KR102614885B1 - Close adherence and fixed type rebar coupler - Google Patents

Abstract

The present invention relates to a rebar coupler in which the end of the rebar for joint connection or joining and the coupler are integrated by being tightly fixed without slipping, so that stress can be clearly transmitted without distortion. The sleeve has an internal inclined surface. It consists of a plurality of wedges that are inserted into the sleeve and hold the reinforcing bar, and a deformation ring in which one part is cut to form a deformation gap, and the deformation ring is pushed a certain distance by the pressure of the rebar and its outer diameter becomes smaller. It is characterized in that it is fixed to the inside of the sleeve and is configured to prevent movement of the reinforcing bar in close contact with it.

Description

Closely fixed rebar coupler {CLOSE ADHERENCE AND FIXED TYPE REBAR COUPLER}

The present invention relates to a rebar coupler for splicing two rebars or joining rebars to steel materials. More specifically, the end of the rebar for splicing or joining the coupler is integrated by being tightly fixed without slipping, thereby reducing stress. This is about a rebar coupler that allows information to be transmitted clearly without distortion.

Reinforcing bars in RC structures or SRC structures are installed in various lengths and shapes, but the lengths are inevitably limited for the convenience of manufacturing, transportation, and assembly work. Therefore, in order to manufacture pre-assembled reinforcing bars or assemble reinforcing bars in the field, the work of connecting the reinforcing bars is inevitably required.

In addition, when it is desired to strongly connect a reinforced concrete beam to a steel column, it is necessary to connect the end of the reinforcing bar embedded in the reinforced concrete beam to the flange of the steel column.

Methods for splicing or joining such reinforcing bars include a method using a tie wire, a method using welding, and a mechanical method using a coupler, but the latter mechanical method is receiving the most attention due to its speed and convenience in operation.

On the other hand, reinforcing bars connected to joints or reinforcing bars joined to a steel frame must maintain a stable fixed state against tensile, compressive, or bending forces applied to them.

For example, compressive force acts on reinforcing bars used as vertical reinforcing bars in reinforced concrete columns. However, if there is a gap between the reinforcing bar and the coupler, which is the connection part of the joint, slipping occurs between them, causing the problem that the length of the vertical reinforcing bar is reduced.

To solve this problem, the inventor of this application proposed a plastic deformation-inducing rebar connector under registration number 10-2341669.

As shown in FIG. 1, the plastic deformation-induced rebar connector allows the wedge 200 to be inserted into the inside of the sleeve 42 unit 100, and the sleeve 42 unit 100 is inside. It is provided with a fastening space 110 and a deformation space 120, and the sleeve 42 enters the fastening space 110 from the outside of the unit 100 using a screw fastening method and presses the reinforcing bar 400 to form the sleeve. (42) A wedge 200 that is fixed to the unit 100 and is provided with a transverse rib 42 groove 210 on the inner surface for accommodating the transverse ribs 42 and 420 formed on the outer surface of the reinforcing bar 400. is installed in the deformation space 120 to suppress the entry of the reinforcing bar 400 entering along the wedge 200 while being deformed in the longitudinal direction, so that the entry distance of the reinforcing bar 400 is greater than the entry distance of the wedge 200. A deformable inductor 300 is installed to shorten the distance, and the deformable inductor 300 includes a support part 310 having an outer diameter corresponding to the inner diameter of the deformable space part 120, and both sides of the support part 310. It is characterized in that it consists of a plastic deformation portion 320 that protrudes vertically from at least one of the surfaces.

