KR101498343B1 - Ground anchor head fixing syatem - Google Patents

Abstract

The present invention can prevent deviation of the load plate and smooth angle adjustment, prevent the stress concentration and buckling deformation of the arcuate anchor bracket, prevent the buckling of the H-shaped steel strip by the ground pressure generated from the two axes And provides a ground anchor tofu fixation system.
A preferred embodiment of the ground anchor head fixing system according to the present invention comprises: an angle adjustable earth anchor bracket that is mounted on upper and lower adjacent H-shaped steel wales; A stiffener for preventing buckling of the H-shaped steel band strip;
The stiffener comprising: a stiffener body detachably mounted on a web of an H-shaped steel strip; A pair of paper compacts arranged side by side at a constant axial distance on the stiffener body and rotatable independently from each other at a predetermined position; And an acupressure pad which is threadedly coupled to the other end of each of the pair of compression so as to move forward and backward in a predetermined section.

Description

{Ground anchor head fixing syatem}

The present invention relates to a ground anchor head fixing system, in particular, it is possible to prevent separation of anchor fixing position and smooth angle adjustment, prevent stress concentration and buckling deformation of an anchor bracket forming an arched shape, To a ground anchor head fixing system capable of efficiently suppressing buckling of an H-shaped steel band.

Generally, an earth anchor method is widely used as a method for supporting a temporary wall against earth pressure such as earth pressure or water pressure acting on a retaining wall during excavation work of civil engineering or construction work, together with a method using a wale and a strut. In the conventional earth anchor method, a wale band made of H beams is installed in a hypothetical wall, and a perforation hole is formed toward the back side of the hypothetical wall. Thereafter, the steel wire is inserted into the perforation hole, and then the steel wire is fixed by grouting. At this time, part of the steel wire is exposed for a certain length in the perforation hole. Then, the bracket for the earth anchor is inserted into the strand, and the strand is fixed to the strand, and the strand is taut and fixed to the earth anchor bracket so that the upright wall is maintained upright and the side pressure is resisted.

On the other hand, if the angle of the perforation hole is slightly changed, the insertion angle of the steel wire changes, so that the fixing position of the steel wire must be shifted. In order to achieve this, a method of fixing the side plate and the pressure plate to each other using a tooth-type coupling structure has been used. However, when the pressure applied by the anchor body is continuously applied to the side plate, It is easy to break or buckle, and it is also very difficult to adjust the angle of the steel wire. Also, when the worker is installed outside the anchor body installation position of the pressure plate, the eccentricity problem (buckling, deformation, stress concentration) due to angle discrepancy may occur in the specific tooth of the coupling structure. In this case, as the tensional load increases on the tread, the problem of separation of the tread is out of the width of the bracket.

As a background technique for solving such a problem, Korean Patent Registration No. 10-0760213 discloses an earth anchor bracket having a curved portion formed with teeth. Two side plates formed with curved portions having teeth and facing each other; A connecting member for connecting and fixing the both side plates; And support means supported by the both side plates and having a latching jaw that mates with the teeth of the both side plates and a penetrating portion for pulling out the free length of the anchor body.

However, the earth anchor bracket does not provide an alternative to prevent the stress concentration and the buckling deformation of the arcuate side plate.

On the other hand, when the earthworks is constructed, piles are installed to construct the earth retaining walls. Because the earth retaining walls are subjected to earth pressure, the struts are installed horizontally between the walls facing each other or adjacent to each other. At this time, a screw jack is installed on the strut so that the compressive force is generated in the longitudinal direction, and the H-shaped steel band is installed on the retaining wall so that the supporting force acts widely on the retaining wall.

In this case, if the strength of the H-section steel is not sufficient or the jacking force is excessively increased, the H-section steel band receives the supporting force of the screw jack continuously to support the retaining wall, and local buckling due to shear force and bending stress acting on the H- . This buckling damages the support force of the strut, which hinders the stable strut construction of the earth retaining wall.

