KR102386761B1 - a structure for rebar coupler - Google Patents

Abstract

The present invention relates to a rebar coupler structure, and more particularly, to a rebar coupler structure in which a coupler body is manufactured out of carbon nanotubes and body internal parts are manufactured using a non-metallic material such as plastic, so that the weight of a coupler used to connect reinforcing bars is dramatically reduced, and at the same time, the internal structure of the coupler is improved to easily change the size of the coupler when the diameter of reinforcing bars to be connected changes, and the internal parts are partially integrated to simplify assembly and disassembly of internal modules.

Description

Rebar coupler structure {a structure for rebar coupler}

The present invention relates to a reinforcing bar coupler structure, and more particularly, the coupler body is made of reinforced plastic or composite material including carbon nanotubes, and internal parts of the body are manufactured using a non-metallic material such as plastic to connect reinforcing bars. While remarkably reducing the weight of the coupler, the internal structure of the coupler is improved so that the same pyeonche holder method can be used even if the diameter of the reinforcing bar to be connected changes It relates to a simple reinforced coupler structure.

In general, reinforcing bars are a building material often used to reinforce the strength of concrete structures by being buried inside concrete when constructing reinforced concrete structures in the field of architecture or civil engineering. A large amount of reinforcing bars are placed and used in the foundation structure.

Since reinforcing bars are standardized and produced with a certain length, in the case of large buildings, special structures, and civil structures such as bridges, rebars produced with a limited length must be used by connecting them. Reinforcing bar connection methods that have been commonly used so far include methods such as double splicing, welding, screwing, and mechanical joining. Overlapping is a method of overlapping reinforcing bars to a predetermined length and tying them with wire or wire. Since reinforcing bars must be overlapped every time, the amount of reinforcing bars is large and the strength of the overlapping part is weak, so it is easily separated, and the workability is not good, so air is stretched. , the weld joint is cumbersome to construct and heats the weld, so the strength of the reinforcing bar around the weld is significantly weakened due to heat.

The mechanical joint is a method of connecting the end of the rebar to be connected with a coupler, and is divided into a screw type, a steel pipe compression type, a wedge type, a mortar filling type, etc. depending on the type. The strength of the connection part connected by the coupler has the advantage of being stable without being significantly affected by the skill or weather of the operator.

However, the screw-type coupler, which accounts for most of the mechanical joint, has no choice but to have a minute play between the threads, so it can be easily loosened by other than by repeated load. In addition, it is cumbersome to rotate the reinforcing bar after inserting it into the housing, and a dedicated equipment for forming the male thread on the reinforcing bar itself is required.

In order to solve the shortcomings of the screw type coupler, various types of wedge type couplers have been proposed. For example, Korean Patent Registration No. 10-1796538 discloses a coupler for reinforcement having a housing, a cover portion fixed to both ends of the housing, and a coupling portion that bites and fixes the housing that has entered the inside while installed inside the housing, there is.

However, the wedge-type coupler for reinforcing bars has a disadvantage that the assembly process is quite cumbersome in view of its structure. For example, in order to assemble the coupler, it is necessary to insert the coupling parts one by one between the guide members of the mount part, and carefully insert the mount part in a state where the coupling part is inserted into the cover part. At this time, the coupling part may be separated from the mount part. The assembly work requires a long time and careful hand movements. Considering that not only one or two couplers are used at the construction site, but hundreds or more, the above inconvenience acts as a factor that greatly reduces productivity.

In addition, as the material used for the housing (body) of the coupler or the internal elastic body structure, iron steel is used. Usually, the coupler has a weight of 1.3 kg to 1.5 kg, and the weight of this coupler is added to the weight of the reinforcing bar at the construction site. It is putting a lot of pressure on the workers.

In addition, reinforcing bars used in construction sites are manufactured in various sizes, so even when connecting rebars of similar size, for example, rebars with diameters of 27, 29, and 31mm, in the past, couplers of different sizes must be used according to each dimension. Therefore, there is a difficulty in having a coupler of various sizes to fit the dimensions of the reinforcing bar.

In addition, since the parts for bonding inside the body are made of steel, it is difficult to manufacture them in one piece, so when the parts are disassembled, it is difficult to simply reassemble and use them.

An object of the present invention is to compensate for the disadvantages of the conventional rebar coupler as described above, and to remarkably reduce the weight of the rebar coupler itself so that workers can make the coupling work more easily. Another object of the present invention is to reduce the cost of construction work by using a coupler made of a material of a cheaper material while having much higher strength than a steel material instead of using an expensive steel material for the coupler material. Another object of the present invention is to change the size of the coupler when the size of the reinforcing bars to be connected is different. At this time, the size of the coupler can be changed in a simple way, and the coupler body internal parts are partially made into a single unit to assemble or disassemble the coupler. It is to provide a simple reinforced coupler structure.

