KR102503383B1 - Earth retaining wall - Google Patents

Abstract

Disclosed is a temporary retaining wall. The temporary retaining wall according to the present invention comprises: vertical beams which are arranged to receive earth pressure from the excavated ground and are formed to allow the installation of retaining walls therebetween; horizontal beam type furring stripes which are installed on the front surfaces of the vertical beams; an arch-shaped support strut which is provided at a predetermined interval from the furring stripes and is formed in an arch; and a straight support strut which is connected from the end of the arch-shaped support strut in a direction perpendicular to the band, and is arranged to cross the excavated ground, such that an end thereof is connected to a beam connected to the furring stripes and an end of the arch-shaped support strut. A compression force introduction part is provided between the arch-shaped support strut, which has a pre-introduced compressive force, and the furring stripes. The compressive force can be additionally introduced to the arch-shaped support strut, the straight support strut, and the furring stripes by using the compression force introduction part. Therefore, the temporary retaining wall can appropriately introduce compression force in response to the depth of the excavated ground, thereby improving structural safety.

Description

Earth retaining facility {EARTH RETAINING WALL}

The present invention relates to a temporary retaining facility, and more particularly, to a temporary retaining facility that can increase the structural safety of the temporary retaining facility by providing a compressive force introduction unit between the wale and the arched beam so that additional compressive force is introduced.

In general, construction works are often carried out by excavating the ground by extending it to a predetermined depth and longitudinal direction, such as buildings, excavation tunnels, subways, power conduits, communication outlets, sewage pipes, etc., and installing structures in the internal space of the excavated ground there is.

In this case, since the excavated ground surface is always going to be collapsed by earth pressure (active earth pressure), usually a vertical beam such as an H-beam is first driven into the ground and buried, and then the earth is excavated between vertical beams while excavating the ground. The excavated ground support is installed by inserting the wall (retaining plate).

At this time, a vertical beam in the form of a horizontal beam (usually an H beam) is installed on the vertical beam on which the earth wall is installed. in order to be able to resist more effectively. Furthermore, between the wale and the wale, a strut is installed so that both ends are supported by the wale across the excavated ground and can also resist earth pressure. Usually, H beams are also used for this.

Since these braces are installed as a kind of transverse support beam between the wales installed on the ground excavation surface to more effectively resist the working earth pressure, they are used in almost all excavated ground supports.

However, conventional excavated ground supports have their own merits, but as the depth of ground excavation increases, the size of the earth pressure acting increases, so the number of installation of braces increases according to the excavation depth, and the installation interval (mostly 2-3M) decreases. It is a major obstacle in the use of excavation space, and especially when it is necessary to move the position of an already installed brace during work, it takes a lot of effort and time.

In order to solve this problem, Korean Patent Registration No. 10-1832461 discloses a temporary retaining facility system as shown in FIG. A wale strip assembly made of a wale connecting block having a connecting portion and installed inside the retaining wall; A beotimbo assembly composed of a telescopic multi-axis jack and a beotimbo connected to the multi-axis jack, both ends in the longitudinal direction are connected to the wale strip connection block of the wale strip assembly, and are stretched through the multi-axial jack to support the wale strip assembly; It includes a connector connected between the wale connection block of the wale assembly and the beotimbo assembly and between the multi-axis jack and the beotimbo of the beotimbo assembly.

This earth retaining facility system has the advantage of securing high support stiffness, but has a problem in that its configuration is excessively complex, resulting in deterioration in workability and deterioration in usability when the area of the excavated ground is large.

The present invention has been made to solve the above-mentioned problems of the prior art, and by providing a compressive force introduction part between the wale and the arch-shaped brace, it is possible to increase structural safety and improve workability by introducing various additional compressive forces according to the excavation depth and design. It is to provide a temporary retaining facility that can be done.

A temporary earth retaining facility according to an embodiment of the present invention for solving the above-described technical problem is provided to receive earth pressure from the excavated ground, and includes a vertical beam formed such that earth walls are installed therebetween; A wale in the form of a horizontal beam installed in front of the vertical beam; An arched beotimbo provided at a predetermined interval with the wale and formed in an arch shape; And a straight-type beotimbo connected in a direction perpendicular to the wale from the end of the arcuate beotimbo and provided to be connected to a support beam provided so that the end is connected to the wale and the end of the arcuate beotim across the excavated ground. A compressive force introduction unit is provided between the introduced arcuate brace and the wale, and the compressive force introducer is used to additionally introduce compressive force into the arcuate brace, the straight brace, and the wale.