As a background to solve this problem, Korean Registered Utility Model Registration No. 20-0270234, which is a registered stapler jack, is presented. In this case, a bolt inserting hole is formed in a support plate integrally formed with an inlet of a gap adjusting rod formed with a non-slip hole and a threaded portion, and a base plate is formed so that the bolt inserting hole of the bottom plate can be communicated. And is coupled with a control rod.

However, the civil stiffener jack exerts its supporting force on only one axis of the gap adjusting rods. Therefore, when the area for preventing buckling is narrowed, and the stress generated in the gap adjusting rods is large, the buckling force is liable to prevent buckling.

Korea Patent Registration No. 10-0898830 Korean Registered Utility Model Registration No. 20-0344979 Korea Patent Registration No. 10-0851062

The present invention can prevent deviation of the load plate and smooth angle adjustment, prevent the stress concentration and buckling deformation of the arcuate anchor bracket, prevent the buckling of the H-shaped steel strip by the ground pressure generated from the two axes And to provide a ground anchor tofu settlement system.

A suitable embodiment of the ground anchor head fusing system according to the present invention,

An angle adjustable earth anchor bracket mounted on upper and lower adjacent H-shaped steel wales;

A stiffener for preventing buckling of the H-shaped steel band strip;

The stiffener

A stiffener body detachably mounted on the web of the H-shaped steel band strip;

A pair of paper compacts arranged side by side at a constant axial distance on the stiffener body and rotatable independently from each other at a predetermined position;

And an acupressure pad which is threadedly coupled to the other end of each of the pair of compression so as to move forward and backward in a predetermined section.

In addition, the stiffener body may include:

A fixing plate having a width and a predetermined length suitable for gripping by hand;

A fulcrum support plate which is integrally bent at right and left sides of the fusing plate at opposite ends thereof so as to face each other;

And at least one attachment magnet provided on an upper surface of the fusing plate;

And a compression support bushing having an annular retaining groove and a compression support hole is formed in the shaft support plate on one side and a compression support hole is formed on the other shaft support plate to support the compression.

In addition, the above-mentioned acupressure lever is provided with a boss having a threaded hole to be engaged with a male thread portion of each boss, and a circular boss having a cross-sectional area expanded at the tip of the boss.

Further, the paper compression includes a rotation operation part having a polygonal cross section over a predetermined interval.

Further, the stiffener is further provided with a cylindrical sleeve for supporting rotation of paper compression on the shaft support plate.

In addition, the finger grip is configured to linearly move by a guide rod whose one end is inserted into the guide hole of the stiffener body and the other end is fixed to the finger grip.

Further, in the earth anchor bracket for angle adjustment,

A pair of vertical plates having upper arc curved surfaces along a predetermined radius of curvature in a section of a predetermined angle and arranged to face each other at regular intervals;

An upper and lower flare prevention plate which is joined to the upper and lower inner sides of the pair of vertical plates to prevent the fulcrum of each fulcrum;

A ground expansion plate having a curved surface having the same curvature as that of the upper arch curved surface of the pair of vertical plates;

A release plate preventing plate mounted on the outer surface of the upper arch curved portion of the pair of vertical plates to prevent release of the load plate; And

And a load plate which is supported on both the upper arch curved surface of the pair of vertical plates and the upper surface of the ground spreading plate for stress dispersion and which can be moved within a certain angle of the arch curved surface.

Further, a plurality of angular adjustment stoppers provided at predetermined intervals within a predetermined angle are provided on the inner surface of the earth expanding plate for both stress distribution,

The above-

A lower plate upper plate having a through hole at the center of a flat upper surface;

A pair of load plate grounding blocks provided on both sides of the underside of the load plate top plate and having a ground curved surface simultaneously contacting the curved surface portion of the arcuate surface of the vertical plate and the curved surface portion of the ground expansion plate,

A load plate engaging plate disposed at a right angle to the pair of load plate grounding blocks and having engaging jaws selectively engaged with the angle adjusting stopper at both ends;

And a load plate guide rod which is installed at the lower end of the load plate clamping plate and is guided along the bottom surface of the earth expansion plate for stress dispersion and when the load plate is moved.

