KR101058561B1 - Retaining wall with improved drainage function and construction method of retaining wall - Google Patents

Abstract

The present invention relates to a retaining wall and a retaining wall construction method with improved drainage, and more particularly, to smooth drainage between a cut surface of a slope and a construction part, and to smoothly discharge surface water passing through a stratum under the influence of surface water. It relates to a retaining wall and a method of constructing a retaining wall with improved drainage to prevent settlement.

The present invention provides a retaining wall that prevents soil from collapsing in response to earth pressure, wherein the retaining wall includes: a panel 100 installed along an installation boundary line to be installed on the ground; A coated iron 200 formed so that one side of the panel 100 penetrates a rear surface of the panel 100 while one side protrudes a predetermined length; A fixed anchor 400 connected to the other side of the coated steel 200 through a connecting means 300 and inserted into and fixed to the fixing unit 10 formed to be inclined downward on the cut slope; A vertical drainage part 500 installed at a rear part of the panel 100 to be perpendicular to the ground; A transverse drainage part 600 installed horizontally with the ground with one side connected to the rear surface of the vertical drainage part 500; Is connected to the other side of the transverse drainage portion 600 is composed of a horizontal drainage portion 700 which is installed close to the cut slope.

Panel, Coated Hardware, Fixed Anchor, Drainage, Dispersion, Connecting Method

Description

Retaining WALL HAVING A IMPROVED DRAINING FUNTION AND CONSTRUCTION METHOD THEREOF

The present invention relates to a retaining wall and a retaining wall construction method with improved drainage, and more particularly, to smooth drainage between a cut surface of a slope and a construction part, and to smoothly discharge surface water passing through a stratum under the influence of surface water. It relates to a retaining wall and a method of constructing a retaining wall with improved drainage to prevent settlement.

In general, the retaining wall refers to a wall structure that prevents soil from falling down by resisting soil pressure, and is commonly used for efficient use of land in mountainous areas and high land prices.

In other words, it is used to pile up soil, to cut down mountains, or to fill coasts. In order to prevent the collapse of soil, it is common to build retaining walls using blocks such as stones or concrete, such as embankments or side walls of roads. In addition, it refers to the construction of the apartment complex and the construction to ensure the safety of the slope, the construction of the bridge shift wing wall, and other waterworks construction.

Reinforced soil retaining wall is a horizontally inserted reinforcement material with high tension and good frictional force in the backfilled soil of sandy soil to stabilize the soil by suppressing the lateral displacement of the soil. It consists of a protecting block.

Among them, the block reinforcement soil retaining wall is advantageous in securing the land in the construction of roads, railways, and complexes. Therefore, its use is being expanded to replace the concrete retaining wall.

Among these retaining walls, there is a retaining wall using a permanent anchor, and the retaining wall using a permanent anchor covers the entire slope of the slope with a concrete wall, which makes it impossible to plant vegetation on the retaining wall. In addition, since the angle between the horizontal earth pressure applied to the concrete wall and the longitudinal direction of the permanent anchor is slightly widened, the retaining wall has a weak resistance, and to compensate for this, the retaining wall construction cost increases because the permanent anchor with a relatively high tensile force must be constructed. The disadvantage is that.

In addition, since the drainage is induced only by the nonwoven fabric on the rear of the retaining wall, the drainage efficiency decreases, and the ground on the rear of the retaining wall filled with the compaction due to the continuous inflow of surface water may sink. Rebar joints were welded and connected. As a result, the coating film is peeled off and the original strength of the reinforcing bar is lowered, resulting in a deterioration in construction quality and a long working time.

In addition, the outer part of the panel is protruded from the panel surface a lot of problems aesthetically unfavorable, and bolts outside the panel to fix a number of nuts to meet the high tensile force is not good appearance due to several nuts There are disadvantages.

The present invention was devised to solve the above problems, and an object of the present invention is to install a vertical drainage part, a transverse drainage part, and a horizontal drainage part between the cut surface and the construction part of the inclined ground, as well as the cut surface of the cut surface of the inclined ground. It is to facilitate the drainage between the surface and the construction portion and the retaining wall rear surface, and to facilitate the discharge of surface water through the strata to prevent settlement due to the influence of the surface water.

