KR19990078827A - ground anchor using a steel pipe - Google Patents

Abstract

The present invention relates to a ground anchor strip using a steel pipe, the anchorage 120 formed by drilling the steel wire inlet 103 in the excavation back surface provided with the earth wall 100, free on the extension of the anchorage 120 In the ground anchor construction in which the chapter 130 is formed, it is inserted into the steel wire inlet 103 and is connected to the free field 130 from the anchorage field 120, and the tensioning force is formed using the anchorage 120 as a support. A steel wire (110) provided to make; A binding cone 180 formed on an outer circumferential surface of the steel wire 110 and supporting the tensile force formed in the steel wire 110 by using the anchorage 120 as a support and transferring the lower portion to a lower portion thereof; Acupressure plate 150 for receiving the tensile force generated in the steel wire 110 through the binding cone 180, distributed to the lower portion; Steel wire 110 is formed of a cylindrical steel pipe provided with a steel wire inlet hole 141, in close contact with the front wall of the earth wall 100, regardless of the insertion direction of the steel wire 110, the steel wire 110 is transmitted by the pressure plate 150. Belt strip 140 to receive the tensile force of the transfer to the earth wall (100); In addition, the steel wire 110 is configured to wrap around the outer circumferential surface of the strip 140, and is installed in close contact with the strip 140 and the earth wall 100 is delivered to the strip 140 by the pressure plate 150. The upper and lower pedestals 160 and 170 provided to support the strip length 140 and are distributed and transmitted to the earth wall 100 by receiving the tensile force of the); and the steel wire inserted into the excavation back side It is installed regardless of the insertion direction of the 110, the ground anchor belt using a steel pipe in which the tensile force of the steel wire 110 is dispersed and transmitted to the earth wall 100 is a technical gist. Therefore, the belt length 140 and the pressure plate 150 and the upper and lower pedestals 160, 170 can be reused by standardizing the economic advantages.

Description

Ground anchor using a steel pipe {ground anchor using a steel pipe}

The present invention relates to a ground anchor construction performed in underground excavation or retaining wall construction in civil engineering and building construction, and more specifically, a standard cylindrical cylindrical that is used universally regardless of the installation direction of the steel wire installed to the excavation back side The present invention relates to a ground anchor strip using a steel pipe that uses a steel pipe as a strip to distribute the tensile force of the steel wire transmitted to the wall.

Generally, underground excavation or retaining wall construction is required in the process of civil engineering and building construction. When the underground excavation or retaining wall construction must be installed in order to ensure the safety of the barrier structure, a temporary facility that can support the barrier structure is essential. As the temporary equipment, a brace and a ground anchor are mainly used.

The prop is mainly used for construction of subway station construction, etc. in consideration of economics. That is, the earth wall is installed on both side walls, and a plurality of braces are provided to connect the earth wall so that the earth wall is supported. The retaining wall is usually composed of an H-pile and an earth plate or an earth wall.

However, since the support structure using the brace is longer in the excavation width, the length of the brace becomes longer, which causes damage to the surrounding buildings due to the collapse of the masonry structure due to buckling, bending deformation, construction delay, and settlement of the ground. In narrow places, the working space of the equipment is insufficient, which interferes with the smooth operation.

Therefore, conventionally, the construction of the ground anchor increases in place of the brace.

As shown in FIG. 1, the conventional technique using the ground anchor is divided into a steel wire 1, a belt holder 2, a belt holder 3, a pedestal 4, a pressure plate 5, and a binding cone 6. It is composed.

The ground anchors primarily support the earth pressure acting on the back of the excavation, and then install and install a steel wire by drilling a hole to the passive area behind the angle of repose to prevent the soil wall from falling off and deformation. The fixing station 8 is formed as a support. Here, the retaining wall 7 is usually composed of an H-file fixed at equal intervals, and an earth plate or an earth wall attached to the H-file.