Further, the present invention is further characterized in that a buckling preventing stress dispersing plate is further provided, which is connected to the inner surface of the pair of vertical plates near the lower end portion preventing plate.

Further, the upper and lower branch plates are further attached to the upper and lower ends of the pair of vertical plates, respectively.

Further, a local stress stiffener is further provided to prevent concentration of stress on the curvature of the lower arch curved surface in the outer surface side angle adjusting region of the pair of vertical plates.

According to the angle adjuster earth anchor bracket applied to the ground anchor head fixing system of the present invention, it is possible to adjust the angle smoothly by facilitating the positional movement as well as preventing separation of the load board. In addition, stress concentration and buckling deformation of the arcuate vertical plate can be suppressed by the upper and lower flare prevention plates, the earth expansion plate for stress distribution and the cover plate for the load plate, thereby effectively preventing breakage and destruction.

Also, according to the stapler for preventing buckling of the earth retaining wall band from buckling applied to the ground anchor head fixing system of the present invention, it is possible to quickly mount the buckling prevention apparatus in response to buckling by being easily attracted to the H- Also, by generating a supporting axial force against buckling in the biaxial direction by a pair of side-by-side compression, the buckling suppressed area is widened, and a stable supporting force of the stiffener is exerted.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
FIG. 1A is a use state diagram of a ground anchor head fixing system according to the present invention. FIG.
FIG. 1B is a view showing a state of use of a stiffener for buckling prevention of a wedge wall wale band applied to a ground anchor head fixing system according to the present invention.
2 is a perspective view of a stiffener for buckling prevention of a wedge wall wale band applied to a ground anchor head fixing system according to the present invention.
3 is a sectional view of one side of Fig.
Figure 4 is a plan view of Figure 1;
5 is a view showing various cross-sectional views of the geotechnical compression constituting the stiffener for buckling prevention of the earth retaining wall band in Fig.
6 is a modified perspective view of the stiffener for preventing buckling of the earth retaining wall band in FIG. 2;
7 is a sectional view of one side of Fig. 6;
8 is a perspective view of an angle adjustable earth anchor bracket applied to the ground anchor head fixing system according to the present invention.
Fig. 9 is a partially exploded perspective view of Fig. 8; Fig.
10 is an exemplary view showing a lifting action of a load plate for position movement;
Fig. 11A is a cross-sectional view of one side of Fig. 10, showing an example in which the load plate is fixed to the stopper. Fig.
Fig. 11B is a cross-sectional view of one side of Fig. 10 showing an example in which the load plate is released from the stopper.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

The ground anchor head fixing system according to the present invention includes an earth anchor bracket 10 for angle adjustment, which is mounted on upper and lower adjacent H-shaped steel wales S and S as shown in Fig. 1, and a buckling prevention member for preventing buckling of the H- The stiffener 1 is made up of a plurality of stiffeners. At this time, the H-shaped steel band S may receive a tension force (a force generated in a stranded wire) acting on the angle adjustable earth anchor bracket 10 as shown in FIG. 1A, It can be received.

As shown in FIGS. 2 to 4, the stiffener 1 according to the present embodiment includes a stiffener body 2. The stiffener body 2 is detachably mounted on the web of the H-shaped steel band S as shown in Figs. 5 and 6.

The stiffener body 2 is made of a metal material and has a fixing plate 2a having a length smaller than a flange interval which is opposite to the width K of the H-shaped steel band S suitable for gripping by hand, Axis supporting plates 2b and 2c bent at right angles to each other at opposite ends thereof and one or more attaching magnets 2d provided on the upper surface of the fixing plate 2a. In the present embodiment, two mounting magnets 2d are provided, but the present invention is not limited to these.

