KR101992177B1 - A gang-seon waling for temporary of defending earth - Google Patents

Abstract

More particularly, the present invention relates to a stranded wire for a temporary earth retaining structure, and more particularly, to a method for preventing a collapse of the earth after a terra cotta work, by applying a earth pressure applied to a wale band in a reverse direction to stably support the earth pressure, And can easily adjust the strength of pressing in the opposite direction according to the earth pressure applied to the strand wale.

Description

{A GANG-SEON WALING FOR TEMPORARY OF DEFENDING EARTH}

More particularly, the present invention relates to a stranded wire for a temporary earth retaining structure, and more particularly, to a method for preventing a collapse of the earth after a terra cotta work, by applying a earth pressure applied to a wale band in a reverse direction to stably support the earth pressure, And can easily adjust the strength of pressing in the opposite direction according to the earth pressure applied to the strand wale.

Generally, for the construction of buildings, subway, etc., it is necessary to calculate the earth pressure and strut load by excavation stage and install strut beam to withstand earth pressure.

In this way, the number of struts increases, and in most cases, they are closely arranged within 2 ~ 3m, which increases the obstacles to transportation of construction materials, transportation of heavy equipment and construction work in the closing area, An economical burden is caused by the heavy equipment used for installing the pillar in the lateral direction.

In addition, it has a great disadvantage in the work such as the formwork and the reinforcing bar which are carried out later.

There is a support method using anchor anchor without strut, but this method is a method of inserting a steel wire or a steel bar by drilling the back ground of the pile and fixing the end of the inserted steel wire by mechanical method, epoxy, cement or the like.

Although the method using the earth anchor can sufficiently secure the inner space, there is a problem in that it causes problems due to invasion of the adjacent area, and the construction method such as the perforation and the steel wire increases, resulting in a cost burden.

In order to solve such a problem, Korean Patent No. 10-1549356 entitled " Belt material for retaining method by press tray "

However, such a conventional technique can generate a prestressing moment, but it has a complicated structure for installing it, and it is impossible to adjust the steel wire after the installation and to perform separate follow-up measures.

In addition, it takes a long time to adjust and assemble in the field due to the complicated structure, which increases the cost.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a lining wire for a temporary earth retaining structure, which can prevent the earth pressure applied to the earth retaining wall to prevent collapse of the earth, To provide a belt.

The object of the present invention is to provide a stranded wire girder for a temporary earth retaining structure capable of pressurizing the opposite direction of the earth pressure by controlling the tensile force in accordance with the earth pressure applied after installation on the earth retaining wall and conveniently controlling the tensile force loosened by prolonged exposure I have to.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stranded wire for a temporary earth retaining structure that can be quickly assembled and adjusted in tension by a simple structure and can be efficiently used in a narrow space and a complicated space.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stranded wire for a temporary earth retaining structure capable of preventing a deformation due to a bending moment by evenly distributing a pressurized force to cancel the earth pressure.

To achieve the above object, according to the present invention, there is provided a wedge which is installed inside a retaining wall and supported on both sides by a strut; A strut connection part formed on both sides relatively lower than a height of the band; An arcuate reinforcing plate cross-coupled to both sides of the vertical beam of the belt; And fixing means for fixing the wire steel wire portions which are tensioned on both sides of the band zone to press the reinforcing plate in a direction opposite to the earth pressure.

And a connection plate coupled between the overall height of the strap and the step of the strand connection part.

The support bracket may further include a slanting or vertical support plate on both sides of the brace connecting portion for providing a fixing means.

Preferably, the fixing means is fixed to the connection plate and the support plate so that both sides of the wire wire portion are tense, and the wire wire portions are crossed on both sides of the band sheet.

The fixing means may be fixed to each of the support plates to tense both sides of the wire wire portion, and the wire wire portions are preferably provided on both sides of the belt portion.

Both ends of the fixing bolt installed across the connecting plates are preferably fixed with a nut.

Preferably, the fixing means comprises an anchor fixing plate on which the supporting plate and the connecting plate are mounted, an insertion hole formed therein, and a wedge anchor inserted into the insertion hole and having the wire steel wire portion incorporated therein.

