KR20190033369A - Coupler for prestressing strand - Google Patents

Abstract

The present invention relates to a strand coupler capable of increasing a biting rate of a strand. According to the present invention, the strand coupler comprises: a pair of bodies having both opened ends to insert a strand thereinto, having an inner diameter gradually reduced toward an inlet, and including a pair of inner tilted parts disposed in a direction facing each other; a wedge coupling a pair of divided pieces divided into halves to the inner tilt part of each body, wherein an outer tilted part with an outer diameter gray reduced toward the inlet is formed on the outside, and a tooth profile to insert and fix the strand thereinto and thereto is formed on the inside; a spring disposed in the body to elastically press the wedge toward the inner tilted part so as to compress the strand and provide a fixing force; and a socket coupled between the pair of bodies and having a protruding step formed therein to support the spring. The spring comprises: a fixed part closely attached to the step and the inside of the body to be press-fit and fixed thereto; and an elastic part extended from the fixed part, wherein a diameter is formed by a relatively small size to elastically support the wedge. An inlet tilted part with an inner diameter gradually expanded toward the inlet is formed on an inner end of the wedge. The angle of the outer tilted part of the wedge is relatively less than that of the inner tilted part of the body, such that the angle of the wedge is able to be varied by an angle difference and is gradually reduced toward the inner diameter of the inlet side of the wedge, thereby increasing an initial biting ratio of the strand. Moreover, a strand guide block to guide a strand stepped by being tilted toward the inlet side to the inlet side is formed on the outer circumferential surface of one end part of the body.

Description

Coupler for prestressing strand}

TECHNICAL FIELD The present invention relates to a stranded wire coupler, and relates to a technique for connecting a stranded wire adjacent to a stranded wire, and more particularly, to a stranded wire coupler capable of increasing a stitching rate of a stranded wire.

Generally, in the post-tensioning method in reinforced concrete construction, after installing a steel wire (stranded wire) as in reinforcing steel laying work to a slab or a portion where a beam is to be formed, concrete is laid thereon and tensile work of the buried strand is performed. The construction is carried out in such a way as to do.

In this process, stranded wires can be connected to each other in a non-attached post-tensioning method using a single stranded wire, and a stranded wire is connected using a stranded wire connecting coupler.

Figure 1 shows a conventional strand connecting coupler in which a wedge 2 is assembled at the end of the strand S1 and S2 and the fixing port 14 is moved in the direction in which the wedge 2 is located, So that the fixing surface 10 of the fixation port 14 can be in surface contact with the outer surface. Then, in this state, the start portions of the male screw portions 12 are fastened to the first and second female screw portions 18a and 18b of the connector 16, and then the connector 16 is screwed in one direction The male screw portions 12 formed on the respective fixing holes 14 move along the first and second female screw portions 18a and 18b of the connecting hole 16 to narrow the gap between the fixing holes 14, 16 are assembled on both sides.

However, the ordinary strand has a problem that the strand is formed by twist, and the diameter is 12.7 mm, which is relatively thin compared to the rebar, so that slip occurs when the wedge is fixed.

In the case of a coupler manufactured by making the inner diameter of the wedge smaller than the outer diameter of the strand, the inner diameter of the wedge is larger than the outer diameter of the strand, which makes it difficult to insert the strand.

KR 10-2009-0129218 A KR 20-0286138 Y1

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stranded wire coupler having a structure capable of changing the angle of a wedge so as to facilitate introduction of a stranded wire and increase a biting ratio.

According to an aspect of the present invention, there is provided a straddle-type vehicle comprising a body having a pair of opposite side faces, both ends of which are opened and a stranded wire is inserted therein and an inner side inclined portion gradually reduced in diameter toward the entrance side, A wedge whose outer side is formed with an outer inclined portion whose outer diameter is gradually reduced toward the entrance side and whose inner side is formed with a tooth to be fixed by insertion of the stranded wire, A spring provided inside the body and elastically pressing the wedge toward the inner inclined portion to press the strand to provide a clamping force; and a stepped portion protruding inward from the pair of the bodies to form the spring, A stranded wire coupler comprising a socket that can be supported, And an elastic portion extending from the fixed portion and formed to have a relatively small outer diameter and elastically supporting the wedge, wherein the inner end of the wedge is gradually and gradually moved toward the entrance side, Wherein an inclined angle of an outer side of the wedge is formed to be smaller than an angle of an inner side inclined portion of the body so that the angle of the wedge is variable by an angle difference, And the stiffening guide block is formed to be inclined toward the entrance side on the outer peripheral surface of the one end so that the stiffened strand is guided to the entrance side.