Accordingly, when the wedge 200 surrounding the reinforcing bar 400 is inserted into the fastening space 110 of the sleeve 42 unit 100 and rotated in a screw fastening manner and entered forward, the end of the reinforcing bar 400 is When the strain inducer 300 comes into contact with the plastically deformed portion 320, and the strain inducer 300 comes into contact with the opposite reinforcing bar 400 to which the joint is to be connected located at the rear, the reinforcing bar 400 in contact with the plastically deformed portion 320 is no longer able to enter and stops. At this time, if the wedge 200 is rotated more strongly, plastic deformation occurs in the plastic deformation portion 320 and the overall length of the deformable body 300 is reduced, and the reduced length This allows additional wedges (200) and reinforcing bars (400) to enter. When the plastic deformation of the strain derivative 300 is sufficiently achieved, the ends of the wedge 200 come into close contact with the transverse ribs 42 and 420 of both reinforcing bars 400, thereby exerting a compressive force on the joint connection as described above. Even so, the reinforcing bar 400 is prevented from moving downward.

However, since the deformation of the plastic deformation portion 320 requires very strong force, there is a problem in that it is not easy for workers to cause the deformation only by hand in the field.

KR 10-2341669 B1

The present invention is intended to solve the problems of the prior art described above, and it is possible to easily form a means to prevent the jointed reinforcing bar from moving in the longitudinal direction at the splice connection even with a small force, thereby changing the overall length of the splice-connected reinforcing bar. The purpose is to provide a tightly fixed rebar coupler that can easily connect vertical rebar joints in the field and improve work efficiency.

According to the most preferred embodiment of the present invention for the above-described problem, the rebar coupler according to the present invention includes a sleeve having an inclined inner surface therein, a plurality of wedges that are inserted into the sleeve and grip the rebar, and one part of the rebar coupler according to the present invention. It consists of a deformation ring that is cut to form a deformation gap, and the deformation ring is pushed a certain distance by the pressure of the reinforcing bar, reduces its outer diameter, and is then fixed to the inside of the sleeve to prevent the movement of the rebar in close contact with it. A sliding surface having the same inclination angle as the inclined inner surface may be formed at the inner end of the inclined inner surface.

The sleeve may be configured as a two-way sleeve in which reinforcing bars are inserted in both directions, or may be configured as a one-way sleeve in which reinforcing bars are inserted in only one direction.

The sleeve may be configured as an integrated piece, or the inner sleeve and the outer sleeve may be assembled by screw fastening. At this time, the inner sleeve and the outer sleeve are each configured one by one, and each of them may be provided with an inclined inner surface, or it may be composed of a pair of inner sleeves and one outer sleeve.

When the inner sleeve and the outer sleeve are composed of one each, each of them is provided with an inclined inner surface, and each inclined inner surface may be configured in a symmetrical structure in which the inner diameter becomes smaller around the center of the sleeve, and the inner sleeve and the outer sleeve are screwed. Although it is a structure assembled by a fastening method, the inclined inner surfaces provided on each of these inner sleeves and outer sleeves can be configured as an asymmetrical structure in which the inner diameters of the assembled sleeves become smaller toward the outer end of the outer sleeve.

In the case of an electronically symmetrical assembly structure, a pressurized female screw is provided on the inner surface of each slope provided in the inner sleeve and the outer sleeve, and the outer surface of the wedge fastened to this is provided with a pressurized male screw fastened to the pressurized female screw, and the outer sleeve A fastening female screw may be provided on the inner surface of the side that is not provided with an inclined inner surface, and a fastening male screw may be provided on the outer surface of the inner sleeve fastened to it.

In the case of the latter asymmetric structure and assembly structure, a pressurizing female screw is provided on the inclined inner surface of the outer sleeve, and a fastening female screw is provided on the inner surface of the outer sleeve on the side that is not provided with an inclined inner surface, and is fastened to the outer surface of the inner sleeve to which it is fastened. While providing male threads, the pressurizing female threads and fastening female threads of the outer sleeve can be configured to have the same pitch. In addition, a push step may be provided at the inner end of the inner sleeve to press the reinforcing bar located in the outer sleeve, and a pressure spring capable of pressing the wedge may be further installed on the inclined inner surface of the outer sleeve.