The compressive force introduction unit may include: a gap maintaining unit provided to maintain a gap between the arcuate beotimbo and the wale; A hydraulic control unit for adjusting the gap between the arcuate beotimbo and the wale; It characterized in that it comprises a; and a support portion for supporting the gap maintaining portion.

The gap maintaining unit may include a first nut-shaped support portion seated on a first support portion provided on a flange of the wale; A second nut-type supporting portion seated on a second supporting portion provided on one flange of the arch-shaped beotimbo; A plurality of bolt-type steel rods that pass through the second nut-type supporting portion and the arcuate brace from the first nut-shaped supporting portion, and pass through the third supporting portion provided on the other flange of the arched supporting portion and are fastened by nuts. It is characterized by doing.

The first support portion is provided in a flat plate shape having a constant thickness, and the second and third support portions are characterized in that the thickness varies in the longitudinal direction.

The second support portion gradually increases in thickness toward one side and the third support portion gradually decreases in thickness toward one side, and the sum of the thickness of one side of the second support portion and the thickness of one side of the third support portion is the second support portion. It is characterized in that it is equal to the sum of the thickness of the other side of the support and the thickness of the other side of the third support.

A reinforcing part is provided in the wale and the arcuate brace at the place where the compressive force introduction part is provided, and the steel bar of the gap maintaining part is provided between the reinforcing parts of the arcuate brace.

The wale is coupled to the vertical beam installed from the lowest end of the excavated ground to the top of the excavated ground according to the height, and the compressive force introduction part provided between the wale and the arch-shaped beotimbo from the top to the bottom of the vertical beam. It is characterized in that the compressive force gradually decreases.

According to the present invention, since the compressive force introduction unit is provided between the wale and the arcuate strut, it is possible to easily resist earth pressure by introducing additional compressive force, so that the additional strut can be reduced, and the compressive force is appropriately introduced in response to the depth of the excavated ground. This can improve structural safety.

1 is a plan view showing a retaining facility system according to the prior art;
2 is a conceptual diagram showing a temporary retaining facility according to an embodiment of the present invention;
3 is a perspective view showing a wale, an arch-shaped brace, and a compressive force introduction part of a temporary earth retaining facility according to an embodiment of the present invention;
4 is a perspective view showing a compression force introduction unit according to an embodiment of the present invention;
5 is a perspective view showing a retaining facility according to an embodiment of the present invention;
6 is a perspective view of a partial excerpt showing a temporary earth retaining facility according to an embodiment of the present invention;
Figure 7 shows a perspective view of the temporary retaining facility according to an embodiment of the present invention viewed from above.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

Referring to the drawings below, a retaining facility according to an embodiment of the present invention will be described in detail.

Figure 2 is a conceptual diagram showing a temporary retaining facility according to an embodiment of the present invention, Figure 3 is a perspective view showing a wale, an arch-shaped brace, and a compressive force introduction portion of a temporary retaining facility according to an embodiment of the present invention, Figure 4 is an embodiment of the present invention 5 is a perspective view showing a temporary retaining facility according to an embodiment of the present invention, Figure 6 is a partially excerpted perspective view showing a temporary retaining facility according to an embodiment of the present invention, and Figure 7 is a perspective view showing a temporary retaining facility according to an embodiment of the present invention. Shows a perspective view from above the soil magging facility according to the embodiment.

1 to 7, the retaining facility according to the embodiment of the present invention includes a vertical beam 10, an earth wall 20, a wale 110, a corner brace 30, a corner brace 40, It includes a connector 50, an arcuate brace 120, a support beam 130, a connector 140, a straight brace 150, and a compression force introduction unit 160.

The earth retaining facility is for constructing a structure by excavating the ground in the underground direction. Basically, a plurality of vertical beams 10 are provided along the inner circumferential surface of the excavated ground, and earth walls 20 are provided between the vertical beams 10 This is installed, and the earth wall 20 is provided as a earth plate and installed in the transverse direction between the vertical beams 10 and the vertical beams 10.

The wale 110 is installed on the front or one side of the vertical beam 10 and may be provided as an I-shaped or H-shaped beam. The wale 110 is formed to be in contact with the front surface of the vertical beam 10 in a straight line.

In front of the wale 110 (in the excavation ground direction), the arch-shaped beotimbo 120 is provided to be spaced apart at preset intervals. The arcuate beotimbo 120 may be provided in plurality in front of the wale 110, and support beams 130 may be provided at both ends of each arched beotimbo 120.

The support beam 130 is formed in a direction perpendicular to the longitudinal direction of the wale 110, and a straight beam 150 is provided in front of the support beam 130 to extend. A connector 140 may be provided between the branch beam 130 and the straight beotimbo 150.

