KR101460180B1 - Nail connectors for soil nailing method - Google Patents

Abstract

The present invention relates to a reinforcing bar used in a soilless nailing method for stabilizing a slope such as a cleavage site, and more particularly, to a reinforcing bar having a reinforcing bar made of a deformed reinforcing bar and a helical reinforcing bar, And the other end of the connecting member is formed with a threaded groove for a spiral reinforcing bar and a threaded screw on the other side of the connecting member, And an arm member formed with a fastening female screw portion,
In the course of performing the soil nailing method for the purpose of slope stabilization and so on, it is possible to connect the deformed reinforcing bar corresponding to the piercing depth and the helical reinforcing bar for pressing the front face to the slope face firmly and easily, It is possible to shorten the construction period due to the fact that it is possible to directly connect and fix the original deformed reinforcing bar and the spiral reinforcing bar in the field, It is possible to insert the nail so as to have the best length corresponding to the depth of the slope piercing in the nailing method, thereby achieving more uniform and high-quality soil nailing construction.

Description

{Nail connectors for soil nailing method}

The present invention relates to a reinforcing bar used in a soilless nailing method for stabilizing a slope such as a cleavage site. More particularly, the present invention relates to a reinforcing bar made of a deformed reinforcing bar and a spiral reinforcing bar, To a different type of reinforced concrete connection.

Generally, when a structure is constructed on a building underground or a slope, a staking work is performed to stabilize slopes and slopes excavated vertically. Such a conventional staking work includes a pile of a thimble, a sheet pile, a sheet pile ), Etc. However, since this method uses large piercing equipment, noise and vibration accompanied with the installation of the pile are problematic. Also, since the supporting space narrows the construction space, it is difficult to carry the excavated soil The earth anchor method has a disadvantage that the excavation work itself is easy but the construction time is long and the length of the anchor is very long, .

Accordingly, the soil nailing method has been widely used in recent years. The soil nailing method has been widely used for the purpose of excavating the slope or the underground excavation of the building as described above, It is possible to perform excavation work with low noise and low vibration by using comparatively light weight equipment as a method of reinforcing the excavation slope only by a plate (shotcrete or concrete facing) As the depth of penetration is very short, it infiltrates the boundary of the adjacent land, which minimizes the occurrence of disputes, which is very advantageous for the construction of urban areas. It is currently being applied to various construction sites in foreign countries as well as domestic.

As described above, reinforced soil (reinforcement material) is used to reinforce the tensile force and shear force in the cut slope so as to form an integrated block of the soil, which is reinforced with local soil, to function as a gravity retaining wall as a soil wall Soil nailing method, which keep slope slope stable, can construct a retaining wall with high stability by forming a structure using nail reinforced ground itself, and it is possible to construct with a small machine, It is effective in construction method, easy to work and noise and vibration is low, so it is possible to construct close to the residence area. It is also safe because it is very resistant to movement of surrounding ground such as earthquake. It is safe to set a gradient and widen the use area of the land to increase the use of the land and to preserve the surrounding environment. It is possible.

The general construction method and construction structure by the soil nailing method are disclosed in Utility Model Registration No. 20-0205781.

1 and 2, the conventional soil nailing method is a method of performing a piercing operation on the slope 100 and inserting the deformed reinforcing bar 110 into the piercing as described above, The perforated part in which the reinforcing bar 110 is inserted is firmly fixed and cured by fixing the deformed reinforcing bar 110 by a method such as cement milk grouting and the exposed front end of the deformed reinforcing bar 110, A separate nailing nut 130 is firmly fastened to the end of the deformed reinforcing bar 110 in a state where the front surface 120 of the slope 100 is inserted, So that stabilization can be achieved.

In particular, since the nailing nut 130 fastened to the exposed end of the deformed reinforcing bar 110 can not be directly screwed to the deformed reinforcing bar 110, a separate liner screw is wrapped and fixed on the deformed reinforcing bar 110 The nipping nut 130 can be fastened to the liner screw 130. However, since the fastening method using the liner screw as described above is very troublesome and thus avoids in the field, The spiral reinforcement 140 is exposed from the slope 100 by connecting and fixing the spiral reinforcement 140 to the end of the spiral reinforcement 140 so that the nailing nut 130 can be directly screwed onto the spiral reinforcement 140 It is.

In addition, the deformed reinforcing bar 110, which is manufactured as described above, is typically purchased from a factory and is manufactured in a certain length. The deformed reinforcing bar 110, which can not be specially manufactured or manufactured on site, Meter and 12 meters in length. Therefore, when the hole is drilled or drilled to a depth deeper than these lengths, a separate spiral reinforcing bar 140 is connected and fixed to the end of the deformed reinforcing bar 110 as described above. So that the length of the nail can be secured.