In addition, regardless of the twisted angle between the fixed anchor is installed in the ground of the slope and the coated iron connected to the panel by connecting means freely by reducing the working time as well as to reduce the raw materials during repair work.

And, it is to distribute the load applied to the panel when the dispersion part is installed on the coated hardware between the soil cut surface and the construction part of the slope.

The construction of the present invention for achieving the above object, in the retaining wall to prevent the soil from collapsing in response to the earth pressure, the retaining wall, the panel 100 which is installed along the installation boundary line to be installed on the horizontally ground; ; A coated iron 200 formed so that one side of the panel 100 penetrates a rear surface of the panel 100 while one side protrudes a predetermined length; A fixed anchor 400 connected to the other side of the coated steel 200 through a connecting means 300 and inserted into and fixed to the fixing unit 10 formed to be inclined downward on the cut slope; A vertical drainage part 500 installed at a rear part of the panel 100 to be perpendicular to the ground; A transverse drainage part 600 installed horizontally with the ground with one side connected to the rear surface of the vertical drainage part 500; Is connected to the other side of the transverse drainage portion 600 is characterized in that consisting of a horizontal drainage portion 700 is installed close to the cut slope.

Here, the dispersion portion 800 for dispersing the horizontal earth pressure is provided on the outer circumferential surface of the coated iron 200,

The dispersion unit 800 includes a pair of fasteners 810 surrounding the outer circumferential surface of the coated iron 200; Reinforcing holes 820 screwed to the outer circumferential surface of the fastener 810; It is preferably composed of a dispersion plate 830 coupled to the fastener 810 perpendicularly.

The vertical drainage part 500 includes a hollow vertical plate 510 having a predetermined length; It is composed of a joint socket 520 is connected to one side of the cross-drainage portion 600 in a state in which one side of the vertical plate 510, the cross-drainage portion 600, one side to the joint socket 520 A hollow first connection socket 610 to be connected; A hollow transverse drainage plate 620 in which a through hole 621 is formed at an upper side in a state of being coupled to the first connection socket 610, and a nonwoven fabric 625 is wound around an outer circumferential surface thereof; The transverse drainage plate 620 and the horizontal drainage portion 700 is connected to the second connection socket 630, the horizontal drainage portion 700 is connected to the second connection socket 630 (protrusion connector) ( 711 is formed, the hollow horizontal drainage plate 710 wound around the outer circumferential surface in a state in which the inlet hole 713 is formed; It is preferable that the horizontal drainage plate 710 is formed of a hollow horizontal drainage plate connector 720.

On the other hand, the retaining wall construction method to prevent the soil from collapsing by resisting the earth pressure, comprising: a rearranging step of leveling the ground along the boundary line to install the retaining wall and cutting the slope; A fixed anchor fixing step of drilling the fixing unit 10 inclined downward toward the inside of the inclined ground and inserting the fixing anchor 400 into the fixing unit 10 to fix the fixing unit 10; A panel installation step of installing the panel 100 along an installation boundary line for installing the retaining wall on the horizontally ground; A coating hardware forming step of penetrating and forming the coating hardware 200 from the front part of the panel 100 to the rear part; A connection step of connecting the fixed anchor 400 and the coating hardware 200 to the connection means 300; A waterproof tent installation step of installing a second waterproof tent 170 on the slope; The vertical drainage part 500 is installed on the rear surface of the panel 100 so as to be perpendicular to the ground, and the horizontal drainage part 600 is installed between the second waterproofing membrane 170 and the slope. A drainage part forming step of connecting the vertical drainage part 500 and the horizontal drainage part 700 by using; Characterized in that it consists of a fill step of backfilling between the panel 100 and the cut slope.

As described above, according to the present invention, the drainage of the slope cut surface is smoothly drained between the cut surface and the construction portion, and the retaining wall rear surface, and the surface water passing through the stratum smoothly to prevent the settlement due to the influence of the surface water. It is effective.

In addition, regardless of the twisted angle between the fixed anchors installed on the ground of the slope and the coated steel connected to the panel, the connection means can be freely connected to shorten the working time and reduce the raw materials during repair work. When the part is installed and soil or concrete backfills between the cut surface of the slope and the construction part, the load applied to the panel is distributed.