And the angle of the outer inclined portion of the wedge is formed to be 0.7 to 1.5 degrees smaller than the angle of the inner inclined portion of the body.

The thread height of the teeth is 0.7 to 1.5 mm, and the thread width of the teeth is 1 to 2 mm.

According to the present invention having the above-described configuration, the following effects can be expected.

It is possible to change the angle of the wedge located inside the body of the coupler, so that the inflow of the strand can be smoothly performed and the rate of sticking to the strand can be increased.

At the inner end of the wedge there is formed an inflow slope portion whose inner diameter is gradually enlarged toward the entrance side, so that the stranded wire is easily guided into the wedge.

Further, a stranded guide block is formed on the outer circumferential surface of the entrance of the body, so that the inserted stranded strand can be easily inserted into the body entrance side.

1 is a view showing a conventional strand connecting coupler.
2 is a cross-sectional view of a stranded coupler according to an embodiment of the present invention.
3 is an exploded left side view of Fig.
4 (a), 4 (b), and 4 (c) show examples of strand connecting sequence.

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

2 is a cross-sectional view of a stranded coupler according to an embodiment of the present invention.

2, the stranded wire coupler of the present invention is basically composed of a body 100, a wedge 200, a spring 300, and a socket 400, and is characterized by the configuration of the spring 300, 200), it is possible to smoothly inflow the stranded wire and to increase the seizing ratio.

Hereinafter, each configuration will be briefly described in detail, and the wedge 200, which is a main feature of the present invention, will be described in detail.

First, the body 100 corresponds to the outer shape of the coupler, and the wedge 200 and the spring 300 can be accommodated therein.

Here, the body 100 is provided with a pair of mutually opposing directions for connecting the stranded wire to both sides, and both ends thereof are open so that the stranded wire can be inserted. Inside, an inner slope 120 is formed in which the inner diameter of the strand is gradually reduced toward the inlet side, that is, toward the entrance side.

The wedge 200 is a part capable of engaging the strand.

The wedge 200 has a pair of split pieces 220 split in an inner inclined portion 120 of each of the bodies, and an outer inclined portion 222 whose outer diameter is gradually reduced toward the entrance side is formed And a tooth 224 which can be fixed by inserting the strand of the strand is continuously formed on the inner side.

The spring 300 is a part capable of elastically supporting and pressing the wedge 200.

The spring 300 is provided inside the body 100 to elastically press the wedge 200 toward the inner inclined portion 120 of the body 100 to press the strand to provide a clamping force.

The socket 400 is clamped between the pair of the bodies 100 and has a step 420 protruding in a ring shape along the inner circumferential surface of the socket 400 to support the spring 300. A groove may be formed in the step 420 to partially receive the end of the spring 300.

The spring 300 includes a fixing part 320 which is in close contact with the step 420 and closely fitted and fixed to the inside of the body 100 and a fixing part 320 which is extended from the fixing part 320, And an elastic portion 340 for elastically supporting the wedge 200.

The fixing portion 320 of the spring 300 has a greater elastic modulus k than that of the elastic portion 340 so that the deformation amount of the fixing portion 320 is smaller than that of the external force, Make a lot of deformation. Since the fixing portion 320 is fixed and rubbed against the inner wall of the body 100, it is desirable that the amount of deformation is as small as possible for durability of the body 100 and the spring 300.

The inlet end of the wedge 200 is formed with an inflow slope 260 having an inner diameter gradually enlarged toward the inlet side so that the initial inflow of the strand can be smoothly performed.

The angle of the outer inclined portion 220 of the wedge 200 is relatively smaller than the angle of the inner inclined portion 120 of the body 100 so that the angle of the wedge 200 can be varied by an angle difference .

That is, when the wedge 200 is positioned on the inner side of the body 100, the wedge 200 becomes narrower toward the inner diameter of the entrance of the wedge 200, so that the initial engagement ratio of the stranded wire can be increased.