In the arch-type strut 120, a pre-compression force can be basically introduced by earth pressure due to its structure, and a compression force introduction part 160 is provided between the arch-type strut 120 into which the pre-compressive force is introduced and the wale 110, so that the arch-type brace 120 , the straight strut 150, and the compressive force are additionally introduced to the wale 110.

When a compressive force is introduced to the arcuate strut 120 by the compressive force introduction unit 160, the compressive force is transferred to both ends of the arched strut 120 as it is because the arched brace 120 is arched, and is transmitted to the support beam 130 The compressive force resists the earth pressure.

As shown in FIG. 2, it may not be provided at the top of the arch-type brace 120, but preferably, the arch-type brace 120 is also provided at the top to transmit the compressive force from the wale 110 to the top of the arch-type brace 120 and It can be shaped to introduce additional compressive forces.

In addition, referring to FIG. 2, the arcuate strut 120 may be provided so that both ends are symmetrical and the uppermost end is formed between both ends, but one end is provided at the top end and the other end is formed in a half-arch shape so that it is connected to the support beam 130 It is also possible.

The compressive force introduction unit 160 includes gap maintaining units 161, 162, 163, 165, and 168 provided to maintain a gap between the arcuate brace 120 and the wale 110, and between the arched brace 120 and the wale 110. It includes a hydraulic control unit 167 for adjusting the interval and a support unit (P1, P2, P3) for supporting the interval maintaining unit.

The gap maintaining parts 161, 162, 163, 165, and 168 are the first nut-shaped support part 161 seated on the first support part P1 provided on the flange of the wale 110, and one side of the arch-shaped brace 120 The second nut-shaped supporting portion 163 seated on the second supporting portion P2 provided on the flange passes through the second nut-shaped supporting portion 163 and the arched support 120 from the first nut-shaped supporting portion 161 However, it includes a plurality of bolt-type steel rods 165 fastened by a nut 168 through the third support portion P3 provided on the other flange of the arch-shaped beotimbo 120.

The first nut-type supporting portion 161 is provided so that the bolt-type steel bar 165 penetrates, but preferably has a nut-type screw thread inside, one end and the other end are provided with a circular flange, and one end and the other end A plurality of ribs connecting the are formed.

The second nut-shaped supporting portion 163 is formed to correspond to the first nut-shaped supporting portion 161, and a nut 162 is provided at one end of the second nut-shaped supporting portion 163 to form a hydraulic control unit 167 When a constant gap is formed between the wale 110 and the arcuate brace 120, a constant gap is maintained between the wale 110 and the arcuate brace 120 by adjusting the nuts 162 and 168.

The first support portion P1 is provided in a flat plate shape having a constant thickness, and the second and third support portions P2 and P3 are formed to have varying thicknesses in the longitudinal direction.

The thickness of the second support portion P2 gradually increases toward one side and the thickness of the third support portion P3 gradually decreases toward one side, but the thickness of one side of the second support portion P2 and one side of the third support portion P3 The sum of the thicknesses of is equal to the sum of the thickness of the other side of the second support part P2 and the thickness of the other side of the third support part P3.

When the curvature of the arcuate support 120 is small, the second support part P2 and the third support part P3 may be provided to increase or decrease in thickness in a straight line, but when the curvature of the arcuate support part 120 is large, the second support part P2 and the third support part P3 may be provided. The support part P2 and the third support part P3 may be provided to increase or decrease in thickness in a curved shape.

Reinforcing parts 117 and 127 are provided in the wale 110 and the arcuate brace 120 where the compressive force introduction part 160 is provided, respectively, and the steel bar 165 of the gap maintaining part is the reinforcing part 127 of the arched brace 120. ) is provided between

5 to 7, the vertical beam 10 is installed to be connected to the lowest end of the excavated ground, and the wale 110 and the arched beam 120 are also provided in a plurality of layers at predetermined intervals of the vertical beam 10. Can be placed forward.

That is, a plurality of wales 110 are combined according to the height of the vertical beam installed from the bottom of the excavated ground to the top of the excavated ground, and between the wale 110 and the arched beam 120 from the top of the vertical beam 10 to the bottom. It may be provided so that the compressive force of the compressive force introduction unit 160 is gradually reduced.

Accordingly, as the excavation ground is formed and the excavation depth of the excavation ground increases, the vertical beam 10 installed at the top takes a larger earth pressure, and to resist this, the compressive force introduction unit 160 adjacent to the top of the vertical beam 10 ) The compressive force of ) is set to be the largest, and since the earth pressure is applied to the lowermost end, the compressive force of the compressive force inlet portion 160 is applied so that the compressive force of the compressive force inlet portion 160 adjacent to the lowermost end of the vertical beam 10 takes the smallest amount. .