The present invention can easily induce a change in the outer diameter of the deformation ring with a small force, so that workers can easily induce deformation of the deformation ring to prevent rebar movement at the joint connection area with only manual work in the field, and has a structure that is assembled with inner and outer sleeves. In the case of , the assembly of the inner and outer sleeves and the wedge fastening inside the outer sleeve are carried out simultaneously by rotating either the rebar or the inner and outer sleeve, thereby improving the precision and efficiency of the rebar joint connection work.

In addition, the present invention provides a rebar coupler for economical rebar joint connection work by reducing the unit cost for manufacturing the rebar movement because the means for preventing rebar movement is very simple.

Figure 1 is an explanatory diagram of the operation of a plastic deformation-inducing rebar connector according to the prior art.
Figure 2 is a perspective view and cross-sectional view of the sleeve of a rebar coupler according to the first embodiment of the present invention.
Figure 3 is a perspective view and cross-sectional view of the structure of the wedge and deformation ring of the present invention.
Figure 4 is an explanatory diagram of the operation of the deformation ring.
Figure 5 is a perspective view and a cross-sectional view of a modified example of the sleeve of the rebar coupler of the first embodiment.
Figure 6 is an explanatory diagram of each step of joint connection of reinforcing bars using the reinforcing bar coupler of the first embodiment.
Figure 7 is a perspective view and cross-sectional view of the sleeve of the rebar coupler according to the second embodiment of the present invention.
Figure 8 is a perspective view and a cross-sectional view of a modified example of the sleeve of the rebar coupler of the second embodiment.
Figure 9 is an explanatory diagram of each step of an example of a method for jointly connecting reinforcing bars using the reinforcing bar coupler of the second embodiment.
Figure 10 is a perspective view and cross-sectional view of the sleeve of the rebar coupler according to the third embodiment of the present invention.
Figure 11 is an explanatory diagram of each step of an example of a method of jointing reinforcing bars using the reinforcing bar coupler of the third embodiment.
Figure 12 is a perspective view and cross-sectional view of a modification of the outer sleeve and wedge in the third embodiment.
FIG. 13 is an explanatory diagram of each step of an example of a method of connecting reinforcing bars using a reinforcing bar fastener according to a modified example of FIG. 12.
Figure 14 is a diagram showing the connection state of each joint in the example where the pressure spring is installed on the outer sleeve in the third embodiment.
Figure 15 is a perspective view of a rebar coupler according to a fourth embodiment of the present invention.
Figure 16 is a conceptual diagram of the method for jointly connecting reinforcing bars according to the fourth embodiment.
Figure 17 is a perspective view and a cross-sectional view of each modification of the inner sleeve in the third and fourth embodiments.
Figure 18 is a perspective view and cross-sectional view of the sleeve of the rebar coupler according to the fifth embodiment of the present invention.
Figure 19 is an explanatory diagram of each step of an example of a method of jointing reinforcing bars using the reinforcing bar coupler of the fifth embodiment.
Figure 20 is a perspective view and a cross-sectional view of a modification of the sleeve of the rebar coupler of the fifth embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. However, when explaining the present invention in detail, if the technical idea of the present invention is obscured or unclear, the description of the known configuration will be omitted.

The present invention has a structure of a rebar coupler used when connecting two rebars 40 or joining rebars 40 to steel. The rebar coupler of the present invention includes a sleeve 10 and a plurality of wedges 20 that are inserted into the sleeve 10 and hold the rebar 40 to be jointed on the principle of a wedge, and the wedges 20 are formed through deformation. and a deformation ring (30) that prevents unnecessary movement of the reinforcing bar (40) held by it.

This rebar coupler of the present invention has various embodiments depending on the structural shape of the sleeve 10, Figures 2 to 6 relate to the first embodiment, Figures 7 to 9 relate to the second embodiment, Figure 10 Figures 15 to 14 relate to the third embodiment, Figures 15 and 16 relate to the fourth embodiment, Figures 17 relate to modifications of the inner sleeve 10A of the third and fourth embodiments, and Figures 18 to 20 relate to the fifth embodiment. Each example is shown in detail. Among them, the first to fourth embodiments consist of a two-way sleeve in which the reinforcing bar 40 is inserted in both directions, and the fifth embodiment consists of a one-way sleeve in which the reinforcing bar 40 is inserted in only one direction.

