KR20110008514A - Apparatus for connecting steel wire - Google Patents

Abstract

PURPOSE: A strand coupling device is provided to stably maintain the connection state of a wedge assembly and a strand. CONSTITUTION: A strand coupling device(31) comprises a connection pipe(33), two wedge assemblies(15), springs(37), and pressing holders(17). The inner center of the connection pipe has a partition wall(33a). The wedge assemblies cover the ends of wteel wires(W1,W2) and are inserted into both ends of the connection pipe. The springs are installed between the wedge assemblies and the partition wall. The pressing holders accept the wedge assemblies and are screwed in the connection pipe.

Description

Stranded Wire Fittings {Apparatus for connecting steel wire}

The present invention relates to a stranded wire joint apparatus.

A stranded wire, which is almost essential for various civil and building works, is a line made of twisted steel wires, and has excellent tensile ability, such as fixing various structures or buildings to the ground or by excavation. It is necessarily used in ground anchoring method that prevents collapse of formed slope or vertical surface.

The strand may be cut to an appropriate length as necessary, or may be used by connecting a plurality of strands in the longitudinal direction. There is a type of stranded wire connecting device for connecting the stranded wires of the type shown in FIG.

1 is a cutaway exploded perspective view showing the structure of a conventional stranded wire joint apparatus.

As shown in the drawing, the conventional stranded wire connecting device 11 has a connecting pipe 13 having a female pipe 13a formed on an inner circumferential surface thereof in the form of a pipe having both ends open, and the connecting pipe 13. Two wedge assemblies 15 each installed into the connecting pipe at both ends of the wedge assembly, and pressure holders 17 screwed to both ends of the connecting pipe 13 in a state of receiving the respective wedge assemblies 15. do.

The wedge assembly (15) consists of three wedge pieces (15a) divided at an angle of 120 degrees in the longitudinal direction and remains assembled by an O-ring (15e). The o-ring 15e is inserted into a groove 15c formed in the outer surface of each wedge piece 15a to collect the wedge piece 15a inward. The o-ring 15e may have an elastic force and may be stretched to some extent so that, for example, the wedge piece 15a may be spread and the strands w1 and w2 may be passed therein.

A toothed portion 15d is formed on the inner surface of each of the wedge pieces 15a. The teeth 15d strongly tighten the outer circumferential surfaces of the wrapped strands w1 and w2 to prevent the strands from slipping out of the wedge assembly 15. Moreover, the inclined surface 15b is provided in the outer surface of each said wedge piece 15a. The inclined surface 15b is formed such that the outer circumferential surface of the wedge assembly 15 is tapered to one side.

The pressure holder 17 is in the form of a hollow pipe and is screwed into the connecting pipe 13 in a state in which each wedge assembly 15 is accommodated therein, thereby causing the wedge assembly 15 to be a central axis. To tighten the wedge assembly 15 to the strands w1 and w2.

To this end, an inner circumferential surface of the pressing holder 17 is provided with a pressing surface 17c for interviewing the inclined surface 15b. The pressing surface 17c presses the inclined surfaces 15b of the wedge pieces 15a in the direction of the strands w1 and w2 as the pressing holder 17 enters the inside of the connecting pipe 13.

In addition, the outer circumferential surface of the pressure holder 17 is provided with a male thread 17a and a fastening portion 17b. The male thread 17a is a portion that couples to the female thread 13a of the connecting pipe 13. In addition, the fastening portion 17b is a clamping tool for clamping the pressure holder 17, such as a spanner or a pipe wrench.

However, the conventional twisted wire joint apparatus 11 has a problem in that the degree of entry of the strands w1 and w2 as well as the wedge assembly 15 entering the inside of the connecting pipe 13 cannot be accurately determined. Due to the above problem, for example, as shown in FIG. 2D, an entry length P1 of one strand w1 and an entry length P2 of an opposite strand w2 may be different.

2A to 2D are cross-sectional views illustrating problems of the stranded wire joining device 11, and sequentially illustrating a process of connecting two stranded wires w1 and w2 to the stranded wire joining device 11.

First, the wedge assembly 15 is attached to an end portion of one side strand w1 penetrating the pressure holder 17, and the end portion of wedge strand w1 and the wedge assembly 15 are connected to each other in the pipe 13. Insert into one end. At this time, the tip portion of the strand w1 protrudes from the wedge assembly 15 by the length A. The protruding length A is appropriately determined in view of the length of the connecting pipe 13.

If one side of the strand (w1) and the wedge assembly 15 is inserted into the connection pipe 13 to some extent, as shown in Figure 2b, the pressure holder 17 is screwed to the connection pipe (13). As the pressure holder 17 enters into the connection pipe 13 through screwing, the wedge assembly 15 is tightened and the wedge assembly 15 folds the strand w1 in the direction f1 of FIG. 2C.

However, referring to FIG. 2C, it can be seen that the distal end portion of the strand w1 is fixed to enter the opposite side beyond the intermediate point of the connection pipe 13. This phenomenon occurs because the position of the tip portion of the strand w1 cannot be seen from the outside of the connecting pipe 13. If the inside of the connecting pipe 13 can be seen from the outside, when the initial wedge assembly 15 enters the inside of the connecting pipe 13, the entry depth of the tip of the strand w1 may be adjusted.