Referring to FIGS. 5 and 6 , the compression force introduction unit 160 may include an uppermost compression force introduction unit 160a, a middle layer compression force introduction unit 160b, and a lowermost compression force introduction unit 160c.

As the excavation depth of the excavated ground increases, an additional wale 110, an arcuate support 120, and a compressive force introduction unit 160 may be provided.

First, when the depth of the excavated ground is shallow, the first compressive force is introduced to the uppermost compressive force introduction portion 160a, and when the excavated ground becomes deep and the intermediate layer compressive force introduction portion 160b is provided, the first compressive force is introduced into the middle layer compressive force introduction portion 160b After that, a second compressive force, which is a larger compressive force, is additionally introduced to the first compressive force introduction part.

When the excavated ground is deeper and the first compressive force is introduced to the lowermost compressive force introduction portion 160c, the second compressive force is introduced to the middle layer compressive force introduction portion 160b, and the uppermost compressive force introduction portion 160a has a second compressive force that is greater than the second compressive force. 3 compression force can be introduced.

In the case of the uppermost compression force introduction part 160a, the first compression force introduction part 161a provided in the middle of the arcuate strut 120, and the second and third compression force introduction parts 163a and 165a provided on both sides of the first compression force introduction part 161a may be provided, respectively, and the compressive forces of the first compression force introduction unit 161a and the second and third compression force introduction units 163a and 165a may be introduced identically or differently.

When a compressive force is introduced into the compressive force introduction unit 160 and the gap between the wale 110 and the arcuate strut 120 is maintained by the gap maintainers 161, 162, 163, 165, and 168, the hydraulic control unit 167 It can be removed and reused.

According to the present invention, since the compressive force introduction unit is provided between the wale and the arcuate strut, it is possible to easily resist earth pressure by introducing additional compressive force, so that the additional strut can be reduced, and the compressive force is appropriately introduced in response to the depth of the excavated ground. This can improve structural safety.

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be construed as being included in the scope of the present invention. do.

10: vertical beam
20: earth wall
30: corner part brace
110: wale
120: arched brace
130: branch beam
140: connector
150: straight brace
160: compression force introduction

Claims (7)

A vertical beam provided to receive earth pressure from the excavated ground and formed such that earth walls are installed therebetween;
A wale in the form of a horizontal beam installed in front of the vertical beam;
An arched beotimbo provided at a predetermined interval with the wale and formed in an arch shape; and
Including,
A compressive force introduction unit is provided between the arcuate strut and the wale to which the preceding compressive force is introduced, and the compressive force is additionally introduced into the arcuate strut, the straight strut, and the wale by using the compressive force introduction unit,
The compressive force introduction unit may include: a gap maintaining unit provided to maintain a gap between the arcuate beotimbo and the wale; A hydraulic control unit for adjusting the gap between the arcuate beotimbo and the wale; And a support part for supporting the gap maintaining part; includes,
The gap maintaining unit may include a first nut-shaped support portion seated on a first support portion provided on a flange of the wale; A second nut-type supporting portion seated on a second supporting portion provided on one flange of the arch-shaped beotimbo; A plurality of bolt-type steel rods that pass through the second nut-type supporting portion and the arcuate brace from the first nut-shaped supporting portion, and pass through the third supporting portion provided on the other flange of the arched supporting portion and are fastened by nuts. Earth retaining facility, characterized in that for doing. delete delete According to claim 1,
The first support portion is provided in a flat plate shape having a constant thickness, and the second and third support portions are retaining retaining facilities, characterized in that the thickness varies in the longitudinal direction. According to claim 4,
The second support portion gradually increases in thickness toward one side and the third support portion gradually decreases in thickness toward one side, and the sum of the thickness of one side of the second support portion and the thickness of one side of the third support portion is the second support portion. Earth retaining facility, characterized in that the same as the sum of the thickness of the other side of the support and the thickness of the other side of the third support. According to claim 1,
Reinforcing parts are provided on the wale and the arch-shaped brace at the place where the compressive force introduction part is provided,
The steel bar of the gap maintaining part is a temporary retaining facility, characterized in that provided between the reinforcing parts of the arch-shaped beotimbo. According to claim 1,
The wale is coupled to the vertical beam installed from the lowermost end of the excavated ground to the uppermost end of the excavated ground according to a height, and
Retaining temporary facility, characterized in that the compressive force of the compressive force introduction portion provided between the wale and the arch-shaped beotimbo gradually decreases from the uppermost end of the vertical beam to the lowermost end.

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