Therefore, the stiffener body 2 is formed in a substantially U-shape by the fixing plate 2a and the shaft supporting plates 2b and 2c.

The shaft supporting plate 2b on one side is provided with a ground supporting bushing 2e having an annular engaging groove 2f and a ground supporting compression hole 2g and the other shaft supporting plate 2c is provided with a ground supporting hole 2h Is formed.

The stiffener body 2 is provided with a pair of paper compressions 4 and 4 which are arranged side by side with a constant axial distance L and are made of a metal material which can rotate independently from each other at a predetermined position. The sheet presses 4, 4 are installed at a constant interval H in the fuser plate 2a to facilitate the rotary operation by the operator's hand. Therefore, the fixing plate 2a is not obstructed in the rotation operation of the papers 4, 4. It is preferable that the inter-shaft distance L between the pressurizing pressures 4, 4 is at least not less than a distance which is not difficult to be controlled by the operation of the operator.

A pair of ground compaction (4, 4) is made of metal. At this time, the compression units 4 and 4 preferably include a rotation operation unit 4b having a polygonal cross section over a predetermined interval. The rotary operation portion 4b may be formed not only in a circular shape but also in a rectangular or hexagonal cross section as shown in Fig. The cross-sectional area of compression (4, 4) can be increased or decreased in consideration of the stiffness of the metal material and the working load affecting the buckling.

One end of the pair of compression pieces 4, 4 is rotatably engaged with the support bushing 2e, and a male threaded portion 4a is formed at the other end thereof over a predetermined interval. At this time, the pair of papers 4, 4 are provided with an annular engaging step 4c which is engaged with the annular engaging groove 2f.

(6, 6) made of a metal material are installed on a pair of paper presses (4, 4). The pressurizing members (6, 6) are screw-connected so as to move forward and backward in the compression (4, 4). The pressing members 6 and 6 are provided with a boss 6a having a threaded hole 6a 'to be engaged with the male threaded portion 4a of the paper pressing member 4 and a bush 6a having a circular cross- (6b). Each of the acupressure nuts 6 and 6 is supported by guide rods 5 and 5 whose one ends are inserted into the guide holes 2j and 2j of the stiffener body 2 and the other end is fixed to the acupressure devices 6 and 6 And is configured to perform linear motion. Although one guide rod 5 is provided in each of the pressure-applying ports 6, 6, it may be provided in plural or more.

The use method and operation of the stiffener 1 thus configured will be described.

The stiffener 1 is installed in the H-shaped steel wales S and S where the angle adjusting earth anchor bracket 10 is installed as shown in Fig. 1A, or the stiffener 1 is mounted on the H- (S, S) of the H-shaped steel band.

3, the punches 4 and 4 are rotated in one direction to move backward the pushers 6 and 6 to the right, and then the entire stiffener 1 is moved to the right side of the H- And the fusing plate 2a provided with the mounting magnet 2d is brought into contact with the web of the H-shaped steel band 2. In this case, the stiffener 1 is magnetically attached to the web of the H-shaped steel band S by the magnetic force of the attaching magnet 2d.

In this state, the paper pressing units 4 and 4 are rotated in the other direction to move the paper pressing units 6 and 6 forward (left direction). Therefore, the pressing members 6 and 6 are brought into close contact with the flange on one side of the H-shaped steel band S. At this time, the shaft supporting plate 2b of the stiffener body 2 is closely attached to the other flange of the wristband S. Here, the paper pressing 4 is easily rotated by the rotational operation force of the rotation operating portion 4b, and the direction of movement of the paper pressing means 6 is determined by the increase or decrease of the thread engagement portion with the male screw portion 41.

As a result, the stiffener 1 acts as a pressure between the flanges of the H-shaped steel band S facing each other and the screwing force between the paper pressing 4 and the paper pressing tool 6 is pushed toward both sides in the axial direction .