In order to achieve the above object, the reinforcing bar coupler structure according to an embodiment of the present invention is made of a reinforced plastic or composite material including carbon nanotubes as a material of the body of the coupler, The elastic body, the diaphragm, etc. are made of a plastic material so that the parts necessary for the coupling can be integrally connected. In addition, the pyeonche is made of a plurality of polygonal slices so that the size of the coupler can be easily changed by adjusting the number of the pyeonche holder and the pyeonche coupled thereto.

According to the present invention, it is possible to dramatically reduce the weight of the coupler by using all of the material of the coupler as a non-metal material, and it becomes possible to easily change the size of the coupler when the diameter of the reinforcing bar changes, saving material and processing time It can bring shortening of the coupling, and by integrating the parts inside the coupler body, there is an effect that the coupling operation becomes simple and easy.

1 is a perspective view showing an internal structure of a body portion in a coupler according to an embodiment of the present invention.
Figure 2 shows the internal module of the coupler formed inside the body portion.
Figure 3 shows the pyeonche and the pyeonche holder.
4 is a perspective view of the first and second rotation blocks.
Fig. 5 (1) shows a state in which the reinforcing bars are inserted and then combined, and Fig. 5 (2) is a view showing the changes in the internal module when a force is applied to the reinforcing bars.

Hereinafter, embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that in adding reference numerals to the components in each drawing, the same components are given the same reference numerals as much as possible even though they are indicated in different drawings. Also, in the description of the present embodiment, if it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present embodiment, the detailed description thereof will be omitted.

It will be understood that the operating method shown in the present invention has various embodiments as described below and may be implemented in a modified form without departing from the essential characteristics of the description. Therefore, the methods disclosed below should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than in the detailed description of the invention, and all differences within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Hereinafter, a reinforcing bar coupler structure according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing an internal structure of a coupler body according to an embodiment of the present invention. According to Figure 1, the coupler body part of the invention is divided into upper and lower bodies 16 and 18 with upper and lower openings 12 and 12' for accommodating the reinforcing bars when the reinforcing bars are coupled, and the entire body portion ( 10) is formed.

The upper and lower body portions 16 and 18 are formed in two regions, a tapered forming portion 13 and a vertical portion 14, and on the inner surface of the upper and lower body, a first rotation block ( 26) is formed with a rotation guide groove 19 for guiding while constraining the rotation of the first rotation block when it ascends and descends while rotating inside the body during the locking process.

The upper and lower bodies 16 and 18 constituting the body portion 10 of the present invention may be made of a reinforced plastic or composite material including carbon nanotubes. In one embodiment, the carbon used in the body portion Nanotubes have a tensile strength of about 70 times higher than that of steel, and have excellent properties such as high elasticity, low coefficient of thermal expansion, and resistance to friction and abrasion. Since it is only half of the steel material and the price is low, when carbon nanotubes are used as the coupler material, the weight and cost of the coupler itself can be reduced at the same time, thereby reducing the burden on the coupling operator.

Figure 2 shows the inner module 20 of the coupler formed inside the body portion 10. According to Figure 2, the inner module serves to hold the reinforcing bar at the time of coupling so that the reinforcing bar is not separated. The pyeonche 32 and the pyeonche 32 are inserted and the pyeonche holder 31 for fixing them and the reinforcing bar are connected in contact with the pyeonche holder 31 to enable locking and unlocking in the coupler, and a first rotation block 26 ) and the second rotation block 28 formed to be combed with the first rotation block 26 and the upper and lower two second rotation blocks 28 and 28', the elastic providing a restoring force to the rotation block It consists of a member (29).

Here, the pyeonche 22, pyeonche holder 24, and the first and second rotation blocks 26 and 28 may be formed of a reinforced plastic material, and the elastic member 29 is flexible to have an appropriate elastic force. A plastic material may be used.

The inner module 20 of the present invention can integrate the upper pyeonche holder 31 and the upper first rotation block 26 in order to improve the convenience of operation when assembling and disassembling components, and the upper second rotation block (28), the elastic member 29, and the three components of the lower second rotating block 28' can be integrated using various coupling methods, and the lower first rotating block 26' and the lower pyeonche holder 31 ') can also be formed integrally.

3 shows a pyeonche part 30 consisting of a pyeonche 32 for holding and fixing the reinforcing bars to be coupled in a coupler and a pyeonche holder 31 in which the pyeonche 32 is inserted and supported, the pyeonche 32 is The cross section has a trapezoidal shape and is in the form of a slice having a certain thickness, and a coupling end 34 is formed to fit into the pyeonche holder 31, and the pyeonche holder 31 is a donut-shaped bottom part 35 and the plurality of pyeonche holder 31. A slit groove 36 corresponding to the thickness of the pyeonche is formed in the upper part so that the pyeonche 32 is inserted to support the reinforcing bar.