Hereinafter, with reference to the accompanying drawings will be described in detail the retaining wall is improved drainage function of the present invention.

1 is a schematic view showing a retaining wall with improved drainage function according to the present invention.

As shown in FIG. 1, the retaining wall having an improved drainage function according to the present invention is a retaining wall that prevents soil from collapsing due to resistance to earth pressure, and the retaining wall is installed on a horizontally grounded panel, coated iron, a fixed anchor, It consists of vertical drainage, transverse drainage and horizontal drainage.

The panel 100 is continuously installed along the installation boundary line to be installed on the ground ground.

Here, the panel 100 has a through hole formed so that one side of the coated iron 200, which will be described later, protrudes toward the front portion, and the first waterproofing membrane 110 is formed on the rear portion of the panel 100.

In addition, the coated iron 200 is penetrated to the rear portion of the panel 100 while the other side is protruded a predetermined length on the front portion of the panel 100.

Here, it is preferable that the coated iron 200 uses a deformed steel bar or a spiral bar.

And, as shown in Figure 2a and 2b, the outer peripheral surface of the coating hardware 200 is provided with a dispersion for dispersing the horizontal earth pressure, the dispersion portion 800 is a pair of surrounding the outer surface of the coating hardware 200 It consists of a fastener 810, a reinforcing tool 820 screwed to the outer peripheral surface of the fastener 810, and a dispersion plate 830 is vertically coupled to the fastener 810.

In other words, when the backfill is filled between the panel 100 and the cut slope, the load of the backfilled soil or concrete affects the panel 100. The dispersion unit 800 is to be dispersed.

In addition, the fixed anchor 400 is connected to the other side of the coating hardware 200 via the connecting means 300, and is fixed to the fixing unit 10 formed to be inclined downward on the cut slope.

Hereinafter, the connecting means 300 for connecting the fixed anchor 400 and the coating hardware 200 described above will be described in detail with reference to FIGS. 3A to 5C.

Figure 3a is a perspective view showing a connecting means according to an embodiment of the present invention, Figure 3b is an exploded perspective view showing a connecting means according to an embodiment of the present invention, Figure 3c is another connecting means in an embodiment of the present invention Is a cross-sectional view.

As shown in Figures 3a to 3c connecting means 300 according to an embodiment of the present invention, surrounding the outer peripheral surface of the coated iron 200, the hemispherical first release region 315a is formed on one side A first connection bolt coupled to the pair of first connection bolt 310a, the first fixing body 325a is screwed to the outer circumferential surface of the first connection bolt (310a) and surrounds the first release preventing hole (315a) on one side A pair of second connecting bolts 330 formed around the nut 320a and the outer peripheral surface of the fixed anchor 400 and having a hemispherical second release preventing tool 335 formed at one side thereof, and the second connecting bolt 330 The second connection nut 340 is screwed to the outer circumferential surface and the second fixing body 345 is formed on one side and surrounds the second release preventing member 335 and the first inserted into the first release preventing member 315a. A hinge ball 351 and a second hinge ball 355 connected to the first hinge ball 351 via a connecting rod 353 and inserted into the second release preventing hole 335. .

In other words, the first connection bolt 310a is formed in the shape of a semi-circular tube and a pair is coalesced to surround the outer periphery of the coated iron 200, and at one side, a hemispherical first release preventing hole 315a is formed. The first hinge ball 351 is inserted into the first departure preventing device 315a, and a semicircular groove is formed in the inner circumference to insert a protruding node of the coated steel 200 at a predetermined interval. Since the screw portion is formed, the first connection nut 320a is screwed together.

In addition, an internal thread portion of the first connection nut 320a is formed on the inner circumference of the first connection bolt 310a to form a female screw part to be coupled to the first connection bolt 310a. The first fixing body 325a is screwed to the outside of the 310a, and the first fixing nut 315a is formed at one side of the first connection nut 320a.

Here, the first fixing body 325a is preferably formed to surround only about half of the first release region 315a as shown in FIG. 3C.

The second connection bolt 330 and the second connection nut 340 have the same structure as that of the first connection bolt 310a and the first connection nut 320a and are installed on the fixed anchor 400. The second hinge ball 355 connected to the first hinge ball 351 through a connecting rod 353 is inserted into the second release preventing hole 335, thereby coating the coated iron 200 and the fixed anchor ( 400) is connected.