The tension of the stranded wire acting on the earth anchor bracket 10 and the tensile strength of the screw jack J generated when the strut T is installed on the part where the stiffener 1 is installed and the corresponding compression 4), the buckling of the H-shaped steel band (S) is prevented.

Particularly, the present invention has a pair of paper presses (4) to exert a ground pressure on two axes, thereby enlarging the buckling corresponding area, and stably resisting the jacking force.

Thereafter, the unloading force of the earth retaining device 4 is reversed by releasing the ground pressure, and a gap is generated between the presser foot 6 and the flange of the H-shaped steel band S, and then the magnetic force of the attaching magnet 2d If the stiffener 1 is forcibly pulled out by using a larger force, the stiffener 1 is easily removed from the H-shaped steel band S.

Here, the guide members 5 and 5 are inserted into the guide holes 2j and 2j and are guided by the guide rods 5 and 5, respectively.

As another embodiment of the present invention, the stiffener 1 may further include a cylindrical sleeve 3 having a support hole 3a made of a metal material on the shaft support plate 2c as shown in Figs. The cylindrical sleeve 3 supports the rotation of the paper compression 4 and reinforces the shaft support plate 2c without increasing the thickness of the shaft support plate 2c.

As shown in FIGS. 8 to 10, the earth anchor bracket 10 according to the present embodiment is provided with a pair of vertical plates 12 and 12 which are arranged so as to face each other with a predetermined gap therebetween. The pair of vertical plates 12 and 12 are made of steel and have a constant thickness. The pair of vertical plates 12 and 12 have the same upper arch curved surface 121 having a convex shape along a predetermined radius of curvature in a certain section of the upper part. The pair of vertical plates 12 and 12 has a lower arch curved surface 122 at a lower portion thereof. At this time, the upper end surface orthogonal to one end of the vertical plates 12 and 12 is the upper end point, and the lower end surface orthogonal to the other end is the lower end point.

The upper and lower flare prevention plates 14A and 14B are provided on the upper and lower sides of the pair of the vertical plates 12 and 12, respectively. It is preferable that the upper flared release plate 14A is disposed close to the upper point and the lower flared release plate 14B is disposed closer to the lower point. The upper and lower flare prevention plates 14A and 14B are preferably formed in a flat shape or in a curved shape in order to increase a bonding area with the vertical plates 12 and 12 as in the present embodiment. Upper and lower flare prevention plates 14A and 14B are made of a steel material having a thickness smaller than that of the vertical plate 12. [ The upper and lower flare prevention plates 14A and 14B are arranged so that convex curved surfaces appear in opposite directions to the respective points, but the present invention is not limited to this arrangement direction. The upper and lower flare prevention plates 14A and 14B are welded to a pair of the vertical plates 12 and 12, but may be installed using bolts.

The pair of the vertical plates 12 and 12 are provided with the earth expansion plates 16 and 16 for both stress distribution. The stress spreading and joint expansion plates 16 and 16 are made of a steel material. The stress spreading and joining extension plates 16 and 16 increase the local thickness of the vertical plates 12 and 12 to disperse high tensile tensile stresses received from the lower plate 20 and reduce the ground contact area with the lower plate 20 Expand. The earth expansion plates 16 and 16 serving as the stress dispersion joints form an arch having a ground extension plate curved surface portion 161 having the same radius of curvature as that of the arc curved surface portion of the vertical plate 12. [ The earth expansion plates 16 and 16 also serve as stress distributing plates and have an arc-shaped load plate moving guide surface 163 opposite to the grounding extension plate curved surface portion 161. The earth expansion plates 16 and 16 for stress distribution are joined to a pair of vertical plates 12 and 12 by welding, but they may be installed through bolts.

