KR101604581B1 - Method of wire bonding and wire fixture fixture - Google Patents

Abstract

A wire fixture (10) of the present invention includes: a horizontal linear unit on one side of the outer circumference, at least one gripper formed into an inclined part connected to the liner unit and having a pressing groove in the inner circumference; a pair of wedges joined to the outer circumference of a steel wire by a ring member joined in the other side of the gripper; and a housing joining the wedges by forming an internal inclined hole. The internal inclined hole is composed of a first inclined hole formed inward from one side, a linear hole having a horizontal inner circumference connected to the first inclined hole, and a second inclined hole connected to the linear hole and formed in the other side of the inclined hole. The steel wire, the center of the grippers, and the center of the inclined holes coincide all together when extending the steel wire after penetrating the steel wire through the inclined holes by joining the wedges, which are joined to the steel wire, to the inclined holes and joining linear units of the wedges to the inclined holes. Thus, each of the grippers around the outer circumference of the steel wire is joined to the inclined hole without twisting. The purpose of the present invention is to provide a stable fixing force of the steel wire fixture.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of joining a wire fastener and a wire fastener,

More particularly, the present invention relates to a method of joining a steel wire fastener and a steel wire fastener, and more particularly, to a method of joining a steel wire fastener and a steel wire fastener, To a method of joining steel wire anchors and steel wire anchors, wherein inner and outer peripheries of respective wave cores are combined with an inner and outer peripheries of the steel wire and the inclined wire by an even contact distribution diagram to provide a stable fixing force of the wire anchor.

Construction method of civil structure The construction method to prevent the structure from collapsing and falling by external force such as earthquake, wind, water pressure, and earth pressure is divided as follows.

As shown in Fig. 1, (a), (b), (c), (c) and (e) The construction of various civil engineering and constructional structures such as the prevention of falling of steel towers and large chimneys and the construction of various kinds of buildings such as high-rise buildings is required to be carried out by an external force such as earthquake, wind pressure, In order to prevent collapse or conduction, various constructional structures are supported and fixed using a ground anchor.

Construction work for construction of various civil engineering and architectural structures to build various buildings such as construction work, stabilization construction of pier of (E), prevention of steel tower and large chimney of (B), and other high- In order to prevent the structure from collapsing or being conducted by an external force such as earthquake, wind force, water pressure, and earth pressure, various construction structures are supported and fixed using a ground anchor.

As shown in FIG. 2, the ground anchor used for supporting and supporting the various construction structures as described above is formed by forming a concrete pouring layer having a predetermined thickness on the ground surface such as the upper surface or the side surface of the ground where the pillar structure is constructed, A hole is drilled at a predetermined depth from the ground layer. After the hole is drilled in the ground, the fish strand 1 is extruded and inserted into the distal end portion by a predetermined length.

Thereafter, a liquid or gel grout material is injected into the perforated hole to fix the fish strand 1 in the perforated hole, and a "H" beam or metal Anchor plate and anchor made of a plate material are provided on the outer side of the anchor, and a fish-shear line clamping and fixing means is provided for clamping and fixing the exposed end of the fish-like strand 1 exposed to the outside of the anchor.

After the fish strand 1 having a long length and a large tensile strength as described above is buried deep in the ground, the fish strand 1 is stretched through the distal end of the fish strand 1 exposed to the outside of the ground.

Thereafter, the fiber strand is fixed by the clamping means.

Accordingly, even when the construction structure is shaken by an external force such as an earthquake, a wind force, a water pressure, or a biased earth pressure, the ground anchor including the fish strand 1 can firmly hold the structure to prevent collapse or conduction of the structure will be.

3, the exposed end of the wire strand 1 exposed to the outside of the anchor bracket passes through the tapered hole 11, And a collet chuck type wedge 100 inserted into the tapered hole 11 of the anchor 10 in a wedge-like manner.

The wedge 100 is divided into three sections by respective cut-out portions formed at a predetermined angle. The wedge 100 is provided on the inner side of each cut-off piece along the inner periphery of a through hole (not shown) through which the fish strand 1 passes, A plurality of clamping teeth (not shown) for clamping are formed.