As shown in FIG. 2, the reinforcing bar coupler of the first embodiment is composed of an integrated sleeve 10, and an opening through which reinforcing bars 40 can be inserted in both directions is formed, so that two reinforcing bars 40 can be jointed. It has a structure.

An inclined inner surface 16 inclined in one direction is formed inside the opening of the sleeve 10. Therefore, the inclined inner surfaces 16 are formed on both sides of the center of the sleeve 10. The inclined angles θ may be formed so that each of these inclined inner surfaces 16 has the same direction, but in this embodiment, It has a symmetrical structure in which the inner diameter becomes smaller around the center of the sleeve 10.

In addition, a plurality of wedges 20 are closely fastened to the inclined inner surface 16. Depending on the external shape of the wedge 20, it may be composed of a smooth surface without curves or may be composed of a pressurized female screw 19 with a threaded body. there is.

In this embodiment, a pressurized female screw 19 is formed on the inclined inner surface 16. Therefore, as shown in (a) of FIG. 3, the outer surface of the wedge 20 has a pressurized male screw 21 that is screwed to the pressurized female screw 19, and an O-ring groove to bind the plurality of wedges 20 into one. (23) is provided. Additionally, the inner surface of the wedge 20 is provided with joint grooves 22 and 22 into which the joints 41 of the reinforcing bars 40 are inserted.

The deformation ring 30 shown in (b) of FIG. 3 is configured so that a deformation gap 31 is formed by cutting a portion, and is located in front of the end of the reinforcing bar 40 held by the wedge 20. It is placed so that it can slide inside the sleeve 10.

Figure 4 is an explanatory diagram of the operation of the deformation ring 30, which will be described with reference to the following.

First, the deformation ring 30 is inserted into the sleeve 10, and the end of the reinforcing bar 40 to be jointed is wrapped with a plurality of wedges 20, and then the O-ring 24 is inserted into the O-ring groove 23. The wedge 20 is fixed to (40) {(a) in Figure 4}.

Next, the reinforcing bar 40 is rotated or the sleeve 10 is reversely rotated to move the wedge 20 toward the center of the sleeve 10 using a screw fastening method. At this time, the node groove 22 provided in the wedge 20 is formed larger than the node 41 of the reinforcing bar 40 inserted therein, and the integrated rotation of the wedge 20 and the reinforcing bar 40 is performed by a plurality of wedges (20). ) This is achieved by the ribs 42 of the reinforcing bars 40 inserted into the gap formed between the reinforcing bars 40. Even if the wedge 20 is rotated by the reinforcing bars 40, the reinforcing bars 40 are maintained at nodal grooves 22 up to some sections. ) and the node 41 remains capable of moving forward and backward as much as the distance (△ ₁ ,△ ₂ ) {(b) in Figure 4}.

Movement of the wedge 20 in the direction in which the inner diameter of the sleeve 10 becomes smaller increases the gripping force of the wedge 20 with respect to the reinforcing bar 40 and also increases the friction force between the inclined inner surface 16 and the outer surface of the wedge 20. As the wedge 20 increases, the movement of the wedge 20 becomes increasingly difficult, and at the final movement completion stage of the wedge 20, the joint 41 of the reinforcing bar 40 is brought into close contact with the front of the joint groove 22 of the wedge 20. There is no choice but to rotate by pushing (40). Accordingly, the degree to which the reinforcing bar 40 advances becomes greater than the degree to which the wedge 20 advances, and at this time, the reinforcing bar 40 presses the deformation ring 30 in contact with its end surface. As a result, the deformation ring 30 is pushed a certain distance along the inside of the sleeve 10, where the inner diameter gradually narrows, and the deformation gap 31 is removed to reduce the outer diameter, and then is fixed inside the sleeve 10. The closely adhered reinforcing bar (40) is prevented from moving any further {(c) in Figure 4}.