In this way, the connecting means 300 can be freely connected regardless of the twisted angle between the fixed anchor 400 installed in the ground of the slope and the coated hardware 200 connected to the panel 100.

On the other hand, Figure 4a is a perspective view showing a connecting means according to another embodiment of the present invention, Figure 4b is an exploded perspective view showing a connecting means according to another embodiment of the present invention, Figure 4c according to another embodiment of the present invention Sectional drawing showing the connection means.

As shown in FIGS. 4A to 4C, the connecting means 300 according to another embodiment of the present invention surrounds the outer peripheral surface of the other side of the coated hardware 200 and has a pair of hemispherical first escape preventing holes 315b formed on one side thereof. A first connection nut having a first fixing bolt 325b which is screwed to an outer circumferential surface of the first connection bolt 310b and an outer circumferential surface of the first connection bolt 310b and surrounds the first release preventing part 315b on one side thereof. 320b, a hinge ball 361 inserted into the first release preventing part 315b, and one side of the fixed anchor 400 is inserted by connecting a connector 365 to the hinge ball 361. Consisting of a connecting body 370.

In other words, the first connection bolt 310b is formed in the shape of a semi-circular tube and a pair is combined to surround the outer periphery of the coated iron 200, and at one side, a hemispherical first release preventing hole 315b is formed. The hinge ball 361 is inserted into the first escape prevention hole 315b, and a semicircular groove is formed in the inner circumference at which a protruding node of the coated hardware 200 is inserted at a predetermined interval, and a threaded portion is formed in the outer circumference. Is formed so that the first connection nut 320b is screwed.

In addition, an inner thread portion of the first connection nut 320b is formed at the inner circumference of the first connection bolt 310b to form a female thread to be coupled to the first connection bolt 310b. Screwed to the outside of the 310b, a first fixing body 325b for supporting the first release preventing tool 315b is formed on one side of the first connection nut 320b.

Here, the first fixing body 325b is preferably formed to surround only about half of the first departure preventing tool 315b as shown in FIG. 4C.

In addition, the connector 370 is connected to the hinge ball 361 via the connector 365, and one side of the fixing anchor 400 is screwed.

On the other hand, Figure 5a is a perspective view showing a connecting means according to another embodiment of the present invention, Figure 5b is an exploded perspective view showing a connecting means according to another embodiment of the present invention, Figure 5c is another view of the present invention Sectional drawing showing the connection means according to the embodiment.

5A to 5C, the connecting means 300 according to another embodiment of the present invention surrounds the outer circumferential surface of the other side of the coated hardware 200 and has a hemispherical first departure preventing tool 315c formed on one side thereof. A first connection formed by a pair of first connection bolts 310c and a first fixing body 325c screwed to an outer circumferential surface of the first connection bolts 310c and surrounding the first release preventing tool 315c on one side. The screw 320c, a sphere 381 inserted into the first release preventing part 315c, and a screw anchoring member 390 connected to the sphere 381 and the anchor anchor 400 to which the fixed anchor 400 is connected. Being composed of a fastening bolt (385).

In other words, the first connection bolt (310c) is formed in the shape of a semi-circular pipe is a pair of coalescing to wrap the outer periphery of the coating hardware 200, one side is formed a hemispherical first escape prevention hole (315c) The sphere 381 is inserted into the first release preventing tool 315c, and a semicircular groove is formed in the inner circumference at which a protruding node of the coated iron 200 is inserted at a predetermined interval, and a thread part is formed in the outer circumference. The first connection nut 320c is screwed together.

In addition, an inner thread portion of the first connection nut 320c is formed at an outer circumference of the first connection bolt 310c to form a female thread to be fastened to the first connection bolt surrounding the coating hardware 200. The first fixing body 325c is screwed to the outside of the 310c, and one side of the first connection nut 320c is configured to support the first release preventing tool 315c.

Here, the first fixing body 325c is preferably formed to surround only about half of the first departure preventing tool 315c as shown in FIG. 5C.

In addition, the fastening bolts 385 are screwed to the earth anchor binding body 390 to which the fixed anchor 400 is connected while being connected to the sphere 381.