When clamping the fish wire strand 1 by using the conventional anchor 10 and the wedge 100 having the above-described configuration, as shown in FIGS. 2 and 3, through the taper hole 11 of the anchor 10 provided with the wedge 100 The wedge 100 is inserted into the wedge shape on the anchor 10 outside the fish strand 1 while the fish strand 1 is inserted so as to penetrate the fish strand 1. When the tensile force is removed after pulling the fish strand 1, 1, the wedge 100 is pulled more strongly into the tapered hole 11 to strongly fix the tensile state of the wire strand 1.

In other words, as the wedge 100 is pushed toward the tapered hole 11 side of the anchor 10 while pulling the fish strand 1 outwardly, the wedge 100 formed in a collet chuck shape is wedged into the inside of the tapered hole 11.

At this time, in the wedge 100, as the three incision pieces are contracted inward, first, the incised portion where the entire thickness of the body of the body is incised is swollen, so that both end portions of the incision groove are in close contact with each other.

The three shrinking incisions thus securely fasten the fish strand 1 and firmly fix the end exposed to the outside of the fish strand 1.

As described above, after the end portion exposed to the outside of the fish strand 1 is firmly fixed, the operation of installing the wedge 100 and the anchor 10, which are the clamping fastening means of the fish strand 1, is completed by removing the pulling force of the fish strand 1, The wire strand 1 embedded in the wire pulls the building structure with a strong tensile force so that it is possible to prevent the building structure from being collapsed or conducted by an external force such as an earthquake, wind force, water pressure,

However, as shown in Fig. 4, in the initial stage in which the wedge 2 having the fish wire strand 1 passed through the anchor 4 is installed on the inner inclined hole 3 of the anchor 4 in the process of installing the wedge 2 and the anchor 4, Any one of the plurality of interdigitated pieces 2 is brought into close contact with the lower peripheral edge of the inclined hole 3, and on the contrary, the incised piece 2 located on the opposite side generates a peripheral edge and a gap in the inclined hole 3.

That is, when the wedge 2 coupled to the strand 1 is engaged with the inclined hole 3 of the anchor 4, the inclined outer periphery of the wedge 2 is not correctly engaged with the inclined hole 3 while being bent by the weight of the strand 1 passing through the anchor 4 .

When the strand 1 is pulled in the state in which the centers of the inclined balls 3 of the strand 1, the wedge 2 and the anchor 4 are not coincident with each other on the same axis, when the wedge 2 is pulled in the inclined hole 3, The separate piece 2 in a state in which it is in close contact with the inclined hole 3 can not be inserted into the inclined hole 3 due to frictional force.

As a result, although any one of the plurality of incisions 2 is inserted into the inclined hole 3, the incised piece 2 at another portion can not be inserted into the inclined hole 3, so that the incised piece 2 is combined with an accurate and uniform contact distribution The fixing force of the wedge is weakened.

Particularly, the inner circumference of the three-piece piece 2 for clamping the strand 1 is not in the full-circle state as in the outer circumference, so that it can not contact the outer circumferential surface of the strand of the strand 1 as a whole.

As described above, since the outer circumferential surface of the fish strand 1, the inner circumferential surface of the wedge 4 composed of the three-section piece 2, and the outer circumferential surface of the wedge 2 do not entirely contact each other, the outer circumferential surface of the fish strand 1 and the inner circumferential surface of the three- Point contact.

As described above, the fish strand 1 is easily damaged from the contact portion subjected to the concentrated load due to the concentrated load only at the contact portion which is in point contact or line contact, and the fish strand 1 is gradually broken, Is reduced.

In addition, since the outer periphery does not entirely contact the periphery of the outer periphery of the wedge 2 and the inner periphery of the inclined hole 2, a concentrated load due to point contact is also generated in the outer periphery of the wedge 2.

As a result, the inner peripheral shape of the inclined hole 3 deforms abnormally while overpressure is applied to a specific portion on the periphery of the inclined hole 3 which is in point contact. And the tilted hole 3 that fails to overcome the pressure tilts to the adjacent tilted hole 3, so that the stable state of the wedge 2 and the anchor 4 can not be maintained.