On the outer surface of the upper arch curved portion of the pair of vertical plates 12 and 12, a load plate separation prevention plate 18 for preventing the release of the load plate 20 is mounted. The load plate separation preventing plate 18 may have the same curvature as the upper arch curved surface of the vertical plates 12 and 12 on the upper surface. At this time, the upper surface of the load plate separation preventing plate 18 is set higher than the upper arch curved surface of the vertical plates 12, 12 by a predetermined height h. Therefore, even if the load plate 20 is moved between the adjacent stoppers 162 and 162 provided on the stress spreading and ground spreading plates 16 and 16, So that it is prevented from being released.

As shown in FIGS. 11A and 11B, an angle adjusting stopper 162 is provided to secure the position of the loading plate 20 after the position is shifted. The angle adjusting stoppers 162 are provided on the inner surface of the earth expansion plate 16 serving as a stress dispersion and at a predetermined interval to form a plurality of stoppers 162. In this embodiment, the angle adjusting stoppers 162 are arranged at equal intervals in a range of at least 20 degrees to at most 40 degrees with respect to the upper flank of the earth anchor bracket. Accordingly, the moving angle of the load plate 20 can be made smaller or larger according to the number of the stoppers 162 for adjusting the angle. For example, when four stoppers 162 for adjusting the angle are provided, the load plates 20 can be fixed at four positions at different positions. In this embodiment, the stopper for angle adjustment 162 is formed in the form of a circular protrusion formed by pressing the earth expanding plates 16 and 16 for stress dispersion and convexly protruding in a spherical shape. However, the stopper 162 is not limited to this circular shape, . Further, in this embodiment, the angle adjusting stopper 162 may be integrally formed with the earth expanding plates 16 and 16 for stress dispersion, but it may be separately manufactured and mounted.

8 and 9, the load plate 20 includes a load plate upper plate 201 having a through hole 201a formed at the center of the upper surface thereof, an arc curved surface 121 of the vertical plate 12, A pair of load plate grounding blocks 202 and 202 provided on both sides of the bottom surface of the load plate upper plate 201 and having a grounding curved surface 202a contacting all the curved surface portions 161 of the load plate grounding plate 16 simultaneously, 205a which are arranged at right angles to the first and second clamping plates 205, 205 and which have hooking protrusions 205a, 205a which are selectively engaged with the angle adjusting stopper 162 at both ends thereof, And load plate guide rods 206 and 206 which are respectively installed and guided along the bottom surface of the earth expansion plate 16 serving as the stress distribution and when the load plate 20 is moved.

11A, when the load plate 20 is hooked on the angle adjusting stopper 162, the load plate 20 is lifted as shown in FIG. 11B, The engaging protrusions 205a and 205a of the load plate engaging plates 205 and 205 are moved out of the angle adjusting stopper 162 and the load plate 20 can be moved to a desired position. When the load plate 20 is lowered again at that position after the movement, the engaging protrusions 205a and 205a of the load plate engaging plates 205 and 205 are hooked on the angle adjusting stopper 162 at another position to fix the angle-adjusted position. During the movement of the load plate 20, the load plate guide rods 206 and 206 are supported and guided by the lower load plate moving guide surface 163 of the stress expansion / Therefore, the movement of the load plate 20 is smoothly performed.

The upper and lower branch plates 11A and 11B may be further attached to the upper and lower ends of the pair of vertical plates 12 and 12, respectively. The upper branch plate 11A and the lower branch plate 11B are orthogonal to the vertical plates 12 and 12 and serve as surface points. At this time, the lower branch plate 11B may have a hook shape whose upper end is bent outwardly so as to be easily hooked on the wristband 2 shown in FIG. 1A.

On the other hand, the buckling preventing stress dispersing plate 26 which is connected to the inner surface of the pair of the vertical plates 12, 12 in the vicinity of the lower end portion baffle plate 14B can be further provided. The buckling-preventing stress dispersing plate 26 suppresses the force that the vertical plates 12 and 12 are deformed inward or outward.