Here, the ground anchor 390 is a technique known as a configuration in which the earth anchor is coupled, which will not be described any more.

In this way, the connection means 300 can be freely connected regardless of the twisted angle between the fixed anchor is installed in the ground of the slope and the coated hardware connected to the panel.

And, Figure 6a is a perspective view showing the state of the vertical drainage portion, the transverse drainage portion, the horizontal drainage portion according to the present invention, Figure 6b is a state of the vertical drainage, transverse drainage portion, the horizontal drainage portion according to the present invention Fig. 6C is a cross-sectional view showing a state of vertical drainage, transverse drainage, and horizontal drainage according to the present invention.

As illustrated in FIGS. 6A to 6C, the vertical drainage part 500 is installed perpendicularly to the ground at the rear part of the panel 100.

In other words, the rear portion of the panel 100 which is installed to be connected along the installation boundary is spaced apart at regular intervals.

Here, the vertical drainage part 500 is provided with a first waterproofing membrane 110 on the rear surface of the panel 100, the vertical drainage portion 500 is installed on the rear surface of the first waterproofing membrane 110. It is preferable.

In addition, the vertical drainage portion 500 is a hollow vertical plate 510 having a predetermined length and the joint that is connected to one side of the transverse drainage portion 600 which will be described later in connection with one side of the vertical plate 510 It consists of a socket 520.

In other words, the joint socket 520 is composed of a hollow body 521 formed perpendicular to the ground, and a hollow horizontal body 525 formed horizontally on the rear surface of the body 521, One side of the vertical plate 510 is connected to one side and the other side of the body 521 so that the vertical drainage part 500 is completed in a state perpendicular to the ground, and the horizontal drainage part 525 is disposed on the horizontal body 525. 600 is connected.

In addition, the transverse drainage part 600 is installed horizontally with the ground with one side connected to the rear surface of the vertical drainage part 500.

Here, the cross drain 600 is a hollow first connection socket 610, one side is connected to the joint socket 520, and the through hole in the upper side in a state coupled to the first connection socket 610 ( 621 is formed and is formed of a hollow transverse drainage plate 620 on which a nonwoven fabric 625 is wound on an outer circumferential surface, and a second connection socket 630 connecting the transverse drainage plate 620 and a horizontal drainage plate 710 to be described later. .

The through hole 621 of the transverse drainage plate 620 is the submerged submerged rainwater of the backfilled portion flows into the transverse drainage plate 620 through the through hole 621 through the nonwoven fabric 625, the flowing rainwater It flows to the vertical drain 500, and flows out to the drain pipe 20 installed at the lower rear of the panel 100 to prevent ground subsidence.

In addition, the horizontal drainage part 700 is connected to the other side of the transverse drainage part 600 and is installed close to the cut slope.

Here, the horizontal drainage part 700 is a hollow horizontal drainage plate in which a non-woven fabric is wound around the outer circumference in a state in which a protruding connector 711 is connected to the second connection socket 630 and an inlet hole 713 is formed on the rear surface. 710 and the hollow horizontal drainage plate connector 720 for interconnecting the horizontal drainage plate 710.

In addition, it is preferable that the second waterproofing membrane 170 is covered on the front surface of the horizontal drainage part 700 along the cut slope.

Rainwater and groundwater flowing along the cut slopes flow downward through the back surface of the second waterproof membrane 170, or the inflow hole 713 of the horizontal drain plate 710 formed on the rear surface of the second waterproof membrane 170. It is collected through a) and quickly flows through the transverse drainage portion 600 to the vertical drainage portion 500 to finally move to the drain pipe () located at the bottom rear of the panel to increase the stability of the structure.

In this way, the vertical drainage part, the transverse drainage part, and the horizontal drainage part are installed between the cut surface and the construction part of the inclined ground to smooth the drainage not only of the cut surface of the slope but also between the cut surface and the construction portion and the rear wall of the retaining wall. Smooth discharge of surface water passing through the surface prevents subsidence due to the influence of the surface water.

In addition, regardless of the twisted angle between the fixed anchors installed on the ground of the slope and the coated steel connected to the panel, the connection means can be freely connected to shorten the working time and reduce the raw materials during repair work. When the part is installed and the soil or concrete backfills between the cut surface of the slope and the construction part, the load applied to the panel is distributed.