Further, since the pressure applied to the strand 1 due to the stratification changes from time to time, the stress imposed on the strand of strand 1 due to the pressure change is concentrated on the anchor 4 and the wedge 2, There has been a problem that the problems that have been caused by the above problems are further accelerated.

When the multiple pieces 2 are completely inwardly inserted into the inclined hole 3 of the anchor 4, there is a problem that when the pressing force of the wedge 2 is concentrated on the strand 1 in front of the wedge 2 and exceeds the cutting limit load of the strand 1, there is a problem.

That is, the wedge 4 coupled to the strand 1 enters the inside of the inclined hole 3 by the tension of the strand 1 and when the tensile force of the strand 1 is released, the wedge 2 further enters the inclined ball 3 by the elastic restoring force of the strand 1 The pressing force is concentrated on one side of the inclined hole 3 and one side of the wedge 2.

At this time, the position where the pressing force of the wedge 2 is concentrated on the strand 1 is applied to the ground anchor, and is located in front of the clamping and fixing means that both sides of the stretched strand 1 are fixed. Thus, when the strand is broken, the function of the ground anchor .

Korean Patent Publication No. 2001-0106612, (December 13, 2001) Korean Patent Publication No. 2008-0006448, (December 23, 2008)

In order to solve the above-mentioned problems, the present invention provides a steel wire fastener, wherein the wedge coupled to the steel wire is coupled to the housing, and when the steel wire is tensioned, the center of the steel wire, the wedge and the slanted hole are coaxially aligned, And to provide a stable clamping force of the steel wire fastener by combining the inner and outer circumferences of the steel wire and the slant hole with an even contact distribution.

It is another object of the present invention to provide a wedge having an inclined hole angle larger than an inclined angle of a wedge so as to be inserted into an inclined hole so as to make the pressing force of one side and the other side of the wedge, The pressing force is penetrated through the housing rather than the tensile strength of the steel wire, so that the pressing force is more concentrated on the exposed steel wire portion so that the steel wire portion exposed by the fixing wire is cut off, not the tensile portion of the steel wire, even if the cutting limit load is applied to the steel wire. have.

Another object of the present invention is to provide a wedge having an outer circumferential diameter larger than one of the circumferential diameters in the inlet of the oblique hole, And the like.

In order to accomplish the above object, the present invention provides a steel wire fastener comprising a horizontal straight portion formed on one side of an outer periphery, at least one waveguide having an inclined portion connected to the straight portion, A wedge that is coupled to the other side of the waveguide through a ring member to the outer periphery of the steel wire, and a wedge formed by forming an inclined hole in the wedge, wherein the inclined hole has a first inclined hole formed inwardly from one side thereof, And a second inclined hole formed in a direction of a side of the inclined hole to form a straight hole having a horizontal inner periphery joined to the first inclined hole, wherein the wedge coupled to the steel wire is connected to the inclined hole And then the straight line portion of the wedge is coupled to the straight hole of the housing, and when the steel wire is pulled, the steel wire and the plurality of grips As the center of the ball coincides with the center of the gradient is maintained in contact with the combined interview distribution even at the outer liner periphery, each of the waves without the earth has changed position state from the outer liner periphery.

According to the present invention, it is preferable that the wedge is formed such that the outer peripheral angle of the wedge outside the inclined portion is smaller than the peripheral angle of the first inclined hole with respect to the inclined ball inlet of the housing, And the main pressing part located on the other side has a large pressing force.

According to the present invention, the waveguide is configured to be able to engage the ring member by forming a coupling groove on the outer circumference of the other side.

According to the present invention, the waveguide forms a pressing portion protruding from the outer circumferential end of the other side.

According to the present invention, a pressurizing hole having a horizontal inner circumferential edge is formed at the first inclined-ball inlet, and the inner circumferential diameter of the pressurizing hole is formed to be smaller than the outer circumferential diameter of the pressing portion formed at the other side of the wedge.