In this case, a separate connecting hole 150 is used as a connecting means between the deformed reinforcing bar 110 and the spiral reinforcing bar 140. The connecting hole 150 as described above has a spiral groove 151 formed therein The ends of the deformed reinforcing bars 110 and the helical reinforcing bars 140 are firmly fastened to each other using the helical grooves 151 as described above.

The spiral reinforcing bar 140 is formed with a spiral portion 141 having the same size as the spiral groove 151 so that the spiral reinforcement 140 can be directly fastened to the connecting portion 150 without any additional processing. The threaded portion 111 is formed on the coupling portion of the coupling 150 by a separate finishing process and the threaded portion 111 is screwed to the coupling hole 150 so that the deformed reinforcing bar 110 So that the spiral reinforcing bars 140 can be firmly connected to each other.

However, it is pointed out that the connection structure between the deformed reinforcing bar and the spiral reinforcing bar as described above is disadvantageous in that it is fixed only through a separate finishing process for the deformed reinforcing bar, and thus it does not meet the complicated civil engineering scene conditions.

That is, as described above, since the deformed reinforcing bars can not be directly screwed to the connecting portion having the spiral portion, the screw portion corresponding to the spiral portion of the connecting portion must be coupled to the end portion of the deformed reinforcing steel through post- It is practically impossible to form the threaded portion at the end of the deformed steel bar in the field, so that the tip of the deformed bar used for the purpose of the nail is usually transferred to the site in the state where the pre- And the other.

Therefore, when the deformed reinforcing bars are moved from the factory to the threaded portions in advance, the deformed reinforcing bars having different lengths should be used when the depths of the slopes are different from each other. As described above, If the post-operation of the deformed reinforcing bar having a deformed reinforcing bar is used, it is impossible to cope with the piercing depth, so that the nail installation is performed in an unsuitable state irrespective of the piercing depth.

In addition, as described above, in the process of machining the threaded portion of the deformed reinforcing bars in the factory, and in the course of carrying and using the deformed reinforcing bars, an excessive amount of the distribution cost is generated and the cost of construction is increased. It is difficult to achieve high-quality construction.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide a method of manufacturing a reinforcing bar comprising a plurality of reinforcing bars made of a deformed reinforcing bar and a helical reinforcing bar, A male member having a groove formed on the other side thereof with a fastening screw portion and a female member having a fastening female screw portion on the one side and a slanting surface portion on which the split wedge is inserted,

A spiral reinforcing bar is coupled to the male member and a deformed reinforcing bar is directly coupled to the female member so that the male member and the female member are firmly screwed to each other so that the helical reinforcing bar and the deformed reinforcing bar can be firmly connected and fixed to each other. The present invention has been made to solve the above-mentioned problems occurring in the prior art.

In order to accomplish the above object, the present invention provides a heterobloc connector for connecting and fixing a deformed reinforcing bar and a spiral reinforcing bar used in a soilless nailing method, wherein a spiral groove is formed on one side and a fastening screw is formed on the other side And an arm member having a slanting portion having a gradually reduced diameter from the inside to the outside and having a fastening female screw portion on the other side,

Wherein the split wedge is formed in a bundle shape by a separate elastic band formed on an outer surface of the split wedge, and the spiral groove is formed of a bundle of wedge- And the split wedge in close contact with the outer surface of the deformed reinforcing bar is inserted into the inclined inner surface of the tapered portion so that the threaded portion of the male member and the female threaded portion of the female member are threadedly engaged with each other, Are firmly fixedly connected to each other.

In the course of performing the soil nailing method for the purpose of slope stabilization or the like, it is possible to firmly and easily connect the deformed reinforcing bars corresponding to the piercing depth and the helical reinforcing bars for pressing the front surface to the slopes, It is possible to shorten the construction period due to the improvement of the speed, and it is possible to directly connect and fix the deformed reinforcing bars and the spiral reinforcing bars as they are in the field in the field, not by performing post- In addition, the nail can be inserted to have the best length corresponding to the depth of the slope drilling in the soil nailing method, and more uniform and high-quality soil nailing can be performed.