A free field 9 is formed by being connected to the support, and a pedestal 4 is formed to tension the free field 9 so that the tensile force of the pressure plate 5 is transmitted to the strip 3. The strip 3 is constituted by arranging two H-BEAMs side by side, and is fixed to the front predetermined position of the earth wall 7 by the strip length pedestal 2. In this case, the belt holder 2 is configured using reinforcing bars or angles.

The pedestal 4 is fixed to the belt long (3) is formed so that the front portion is inclined at a predetermined angle in the shape of a triangle. The inclination angle is configured to be perpendicular to the insertion and installation direction of the steel wire (1). The pressure plate 5 is provided at the center of the inclined surface of the pedestal 4. The pressure plate 5 is formed with a through hole (not shown) through which a plurality of steel wires 1 protrude. On the protrusion of the steel wire 1, the binding cone 6 is assembled for each steel wire 1 so that the tensile force is applied.

The operation effect by the above configuration is as described later.

First, a predetermined portion of the retaining wall 7 is drilled at a predetermined angle, and the steel wire 1 is inserted into and installed in the perforation portion to form a fixing unit 8 having a predetermined size. Then, on the front of the retaining wall (7) is installed on the front of the strip (3) consisting of two H-BEAM using a stripe bracket (2). And the pedestal (4) is attached to the front of the strip long (3). At this time, the steel wire (1) protrudes to the front inclined portion of the pedestal (4) through a through hole formed in a predetermined portion of the pedestal (4), and protrudes outside the through hole of the pressure plate (5) formed in communication with the inclined plane through.

After the user applies a predetermined tension to the protruding portion of the steel wire 1 and pulls it, the binding cone 6 is fixed to a predetermined position of the steel wire 1 and the tension is released. The steel wire 1 is fixed to a predetermined position, and a predetermined tensile force is generated on the steel wire 1 connected to the perforation part. The tensile force is transmitted to the retaining wall (7) via the pressure plate (5), the pedestal (4) and the strip (3) to reinforce the bearing force of the retaining wall (7).

However, the above ground anchors have problems described below.

First, there is a problem in that the pedestal must be newly manufactured by varying the inclination angle of the pedestal according to the angle of the steel wire inlet drilled into the excavation back.

Secondly, in order to distribute and transmit the tensile force formed in the steel wire, bar bands composed of two H-BEAMs must be separately used, and there is a problem in that it is not economical.

Accordingly, the present invention has been made to solve the above problems, and provided with a band length consisting of a cylindrical steel pipe, can be constructed regardless of the insertion direction of the steel wire is inserted into the steel wire inlet perforated on the excavation back side, standardization An object of the present invention is to provide a ground anchor strip using steel pipes.

And by using the upper and lower pedestal provided on the outer circumferential surface of the stripe to provide a ground anchor stripe using a steel pipe to distribute the tensile force of the steel wire to the strip wall and to stably support the steel pipe. For other purposes.

It is also another object of the present invention to provide a ground anchor strip using a steel pipe that can be reused by standardizing the strip, reducing the cost of materials and installation costs.

Figure 1-a longitudinal section of the main part showing a ground anchor construction according to the prior art.

Figure 2-Longitudinal cross-sectional view showing the ground anchor construction using a steel pipe as a band according to the present invention.

3 is a schematic view showing the installation shape of the strip and the pressure plate according to the present invention.

4 is a perspective view showing the shape of the reinforcing plate and the strip.

5 is a perspective view showing the shape of the pressure plate.

6 is a perspective view showing the shape of the upper and lower pedestals.