And, Figure 7 is a perspective view showing a join bolt according to the present invention.

As shown in FIG. 7, it is preferable that only one joining bolt 900 is coupled to the coated hardware 200 protruding from the front surface of the panel 100 to emphasize the beauty of the aesthetics.

On the other hand, Figure 8 is a process chart showing a retaining wall construction method according to the present invention.

As shown in Figure 8, the retaining wall construction method according to the present invention, in the retaining wall construction method to prevent the soil from collapsing in response to the earth pressure, arranging step to cut the slope, fixed anchor fixing step, panel installation step and , Coating iron forming step, the connecting step, the installation of the waterproof curtain, the drainage forming step, and the fill phase.

The cleanup step cuts the slope using heavy equipment and horizontally mobilizes heavy equipment and manpower along the boundary line of the retaining wall construction section.

Then, when the ground leveling is finished, the fixing unit 10 is drilled to be inclined downward into the cut slope, and the fixing anchor 400 is inserted into the punched fixing unit 10 to fix it.

Then, the panel is continuously installed along the installation boundary line to install the retaining wall on the horizontally ground.

At this time, it is preferable to form a first waterproofing membrane 110 on the rear portion of the panel, and to install a drain pipe 20 at the bottom of the rear surface of the first waterproofing membrane 110.

In this state, the coating iron 200 penetrates through the front side of the panel 100 from the front side of the panel 100, and a joining bolt 900 is installed on the coating iron 200 protruding from the front side of the panel 100. .

Thereafter, the coated iron 200 and the fixed anchor 400 are connected through the connecting means 300.

At this time, the connecting means 300 is the first connecting bolt (310a) and the first connecting nut 320a which is screwed to the outer periphery of the first connecting bolt (310a) surrounding the coating hardware 200, The second connecting bolt 330 surrounding the fixing anchor 400 and the second connecting nut 340 screwed to the outer periphery of the second connecting bolt 330, and the first connecting bolt 310a and the second connection The first hinge ball 351 and the second hinge ball 355 is inserted into the bolt 330, or

The first connection bolt 310b surrounding the coating hardware 200 and the first connection nut 320b screwed to the outer circumference of the first connection bolt 310b, the first connection bolt 310b is inserted into the first connection bolt 310b Hinge ball 361, the hinge ball 361 is connected to the connector 365 via a medium is preferably composed of a connecting body 370 is inserted one side of the fixed anchor 400.

In addition, the connecting means 300 is the first connecting bolt (310c) and the first connecting nut (320c) screwed to the outer periphery of the first connecting bolt (310c) surrounding the coating hardware 200, 1 is composed of a sphere 381 inserted into the connection bolt 310c, and a fastening bolt 385 connected to the sphere 381 and screwed to the earth anchor binding body 390 to which the fixed anchor 400 is connected. Please note that it may.

In this state, the second waterproof membrane 170 is installed on the cut slope.

Then, the vertical drainage portion 500 consisting of a hollow vertical plate 510 and a joint socket 520 on the rear surface of the first waterproofing membrane 110 corresponding to the rear portion of the panel 100 is perpendicular to the ground. The horizontal drainage plate 710 and the horizontal drainage plate 700 formed between the horizontal drainage plate 710 and the horizontal drainage plate connector 720 between the second waterproofing membrane 170 installed on the cut slope and the cut slope. The vertical drainage part 500 and the horizontal drainage part 700 are connected to each other via a cross drainage part 600 composed of a first connection socket 610, a cross drainage plate 620, and a second connection socket 630.

At this time, the lower end of the vertical drain portion 500 is connected to the drain pipe 20, the transverse drain portion 600 is preferably installed so that the slope becomes lower toward the panel 100.

Then, backfilled with soil or concrete between the panel 100 and the cut slope.

In such a state, the first fill land backfilled with soil or concrete is used as a new ground, and the retaining wall to the desired height may be constructed by repeating the above room.

Although specific embodiments of the present invention have been described in detail, those skilled in the art will appreciate that various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined not only by the patent registration scope described later but by those equivalent to the claims.