Further, local stress stiffeners 30 and 30 may be further provided in the outer surface side angle adjusting region of the pair of vertical plates 12 and 12. The local stress stiffeners 30 and 30 are made of steel. The local stress stiffeners 30 and 30 prevent stress from concentrating on the bent portions of the lower arch curved surface 122 of the vertical plates 12 and 12. [

The operation of the earth anchor bracket 10 constructed as described above will be described.

The earth anchor bracket 10 of this embodiment is used in an anchor method used for stabilizing a slope or a retaining wall. That is, it is used to stably support tens tens of tensile loads acting on the head of the steel wire after fixing the steel wire to the ground by injecting grout after inserting the high strength steel wire into the perforation hole.

1A shows an example in which an earth anchor bracket 10 is installed in a wale S on the earth retaining wall W side. At this time, the lower branch plate 11B is interposed over the lower wale, and the upper branch plate 11A is interfaced with the upper wale. 11A, when the load plate hanger 204 is straddled by the angle adjusting stopper 162 at the corresponding position, movement of the load plate 20 is limited. Thereafter, the position of the load plate 20 may have to be moved according to the insertion angle of the strand Z. In this case, as shown in FIG. 11B, it is simple to lift the load plate 20, move it to a desired position and then lower it again. At this time, when the load plate 20 is lifted up, the load plate hook 204 is allowed to move out of the engagement of the stopper for adjusting the angle of the corresponding position to move the load plate 20, When the load plate 20 is lowered after being moved, the position is fixed by another angle adjusting stopper 162 existing at the position where the load plate 20 is moved again.

Accordingly, the load plate 20 is adjusted in position in the range of 20 to 40 degrees and at an interval of 5 degrees in the secondary direction so as to correspond to the insertion angle of the stranded wire Z, 121).

At this time, the load plate 20 is subjected to a tensile load, which acts on both the arch curved surface of the vertical plates 12 and 12 and the upper surface of the earth expanding plate 16 serving as the stress dispersion joint at the same time. Therefore, the stress spreading and grounding expansion plate 16 disperses the load stress received by the vertical plates 12 and 12 and at the same time expands the ground plane with respect to the load plate 20 to concentrate the stress on the vertical plates 12 and 12 Thereby preventing deformation and destruction.

In addition, the buckling preventing stress distributing plate 26 catches the force that the vertical plates 12 and 12 are deformed inward or outward when the pulling force is applied to the strand Z. Therefore, the vertical surfaces of the vertical plates 12 and 12 are not deformed.

Meanwhile, in the present embodiment, the lower flank preventing plate 14B and the buckling preventing stress dispersing plate 26 are separated from each other, but they may be formed integrally with each other.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

1: Stiffener
2: Stiffener body
2a: Fusing plate
2b, 2c:
3: Cylindrical sleeve
4: Compression
5: Guide rod
6: Chiropractic
12: Vertical plate
10: Earth anchor bracket for angle adjustment
14A and 14B: Upper and lower fulcrum plates
16: Ground expansion plate with stress dispersion
162: Stopper for angle adjustment
18: Load release plate
20: Load plate
201: load plate top plate
202: load plate grounding block
205: Release plate Hanging plate
205a:
206: load plate guide rod
26: Stress distribution plate combined with anti-buckling
30: Local stress stiffener

Claims (11)