However, since it is not possible to look inside the connection pipe 13 made of metal, the degree of entry of the wedge assembly 15 and the strand w1 can be determined by the sense. As a result, the operator cannot exactly know the entry depth P1 of the tip of the strand w1 from the outside.

Anyway, with the wedge assembly 15 connecting the stranded wire w2 together with the wedge assembly 15 in the same manner on the opposite side with the tip portion of one of the stranded wires w1 fixed to enter the length P1 beyond the middle of the connecting pipe 13 as described above. After entering into the inside of the screw the other side pressure holder (17).

As shown in FIG. 2D, since the one side strand w1 enters the middle portion of the connection pipe 13, the other side strand w2 is less than half the length P2 of the connection pipe 13. It is bitten by the wedge assembly 15 in a state of entering only. Furthermore, in some cases, the tip portion of the right strand w2 may not protrude from the wedge assembly 15. At this time, the right strand (w2) is easily removed from the connecting pipe 13, of course.

As a result, it is very difficult to determine the precise entry depth of the wedge assembly 15 and the strands w1 and w2 that are installed in the connection pipe 13. Since the strands (w1, w2) can not be stably connected, the reliability is very low, especially if the connection part is cut during construction, there is a problem that can cause a large accident.

The present invention has been made to solve the above problems, and since the partition wall portion for limiting the insertion depth of the wedge assembly and the stranded wire is provided inside the connection pipe, the wedge assembly and the stranded wire are fixed to the optimum depth to provide a strong and stable connection. It is an object of the present invention to provide a stranded wire coupling device that can be maintained and that is so reliable.

The stranded wire connecting apparatus of the present invention for achieving the above object is to connect two stranded wires in a longitudinal direction, the connecting pipe having a female thread formed on its inner circumferential surface, and the end of the stranded wire to be connected, Two wedge assemblies respectively positioned to enter the connection pipe through both ends, and a pressure holder for screwing the wedge assembly by screwing to both ends of the connection pipe while accommodating the wedge assembly, thereby allowing the wedge assembly to bite and secure the stranded wire. In the twisted wire joint apparatus comprising,

Inside the connection pipe, the barrier rib portion serving as a stopper for limiting the entry depth of the strand and the wedge assembly, respectively entering into the connection pipe through the both ends of the connection pipe is provided.

In addition, the partition portion; A wall located in the longitudinal center of the connecting pipe and partitioning the inner space of the connecting pipe into two, the steel wires facing the front end of each of the strands, the wedge assembly is opposed to the front end of the wedge assembly It is characterized by having a wedge assembly surface that limits the extent.

In addition, the strand wire and the wedge assembly ground surface is formed stepped so that the strand can be maintained in a protruding state from the wedge assembly in the connecting pipe.

In addition, between the wedge assembly surface and the wedge assembly, characterized in that the spring is further provided to elastically support the wedge assembly in the outward direction of the connecting pipe.

The stranded wire joining device of the present invention made as described above has a partition portion for limiting the insertion depth of the wedge assembly and the stranded wire inside the connection pipe, so that the wedge assembly and the stranded wire enter and fix at an optimum depth to provide a strong and stable connection. We can maintain and are reliable as much.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a partially cutaway exploded perspective view showing the overall structure of the stranded joint according to an embodiment of the present invention, Figure 4 is a cross-sectional view of the stranded joint shown in FIG.

The same reference numerals as the above reference numerals are the same members having the same function, and unnecessary description thereof will be omitted.

Referring to the drawings, the wire strand connecting apparatus 31 according to the present embodiment, taking the form of a pipe, but having a connecting pipe 33 having a partition portion 33a at the inner center thereof, and the connection of the steel wires w1 and w2 to be connected. Two wedge assemblies (15) entering the both ends of the connecting pipe (33) with their respective ends wrapped, a spring (37) installed between the wedge assemblies (15) and the partition wall portion (33a), Consists of a pressure holder 17 for screwing to the connection pipe 33 in a state in which the wedge assembly 15 is accommodated.

The connecting pipe 33 is a pipe-shaped member having a constant diameter with both ends open, and a female thread 33d is formed on the inner circumferential surface thereof. The female screw thread 33d is a portion for screwing into the male screw thread 17a of the pressure holder 17.

On the other hand, the partition portion 33a is integrally provided in the inner center of the connecting pipe 33, and has a lecture ground surface 33e and a wedge assembly ground surface 33c on opposite sides of each other.

The wedge assembly ground surface 33c is a ring-shaped surface corresponding to the front end surface of the wedge assembly 15 that enters the connection pipe 33 as shown in FIG. 5D. A spring 37 is inserted between the wedge assembly surface 33c and the wedge assembly 15, and the wedge assembly surface 33c connects the wedge assembly 15 to the pipe 33 through a spring 37. Elastically press to the outside. The wedge assembly ground surface 33c is a locking jaw that prevents the spring 37 and the wedge assembly 15 from entering further.