A method for joining steel wire fasteners according to the present invention comprises a step of joining a wedge formed by joining a plurality of waveguides to a circumferential outer periphery of a steel wire in one refinement and a step of passing the steel wire through an oblique hole formed in a housing, A step of tensioning the steel wire so that the center of the steel wire and the wedge and the center of the inclined hole are coincident with each other while concentrating the center of the steel wire and the wedge so as to press the steel wire into the tilted hole, And the tension of the steel wire is maintained by pushing the steel wire while the wedge is fully penetrated into the inclined hole by the elastic restoring force of the wire.

According to the present invention, in the second step, a horizontal straight portion formed at one side of the inclined portion formed on the outer periphery of the wedge is inserted into a straight hole having a horizontal inner periphery formed in the inclined hole, and a wedge The center of the steel wire and the wedge and the center of the tapered hole coincide with each other concentrically so as to be joined without changing the position of each of the waveguides coupled to the outer periphery of the steel wire and at the same time, The contact area distribution map.

According to the present invention, in the step 3, the inclined hole of the housing is formed such that a first inclined hole from one side to the other side, a straight hole with a horizontal inner periphery, and a second inclined hole are continuously joined, And the first inclined hole and the second inclined hole are formed so as to be larger than the angle of the inclined portion of the wedge so that the outer peripheral edge of the wedge is pressed against the outer peripheral edge of the wedge, The main pressing part located on the other side of the sub-pressing part located on one side of the pressing groove is larger in pressing force.

According to the present invention, the step 3 is formed such that the diameter of the pressing part protruding from one side of the wedge is larger than the inner peripheral diameter of the horizontal pressing hole formed at the first inclined-ball inlet, so that the pressing part is engaged .

As described above, the steel wire fastener of the present invention is characterized in that the steel wire fastener of the present invention is provided with at least one waveguide formed with a horizontal straight portion on one side of the outer circumference and an inclined portion connected to the straight portion, A wedge which is coupled to the other side of the earth through a ring member in a modified manner on the outer periphery of the steel wire, and a wedge formed by forming an inclined hole in the inside, wherein the inclined hole has a first inclined hole formed inward from one side thereof, And a second inclined hole formed in a direction of a side of the inclined hole to form a straight hole having a horizontal inner periphery joined to the ball and joining the wedge coupled to the steel wire to the inclined hole, When the straight portion of the wedge is coupled to the straight hole of the housing and then the steel wire is pulled, the center of the steel wire and the plurality of waveguides is inclined The wedge coupled to the steel wire is coupled to the housing and the center of the steel wire, the wedge and the tapered hole are coaxially aligned with each other when the steel wire is tensioned So that the inner and outer circumferences of the respective wave zones are coupled to the inner and outer circumferences of the steel wire and the inclined ball with an even distribution of contact so as to have a stable fixing force of the wire wire fastener.

The steel wire fastener according to the present invention is characterized in that the angle of inclination of the housing is made larger than the angle of the inclined face of the wedge so that the pressing force of one side and the other side of the wedge pressurizing the outer periphery of the steel wire, So that the portion of the steel wire exposed by the fixture is cut off not by the tensile portion of the steel wire even if the cutting limit load is applied to the steel wire to break the steel wire , And the tension of the steel wire is maintained.

The steel wire fastener of the present invention is formed such that the outer circumferential diameter of one side of the wedge is formed larger than the circumferential diameter of the entrance of the oblique hole so that when the wedge is fully engaged with the inclined hole of the housing and is engaged with the inclined hole, It is possible to further improve the performance.