According to the present invention, there is provided a stranded wire for a temporary earth retaining structure, comprising: a wedge installed on an earth retaining wall for preventing the collapse of the earth after the earthquake; a bending moment generated by the earth pressure is applied to a reinforcing plate, There is an effect that it can be canceled through the steel wire portion.

According to the present invention, by adjusting the tension of the wire steel wire portion through the fixing member exposed to the outside according to the earth pressure applied to the earth retaining wall, the earth pressure and the loosened tensile force, which are changed by the external environment such as soil and weather, There is an advantage that it can be conveniently adjusted.

According to the present invention, it is possible to evenly press on the entire surface of the belt zone by being positioned crosswise on both sides with the vertical beam of the belt zone as a starting point, and the pressing force applied through the stiffener is evenly distributed to cancel the earth pressure and prevent deformation of the belt zone have.

FIG. 1 is a perspective view showing a strand band for a temporary earth retaining structure according to a first embodiment of the present invention,
FIG. 2 is a sectional view showing the installed state of a stranded band for temporary earth retaining of a first embodiment according to the present invention,
Fig. 3 is a perspective view showing a coupled state of the first embodiment according to the present invention,
4 is a sectional view showing an operating state of the fixing means according to the present invention,
5 is a cross-sectional view showing a stiffener of a reinforcing plate according to the present invention,
6 is a cross-sectional view showing a second embodiment according to the present invention,
FIG. 7 is a cross-sectional view showing a modified state of the beam beam connecting portion of the second embodiment according to the present invention,
8 is a cross-sectional view showing a third embodiment according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully with reference to the accompanying drawings, in which exemplary embodiments of the present invention are shown.

FIG. 1 is a perspective view of a stranded wire girder for use in a first embodiment according to the present invention, FIG. 2 is a sectional view showing an installed state of a stranded wire girder for earthquake-proofing according to a first embodiment of the present invention, 4 is a sectional view showing an operating state of a fixing means according to the present invention, and FIG. 5 is a sectional view showing a stiffener of a reinforcing plate according to the present invention .

As shown in FIGS. 1 to 5, the present invention relates to a stranded wire for a temporary earth retaining structure. More particularly, the present invention relates to a stranded wire for a temporary earth retaining structure, and more particularly, The earth pressure applied to the wale is pressed in the opposite direction to stably support the earth pressure and offset the bending moment generated in the wale, and the strength to press in the opposite direction can be conveniently adjusted according to the applied earth pressure The present invention relates to a stranded wire for temporary use of a retaining member.

The strut 10, the strut connection 20, the reinforcing plate 30, and the fixing means 40 (see FIG. 1) are provided to stably support and offset the earth pressure applied to the earth retaining wall installed through the tearing method to prevent the occurrence of bending moment. ).

The wale band 10 is installed on the inner side of the earth retaining wall 100 and is supported on both sides by a strut 110.

The cross section of the wale band 10 is composed of an H-beam and includes a vertical beam 11 formed in the middle and a horizontal beam 12 formed at the upper and lower ends of the vertical beam 11.

Therefore, after the turf period, it is installed to support the earth pressure applied through the installed earth retaining wall body 100, and is fixed through the strut 110.

The brace joint portion 20 is formed on both sides relatively lower than the height of the wristband 10.

At this time, the brace connecting portion 20 has an H-beam cross section which is the same as that of the wale band 10, and is formed relatively lower than the height of the vertical beam 11. [

Therefore, the strut connection part 20 is formed on the horizontal beam 12 on one side in such a manner as to be in close contact with the earth retaining wall body 100 to support the earth pressure, and a difference in height from the vertical beam 11 is generated on the other surface Is formed at a lower position than the wristband (10), and the strut (110) is positioned.

And a connection plate 50 coupled between the overall height of the wrist strap 10 and the step of the brace joint 20.

That is, it is preferable that the connection plate 50 is formed on both sides so as to have an oblique direction at the end of the wristband 10 where the height difference occurs and the end of the brace joint 20.

Further, the support bracket 20 further includes a support plate 60 in a slanting or vertical shape for mounting the fixing means 40 on both sides of the brace connecting portion 20.