<Description of Symbols for Major Parts of Drawings>

100: earth wall 101: H file

102: earth plate 103: steel wire inlet

110: steel wire 120: anchorage

130: free field 140: belt

141: steel wire inlet hole 142: reinforcement plate

142a: through hole 150: pressure plate

151: binding cone connecting portion 152: band binding portion

153: binding cone connecting hole 160: upper pedestal

161: contact plate 162: thick plate

163: support plate 164: side plate

170: lower pedestal 180: binding cone

The present invention for achieving the above object is, in the anchoring ground formed by drilling a steel wire inlet on the excavation back surface provided with a retaining wall, and in the ground anchor construction in which a free field is formed on the extension of the anchorage, is inserted into the steel wire inlet and fixed A steel wire connected to a free field in a field and provided to form a tensile force using the anchorage as a support; A binding cone formed on an outer circumferential surface of the steel wire and supporting the tensile force formed in the steel wire with the anchorage as a support and transferring the lower portion to a lower portion of the steel wire; A pressure plate receiving the tensile force generated in the steel wire through the binding cone and distributing it downwardly; A strip consisting of a cylindrical steel pipe provided with a steel wire inlet hole, the earth film is in close contact with the front surface of the steel wire irrespective of the insertion direction of the steel wire, and receives the tensile force of the steel wire transmitted by the pressure plate to transfer the earth film to the earth wall; And, it is configured to surround the outer circumferential surface of the band, the belt and the earth film is installed in close contact with the wall to receive the tensile force of the steel wire transmitted to the band by the pressure plate to distribute and transmit to the earth wall, to support the band It is configured to include, the upper and lower pedestal provided, regardless of the insertion direction of the steel wire is inserted into the excavation back side, the ground anchor belt using a steel pipe in which the tensile force of the steel wire is distributed to and transmitted to the earth wall is a technical gist. .

Here, the acupressure plate, the binding cone connecting portion is configured in a flat plate shape having a predetermined thickness to support the tensile force of the steel wire transmitted by the binding cone; A semicircular band binding unit which is formed integrally with the binding cone connecting unit and is distributed along the outer circumferential surface of the band ring to disperse and transfer the tensile force of the steel wire transmitted by the binding cone to the belt band; And, it is formed in communication with the steel wire inlet of the strip-shaped portion in the central portion, it is preferable that the binding cone connecting hole is coupled to the binding cone.

In addition, the strip is preferably configured to further include a reinforcing plate provided on the outer wall surface wall connection portion of the strip to prevent deformation of the strip due to the tensile force transmitted to the strip.

In addition, the upper and lower pedestal, the contact plate along the outer circumferential surface of the strip, the semi-circular contact plate receiving the tensile force of the steel wire transmitted to the strip; A planar thick plate that is in close contact with the front surface of the mud wall and distributes and transmits the tensile force of the steel wire transferred to the contact plate to the mud wall; A planar support plate provided at ends of the contact plate and the rear plate; And, the side plate formed on the side; consisting of, it is preferable that the plate is configured to be combined.

Accordingly, there is an advantage in that the ground anchor construction can be standardized by having a universal belt length that can be used regardless of the direction in which the steel wire is inserted and installed in the steel wire inlet drilled on the excavation back side.

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

Figure 2 is a longitudinal cross-sectional view showing the construction of the ground anchor using the steel pipe according to the present invention as a band, Figure 3 is a schematic view showing the installation shape of the band and acupressure plate according to the present invention, Figure 4 is a shape of the reinforcing plate and the band 5 is a perspective view showing a shape of the pressure plate, Figure 6 is a perspective view showing the shape of the upper and lower pedestal.

As shown, the retaining wall 100 is provided to primarily support the earth pressure. The retaining wall 100 is composed of a plurality of H pile 101 installed at equal intervals, and the earth plate 102 formed by connecting the H pile 101. Here, the earth plate 101 may be replaced by the earth wall. In addition, the wire input hole 103 for inserting the steel wire 110 at a predetermined position of the earth wall 100 is connected to the rear portion of the earth wall 100 while maintaining a predetermined angle. The steel wire 110 is inserted into the rear portion of the steel wire inlet 103 is installed to form a fixed length 120 of the predetermined size. The anchorage 120 serves as a support of the steel wire 110 and the steel wire 110 is connected to the anchorage 120 to extend to the free field 130, the steel wire 110 is the earth wall ( Through the steel wire inlet 103 formed in the 100 maintains the shape protruding to the front of the earth wall (100).