Accordingly, the reinforcing bar 40 held by the wedge 20 is completely prevented from moving due to its own weight or when an external shock occurs, so that the length of the jointed reinforcing bar 40 can be maintained constant.

To facilitate the sliding movement of the deformation ring 30, a sliding surface 17 having the same inclination angle θ as the inclined inner surface 16 may be formed at the inner end of the inclined inner surface 16. The sliding surface 17 is composed of a smooth surface structure with no bends in the direction of movement of the deformable ring 30, so that the outer diameter is reduced by the movement of the deformable ring 30 by the pressure of the reinforcing bar 40 and the deformation gap 31. Facilitates transformation.

Accordingly, in this embodiment, the sliding surface 17 is formed symmetrically on both sides with respect to the center of the sleeve 10. At this time, as shown in FIG. 5, the inner end of each sliding surface 17 has a sleeve 10. ) A flat surface 18 parallel to the longitudinal center line may be further formed.

The above-described details regarding the configuration of the sliding surface 17 and the flat surface 18 also apply to the remaining embodiments described later.

FIG. 6 is a cross-sectional view illustrating each step in the process of joining two reinforcing bars 40 using a reinforcing bar coupler to which the sleeve 10 according to the above-described first embodiment is applied. When the fixing work of the reinforcing bar 40 on one side of the sleeve 10 is completed as already described with reference to FIG. 4, the fixing work of the reinforcing bar 40 on the other side is performed in the same manner, thereby securing the reinforcing bar 40 on both sides. Complete the joint connection work.

As shown in FIG. 7, the second embodiment is different from the first embodiment in that the sleeve 10 has a structure completed by assembling the inner sleeve 10A and the outer sleeve 10B by screwing. There is a difference.

For example, each inclined inner surface 16 of the inner sleeve 10A and the outer sleeve 10B is provided with a pressure female screw 19, and the outer surface of the wedge 20 fastened to this is fastened to the pressure female screw 19. A pressurized male screw 21 is provided, and a fastening female screw 15 is provided on the inner surface of the outer sleeve 10B that is not provided with the inclined inner surface 16, and on the outer surface of the inner sleeve 10A fastened to this. A fastening male screw 11 is provided, and these fastening male screws 11 and female fastening screws 15 are assembled by a screw fastening method to form one sleeve 10.

However, since it has a two-way sleeve structure in which the reinforcing bar 40 is inserted in both directions, the deformation ring 30 is pushed out by the pressure of the reinforcing bar 40, and the outer diameter is reduced and fixed inside the slab, thereby causing unnecessary movement of the reinforcing bar 40. There is no difference from the first embodiment in that this can be prevented.

In addition, each of the inner sleeve 10A and the outer sleeve 10B is provided with an inclined inner surface 16, and each inclined inner surface 16 has a symmetrical structure in which the inner diameter becomes smaller around the center of the sleeve 10. In this respect, it is not different from the first embodiment, and a sliding surface 17 having the same inclination angle θ as the inclined inner surface 16 can be formed at each inner end thereof, and in addition, a flat surface 18 can be formed. That this can be done has already been described above. Figure 8 shows a case where the sliding surface 17 and the flat surface 18 of the second embodiment are formed together.

However, in the case of the second embodiment, there is another advantage in that the joint connection work method of the reinforcing bar 40 can be performed in various ways depending on the field situation.

For example, the inner sleeve 10A and the outer sleeve 10B may be first assembled to complete one sleeve 10, and then the joint connection work of the reinforcing bars 40 may be performed in the same manner as in the first embodiment. However, in Figure 9 As shown, after completing the fixing of the reinforcing bars 40 to be jointed to each of the inner sleeve 10A and the outer sleeve 10B in the manner described with reference to FIG. 4 {(a) and (b) of FIG. 9} , the joint connection work of the reinforcing bars 40 can be performed by assembling the inner sleeve 10A and the outer sleeve 10B by screwing them (Figure 9 (c), (d)).