The support plate 60 is welded to the horizontal beam 12 located at the opposite side of the connection portion of the wristband 10 and the brace connection portion 20 in a vertical form.

A guide pipe 62 for inserting a wire wire portion 41 into the second through hole 61 of the support plate 60 and a guide pipe 62 for horizontally supporting the support plates 60, The plate 63 is engaged.

The reinforcing plate 30 is formed in an arch shape cross-coupled to both sides of the vertical beam 11 as a starting point.

Here, the reinforcing plate 30 has an arch shape at both ends thereof in close contact with the support plate 60, and is connected to both sides of the vertical beam 11, And the arcuate phase is crossed and fixed by various methods such as welding.

At this time, both ends of the reinforcing plate 30 are configured to press the earth pressure by the earth retaining wall body 100 being in close contact with the portions of the wale band 10 and the brace connecting portion 20 which are not stepped.

An auxiliary plate 31 is provided at an upper end of the reinforcing plate 30 in an arcuate shape so as to be in close contact with the vertical beam 11 located at the upper portion of the wale band 10 and to hold the wire wire portion 41.

The auxiliary plate 31 supports the reinforcing plate 30 and the wire wire portion 41 presses the reinforcing plate 30 and is easily inserted into the connecting plate 50.

As a result, the contact area of the wire wire portion 41 is increased to press the reinforcing plate 30, thereby facilitating the bonding.

The support plate 60 fixes both ends of the reinforcing plate 30 in a state where both ends of the reinforcing plate 30 are in close contact with each other to form an arch shape.

The wire stranded portion 41 penetrates the inside of the guide tube 62 and is fixed by the fixing means 40 on the outside of the support plate 60 to press the reinforcing plate 30.

Thus, the wire steel wire portion 41 forms a gentle bend and is guided by the guide pipe 62 to prevent damage and breakage due to contact with the support plate 60. [

In addition, the support plate 60 is prevented from being damaged or damaged by dispersing the load of the support plate 60 when a load is applied by the bracket 110 and the wire steel wire 41.

At this time, it is preferable that the support plate 60 is formed on both sides with respect to the vertical beam 11, and is symmetrically formed on both sides of the imaginary center line L, which is the center of the wale band 10, Do.

That is, the support plate 60 is formed on both sides of the support plate 60, and is positioned on both sides with respect to the vertical beam 11.

The connecting plate 50 and the supporting plate 60 may be joined by welding, but various methods may be used to maintain the shape as described above.

The fixing means 40 fixes the wire wire portions 41 that are tense on both sides of the wale band 10 and presses the reinforcing plate 30 in the direction opposite to the earth pressure.

That is, the wire wire portions 41 are exposed at both sides of the wale band 10 to adjust the tension by the fixing means 40, and the wire wire portions 41 are connected to the reinforcing plate 30, It is possible to prevent deformation of the wale band 10 through the earth pressure.

At this time, it is preferable that the wire stranded part 41 is disposed in the oblique direction through both ends of the connecting plate 50 and the supporting plate 60, and is arranged according to the position of the reinforcing plate 30.

The reinforcing plate 30 is provided with a first through groove 51 through which the wire steel wire 41 penetrates and a second through groove 51 through which the wire steel wire 41 penetrates the support plate 60 61 are formed respectively.

Therefore, the wire steel wire portion 41 provided inside the wristband 10 protrudes outward to the outside through the first through-hole 51 and the second through-hole 61.

The first through grooves 51 and the second through grooves 61 may be formed at positions where the wire wires 41 are exposed on both sides of the vertical beam 11.

The fixing means 40 includes an anchor fixing plate 42 having an insertion groove 42a and a wedge anchor 43 inserted into the insertion groove 42a to fix the wire fixing portion 42 and the wire wire portion 41 do.

The wedge anchor 43 is configured to be freely movable along the wire steel wire portion 41 and inserted into the insertion groove 42a by the tensile force of the wire steel wire portion 41, ).

At this time, the insertion groove 42a is formed by a variety of methods such as a data face or a step so as to prevent the wedge anchor 43 from being pulled by the tensile force.

Therefore, the fixing means 40 is fixed to the connection plate 50 and the support plate 60 to tense both sides of the wire wire portion 41, and the wire wire portion 41 is fixed to the reinforcing plate 30).