Figs. 1 (a) to 1 (b) are illustrations showing examples in which various constructions of a civil engineering structure are fixed as ground anchors. Fig.
2 is a cross-sectional view showing a state in which a wire fastener according to the related art is installed.
3 is an enlarged cross-sectional view showing a wire fastener according to the related art.
FIGS. 4, 5 and 6 are flowcharts showing a state of engagement of a wire fastener according to a related art.
7 is a perspective view showing a wire fastener of the present invention.
8 is a perspective view showing a wedge of a wire fastener of the present invention.
9 is a sectional view showing a wedge of a wire fastener of the present invention.
10 is a cross-sectional view showing a housing of a wire fastener of the present invention.
11 is a cross-sectional view showing a state in which a steel wire is pulled after joining a wedge to an inclined hole in a steel wire fastener of the present invention.
FIGS. 12, 13 and 14 are cross-sectional views showing a state in which a wedge enters and is engaged with an inclined hole after the tension of a steel wire is removed from the steel wire anchor according to the present invention.
15 is an enlarged cross-sectional view showing a state in which a steel wire is pulled after joining a wedge to an inclined hole in the steel wire fastener of the present invention.
FIGS. 16, 17 and 18 are enlarged cross-sectional views showing a state in which a wedge enters and is engaged with a tapered hole after the tension of a steel wire is removed from the steel wire fastener of the present invention.
19 is an enlarged cross-sectional view showing the angle difference between the inclined portion of the wedge and the inclined portion of the steel wire fastener of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that, in the drawings, the same components or parts have the same reference numerals as much as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

As used herein, the terms " about, " " substantially, " " etc. ", when used to refer to a manufacturing or material tolerance inherent in the stated sense, Accurate or absolute numbers are used to help prevent unauthorized exploitation by unauthorized intruders of the referenced disclosure.

FIG. 7 is a perspective view showing a wire fastener according to the present invention, FIG. 8 is a perspective view showing a wedge of the wire fastener of the present invention, FIG. 9 is a cross sectional view showing a wedge of the wire fastener of the present invention, 11 is a cross-sectional view showing a state in which a steel wire is pulled after a wedge is coupled to a tapered hole in a steel wire fastener of the present invention, and Figs. 12, 13 and 14 are cross- FIG. 15 is an enlarged cross-sectional view showing a state in which a steel wire is pulled after a wedge is coupled to an inclined hole in the steel wire fastener of the present invention, and FIGS. 16 and 17 18 is an enlarged cross-sectional view showing a state in which the wedge enters into the inclined hole after the tension of the steel wire is removed from the steel wire anchor according to the present invention, and FIG. 19 is an enlarged cross- 5 is an enlarged cross-sectional view showing the angle difference between the inclined portion and the inclined portion of the wedge.

7 to 19, in the steel wire fastener 10 of the present invention, the steel wire 300 is inserted into the hole drilled to reinforce the ground of the vertical excavation wall, and the concrete mortar is filled in the hole, The fixture 10 is provided at both ends of the mold 300.

When the steel wire 300 is pulled, the fastener 10 maintains the tension of the steel wire 300.

The wedge 100 fixed to the steel wire 300 is coupled to the housing 200, and the center of the steel wire 300, the wedge 100, and the slanted hole 220 are aligned on the same axis when the wire 300 is pulled, The inner circumferential surface and the outer circumferential surface of the wave zones 100a, 100b, and 100c are coupled to the inner and outer circumferences of the steel wire 300 and the inclined ball 220 in an even contact distribution.

The steel wire 300 fixture 10 of the present invention which enables this is composed of a wedge 100 and a housing 200.

The wedge 100 is provided with one or more waveguides 100a, 100b, and 100c having a horizontal straight portion 110 on one side of the outer circumference and an inclined portion 120 connected to the straight portion 110 and having a pressing groove 160 on the inner circumference And is coupled to the outer side of the steel wire 300 through the ring member 150 on the other side of the waveguide 100a, b, c.

It is explained that the wave earths 100a, 100b, 100c, and 100c are not limited to three.

The waveguides 100a, 100b, and 100c have the same shape, and are divided into 120 DEG angles and assembled into a wedge 100 having a 360 DEG angle.

The shape of each of the waveguides 100a, 100b, and 100c has an inclined plane from one side to the other side of the outer periphery of the tip.

At this time, a linear portion 110 formed horizontally is formed on one outer peripheral side of the waveguides 100a, 100b, and 100c, that is, a portion having a small diameter.