Under the conventional coupler structure, the coupling part that holds the reinforcing bar is made of a four-part body with a conical shape, so if the diameter of the rebar to be worked is changed, the size of all parts including the housing must be changed to match the diameter. The process has to be cumbersome and wasteful since it must be newly manufactured to exactly match the diameter of the reinforcing bar that has changed.

However, the coupling structure according to the present invention uses several thin pyeonche 32 in the form of a section when trying to combine reinforcing bars of different standards in the working process. As long as the number of pyeonche is adjusted to match the number of newly knitted slit grooves, it is possible to easily prepare a suitable coupler even if the size of the reinforcing bar changes.

For example, when coupling a reinforcing bar having a diameter of 27mm, the number of slit grooves in the pyeonche holder 31 is 10 and the number of pyeonche 32 fitted therein is also 10, and the coupling work is performed, and a reinforcing bar having a diameter of 31mm is set to 10. In the case of coupling work with a 4mm diameter, the diameter of the pyeonche holder increases as the diameter increases, and a new size coupler can be prepared by simply adjusting the pyeonche part to fit the changed diameter through a simple process of increasing the number of slit grooves. there will be

The pyeonche 32 of the present invention has a trapezoidal shape as a whole, has a pyeonche end portion 33 and a pyeonche coupling portion 34, and has teeth formed on the surface in contact with the reinforcing bar, and the thickness t is 2~ It is preferable to set it as 3 mm.

Figure 4 shows the first and second rotation blocks 26 and 28, which are some components of the internal module of the coupler according to the present invention, wherein the first and second rotation blocks are a so-called 'tick structure' for reinforcing bar coupling and dismantling. The material is made of reinforced plastic, and in order to simplify the assembly and disassembly of the internal module 20, the first rotation block 26 includes the pyeonche holder 31 and the second rotation block 28 ) may be combined with the elastic member 29 as a single body or by a suitable coupling method, or the upper pyeonche holder 31, the first rotation block 26, the second rotation block 28, the elastic member (29), the second rotation block (28'), the first rotation block (26'), the lower pyeonche holder (31') by combining all these parts may be made into a single unit to form an internal module. This is not expected of a conventional coupler, in which all parts are made of steel.

Figure 5 shows a state in which the reinforcing bars are coupled after being inserted through the openings (12, 12') of the body. Fig. 5 (1) is a cross-sectional view showing a state in which two reinforcing bars are coupled through a coupler, and Fig. 5 (2) is a view showing changes in the internal module when a force is applied to the reinforcing bars. Hereinafter, a process in which the reinforcing bars are coupled will be described with reference to the drawings.

When the reinforcing bar is pushed through the openings 12 and 12' of the body, the end of the reinforcing bar and the pyeonche end 33 come into contact, and when the reinforcing bar is further pushed down, the end of the reinforcing bar is the tapered surface formed at the pyeonche end 33 As the pyeonche slides along and the pyeonche is pushed in the circumferential direction along the surface where the body is widened, the reinforcing bar is inserted into the circular space created by the pyeonche and descends until it reaches the first rotation block 24 .

When the descent is finished and the force acting on the reinforcing bar is released, the restoring force of the elastic member 29 is applied, and accordingly, the pyeonche shrinks to support the reinforcing bar when the pyeonche enters the inclined region of the body part while the reinforcing bar rises. The procedure ends.

10: body part
12, 12': opening
13: taper forming part
14: vertical part
16: upper body part
18: lower body part
19: rotation guide groove
20: internal module
26: first rotation block
28: second rotation block
29: elastic member
30: pyeonchebu
31: pyeonche holder
32: pyeonche
33: pyeonche end
34: pyeonche coupling part
35: circular bottom
36: slit groove
38: pyeonche coupled to the pyeonche holder
t: thickness of pyeonche

Claims (5)

In the reinforcing bar coupler structure consisting of a body part and an internal module located inside the body part,
The inner module includes a pyeonche portion comprising a plurality of pyeonche and a pyeonche holder in which the plurality of pyeonche are inserted and supported;
It includes first and second rotation blocks connected to the pyeonche unit to elevate the reinforcing bar and an elastic member positioned between the first and second rotation blocks,
The body portion is divided into upper and lower bodies, and each body has a reinforcing bar coupler structure, characterized in that a rotation guide groove is formed to guide and constrain the rotation when the first rotation block is rotated and ascended and descended. The reinforcing bar coupler structure according to claim 1, wherein the body portion, the pyeonche and the pyeonche holder, the first and second rotation blocks, and the elastic member are all made of a non-metal material. The method according to claim 1, wherein the pyeonche is a trapezoidal shape, the thickness t is 2 to 3mm, the pyeonche end 33 is a reinforced coupler structure, characterized in that inclined with respect to the horizontal plane.
The reinforced coupler structure according to claim 1, wherein a plurality of slit grooves into which the pyeonche is inserted are formed in the pyeonche holder. delete

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