On the front surface of the retaining wall 100, a strip length 140 formed of a cylindrical steel pipe having a predetermined thickness and a predetermined diameter is connected in the horizontal direction, and is installed in close contact with the retaining wall 100 in a tangential direction. . The steel wire inlet hole 141 is provided at a predetermined position of the strip length 140, and the steel wire inlet hole 141 is formed at a position corresponding to the position of the steel wire inlet hole 141 by making the central axis of the strip length 140 symmetrical. Is formed. In this case, the position of the steel wire inlet hole 141 formed in the strip 140 corresponds to the earth plate 102 which is approximately a position between the H pile 101 and the H pile 101.

And a reinforcing plate 142 is attached to the outer circumferential surface wall wall 100 contact portion of the strip 140 to prevent crushing of the strip 140 by the tensile force transmitted to the strip 140. The reinforcement plate 142 is formed in a curved plate shape having the outer circumferential surface of the strip length 140 as the inner circumference, and the through hole 142a is formed at a corresponding position of the steel wire inlet hole 141 formed in the strip length 140. Steel wire 110 is inserted. In addition, the steel wire 110 penetrates through the through hole 142a and the steel wire inlet hole 141 and protrudes to the front portion of the strip length 140.

In this case, when the belt 140 is in close contact with the retaining wall, the steel wire 110 is formed in the through hole 142a and the strip 140 of the steel wire inlet 103 and the reinforcing plate 142 drilled into the retaining wall 100. Since it penetrates the steel wire inlet hole 141 to the outside, the position of the steel wire inlet hole 141 and the steel wire inlet 103 only need to be configured to correspond to a straight line. Therefore, when the insertion direction of the steel wire 110 is inserted and installed in the steel wire inlet 103 is determined, the steel wire inlet 141 and the steel wire inlet 103 is in a straight line by rotating the belt length 140 predetermined. Since it is possible to adjust, so that the belt length 140 can be used universally regardless of the insertion direction of the steel wire 110.

The pressure plate 150 is formed with a connection cone connecting portion 151 having a flat plate shape having a predetermined thickness on its front surface, and a semi-circular strip-shaped binding portion 152 contacting along the outer circumferential surface of the strip length 140. Is formed. In addition, the cone cone connection hole 153 penetrates from the front side to the rear side in the center portion of the acupressure plate 150. On the other hand, since the binding cone connecting hole 153 formed in the acupressure plate 150 communicates with the steel wire inlet hole 141 formed in the belt length 140, the steel wire 110 protruding toward the front surface of the band length 140 is acupressure plate. It is inserted into the binding cone connecting hole 153 of 150 and protrudes to the front of the pressure plate 150.

Here, the belt binding unit 152 formed on the back of the pressure plate 150 is installed in close contact with the belt 140 in the form of surrounding the outer circumferential surface of the belt sheet 150 to couple the acupressure plate 150 to the outer circumferential surface of the belt sheet 140. Let's do it. In addition, the binding cone 180, which will be described later, is inserted into the binding cone connecting hole 153 formed in the front portion binding cone connecting portion 151 of the acupressure plate 150.

The upper pedestal 160 includes a contact plate 161, a rear plate 162, a support plate 163, and a side plate 164.

The contact plate 161 has a substantially curved plate shape and is configured to be in direct contact with the outer circumferential circumferential surface of the strip length 140 to receive the tensile force of the steel wire 110 transferred to the strip length 140. The thick plate 162 is formed in a thin plate shape, and receives the tensile force of the steel wire 110 transmitted through the contact plate 161 by being in close contact with the front surface of the H pile 101 of the earth wall 100. Dispersion transfer to the earth wall (100). The support plate 163 is formed in a thin plate shape, and is installed in close contact with the ends of the contact plate 161 and the rear plate 162 to support the contact plate 161 and the rear plate 162 and at the same time the contact plate ( The tensile force of the steel wire 110 transmitted to 161 is transmitted to the thick plate 162.

