reinforcing bar 1 in the plurality of locking grooves 31 formed in the two members 30 This is so that (2) can be precisely engaged and restrained.

Guide projections 15 and guide grooves between the tapered portion 11 of the coupler housing 10 and the outer surface of the pair body 30 so that the pair body 30 can move only in the longitudinal direction without moving in the circumferential direction (32) is formed to extend along the longitudinal direction. The guide protrusion 15 is formed on the tapered portion 11 of the coupler housing 10, and the guide groove 32 may be formed on the outer surface of the pyeonche 30, but on the contrary, the guide protrusion 15 is the pyeonche ( 30) and the guide groove 32 may be formed on the tapered portion 11 of the coupler housing 10.

And when the reinforcing bar 1 is inserted into the coupler housing 10, the ribs 3 protruding in the longitudinal direction on both sides of the reinforcing bar 1 must enter between the two pieces 30 to the node of the reinforcing bar 1 ( 2) can be accurately engaged with the locking groove 31 of the unit body 30. To this end, both sides of the tapered portion 11 of the coupler housing 10 protrude between both ends of the two pieces 30, contact both ends of the piece 30, and between both ends of the two pieces 30. Two spacing protrusions 16 maintaining a distance of may be formed. Like the guide protrusion 15, the gap maintaining protrusion 16 is formed to extend a predetermined length along the longitudinal direction of the tapered portion 11. The two spacing protrusions 16 have a gap slightly larger than the width of the rib 3 of the two pieces 30 of the two pieces 30 while in contact with both ends of the piece 30 between the two pieces 30. Maintained to form a space in which the rib 3 of the reinforcing bar (1) can be accommodated between the two pyeonche (30). At the same time, the spacing protrusion 16 can prevent the pyeonche 30 from flowing down through the inlet of the coupler housing 10 and exposing one end of the pyeonche 30 to the outside.

In addition, when the node 2 of the reinforcing bar 1 is inserted between the two members 30, the rib 3 of the reinforcing bar 1 is It is desirable to accurately enter between both ends of the dog's knit body 30 . Therefore, as shown in FIG. 7, two positioning grooves 17 guided while the rib 3 of the reinforcing bar 1 are inserted around the inlet of the coupler housing 10 can be formed at 180 degree intervals. . The positioning groove 17 is formed at a position corresponding to the space holding protrusion 16 disposed between both ends of the two pyeonche 30, respectively.

Therefore, when the worker inserts the end of the reinforcing bar 1 by matching it to the outside of the inlet side of the coupler housing 10, the rib 3 of the reinforcing bar 1 is placed in the positioning groove 17 exposed to the outside of the coupler housing 10. ) By inserting according to the end, the rib 3 of the reinforcing bar 1 accurately enters between both ends of the knitting body 30, and the node 2 of the reinforcing bar 1 engages with the locking groove 31 of the knitting body 30 be able to

Instead of the positioning groove 17, a specific mark indicating the insertion direction of the reinforcing bar 1 may be displayed on the inlet side of the coupler housing 10.

The compression spring 40 is disposed between the pyeonche 30 and the joint member 20, one end is supported on one end of the pyeonche 30 and the other end is supported by the joint member 20 to the joint member 20 For the piece body 30, elastic force is applied to the outside in the longitudinal direction so that the piece body 30 can maintain a state in close contact with the tapered portion 11 of the coupler housing 10. The compression spring 40 may be configured by applying a coil spring that provides elastic force in the direction opposite to the compression direction during compression and deformation, but may also be configured by applying a known leaf spring.

The one-touch coupler for rebar joint made of this configuration works as follows.

When the positioning groove 17 formed at one end (inlet) of the coupler housing 10 is aligned with the rib 3 of the reinforcing bar 1 and the reinforcing bar 1 is inserted, the nodes 2 of the reinforcing bar 1 While in contact with the locking grooves 31 of the knitting body 30, it enters while pressing the knitting body 30 in the moving direction of the reinforcing bar 1. At this time, since the tapered portion 11 of the coupler housing 10 widens toward the inside in the longitudinal direction, the piece body 30 moves toward the joint member 20 while compressing the compression spring 40, so that the reinforcing bar 1 naturally It can be inserted into the inside of the coupler housing 10.

At this time, the guide groove 32 formed on the outer surface of the pyeonche 30 moves a predetermined distance only in the longitudinal direction while being guided by the guide protrusion 15 of the coupler housing 10.

When the reinforcing bar 1 is inserted into the joint member 20, the connection between the reinforcing bar and the coupler housing 10 is completed. At this time, when the operator removes the force pushing the reinforcing bar 1, the members 30 are pushed toward the inlet of the coupler housing 10 again by the strong elastic force of the compression spring 40, and are in close contact with the tapered portion 11, The node 2 of the reinforcing bar 1 is inserted into the locking groove 31 of (30) and coupled while being engaged. Accordingly, while the inner surface of the knit body 30 is in close contact with the outer surface of the reinforcing bar 1, the wedge action strongly constrains the reinforcing bar 1.