That is, both ends of the wire steel wire portion 41 formed in the oblique direction where the fixing means 40 is located on the connecting plate 50 and the support plate 60 provided on both sides of the wristband 10 are fixed do.

The bending moment can be canceled by pressing in the direction opposite to the earth pressure applied to the wale band 10 through the wire steel wire portion 41 and the reinforcing plate 30 in an arcuate shape.

Then, as shown in Fig. 4, the fixing means operates the tension of the wire steel wire portion as follows.

The wire strands 41 are inserted into the first through grooves 51 and the second through grooves 61 of the support plate 60 and exposed to the connecting plate 50 in an oblique direction to the wale band 10 .

The connecting plate 50 and the supporting plate 60 may be pressed against the reinforcing plate 30 in a direction opposite to the earth pressure by adjusting the tension of the wire wire 41.

The anchor fixing plate 42 inserted into the insertion groove 42a is positioned in the fixing means 40 so as to be in close contact with the connecting plate 50 and the supporting plate 60, The wedge anchor 43 is engaged with the wire wire portion 41 exposed by the wire insertion portion 42a and inserted into the insertion groove 42a.

Then, the wire wire portion 41 is pulled over a necessary tension through a hydraulic organs, and then the wedge anchor 43 exposed to the outside is inserted again into the insertion groove 42a.

In this state, when the hydraulic organs pulling the wire wire portions 41 are released, the wedge anchors 43 are inserted and fixed in the insertion grooves 42a by a tensile force.

Through this method, the reinforcing plate 30 is pressed through a tensile force generated by pulling the wire steel wire portions 41 at both sides so as to generate sufficient tension.

In addition, the tension of the wale band 10 can be adjusted through the fixing unit 40 exposed in the state where the wale band 10 is installed on the earth retaining wall 100.

Therefore, the wedge 10 having the wire wire portion 41 and the fixing means 40 coupled to the earth retaining wall 100 is installed.

Then, the tension of the wire wire portion 41, which is coupled to the connecting plate 50 and is exposed to the earth pressure applied by the earth retaining wall 100, is pulled by using an oil hydraulic org.

At this time, a tensile force is generated in the wire steel wire portion 41 pulled by the fixing means 40.

Accordingly, the tensile force can be conveniently adjusted according to the earth pressure after the installation of the wale band 10 through the fixing means 40 and the wire wire portion 41 exposed to the outside.

Further, the tension force can be adjusted without detaching or replacing the wristband 10 installed for a long period of time, so that it can be adjusted to the changed earth pressure with ease of construction, and can be stably supported.

The fixing plate 40 is exposed to the outside so that a sufficient space for using the hydraulic oil organs can be secured. The supporting plate 60 is fixed to the wire steel wire portion 41, So as to adjust the tension of the belt.

As shown in FIG. 5, a stiffener is coupled to the inside of the arcuate shape of the reinforcing plate to transmit a tensile force to cancel the earth pressure.

A plurality of the stiffeners 70 are welded to the reinforcing plate 30 and the wale band 10 in an arcuate shape so that the pressure applied in the opposite direction of the earth pressure through the reinforcing plate 30 and the wire steel wire portion 41 To the wale band (10).

At this time, the stiffener 70 is preferably formed in a perpendicular or oblique direction to the reinforcing plate 30 and the wale band 10 so as to disperse a pressing force that can evenly offset the earth pressure.

Through this, although the pressing force generated in the arcuate-shaped reinforcing plate is not uniformly dispersed, it is possible to have a proper pressing force at the required position through the stiffener.

The second embodiment includes the first embodiment, wherein a plurality of the support plates are coupled to both sides of the wale band in the vertical direction.

FIG. 6 is a cross-sectional view illustrating a second embodiment according to the present invention. FIG. 7 is a cross-sectional view illustrating a modified state of the beam beam connecting portion of the second embodiment according to the present invention. A plurality of the reinforcing plates 30 are vertically coupled to the brace connecting portions 20 formed on both sides and the reinforcing plate 30 is supported at both ends by the supporting plates 60 located on both sides to form an arch shape.