In addition, a coupling groove 140 for coupling the ring member 150 having elasticity to the outer peripheral side of the waveguide 100a, b, c, that is, the large diameter portion, is formed.

The inner circumferences of the wave zones 100a, 100b, and 100c have pressing grooves 160 formed of spiral or serration protrusions.

The plurality of waveguides 100a, 100b, and 100c constituted in this way are composed of a wedge 100 that is coupled through a ring member 150 in one modification.

The housing 200 is formed with an inclined hole 220 therein to engage the wedge 100. The inclined hole 220 is formed with a first inclined hole 220 inwardly from one side and a horizontal inner edge connected to the first inclined hole 220 And a second inclined hole 223 which is formed in the direction of the other side of the inclined hole 220 by being joined with the linear hole 222.

As described above, the wedge 100 and the housing 200, which are configured as described above, couple the wedge 100 to the outer periphery of the steel wire 300 and then engage with the inclined holes 220 of the housing 200.

When the straight line 110 of the wedge 100 is coupled to the straight hole 222 of the housing 200 and then the steel wire 300 is pulled, the center of the steel wire 300 and the plurality of waveguides 100a, 100b, And each of the wave zones 100a, b, and c at the outer periphery of the steel wire 300 is coupled to the outer periphery of the steel wire 300 without changing the position, while being in contact with the center of the ball 220. [

19, the outer circumferential angle of the inclined portion 120 of the wedge 100 is formed to be smaller than the circumferential angle of the first inclined hole 221 by the angle of inclination of the entrance of the inclined hole 220 of the housing 200, So that the main pressing portion 161 located on the other side of the sub-pressing portion 162 located on one side of the pressing groove 160 for pressing the peripheral edge has a larger pressing force.

That is, the angle of the inclined ball 220 of the housing 200 is made larger than the angle of inclination of the wedge 100 so that the pressing force of one side and the other side of the pressing groove 160 of the wedge 100, which presses the outer periphery of the steel wire 300, The pressing force of the wedge 100 is not concentrated on the portion of the steel wire 300 where the pressing force of the wedge 100 is stretched but is concentrated on the portion of the steel wire 300 that is exposed through the housing 200 so that the pressing force is concentrated on the portion of the steel wire 300, So that the tensioned state of the steel wire 300 is maintained.

The waveguides 100a, 100b, and 100c form a pressing part 130 protruding from the other outer circumferential end.

The outer circumferential diameter of the pressing portion 130 is formed to be larger than the diameter of the pressing hole 210 having a horizontal inner circumference at the entrance of the inclined hole 220. When the wedge 100 is fully engaged with the inclined hole 220 of the housing 200, So that the fixing force is further improved.

As described above, the joining method of the formed wire fastener 10 is as follows.

A step of joining the wedge 100 to the steel wire 300; a step of pulling the steel wire 300 after joining the wedge 100 and the steel wire 300 to the inclined hole 220 of the housing 200; and a step of pulling the wedge 100 Is completely inserted into the inclined hole 220 and is coupled.

Specifically, in the first step, a plurality of waveguides 100a, 100b, 100c, and 100c are circularly arranged on the outer periphery of the steel wire 300, and then the wedge 100 having the plurality of waveguides 100a, 100b, do.

9 and 15, in the second step, when the inclined portion 120 of the outer periphery of the wedge 100 is inserted into the inclined hole 220 formed of the steel wire 300 in the housing 200, the steel wire 300 and the wedge 100 The center of the inclined ball 220 and the center of the inclined ball 220 are aligned on the same axis, and the steel wire 300 is pulled to press the steel wire 300 while the wave cores 100a, 100b, and 100c are inserted into the inclined hole 220.

Particularly, in the step 2, a horizontal straight portion 110 formed at one side of the inclined portion 120 formed on the outer periphery of the wedge 100 is inserted into a straight hole 222 having a horizontal inner periphery formed inside the inclined hole 220, The center of the steel wire 300 and the wedge 100 and the center of the tapered hole 220 coincide concentrically with each other when the wedge 100 is coupled to the ball 220 and the wire segments 300 are tilted at the outer periphery of the steel wire 300, And is pressed to the outer circumferential edge of the steel wire 300 with an even contact area distribution diagram of each of the wave zones 100a, 100b, and 100c.