In a head fixing system applied to a ground anchor method,
An angle-adjustable earth anchor bracket 10 which is mounted on upper and lower adjacent H-shaped steel wales S and S;
And a stiffener (1) for preventing buckling of the H-shaped beam band (2);
The angle-adjustable earth anchor bracket (10)
A pair of vertical plates (12, 12) having upper arc curved surfaces along a predetermined radius of curvature in a section of a predetermined angle and arranged to face each other at regular intervals;
Upper and lower flare prevention plates (14A, 14B) respectively connected to the upper and lower inner sides of the pair of vertical plates (12, 12) to prevent the spread of the fulcrum;
A stress expander and a folding expansion plate (not shown) provided with a plurality of angular adjustment stoppers 162 which are joined to the upper arch curved surfaces of the pair of vertical plates 12 and 12 with curved surfaces having the same curvature, 16, 16);
A loading plate separation preventing plate 18 mounted on an outer side surface of the upper arch curved portion of the pair of vertical plates 12 and 12 to prevent the loading plate 20 from coming off;
It is supported on both the upper arch curved surface of the pair of vertical plates 12 and 12 and the upper surface of the earth expanding plates 16 and 16 serving as the stress dispersion joints so that the movement of the arch curved surface can be adjusted within a certain angle, And a ground curved surface contacting the curved surface portion of the earth curved surface of the perpendicular plate 12 and the curved surface portion of the earth expansion plate 16 for stress distribution at the same time and having a ground surface 201a on both sides of the lower surface of the load plate upper plate 201 205a which are arranged at right angles to the pair of load plate grounding blocks 202, 202 and which are selectively engaged with the stoppers 162 for adjusting the angle at both ends thereof, and a pair of load plate grounding blocks 202, And the load plate guide bars 205 and 205 which are respectively provided at the lower ends of the load plate engaging plates 205 and 205 and are guided along the bottom surface of the earth expanding plate 16, (20,206), wherein the load plate (20,206)
The stiffener (1)
A stiffener body (2) detachably mounted on a web of the H-shaped band sack (S);
A pair of paper compressors (4, 4) arranged in parallel on the stiffener body (2) with a constant axial distance therebetween, the pair of paper compressors (4, 4)
(6, 6) threadedly engaged with the other end of each of the pair of papers (4, 4) so as to move forward and backward in a predetermined section. The method according to claim 1,
The stiffener body (2)
A fixing plate 2a having a width and a predetermined length suitable for gripping by hand;
(2b, 2c) bent at right angles to each other at both ends of the fixing plate (2a) and arranged to face each other;
And at least one attachment magnet (2d) provided on the upper surface of the fusing plate (2a);
The shaft supporting plate 2b on one side is provided with a compression supporting bushing 2e having an annular engaging groove 2f and a paper pressing support hole 2g and the shaft supporting plate 2c on the other side supporting the paper pressing 4 (2h) is formed on the ground anchor head fixing system. The method according to claim 1,
The presser foot 6,6 has a boss 6a having a screw hole 6a 'to be engaged with a male screw portion of the paper pressing 4 and a circular pressure plate 6b having a cross section expanded at the tip of the boss 6a Wherein the ground anchor head fixing system is provided with a ground anchor head fixing system. The method according to claim 1,
The ground anchor head fixing system according to claim 1, wherein the ground compression unit (4, 4) includes a rotation operation unit (4b) having a polygonal cross section over a predetermined interval. The method according to claim 1,
Wherein the stiffener (1) is further provided with a cylindrical sleeve (3) for supporting the rotation of the paper pressing (4) on the shaft supporting plate (2c). The method according to claim 1,
The pressurizing tools 6 and 6 are guided by a guide rod 5 whose one end is inserted into the guide holes 2j and 2j of the stiffener body 2 and the other end is fixed to the pressure- Wherein the ground anchor head fixing system is configured to move the ground anchor head. delete delete The method according to claim 1,
Further comprising a buckling preventing stress distributing plate (26) joined to the inner surfaces of the pair of vertical plates (12, 12) in the vicinity of the lower end portion baffle plate (14B). The method according to claim 1,
Wherein the upper branch plate (11A) and the lower branch plate (11B) are further attached to upper and lower ends of the pair of vertical plates (12, 12), respectively. The method according to claim 1,
Characterized in that local stress stiffeners (30, 30) are additionally provided to prevent concentration of stress on the curvature of the lower arch curved surface in the outer surface side angle adjusting region of the pair of vertical plates (12, 12) system.

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