The side plate 164 is formed in a thin plate shape, one end is formed in a curved shape inwards, the contact plate 161, the rear plate 162 and the support plate 163 is provided in close contact with the end of the side While supporting the contact plate 161, the back plate 162 and the support plate 163, the tensile force of the steel wire transmitted to the contact plate 161 is transmitted to the back plate 162. Here, the contact plate 161, the back plate 162, the support plate 163 and the side plate 164 is preferably combined by welding, but the coupling in other ways will also be within the scope of the present invention. In addition, the upper pedestal 160 may be composed of only the contact plate 161, the side plate 164 and the support plate 163, in consideration of the tensile force of the steel wire 110 is transmitted to the belt length 140, It is also possible to be composed of only the remaining plates except for the contact plate 161. In other words, it may be composed of only necessary plates in consideration of the tensile force and economic efficiency.

The upper pedestal 160 is wrapped around the circumferential surface of the strip 140 and at the same time tightly fixed to the earth wall 100 so that the tension force transmitted to the strip 140 through the steel wire 110 to distribute the earth wall To 100. In addition, since the upper pedestal 160 is in close contact with the circumferential surface of the strip 140, and is fixed to the H-pile 101, to support the strip 140 and of the steel wire 110 is transmitted to the strip 140 The torsional stress generated in the process in which the tensile force is transmitted to the retaining wall 100 through the connection portion of the strip 140 and the retaining wall 100 is prevented.

The lower pedestal 170 is configured in the same shape as the upper pedestal 160 and is in close contact with the lower circular outer circumferential surface of the strip 140, and is fixed to the front portion of the H pile 101, and the upper pedestal 160 and In the same principle, the tensile force is distributed and transmitted to the retaining wall 100. The lower pedestal 170 supports the strip 140 at the lower portion of the strip 140 and serves as a pedestal. Here, since the configuration and role of the lower pedestal 170 is the same as the upper pedestal 160, a detailed description thereof will be omitted.

The binding cone 180 is configured to surround the outer circumferential surface of the steel wire 110 to serve as a support of the steel wire 110. That is, one side of the steel wire 110 is a tensioning force is generated in the steel wire 110 by using the anchorage 120 as a support and the other side of the binding cone 180 as a support. Using the anchorage 120 as a support, pull out the steel wire 110 by applying an artificial external tension toward the protrusion, and fix the binding cone 180 to the protrusion of the steel wire 110 at a predetermined position. When the external tension applied to the steel wire 110 is removed, the binding cone 180 is coupled to the binding cone connecting hole 153 formed in the pressure plate 150 and at the same time the tensile force generated in the steel wire 110 is the pressure plate ( 150). Since the binding cone 180 is a known technique, a detailed description thereof will be omitted.

The operation effect by the above configuration is as described later.

Firstly, in order to support the earth pressure, the H pile 101 is installed at regular intervals and the earth plate 102 or earth wall formed of the earth wall provided by connecting the H pile 101 is provided. .

A steel wire inlet 103 maintaining a predetermined angle on the front surface of the earth plate 102 or the earth wall installed at an intermediate position between the H pile 101 and the H file 101 is connected to a predetermined depth. After the steel wire 110 is inserted into the steel wire inlet 103 and installed, a fixing unit 120 having a predetermined size is formed on the rear surface of the steel wire inlet 103. Then, the cylindrical strip 140 is in close contact with the front portion of the earth wall 100, the reinforcing plate 142 provided with the steel wire 110 formed on the strip 140 is connected to the anchorage (120) Protrudes through the steel wire inlet hole 141 formed in the through hole 142 and the strip 140. At this time, the upper and lower pedestals 160 and 170 are closely attached to the H-files 101 to the H-files 101 provided with the belt-lengths 140.

Here, the protrusion of the steel wire 110 is inserted into the binding cone connecting hole 153 formed in the pressure plate 150 to protrude the steel wire 110 to the front surface of the pressure plate 150, and then the pressure plate 150 is It is in close contact with the outer circumferential surface of the strip 140. Then, after being inserted into the binding cone connecting hole 153 of the pressure plate 150, the binding cone 180 is coupled to the outer circumferential surface of the steel wire 110 protruding to the front portion of the pressure plate 150.