In addition, the strand wire ground surface 33e is a portion that is in close contact with the end surface of the strand wire (w1, w2) entered into the connecting pipe 33 in a state wrapped in the wedge assembly 15, the strand wire (w1, w2) This serves as a stopper to prevent further entry. In particular, the lecture ground surface 33e is stepped from the wedge assembly ground surface 33c by A2.

Therefore, as shown in FIGS. 5A and 5B, the tip end surface of the strand w1 protrudes from the wedge assembly 15 by more than [the length A3 of which the spring is not compressed + the depth A2 of the strand wire groove 33b]. Even when entering the inside of the connecting pipe 33, as the stranded wire w1 is blocked on the stranded ground surface 33e and the spring 37 reaches the wedge assembly grounded surface 33c, the protruding length of the stranded wire Is automatically adjusted to A2. The protruding length A2 is the optimum length.

In addition, the strand wire groove 33b formed by forming the wedge assembly ground surface 33c and the stranded wire ground surface 33e stepwise receives the tip portions of each of the stranded wires w1 and w2 and connects the stranded wire to the center of the pipe 33. Position it on the axis.

The spring 37 is gradually compressed by screwing the pressure holder 17 to the connection pipe 33 and elastically pressurizes the wedge assembly 15 toward the pressure surface 17c of the pressure holder 17.

5A through 5D are cross-sectional views sequentially illustrating a state in which the strand wire is connected through the strand wire joint apparatus shown in FIGS. 3 and 4.

In order to connect two stranded wires w1 and w2 in a straight line by using the stranded wire connecting device 31 according to the present embodiment, the wedge assembly 15 and the spring 37 that wrap one side of the stranded wire w1 are first stranded wires. It is inserted into the connection pipe 33 together with (w1). At this time, the protruding length of the strand w1 with respect to the wedge assembly 15 is kept longer than the known value [A2 + A3].

When the stranded wire w1 entering the connection pipe 33 reaches the stranded ground surface 33e, and the spring 37 contacts the wedge assembly grounded surface 33c, the pressure holder 17 Screwed to the connecting pipe 33 to allow the wedge assembly 15 to bite and fix the strand wire w1.

Subsequently, the opposite strand ww, the wedge assembly 15, the spring 37, and the pressure holder 17 are inserted and fixed to the connecting pipe 33 in the same manner.

If the pressure holder 17 is screwed to both ends of the connecting pipe 33 as described above, the pressure holder 17 is continuously tightened, and the pressure holder 17 tightens the wedge assembly 15 more strongly and at the same time springs. 37 makes the wedge assembly 15 elastically pressurize to the pressure holder 17 and completes the connection process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

1 is an exploded perspective view showing the structure of a conventional stranded wire joint apparatus.

2A to 2D are cross-sectional views illustrating the problem of the stranded wire joint apparatus.

3 is a partially cutaway exploded perspective view showing the overall structure of a stranded wire joint apparatus according to an embodiment of the present invention.

4 is a cross-sectional view of the stranded wire connecting apparatus shown in FIG.

5A through 5D are cross-sectional views sequentially illustrating a state in which the strand wires are connected through the strand wire joint apparatus shown in FIG. 3.

<Explanation of symbols for the main parts of the drawings>

11: Strand-line joint 13: Connecting pipe

13a: female thread 15: wedge assembly

15a: wedge 15b: slope

15c: Groove 15d: Tooth

15e: O-ring 17: Pressure holder

17a: Male thread 17b: Fastening part

17c: Pushing surface 31: Stranded wire joint

33: connecting pipe 33a: partition wall

33b: Stranded groove 33c: Wedge assembly ground

33d: female thread 33e: stranded ground

37: Spring

Claims (4)

Two wedges for connecting two stranded wires in a longitudinal direction, each having a female thread formed on an inner circumferential surface thereof, and two wedges respectively positioned in the connecting pipes through both ends of the connecting pipes with the ends of the strands connected thereto. In the twisted wire joint apparatus comprising a assembly and a pressure holder for screwing the wedge assembly by screwing to both ends of the connecting pipe in a state in which the wedge assembly is accommodated to allow the wedge assembly to bite and secure the stranded wire, The inside of the connection pipe, the twisted pair connecting device is characterized in that the barrier wire which serves as a stopper for limiting the entry depth of the wedge assembly and the stranded wire respectively entering into the connection pipe through both ends of the connection pipe is provided. The method of claim 1, The partition portion; Located in the central portion of the longitudinal direction of the connecting pipe wall to partition the inner space of the connecting pipe into two, A lecture ground surface facing the end surface of each of the strands; And a wedge assembly grounding surface facing the distal end of each wedge assembly and limiting the degree of entry of the wedge assembly. 3. The method of claim 2, And the wedge assembly ground surface and the wedge assembly ground surface are formed stepped so that the wire strand can be maintained in the connecting pipe in a state protruding from the wedge assembly. 3. The method of claim 2, And between the wedge assembly ground surface and the wedge assembly, a spring for elastically supporting the wedge assembly in an outward direction of the connecting pipe is further provided.

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