1 is a schematic view showing a retaining wall with improved drainage function according to the present invention,

Figure 2a is a perspective view showing a dispersion according to the present invention,

Figure 2b is an exploded perspective view showing a separation state of the dispersion portion according to the present invention,

Figure 3a is a perspective view showing a connecting means according to an embodiment of the present invention,

Figure 3b is an exploded perspective view showing a connecting means according to an embodiment of the present invention,

Figure 3c is a cross-sectional view showing a connecting means according to an embodiment of the present invention,

Figure 4a is a perspective view showing a connecting means according to another embodiment of the present invention,

Figure 4b is an exploded perspective view showing a connecting means according to another embodiment of the present invention,

Figure 4c is a cross-sectional view showing a connecting means according to another embodiment of the present invention,

Figure 5a is a perspective view showing a connecting means according to another embodiment of the present invention,

Figure 5b is an exploded perspective view showing a connecting means according to another embodiment of the present invention,

Figure 5c is a cross-sectional view showing a connecting means according to another embodiment of the present invention,

Figure 6a is a perspective view showing the state of the vertical drainage, transverse drainage, transverse drainage according to the present invention,

Figure 6b is an exploded perspective view showing a separation state of the vertical drainage, transverse drainage, transverse drainage according to the present invention,

Figure 6c is a cross-sectional view showing a cross-sectional state of the vertical drainage, transverse drainage, transverse drainage according to the present invention;

7 is a perspective view showing a joining bolt according to the present invention,

8 is a process chart showing a retaining wall construction method according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: fixing unit 20: drain pipe

100: panel 110: first waterproof tent 170: second waterproof tent

200: coated hardware 300: connecting means

310a, 310b, 310c: first connecting bolts 315a, 315b, 315c: first release prevention

320a, 320b, 320c: first connection nut 325a, 325b, 325c: first fixing body

330: second connection bolt 335: second separation prevention 340: second connection nut

345: second fixed body 351: first hinge ball 353: connecting rod

355: second hinge ball 361: hinge ball 365: connector

370: connector 381: sphere 385: fastening bolt

390: Earth anchor binder 400: fixed anchor 500: vertical drainage

510: vertical plate 520: joint socket 521: body

525: horizontal body 600: transverse drainage portion 610: first connecting socket

620: transverse drainage plate 621: through hole 625: nonwoven fabric

630: second connection socket 700: horizontal drainage portion 710: horizontal drainage plate

711; Protruding end 713: Inlet 715: Nonwoven fabric

720: horizontal drain plate connector 800: dispersion portion 810: fastener

820: reinforcement 830: dispersion plate 900: join bolt

Claims (8)

