KR100359742B1 - A binding method of strand element and a binding structure thereof - Google Patents

Abstract

Insert fitting step of inserting the insert into the tension member, first crimping step of compressing the insert radially by passing the tension member and insert through the crimping die, and a sleeve made to have a relatively larger aperture than the primary crimped insert The insert is tensioned by a tension member fixing method comprising a sleeve fitting step of heating and inserting the sleeve into the primary crimped insert, and a second crimping step of compressing the grip in which the sleeve is inserted again in the radial direction through the crimping die. Compression-bonded in the state filled with the bone formed between the element wires of the to prevent slipping of the insert through the spiral.

Description

A binding method of strand element and a binding structure

The present invention relates to a tension member binding hole used to build a continuous underground wall in a building or civil engineering structure, or to bind a heavy structure, and in particular, to prevent the tension member from being damaged due to the load applied to the tension member, and to provide a tensile force and a binding force. The present invention relates to a method of binding a tension member and a binding structure using the same, which are capable of simultaneously improving and simultaneously coping with repeated loads.

When constructing high-rise buildings or underground structures of large structures, earth walls or water walls are formed by using H beams, etc. In this case, excavation around earth walls or water walls to prevent collapse due to earth pressure or other external pressure. The ball is formed, anchored in the excavation hole, and then, grout or mortar is cast, and one end of the tension member constituting the anchor is connected to the earth wall and the water wall to improve the bearing capacity.

On the other hand, the tension member generally used to reinforce the earth wall or water wall is bound to the binding structure by using a wedge cone or grip, in particular, in the case of the grip The drawback is that it penetrates into the tension member surface and provides a cause for lowering the rigidity of the tension member.

That is, as shown in FIGS. 10 to 12, in general, when the tension member is bound, the insert 71 is inserted along the length direction of the sleeve 70 and the tension member 72 is inserted into the insert 71, and then each other. The sleeve 70 and the insert 71 are pressed while being radially pressed while passing through a crimping die (not shown).

The sleeve 70 has a cylindrical shape with a predetermined thickness, and the insert 71 has a continuous opening in the longitudinal direction and has a spiral 73 formed along an inner circumferential surface thereof. Therefore, as described above, when the sleeve 70, the insert 71, and the tension member 72 are compressed, the spiral 73 penetrates into the tension member 72 due to the pressing force, and in this state, the tension member 72 When a load is applied in the longitudinal direction, a kind of notch is formed on the outer surface of the tension member 72. As the tensile load is concentrated at the point where the notch is formed, there is a problem that the tension member 72 is damaged. .

Therefore, the present invention was invented to solve the above-mentioned drawbacks, and the insert is compressed and deformed so that the deformed insert is filled between the twisted lines of the tension member, thereby improving the binding force between the tension member and the grip, thereby causing scratches on the tension member. It is an object of the present invention to provide a tensile member binding method and a binding structure using the same, which can prevent the tensile member from being damaged due to its own load or external impact while effectively preventing the occurrence thereof, while simultaneously improving the resistance against repeated loads.

1 is a schematic view for explaining the binding method according to the present invention,

2 is a cross-sectional view taken along line II of FIG. 1;

3 is a cross-sectional view taken along the line II-II in FIG. 1;

4 is a schematic perspective view of an insert according to the invention,

5 is a schematic perspective view of a sleeve according to an embodiment of the present invention;

6 is a schematic cross-sectional view of a sleeve according to an embodiment of the present invention;

Figure 7 is a cross-sectional view of the use state of the grip according to an embodiment of the present invention,

8 is a cross-sectional view taken along line III-III in FIG. 7;

9 is a cross-sectional view taken along the line IV-IV in FIG. 7;

10 is a schematic perspective view of an insert according to the prior art, the corresponding view of FIG.

Figure 11 is a schematic perspective view of a sleeve according to the prior art, corresponding to Figures 5 and 6,

12 is an enlarged cross-sectional view of a binding structure according to the prior art, and is a corresponding view of FIG. 3.

10 --- tension member, 11,19 --- insert,

12 --- crimping dice, 13,17,22 --- sleeve,

14 --- grip, 15 --- helix,

16 --- circular opening, 17 --- fixture,

18 --- engaging projection, 20 --- tapered section,

21 --- fixing hole,

The present invention for achieving the above object, the insert fitting step of inserting the insert into the tension member, the first pressing step of compressing the insert in the radial direction by passing the tension member and the insert through the pressing die, relative to the first crimped insert Heating the sleeve made to have a large diameter to a high temperature, and then inserting the sleeve into the first crimped insert, and the second crimping step of crimping the grip in the radial direction again through the crimping die. It relates to a tension member binding method included.

In another aspect, the present invention is a tension member binding sphere for pressing and tightening the tension member with a grip having an insert and a sleeve, the insert is made of a hollow cylinder shape having a predetermined thickness, the sleeve can accommodate the insert in a hollow cylinder. The present invention relates to a tension member binding structure having an inner diameter having spirals formed along an inner circumferential surface thereof.