In the third embodiment of the present invention, one sleeve 10 is completed by assembling the inner sleeve 10A with fastening male screws 11 on the outer surface and the outer sleeve 10B with fastening female screws 15 on the inner surface. In that it is no different from the second embodiment described above.

However, in the third embodiment, the inclined inner surface 16 provided on the inner sleeve 10A and the outer sleeve 10B is directed toward the outer end of the outer sleeve 10B among the assembled sleeves 10, that is, the outer sleeve 10B ) has an asymmetric structure in which the inner diameter becomes smaller in the direction in which the opening where the reinforcing bar 40 is inserted is located.

In addition, the inner end of the inner sleeve 10A, that is, the end in the direction in which it is assembled to the outer sleeve 10B, is provided with a push step 12 that presses the reinforcing bar 40 located in the outer sleeve 10B. It prevents the reinforcing bar 40 inserted into the sleeve 10B from moving toward the inner sleeve 10A. Accordingly, in the outer sleeve 10B, unlike in the inner sleeve 10A, there is no room for the deformation ring 30 to be used.

In addition, in the third embodiment, as shown in FIG. 10, a pressurizing female screw 19 is provided on the inclined inner surface 16 of the outer sleeve 10B, and the outer sleeve on the side not provided with the inclined inner surface 16 ( A fastening female screw (15) is provided on the inner surface of 10B). Of course, the outer surface of the inner sleeve 10A fastened to the outer sleeve 10B is provided with a fastening male screw 11 to be screwed with the female fastening screw 15.

At this time, if the pressing female screw 19 and the fastening female screw 15 of the outer sleeve 10B are configured at the same pitch, the degree of movement of the inner sleeve 10A according to one rotation of the outer sleeve 10B is the push step 12. ), the degree to which the reinforcing bar 40 on the outer sleeve 10B moves is equal to ) can be completed at the same time. Figure 11 shows a cross-sectional explanation of each step in the process of joining two reinforcing bars 40 using this fastening method.

First, for the inner sleeve 10A, the end of one reinforcing bar 40 to be jointed is fixed using the deformation ring 30 (Figure 11 (a)). This is no different from the method already described above with reference to FIG. 4.

When the fixation of the end of the reinforcing bar 40 to the inner sleeve 10A is completed, the wedge 20 holding the end of another reinforcing bar 40 is inserted into the portion where the fastening female screw 15 of the outer sleeve 10B is formed. do. At this time, it is desirable to allow the wedge 20 to be partially engaged with the pressurized female screw 19 of the inclined inner surface 16 having a wide inner diameter so that the wedge 20 can be stably positioned inside the outer sleeve 10B. When insertion of the wedge 20 into the outer sleeve 10B is completed, push the inner sleeve 10A, which fixed the end of the reinforcing bar 40 in the previous step, while partially engaging the fastening female screw 15 of the outer sleeve 10B. The step 12 is brought into close contact with the end surface of another reinforcing bar 40 held by the wedge 20 of the outer sleeve 10B (Figure 11 (b)).

Once the push step (12) is in close contact with the end surface of the reinforcing bar (40) located in the outer sleeve (10B), the outer sleeve (10B) is rotated to fasten the inner sleeve (10A) and the outer sleeve (10B). Fastening between the inclined inner surface 16 of the sleeve 10B and the wedge 20 is performed simultaneously (Figure 11 (c)).

The working method of connecting the reinforcing bar 40 of FIG. 11 described above was explained by taking the case where the fastening female screw 15 is provided on the inclined inner surface 16 of the outer sleeve 10B as an example, but as shown in FIG. 12, The same applies even when the inclined inner surface 16 of the sleeve 10B and the outer surface of the wedge 20 are composed of only bare surfaces without threads. Figure 13 shows a method of connecting the reinforcing bars 40 when the inclined inner surface 16 of the outer sleeve 10B and the outer surface of the wedge 20 are composed of only bare surfaces without threads.