In a retaining wall that resists earth pressure and prevents soil from falling down, The retaining wall may include: a panel 100 installed along an installation boundary line intended to be installed on the horizontally ground; A coated iron 200 formed so that one side of the panel 100 penetrates a rear surface of the panel 100 while one side protrudes a predetermined length; A fixed anchor 400 connected to the other side of the coated steel 200 through a connecting means 300 and inserted into and fixed to the fixing unit 10 formed to be inclined downward on the cut slope; A vertical drainage part 500 installed at a rear part of the panel 100 to be perpendicular to the ground; A transverse drainage part 600 installed horizontally with the ground with one side connected to the rear surface of the vertical drainage part 500; Retaining wall with improved drainage, characterized in that consisting of a horizontal drainage portion 700 is connected to the other side of the transverse drainage portion 600 is installed close to the cut slope. The method of claim 1, On the outer circumferential surface of the coating hardware 200 is provided a dispersion unit 800 for dispersing horizontal earth pressure, The dispersion unit 800, the pair of fasteners 810 surrounding the outer peripheral surface of the coating hardware 200; Reinforcing holes 820 screwed to the outer circumferential surface of the fastener 810; Retaining wall with improved drainage, characterized in that consisting of a dispersion plate 830 coupled perpendicularly to the fastener 810. The method according to claim 1 or 2, The vertical drainage part 500 includes a hollow vertical plate 510 having a predetermined length; Consists of a joint socket 520 that is connected to one side of the vertical plate 510 one side of the transverse drainage portion 600, The transverse drainage part 600 includes a hollow first connection socket 610 having one side connected to the joint socket 520; A hollow transverse drainage plate 620 in which a through hole 621 is formed at an upper side in a state of being coupled to the first connection socket 610, and a nonwoven fabric 625 is wound around an outer circumferential surface thereof; It is composed of a second connecting socket 630 for connecting the cross drain plate 620 and the horizontal drain portion 700, The horizontal drain portion 700 is a hollow in which a non-woven fabric 715 is wound around its outer circumferential surface in a state in which a protruding connector 711 connected to the second connection socket 630 is formed, and an inlet hole 713 is formed on its rear surface. Horizontal drain plate 710 of the type; Retaining wall with improved drainage, characterized in that consisting of a horizontal horizontal drainage plate connector 720 for interconnecting the horizontal drainage plate (710). The method of claim 3, The connecting means 300, a pair of first connecting bolts 310a surrounding the outer peripheral surface of the coated iron 200 and having a hemispherical first release preventing tool 315a formed on one side thereof; A first connection nut 320a screwed to an outer circumferential surface of the first connection bolt 310a and having a first fixing body 325a surrounding the first release preventing tool 315a on one side thereof; A pair of second connection bolts 340 surrounding one outer circumferential surface of the fixed anchor 400 and having a hemispherical second release preventing tool 335 formed at one side thereof; A second connection nut 340 which is screwed to the outer circumferential surface of the second connection bolt 340 and has a second fixing body 345 formed around one side of the second release preventing tool 335; A first hinge ball 351 inserted into the first release preventing tool 315a; Retaining wall with improved drainage function, characterized in that consisting of a second hinge ball 355 is connected to the first hinge ball 351 via the connecting rod 353 and inserted into the second escape prevention hole 335 . The method of claim 3, The connecting means 300 includes a pair of first connecting bolts 310b surrounding the outer circumferential surface of the coated iron 200 and having a hemispherical first release preventing tool 315b formed on one side thereof; A first connection nut 320b screwed to the outer circumferential surface of the first connection bolt 310b and having a first fixing body 325b surrounding the first release preventing tool 315b on one side thereof; A hinge ball 361 inserted into the first release preventing tool 315b; Retaining wall with improved drainage, characterized in that the hinge ball (361) is connected via a connector (365) as a medium consisting of a connector 370 is inserted into one side of the fixed anchor 400. The method of claim 3, The connecting means 300 includes a pair of first connecting bolts 310c surrounding the outer circumferential surface of the coated iron 200 and having a hemispherical first release preventing tool 315c formed on one side thereof; A first connection nut 320c screwed to an outer circumferential surface of the first connection bolt 310c and having a first fixing body 325c surrounding the first release preventing tool 315c on one side thereof; A sphere 381 inserted into the first release preventing tool 315c; Retaining wall is improved drainage function, characterized in that consisting of a fastening bolt (385) is connected to the sphere (381), the fixed anchor 400 is screwed to the earth anchor binding (390) connected. In the retaining wall construction method that resists earth pressure and prevents soil from falling down, A rearranging step of leveling the ground along the boundary line for constructing the retaining wall and cutting the slope; A fixed anchor fixing step of drilling the fixing unit 10 inclined downward toward the inside of the inclined ground and inserting the fixing anchor 400 into the fixing unit 10 to fix the fixing unit 10; A panel installation step of installing the panel 100 along an installation boundary line for installing the retaining wall on the horizontally ground; A coating hardware forming step of penetrating and forming a coating hardware () from the front part of the panel 100 to the rear part; A connection step of connecting the fixed anchor 400 and the coating hardware 200 with a connection unit; A waterproof tent installation step of installing a second waterproof tent 170 on the slope; The vertical drainage part 500 is installed on the rear surface of the panel 100 so as to be perpendicular to the ground, and the horizontal drainage part 600 is installed between the second waterproofing membrane 170 and the slope. A drainage part forming step of connecting the vertical drainage part 500 and the horizontal drainage part 700 by using; Retaining wall construction method is improved drainage function, characterized in that consisting of a fill step to backfill between the panel 100 and the cut slope. The method of claim 7, wherein Retaining wall construction method with improved drainage, characterized in that for constructing another panel on the top of the panel by repeating each step of claim 7 with the new ground land constructed in claim 7.

Images