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

In the present invention, the insert fitting step of inserting the insert 11 into the tension member 10, the primary pressing crimping the insert 11 in a radial direction by passing the tension member 10 and the insert 11 through the pressing die 12 Step, the sleeve fitting step of heating the sleeve 13 manufactured to have a relatively larger aperture than the primary crimped insert 11 and then inserting it into the primary crimped insert 11, the sleeve 13 While the grip 14 is inserted in the state below the transformation point is heated again through the pressing die 12 for pressing the grip 14 to compress the tension member while going through the second pressing step in sequence. When the compression step is performed, the sleeve 13 is pressed into the insert 11 in a shrinkage state, so that the insert 11 penetrates into the bone formed in the tension member 10 to improve the fixing force of the tension member 10. It is.

Here, the insert 11 has a hollow cylindrical shape having a predetermined thickness as shown in FIG. 4, and the sleeve 13 can accommodate the insert 11 in a hollow cylindrical shape as shown in FIG. 5. The spiral opening 15 is formed along the inner circumferential surface of the crimp die 12 while the circular opening 16 is formed at the center thereof in the form of a disk, and the circular opening 16 is formed in the center thereof. The grip 14 is passed through.

In addition, it is advantageous to use the insert 11 made of a material having a relatively weaker strength than the sleeve 13, such as aluminum alloy or copper alloy.

In addition, the sleeve may be used in a different form, as shown in Figure 6 using the sleeve 17 is formed with a locking projection 18 at the bottom of the inner peripheral surface to increase the mounting force and the pressing force of the insert (11) This makes it possible to further improve the overall rigidity of the grip 14.

On the other hand, the present invention can be pressed and fixed to the tension member with the insert and the sleeve having a tapered portion, that is, the insert 19 having a tapered portion 18 on one side, as shown in Figure 7, while the inner peripheral surface is tapered The taper portions 18 and 20 are inserted into the sleeve 22 having the fixing holes 21 connected to the taper portion 20 so as to be in contact with each other, and the tension member 10 is inserted into the insert 19 and the sleeve 22. After pressing the insert 19 in the direction shown by the arrow, as shown in the dotted line, the insert 19 is pressed onto the sleeve 22 so that the tension member 10 is fixed.

Next, the operation and effects of the present invention will be described.

When the insert 11 and the sleeve 13 are pressed in the above-described manner, the insert 11 is filled with a groove between the element wires constituting the tension member 10, and the insert 11 deformed as shown in FIG. By being located in the space between the 10 and the sleeve 13, the tension member 10 is firmly bound to the grip (14).

When the tension member 10 is compressed to the grip 14, the insert 11 comes into contact with the sleeve 13, so that a load is applied to the tension member 10 bound by the spiral 15 formed in the sleeve 13. It is possible to effectively prevent the insert 10 from sliding even if the shear force acts along the longitudinal direction to further improve the overall binding force of the fixture 17.

In addition, when the tension member 10 is bound with the sleeve 17 having the engaging protrusion 18 formed at one end thereof, one side of the insert 11 may slide even if the insert 11 slides due to the load acting on the tension member 10. The front end is prevented from being caught by the catching protrusion 18 to be separated from the outside of the sleeve 17, and thus the insert 11 is pushed back so as to refill the portion which is not completely positioned, and the tension member 10. ) Is supported by the locking projection 18 can also improve the fixing force.

As described above, according to the present invention, the insert is artificially deformed so that the deformed insert is filled between the twisted wire strands of the tension member, thereby improving the binding force between the tension member and the grip, thereby effectively preventing scratches on the tension member. It is to prevent the tension member from being damaged due to its own load or external impact, and to improve the resistance to repeated loads.

Claims (4)

Insert fitting step of inserting the insert into the tension member, first crimping step of compressing the insert radially by passing the tension member and insert through the crimping die, and a sleeve made to have a relatively larger aperture than the primary crimped insert Tension material binding including a sleeve fitting step of heating and inserting the first crimped insert, and a second crimping step of pressing the grip again radially through the crimping die while heating the grip with the sleeve below the transformation point. Way. 10. A tension member fastener, wherein the tension member is configured to press-bond the tension member with a grip having an insert and a sleeve. The insert is made of a hollow cylindrical shape having a predetermined thickness, the sleeve has an inner diameter that can accommodate the insert in a hollow cylindrical shape, but a spiral is formed along the inner circumferential surface, the insert fills the bone formed between the element wire of the tension member Tension binding in the state and the tension member binding structure, characterized in that the sliding of the insert is prevented through the spiral. 3. The tension member binding structure as claimed in claim 2, wherein a tapered portion is formed in the insert. 3. The tension member binding structure as claimed in claim 2, wherein the sleeve has a tapered portion on an inner circumferential surface thereof.