As shown in FIGS. 12, 13, 14, 16, 17 and 18, in the third step, when the tensile state of the steel wire 300 is released, the wedge 100 is completely retracted into the inclined hole 220 due to the elastic restoring force of the steel wire 300 So that the tension of the steel wire 300 is maintained.

In the third step, the inclined holes 220 of the housing 200 are formed such that the first inclined holes 220, the straight holes 222 having a horizontal inner peripheral edge, and the second inclined holes 223 are continuous from one side to the other side, The linear portion 110 of the wedge 100 enters into the second inclined hole 223 by the resilient restoring force of the steel wire 300. At the same time, the first inclined ball 220 and the second inclined ball 223 are inclined with respect to the inclination of the wedge 100 So that the main pressing portion 161 located on the other side of the sub-pressing portion 162 located on one side of the pressing groove 160 for pressing the outer periphery of the steel wire 300 has a large pressing force.

This is because the angle of the inclined hole 220 of the housing 200 is made larger than the inclined angle of the wedge 100 so that the pressing force of one side and the other side of the pressing groove 160 of the wedge 100, The pressing force of the wedge 100 is not concentrated on the portion of the steel wire 300 where the pressing force of the wedge 100 is stretched but is concentrated on the portion of the steel wire 300 exposed through the housing 200 so that the cutting force is concentrated on the portion of the steel wire 300, So that the tensile state of the steel wire 300 is maintained.

The third step is formed so that the diameter of the pressing part 130 protruded from one side of the wedge 100 is larger than the inner peripheral diameter of the horizontal pressing hole 210 formed at the entrance of the first inclined hole 221, So that the fixing force of the steel wire 300 of the wedge 100 is improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be clear to those who have knowledge of.

10: Fixture
100: wedges 100a, b, c:
110: rectilinear section 120: inclined section
130: pressing portion 140: engaging groove
150: ring member 160: pressurized groove
161: main pressing portion 162:
200: housing 210:
220: inclined ball 221: first inclined ball
222: straight hole 223: second inclined hole
300: Steel wire

Claims (9)

delete delete delete delete delete In order to reinforce the ground of the vertical excavation wall, the steel wire is inserted into the perforated hole, and in the hole, the fixing mortar is fixed to both ends of the steel wire while the concrete mortar is filled, so that the steel wire is tensioned The method comprising the steps of:
A first step of joining a wedge in which a plurality of wave earths are combined by a modification on the outer periphery of the steel wire,
A horizontal straight portion formed on one side of the inclined portion formed on the outer periphery of the wedge when the inclined portion of the outer periphery of the wedge is inserted into the inclined hole through the inclined hole formed in the housing, And the wedge is engaged with the tapered hole of the housing, and when the steel wire is tensioned, the center of the steel wire and the wedge and the center of the tapered hole coincide with each other concentrically so that they are combined without changing the positions of the respective waveguides coupled to the outer periphery of the steel wire At the same time, two stages of pressing the outer circumferential edge of the steel wire with an even contact area distribution diagram,
Wherein the inclined hole of the housing is formed such that a first inclined hole from one side to the other side, a straight hole with a horizontal inner periphery, and a second inclined hole are continuously formed, and when the tensile force is released from the steel wire, And the first inclined hole and the second inclined hole are formed so as to be larger than the angle of the inclined portion of the wedge, so that the sub-pressing portion located on one side of the press- The pressing force of the main pressing part located on the other side is higher than the pressing force of the part so that the cutting limit load is applied to the steel wire to cut the steel wire part exposed to the housing pressed by the main pressing part rather than the tensile part of the steel wire, And maintaining a tensioned state of the steel wire. delete delete The method according to claim 6,
In the third step,
Wherein a diameter of the pressing portion protruded on one side of the wedge is larger than an inner peripheral diameter of a horizontal pressing hole formed in the first inclined-ball inlet, so that the pressing portion is forcedly engaged with the pressing hole. Way.

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