A pressure spring 25 may be further installed on the inclined inner surface 16 of the outer sleeve 10B. The pressing spring 25 presses the wedge 20 inserted inside the outer sleeve 10B forward to prevent the reinforcing bar 40 held by it from being pushed backward.

Figure 14 shows the state in which the joint connection of the reinforcing bars 40 is completed while being pressed by the pressure spring 25 as described above. As shown in each detail of FIG. 14, the end surface of the reinforcing bar 40 located in the outer sleeve 10B is in close contact with the rear end of the joint groove 22 of the wedge 20. It is in close contact with the push step 12 of the inner sleeve 10A and cannot move in any direction forward or backward.

Figures 15 and 16 each show a fourth embodiment of the present invention, Figure 15 is a perspective view thereof, and Figure 16 is a conceptual diagram of a method of connecting reinforcing bars using the reinforcing bar coupler of the fourth embodiment.

The sleeve 10 of the rebar coupler according to the fourth embodiment is constructed by assembling a pair of inner sleeves 10A and an outer sleeve 10B connecting the pair of inner sleeves 10A by screw fastening. Accordingly, each of the pair of inner sleeves 10A is provided with an inclined inner surface 16, but the inner surface of the outer sleeve 10B is screwed with the fastening screw 11 provided on the pair of inner sleeves 10A. Only the fastening female screw (15) is provided and the inclined inner surface (16) is not provided.

In the case of the fourth embodiment configured as described above, the reinforcing bars 40 to be jointed are respectively fixed to each of the pair of inner sleeves 10A in the manner described with reference to FIG. 4, and then the outer sleeve 10B is rotated to secure its joints. A pair of inner sleeves (10A) are fastened on both sides to ensure unity.

Meanwhile, the outer surface of the inner sleeve 10A shown in (a) of FIG. 10 is provided with a stepped locking step 13 between the part provided with the fastening screw 11 and the gripping part 14 with a bare surface. The degree of fastening of the inner sleeve 10A to the sleeve 10B is limited, but as shown in FIG. 17, the stopping step 13 is not provided, so the outer diameter of the grip portion 14 is that of the fastening screw 11. By configuring the inner sleeve (10A) so that it is not larger than the outer diameter based on the thread, or by configuring the fastening screws (11) on the entire outer surface, the degree of fastening of the inner sleeve (10A) to the outer sleeve (10B) can be increased as needed. You can also go deeper.

18 to 20 show the fifth embodiment having a one-way sleeve structure in which the reinforcing bar 40 is inserted in only one direction.

The reinforcing bar coupler of the fifth embodiment is mainly used when connecting reinforcing bars 40 to steel members 50 such as steel frames or steel plates, and the inclined inner surface 16 formed inside the sleeve 10 is the steel material. It has a structure in which the inner diameter gradually decreases toward the direction in which it is joined to the member 50. In addition, as described above, a sliding surface 17 having the same inclination angle θ as the inclined inner surface 16 may be formed at the inner end of the inclined inner surface 16. In addition, a welding groove (w) may be further provided on the outer surface of one end to facilitate joining the steel member 50.

Figure 19 shows the process of joining the reinforcing bar 40 to the steel member 50 using the reinforcing bar coupler of the fifth embodiment. First, the sleeve 10 is joined to the steel member 50 and then placed inside the sleeve 10. After inserting the deformation ring 30, the reinforcing bar 40 held by the wedge 20 is rotated so that the reinforcing bar 40 is fixed to the sleeve 10. The fixing of the sleeve 10 of the reinforcing bar 40 is no different from what was previously described in relation to FIG. 4.

The sleeve 10 in the fifth embodiment may have the shape shown in FIG. 20 depending on usage conditions.