Therefore, after the tension of the wire wire portion 41 is adjusted, the wale band 10 is installed on the earth retaining wall body 100.

Accordingly, the pressure of the reinforcing plate 30 is uniformly applied to both sides of the vertical beam 11, thereby canceling the earth pressure.

In addition, the step between the wale band 10 and the strut connection part 20 is generated by the connection plate 50, so that the reinforcing plate can easily maintain the arch shape regardless of the length.

Both sides are supported by the strut 120 to efficiently pressurize the earth pressure applied to the center of the wale 10 in the opposite direction to support the earth pressure and to prevent deformation of the wale 10.

The strut connection part 20 may be formed to have the same height as that of the vertical beam 11 of the wristband 10.

This is because the strut 10 and the strut connection 20 support the strut connection 20 by the earth pressure and the load applied to the strut 110.

Therefore, when the earth pressure and the load applied to the strut connection part 20 by the strut 110 are weak, the strut connection part 20 is formed to be relatively lower than the vertical beam 11 to support the earth pressure, When the load is strong, the strut connection part 20 and the vertical beam 11 may be formed to have the same height.

The third embodiment includes a second embodiment in which the connecting plate 50 is vertically coupled to an end of the wristband 10 and the strut connection 20 and is disposed between the connecting plates 50 The high tension bolt 80 is engaged.

 7, the connection plate 50 is vertically disposed between the wale band 10 and the stepped connection portion 20, as shown in FIG. 7, and FIG. 8 is a sectional view showing a third embodiment according to the present invention. And the high tension bolt 80 is engaged with the connecting plate 50 located on both sides.

Accordingly, the wrist strap 10 can have a high tensile strength and is efficiently supported by the strut 120 to prevent deformation due to the earth pressure.

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 invention as defined by the appended claims. It is obvious that you can do it.

10: Welt 11: Vertical beam
12: horizontal beam 20: strut connection
30: reinforcing plate 31: supporting plate
40: Fixing means 41: Wire wire section
42: anchor fixing plate 42a: insertion groove
43: wedge anchor 50: connecting plate
51: first through hole 60: support plate
61: second through hole 62: guide tube
63: Support plate 70: Stiffener
80: high tensile bolt 100: cladding wall
110: strand L: imaginary center line

Claims (8)

A wrist strap 10 installed inside the earth retaining wall 100 and supported on both sides by a strut 110;
A brace joint portion 20 formed on both sides relatively lower than a height of the wristband 10;
A reinforcing plate 30 supported on both ends in the longitudinal direction of the wale band 10 and elastically deformed and arranged in an arch shape and mounted on both surfaces of the wale band 10 starting from the vertical beam 11;
A fixing means 30 for pressing the reinforcing plate 30 in a direction opposite to the earth pressure while the wire stranded portions 41 fixed to both ends in the longitudinal direction of the wale band 10 are tensed while being in contact with the upper surface of the reinforcing plate 30, (40)
Further comprising a connecting plate (50) coupled between a total height of the wale band (10) and a step of the brace joint (20)
The support bracket 20 further includes vertical support plates 60 on both sides thereof for mounting the fixing means 40,
The fixing means 40 is fixedly fixed to the connection plate 50 and the support plate 60 to tense both sides of the wire steel wire portion 41,
The wire wire portions 41 are cross-mounted on both sides of the wale band 10 so as to cross each other,
Further comprising a plurality of stiffeners (70) located inside the arch shape of the reinforcing plate (30) and connecting the wale band (10) to the reinforcing plate (30). delete delete delete The method according to claim 1,
The fixing means 40 is fixedly fixed to each of the support plates 60 to tense both sides of the wire steel wire portion 41,
Wherein the wire steel wire portion (41) is provided on both sides of the belt strip.
6. The method of claim 5,
Is installed across the connecting plates (50) located on both sides and is fixed by a high tension bolt (80).
The method according to claim 1,
The fixing means (40)
An anchor fixing plate 42 which is seated on the support plate 60 and the connection plate 50 and has an insertion groove 42a formed therein,
And a wedge anchor (43) inserted into the insertion groove (42a) and having a wire wire portion (41) embedded therein to fix the wedge anchor (43). delete

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