Then, an external tension directed toward the protrusion part is artificially applied to the protrusion of the steel wire 110 protruding to the front of the pressure plate 150, and the binding cone 180 is moved to a predetermined position of the protrusion of the steel wire 110 to fix it. After that, the external tension applied to the steel wire 110 is removed. At the same time as the external tension is removed, the binding cone 180 is coupled with the binding cone connecting hole 153 formed in the pressure plate 150 by the tensile force transmitted to the steel wire 110 in the anchorage (120).

By the coupling, the tensile force of the steel wire 110 is transmitted to the pressure plate 150 through the binding cone connecting hole 153 of the pressure plate 150. The transmitted tensile force is supported by the binding cone connecting portion 151 of the pressure plate 150, and is distributed and transmitted to the belt 140 through the circumferential surface of the belt length 140 through the band binding part 152. . Tensile force transmitted to the strip 140 is connected to the reinforcing plate 142 installed on the rear of the strip 140 and the earth wall 100 is in contact with the earth wall through the upper and lower pedestals 160, 170 The soil wall 100 is supported by being distributed to 100.

The present invention according to the above configuration, the ground plate made of steel pipe and the chiropractor formed on the outer circumferential surface of the steel strip and the upper and lower pedestal supporting the belt is distributed to the earth wall wall by transmitting the tensile force formed in the steel wire with the anchorage as a support, It is effective that anchor construction is possible.

In addition, the belt and the acupressure plate and the upper and lower pedestals can be used regardless of the inclination angle of the steel wire is inserted through the steel wire inlet, equipped with a standardized specification according to the degree of tensile force, economical because it can be reused There is also.

Claims (4)

In the anchorage site formed by drilling a steel wire inlet on the excavation back surface provided with a retaining wall, and the ground anchor construction in which the free field is formed on the extension of the anchorage site, A steel wire inserted into the steel wire inlet and connected to a free field in a fixing field, and provided to form a tensile force using the fixing field as a support; A binding cone formed on an outer circumferential surface of the steel wire and supporting the tensile force formed in the steel wire with the anchorage as a support and transferring the lower portion to a lower portion of the steel wire; A pressure plate receiving the tensile force generated in the steel wire through the binding cone and distributing it downwardly; A strip consisting of a cylindrical steel pipe provided with a steel wire inlet hole, the earth film is in close contact with the front surface of the steel wire irrespective of the insertion direction of the steel wire, and receives the tensile force of the steel wire transmitted by the pressure plate to transfer the earth film to the earth wall; And, It is configured to surround the outer circumferential surface of the strip, and is installed in close contact with the strip and the earth film wall is transmitted to the earth wall by receiving the tensile force of the steel wire transmitted to the strip by the pressure plate, and provided to support the earth wall. Consists of including, upper and lower pedestals, Regardless of the direction in which the steel wire is inserted into the excavation back side, the ground anchor strip using the steel pipe, characterized in that the tensile force of the steel wire is distributed to the earth wall. According to claim 1, wherein the pressure plate, A binding cone connecting portion configured to have a flat plate shape having a predetermined thickness to support the tensile force of the steel wire transmitted by the binding cone; A semicircular band binding unit which is formed integrally with the binding cone connecting unit and is distributed along the outer circumferential surface of the band ring to disperse and transfer the tensile force of the steel wire transmitted by the binding cone to the belt band; And, A ground anchor stripe using a steel pipe, characterized in that formed in the center portion in communication with the steel wire inlet hole of the strip, the binding cone is coupled to the binding cone. According to claim 1 or 2, wherein the strip, characterized in that it further comprises a reinforcement plate provided on the outer wall surface wall connection portion of the strip to prevent the deformation of the strip by the tensile force transmitted to the strip. Ground anchor belt. According to claim 1 or 2, The upper and lower pedestal, A semicircular contact plate contacting along an outer circumferential surface of the strip and receiving a tensile force of a steel wire transmitted to the strip; A planar thick plate that is in close contact with the front surface of the mud wall and distributes and transmits the tensile force of the steel wire transferred to the contact plate to the mud wall; A planar support plate provided at ends of the contact plate and the rear plate; And, It is composed of a side plate formed on the side, Ground anchor strip using a steel pipe, characterized in that the plate is configured to combine.