In the above, the present invention has been described in detail with reference to specific embodiments, but the embodiments are merely examples to make the present invention easier to understand, so those skilled in the art will understand the scope of the technical idea of the present invention. It is obvious that this can be implemented with various modifications. Accordingly, such modifications will be said to fall within the scope of the present invention as set forth in the claims.

10: Sleeve 10A; my sleeve
10B; Outer sleeve 11; fastening screw
12; Milmeumdanteok 13; step
14; Grasp 15; Fastening female screw
16; slope 17; sliding surface
18; flat surface 19; Pressurized female thread
20; wedge 21; Pressurized male screw
22; Madihom 23; O-ring groove
24; O-ring 25; pressure spring
30; deformation ring 31; Deformation gap
40; rebar 41; word
42; rib 50; Steel members

Claims (13)

In the rebar coupler for connecting two rebars 40 or joining rebars 40 to steel,
A sleeve 10 having an inclined inner surface 16 on the inside, a plurality of wedges 20 that are inserted into the sleeve 10 and grip the reinforcing bar 40, and a deformation gap 31 formed by cutting one part thereof. It consists of the formed deformation ring 30,
The deformation ring 30 is pushed a certain distance by the pressure of the reinforcing bar 40 and its outer diameter becomes smaller, and then is fixed to the inside of the sleeve 10 to prevent the movement of the reinforcing bar 40 in close contact with it,
The sleeve 10 is a two-way sleeve in which reinforcing bars 40 are inserted in both directions, and the inner sleeve 10A and the outer sleeve 10B are assembled by screwing, and the inner sleeve 10A and the outer sleeve ( 10B) is each provided with an inclined inner surface 16, and each inclined inner surface 16 has an asymmetric structure in which the inner diameter becomes smaller in the direction of the outer end of the outer sleeve 10B among the assembled sleeves 10. Fixed rebar coupler. delete delete delete According to paragraph 1,
The inner sleeve 10A and the outer sleeve 10B are each provided with an inclined inner surface 16, and each inclined inner surface 16 has a symmetrical structure in which the inner diameter becomes smaller around the center of the sleeve 10. Closely fixed rebar coupler. According to paragraph 1,
The inner sleeve 10A and the outer sleeve 10B are each provided with an inclined inner surface 16, each of the inclined inner surfaces 16 is provided with a pressurized female screw 19, and the outer surface of the wedge 20 fastened to this is provided with an inclined inner surface 16. A pressurized male screw (21) is provided that is fastened to the pressurized female screw (19),
A fastening female screw 15 is provided on the inner surface of the outer sleeve 10B that is not provided with the inclined inner surface 16, and a fastening male screw 11 is provided on the outer surface of the inner sleeve 10A fastened thereto. Closely fixed rebar coupler. delete According to paragraph 1,
The inclined inner surface 16 of the outer sleeve 10B is provided with a pressing female screw 19, and the inner surface of the outer sleeve 10B on the side not provided with the inclined inner surface 16 is provided with a fastening female screw 15, A fastening screw 11 is provided on the outer surface of the inner sleeve 10A fastened to this,
A tightly fixed rebar coupler, characterized in that the pressurizing female screw (19) and the fastening female screw (15) of the outer sleeve (10B) are made of the same pitch. According to paragraph 1,
A tightly fixed rebar coupler, characterized in that the inner end of the inner sleeve (10A) is provided with a push step (12) that presses the rebar (40) located in the outer sleeve (10B). According to paragraph 1,
A tightly fixed rebar coupler, characterized in that a pressure spring (25) is installed on the inclined inner surface (16) of the outer sleeve (10B). According to paragraph 1,
The sleeve 10 is a tightly fixed rebar coupler, characterized in that a pair of inner sleeves 10A and an outer sleeve 10B connecting the pair of inner sleeves 10A are assembled in a screw fastening manner. . According to paragraph 1,
A tightly fixed rebar coupler, characterized in that a sliding surface (17) having the same inclination angle (θ) as the inclined inner surface (16) is formed at the inner end of the inclined inner surface (16). delete

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