In this way, when a strong tensile force is applied to the reinforcing bar 1 in a state where the reinforcing bar 1 is constrained to the coupler housing 10 by the knitting body 30, the node 2 of the reinforcing bar 1 is of the knitting body 30 Since it is inserted into the locking groove 31 and is in a restrained state, initial slip hardly occurs, and therefore, the residual strain can be maintained at 0.3 mm or less, so that the stability of the building can be secured. That is, since the locking groove 31 of the knitting body 30 has almost the same shape as the node 2 of the reinforcing bar 1, when an external force is applied to the reinforcing bar 1 in the longitudinal direction, the node 2 of the reinforcing bar 1 ) Since the locking groove 31 of the unit body 30 is completely caught and constrained, it is possible to minimize the initial slip.

In addition, between the tapered portion 11 of the coupler housing 10 and the outer surface of the pair body 30, the guide protrusion 15 and the guide groove 32 allow the pair body 30 to move only in the longitudinal direction without moving in the circumferential direction ) Is formed to extend along the longitudinal direction, and protrudes between both ends of the two members 30 on both sides of the tapered portion 11 of the coupler housing 10, while contacting both ends of the body 30, the two Since two spacing protrusions 16 are formed to maintain a distance between both ends of the pair body 30, the coupling between the pair body 30 and the reinforcing bar 1 when connecting the reinforcing bar 1 by inserting it into the coupler housing 10 Accuracy can be improved.

At this time, when the positioning groove 17 guided while the rib 3 of the reinforcing bar 1 is inserted between both ends of the two members 30 is formed on the inlet side of the coupler housing 10, the reinforcing bar 1 ) It is possible to further improve the coupling accuracy between the pyeonche 30 and the reinforcing bar (1) when connected by inserting into the coupler housing (10).

In the above, the present invention has been described in detail with reference to the examples, but those skilled in the art to which the present invention belongs will be able to make various substitutions, additions, and modifications without departing from the technical idea described above. Of course, it should be understood that such modified embodiments also belong to the protection scope of the present invention, which is defined by the appended claims below.

1: rebar 2: node
3: rib 10: coupler housing
11: taper part 12: first screw thread
15: guide protrusion 16: spacing maintenance protrusion
17: positioning groove 20: joint member
22: second screw thread 30: knitting body
31: locking home 32: guide home
40: compression spring

Claims (6)

An inlet into which reinforcing bars are inserted is formed at one end, a tapered portion 11 whose inner diameter gradually increases from the inlet to the opposite side of the inlet, and a first screw thread 12 is formed on the inner or outer circumferential surface of the other end. A plurality of coupler housings 10 and;
It is disposed between the plurality of coupler housings 10, and a second screw thread 22 helically coupled with the first screw thread 12 of the coupler housing 10 is formed on the outer circumferential surface or the inner circumferential surface of both ends, so that the plurality of coupler housings Joint member 20 connecting the (10) to each other;
It is inserted into the inside of the coupler housing 10, and the outer surface is formed inclined at an angle corresponding to the taper part 11 of the coupler housing 10 to be in close contact with the taper part 11, and the reinforcing bar 1 on the inner surface A plurality of knitting bodies 30 in which a plurality of locking grooves 31 supported by the nodes 2 of the are arranged at regular intervals along the longitudinal direction; and,
A compression spring 40 disposed between one end of the unit body 30 and the joint member 20 to elastically support the unit unit 30 with respect to the joint member 20;
including,
The locking groove 31 of the knit body 30 has a shape corresponding to the node 2 of the reinforcing bar 1, and the pitch of the node 2 of the reinforcing bar 1 (P ₀ ) 1/n Rebar locking device of one-touch coupler for rebar joint, characterized in that arranged in pitch (where n is an integer of 2 or more). According to claim 1, Rebar locking device of a one-touch coupler for rebar joint in which two pieces (30) are paired. According to claim 2, between the tapered portion 11 of the coupler housing 10 and the outer surface of the pyeonche 30 guide protrusions so that the pyeonche 30 can move only in the longitudinal direction without moving in the circumferential direction and a reinforcing bar locking device of a one-touch coupler for reinforcing bars, in which guide grooves into which guide protrusions are inserted and guided are extended along the longitudinal direction. According to claim 2, both sides of the tapered portion 11 of the coupler housing 10 protrudes between both ends of the two pieces 30, while contacting both ends of the pieces 30, the two pieces 30 The reinforcing bar further comprises a spacing protrusion 16 for forming a space in which the rib 3 of the reinforcing bar 1 can be accommodated and preventing the unit 30 from escaping to the outside of the coupler housing 10. Rebar locking device of one-touch coupler for splice. The method of claim 4, wherein the rib 3 of the reinforcing bar 1 is inserted at a position corresponding to the spacing maintaining protrusion 16 at the inlet of the coupler housing 10 to determine the insertion direction of the reinforcing bar 1 A reinforcing bar locking device of a one-touch coupler for reinforcing bars in which two positioning grooves 17 are formed to be spaced apart at 180 degree intervals. According to claim 2, when the node (2) of the reinforcing bar (1) is formed in a spiral, the locking groove (31) formed in the pyeonche (30) is formed in a spiral corresponding to the node (2) of the reinforcing bar (1) Rebar locking device of one-touch coupler for rebar joint.

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