Figure 1 shows a general view of a typical soil nailing construction
2 is an enlarged cross-sectional view of a reinforcing bar in the conventional soilless nailing method
3 is an exploded perspective view of a different reinforcing bar joint according to the present invention.
Fig. 4 is a cross-sectional view of the connection of the different reinforcing bars according to the present invention
Fig. 5 is a sectional view of a different reinforcing bar joint according to the present invention
6 is a cross-sectional view showing another embodiment of the hetero-bar connecting portion according to the present invention.
7 is a cross-sectional view showing another embodiment of the hetero-bar connecting portion according to the present invention.
8 is a cross-sectional view showing another embodiment of the hetero-bar joint according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

FIG. 3 is an exploded perspective view of a different reinforcing bar joint according to the present invention, FIG. 4 is an assembled cross-sectional view of a different reinforcing bar joint according to the present invention, and FIG. 5 is a sectional view of a different reinforcing bar joint according to the present invention.

As shown in the drawing, the connector according to the present invention is formed by joining a male member 10 and a female member 20 formed by processing a metal material, and the male member 10 has a spiral groove 11 formed on one side thereof And an interference preventing groove 13 is formed on the other end of the male thread member 12 at the other end where the female threaded portion 12 is formed .

The female member 20 is formed with a slanting surface portion 21 at one side and a fastening female threaded portion 22 for screwing the fastening male thread portion 12 of the male member 10 And the inclined guide portion 21 has a tapered shape gradually reduced in diameter from the inside to the outside of the arm member 20. [

At this time, a separate wedge 30 is inserted into the inclined guide portion 21, and the division wedge 30 is composed of two to four parts, and the inner surface of the wedge 30 has interference The protrusion 31 is formed and an inclined portion 32 is formed on an outer surface thereof to coincide with the inclined angle of the inclined guide portion 21. In addition, a separate elastic band 33 is formed on the outer surface of the split wedge 30 to separate the split wedges 30 from each other by the circular elastic band 33.

A separate spiral reinforcement 40 is coupled to the spiral groove 11 of the male member 10 as described above and the spiral portion 41 is formed on the outer surface of the spiral reinforcement 40, When the end of the screw member 40 is screwed into the helical groove 11, the male member 10 and the helical bar 40 are mutually coupled.

The arm member 20 is fixed to the end of the deformed reinforcing bar 50. The end of the deformed reinforcing bar 50 is pushed into the inclined guide portion 21 of the arm member 20, The inclined portion 32 of the split wedge 30 is inclined at an angle of inclination of the arm member 20 when the split wedge 30 is engaged with the end of the split wedge 30, So that they are firmly engaged with each other and firmly engaged with each other.

At this time, since the inner space of the split wedge 30 can be forcibly expanded by the elastic band 33, the deformed reinforcing bar 50 is inserted while the inside of the split wedge 30 is forcibly expanded The split wedge 30 is held in close contact with the end of the deformed reinforcing bar 50 due to the elastic restoring force of the elastic band 33.

When the split wedge 30 is engaged with the deformed reinforcing bar 50 as described above and the deformed reinforcing bar 50 is pulled in a direction separating from the arm member 20, the inclined portion 32 of the split wedge 30 And the slanting face portion 21 of the arm member 20 are brought into tight contact with each other.

When the fastening screw portion 12 of the male member 10 and the fastening female threaded portion 22 of the female member 20 are firmly screwed to each other in this state, the helical reinforcement 40 and the deformed reinforcing bar 50, A firm connection and a fixed state are established.

When the male member 10 and the female member 20 are engaged with each other as described above, the end surface of the fastening screw portion 12 of the male member 10 can press the tip of the split wedge 30, The split wedge 30 is pushed outwardly by the male member 10 when the female member 10 and the female member 20 are engaged with each other, So that it can be firmly fixed to the member 20 and the deformed reinforcing bar 50.

An end of the deformed reinforcing bar 50 formed by forming the interference preventing groove 13 at the end of the coupling threaded portion 12 of the male member 10 may be inserted into the interference preventing groove 13 The ends of the deformed reinforcing bars 50 are inserted into the interference preventing grooves 13 when the joining positions of the deformed reinforcing bar 50 and the split wedge 30 are irregular, So that the split wedge 30 can be strongly pressed without interfering with the deformed reinforcing bar 50.

Therefore, it is possible to firmly connect the different types of spiral reinforcing bars 40 and the deformed reinforcing bars 50 with each other by the arm member 20 including the water member 10 and the split wedge 30, And it is possible to reduce the construction cost and the construction cost as well as the work efficiency because the field work of the spiral reinforcing bars 40 and the deformed reinforcing bars 50 including the connecting joints or the factory work is not required at all.