The body 100 may further include a strand guide block 500 formed at one end of the body 100 so as to be inclined toward the entrance side on the outer circumferential surface and guiding the stranded strand to the entrance side. Here, the problem that the stranded wires on both sides are not easily connected at the site of the stranded wire on the opposite side when one stranded wire is connected due to the mutual height difference is solved, and will be described in detail with reference to FIG.

3 is an exploded left side view of Fig.

3, the angle of the outer inclined portion 222 of the wedge 200 is smaller than the angle of the inner inclined portion 120 of the body 100 by 0.7 to 1.5 degrees.

In the drawing, the angle of the outer inclined portion 222 is 7 °, the angle of the inner inclined portion 120 is 8 °, the angle difference is about 1 °, and the outer inclined portion 222 is 6.6 to 7.3 ° It is preferable that tolerances can be tolerated to a certain degree when the split pieces 220 of the wedge 200 are machined.

The thread height of the teeth 224 is 0.7 to 1.5 mm and the thread width of the teeth 224 is 1 to 2 mm. The strands 22 having a diameter smaller than that of the reinforcing bars can be tightly seated.

4 (a), 4 (b), and 4 (c) show examples of strand connecting sequence.

4 (a), a wedge 200 is inserted into a left body 100, a spring 300 is sequentially inserted, a socket 400 is coupled to the wedge 200, The left strand S1 is inserted and the strand S1 projected to the exit side of the left body 100 is pulled to provide a tensile force to the strand S1 Cut it.

4 (b), the wedge 200 is fastened to the socket 400 while the wedge 200 is inserted into the body 100 on the right side.

Finally, the strand S2 on the right side in Fig. 4 (c) can be inserted into the side of the right side body 100 to join the strand S2. At this time, the strand guide block 500 is formed on the right side body 100, so that when the strand S2 on the right side is joined, the strand S2 on the right side is not aligned with the strand S1 on the left side, To be guided to the entrance side of the body 100 of the body 100, thereby facilitating the engagement. The entrance side end of the body 100 may also be inclined to correspond to the strand guide block 500.

As described above, it can be seen that the present invention provides a stiff wire coupler as a basic technical idea, and within the scope of the basic idea of the present invention, many other modifications Of course, this is possible.

100: Body
120: Inner inclined portion
200: Wedge
220:
222: outer inclined portion
224: Tooth type
226: inflow slope
300: spring
320:
340: elastic part
400: Socket
500: Strand guide block

Claims (4)

A body 100 having an inner inclined portion 120 having a pair of opposing sides facing each other, both ends of which are opened and a stranded wire is inserted, and whose inner diameter is gradually reduced toward the entrance side; The outer side is formed with an outer inclined portion 222 whose outer diameter is gradually reduced toward the entrance side and on the inner side is formed a toothed portion 224 to which the strand is inserted and fixed, A spring 300 provided inside the body to elastically press the wedge toward the inner inclined portion to press the strand to provide a clamping force, and a spring 300 coupled between the pair of the bodies, And a socket (400) having a stepped protrusion (420) protruding inwardly to support the spring,
The spring (300) has a fixing part (320) which is in close contact with the step and fitted and fixed to the inside of the body, and an elastic part (320) which is extended from the fixing part and has a relatively small outer diameter, (340)
The inlet end of the wedge 200 is formed with an inflow slope portion 226 gradually increasing its inner diameter toward the inlet side,
The angle of the outer inclined portion 222 of the wedge 200 is relatively smaller than the angle of the inner inclined portion 120 of the body so that the angle of the wedge can be varied by an angle difference, The initial stiffness of the strand is increased,
Wherein the body (100) further comprises a strand guide block (500) formed at an end of the body (100) and sloping toward the entrance side to guide the stranded strand to the entrance side. The method according to claim 1,
Wherein an angle of the outer inclined portion (222) of the wedge (200) is smaller than an angle of the inner inclined portion (120) of the body (100) by 0.7 to 1.5 degrees. The method according to claim 1,
Wherein a thread height of the teeth (224) is 0.7 to 1.5 mm, and a thread width of the teeth is 1 to 2 mm. The method according to claim 1,
Wherein the fixing part (320) of the spring (300) is larger in diameter than the elastic part (340) of the spring (300) and has a high elastic modulus.

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