In the soilless nailing method using the above-described reinforcing bars, the deformed reinforcing bar 50 having the corresponding length is prepared according to the depth of the pit formed on the slope, 40 and the front plate and the nailing nut are firmly fixed to each other by using a helical reinforcing bar 40 which is exposed to the slope so that the front plate and the nailing nut are firmly fixed to each other, The construction can be completed.

As another embodiment of the present invention, the fixing force to the deformed reinforcing bar 50 may be improved by using the elastic pressing member 60 as shown in FIG. 6, A separate elastic pressing member 60 is fixed to one side of the male member 10 by using the coupling groove 14 at one end of the elastic pressing member 60, And a coupling protrusion 61 is formed at an end of the coupling groove 14 so as to be engaged with the coupling groove 14.

The male member 10 having the spiral reinforcing bar 40 and the arm member 20 having the deformed reinforcing bar 50 are fixed to each other with the separate elastic pressing member 60 engaged with the male member 10, The resilient pressing member 60 strongly urges the end of the deformed reinforcing bar 50 so that the divided wedge 30 coupled to the deformed reinforcing bar 50 is inserted into the inclined inner surface of the arm member 20, (50) due to the elastic force and the restoring force of the elastic pressure applying tool (60), and the protrusion of the deformed reinforcing bar (50) And it is also possible to prevent the male member 10 and the female member 20 to be screwed easily from being released due to the elastic restoring force.

7, an injection hole 15 is formed in the male member 10 and the female member 20 so as to penetrate the male member 10 and the female member 20, and the male member 10 and the female member 20 are connected by the injection hole 15, The inner side of the arm member 20 is penetrated to the outside and the hardening fixing agent such as silicone or epoxy is injected into the interior of the male member 10 and the female member 20 by using the injection hole 15 The helical reinforcing bars 40 and the deformed reinforcing bars 50 connected to the male member 10 and the arm member 20 can be more firmly fixed to each other by the curing agent 70. [

8, a continuous thread 16 is formed on the outer surface of the male member 10 and the female member 20, and a separate connection ring 80 is formed on the thread 16 When the male member 10 and the female member 20 are screwed together and the connecting ring 80 is coupled to the outer surface of the male member 10 and the female member 20, Since the arm member 20 is re-connected, the connection and fixing of the male member 10 and the arm member 20 can be more firmly performed.

Because of the various connection reinforcing means, the spiral reinforcing bars 40 and the deformed reinforcing bars 50, which are conveyed or handled in the field of construction, are not loosened or separated from each other due to the above- And handling properties can be further improved.

Therefore, the connector of the present invention can quickly and easily and securely fix the separate spiral reinforcement 40 to the deformed reinforcing bar 50 having the best length corresponding to the piercing depth at the construction site to which the soil nailing method is applied So that it is possible to construct a very reasonable level of construction as well as a high quality construction.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

10: Water member 11: Spiral groove
12: fastening screw part 13: interference prevention groove
14: defect groove 15: injection hole
16: Thread
20: arm member 21: inclined inner surface
22: fastening female thread portion
30: split wedge 31: interference projection
32: inclined portion 33: elastic band
40: spiral reinforcement 41: spiral part
50: Reinforced steel bars
60: Elastic pressing member 61:
70: Hardener
80: connecting ring

Claims (5)

In this paper, we propose a new type of reinforcement for reinforced concrete barrels.
A male member 10 having a helical groove 11 formed on one side thereof and a fastening screw 12 formed on the other side thereof and an inclined guide portion 21 having a gradually reduced diameter from the inside to the outside are formed on one side, And an arm member (20) having a female threaded portion (22)
The split wedge 30 has an interference projection 31 formed on an inner surface thereof and an inclined portion 32 formed on an outer surface of the inclined insertion portion 21. The split wedge 30 has a separate elasticity Band 33 by a band 33,
The spiral portion 41 of the spiral reinforcing bar 40 is fastened to the helical groove 11 and the split wedge 30 closely attached to the outer surface of the deformed reinforcing bar 50 is inserted into the inclined guide portion 21. [ The threaded reinforcing bar 40 and the deformed reinforcing bar 50 are firmly fixed to each other as the fastening screw portion 12 of the male member 10 and the fastening female threaded portion 22 of the female member 20 are screwed together. In a sole nailing method,
The elastic member 60 is formed at one end of the male member 10 with an engaging groove 14 for inserting a separate elastic pressing member 60 into the engaging groove 14, So that the end of the deformed reinforcing bar 50 is pressed by the elastic pressing part 60 so that the tight fitting force of the deformed reinforcing bar 50 by the divided wedge 30 is increased Characterized in that it comprises a plurality of reinforcing bars for the soilless nailing method.
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