KR20000005647A - A wall face panel and a reinforcement soil structure - Google Patents

Abstract

PURPOSE: A structure of a wall panel and a reinforcement earth is provided to improve the stability, the work efficiency and the economical efficiency by preventing the changing or destruction when a strong power is given to the filling reinforcement material. CONSTITUTION: A wall panel(2) formed in a shape of a rectangular plate has; an extension rib; a reinforcement rib(2b) vertically extended on the back face; a connection metal ball(4) protruded on the reinforcement rib and to connect to the filling and reinforcement material paved into the filling layer. Herein, the metal ball is formed in U, and installed by an anchor plate(4a) laid down the reinforcement rib and having a connection plate with a connection hole narrowly formed in vertical.

Description

Wall Panel and Reinforced Earth Structure {A WALL FACE PANEL AND A REINFORCEMENT SOIL STRUCTURE}

The present invention relates to a reinforcement soil structure consisting of the wall panel and the wall panel to maintain the fill layer.

For example, FIG. 5 illustrates an example of a reinforcement soil structure constructed by filling, and several wall panels 21 are vertically disposed along the surface of the end of the fill layer 20 formed by filling with voltage evenly in the drawing. It is installed adjacent to the left and right directions.

In addition, the connecting brackets 22 protrude from the rear portions of the respective wall panels 21, and each of the wall panels 21 is a fill reinforcement made of a strip steel or the like embedded in the fill layer 20 through the connecting brackets 22. It is connected to (23) and is fixed to the tip of the fill layer (20).

However, the wall panel 21 is usually formed of a rigid material such as concrete, while the fill forming the fill layer 20 forms a granular body, and is compressed and easily deformed at voltage, in particular, the connection bracket 22 and the fill reinforcement material. The connection part (a) with (23) may cause relative displacement at the voltage of the fill layer 20, and may be broken by the influence of the movement of the soil particle around.

In addition, it is extremely economical and desirable to use local materials as fill, but there is a problem that the wall is easily displaced because of poor compressibility if the fill is poor.

In general, concrete panels of reinforced earth retaining walls are usually 1 centimeter to 22 centimeters thick, so they require a lot of material and are not economical, and because of their high weight, transportation costs are high and workability is not good when the wall is assembled in the field. there was.

In order to solve the problems caused by the use of a large compressive fillet of the above problems, a method of connecting the concrete panel and fill reinforcement through a slide joint is known.

The method using the slide joint is preferable for the connection part (a) to conform to the compression of the fill, but the position of the connection part (a) of the wall panel and the fill stiffener is changed according to the compression of the fill, the stress state is easy to change and the connection part There is a problem that an indefinite stress is generated in (a) and deformation easily occurs.

As described above, the stress generated in the connecting portion a changes with time, and a complex stress that is difficult to predict in time occurs, which may cause the connecting portion a to deform.

In general, in this type of reinforcement structure, the displacement of the wall surface is due to the compression of the fill layer 20 due to the voltage load and spread in the lateral direction, the change in the horizontality of the fill reinforcement according to the compression of the fill, Increasing the resistance and reducing the stress concentration at the connecting portion, the loosening of the connecting portion (a) during voltage increases, and the deformation occurs in the connecting portion (a).

In addition, displacement of the wall reinforcement material 23 and the wall panel 21 due to the compression of the fill layer 20 due to the load placed thereon is also caused by stress concentration at the connecting portion a.

Until now, in order to cope with such indeterminate stress changes, it has been necessary to secure the stability by increasing the thickness of the wall panel, increasing the connection part having the slide joint function, or thickening the member.

The present invention has been made to solve the above problems, and a large stress acts on the fill reinforcement by using a thin concrete panel having a slide function as a wall panel, and deformation is caused even when the connection portion of the fill reinforcement is displaced by the use of compressive fill. Its purpose is to provide wall panels and reinforced earth structures that are stable, hard to break, and excellent in workability and economic efficiency.

1A is a partial front view of an example of a reinforced earth structure.

Figure 1b is a longitudinal cross-sectional view of an example of reinforced earth structure.

Figure 2a is a plan view of an example wall panel.

Figure 2b is a front view of an example wall panel.

Figure 2c is a side view of an example wall panel.

FIG. 2D and FIG. 2E are cross-sectional views of the pseudo-curve and spiral-helix of FIG. 2B, respectively.

3A and 3B are longitudinal sectional views showing the structure of the connection portion between the wall panel and the fill reinforcing material by the connection bracket;

Figure 3c is a cross-sectional view showing the structure of the connection portion of the wall panel and the fill stiffener by the connecting bracket.

4 is a partial longitudinal sectional view showing a construction method.

Figure 5 is a perspective view showing the structure of the connection portion of the conventional wall panel and the fill stiffener.

※ Explanation of symbols about main part of drawing ※

1: fill layer 2: wall panel

2a: expansion rib 2b: reinforcement rib

2c: seam 2d: seam

3: fill reinforcement 3a: connecting plate

3b: connecting hole 4: connecting bracket

4a: anchor plate 4b: connecting plate

4c: connecting hole 5: connecting bolt

6: shiatsu plate 7: turnbuckle

The wall panel according to the first aspect of the present invention has a reinforcing rib which has a substantially rectangular plate shape, has an extension rib projecting in the same plane at both left and right edges, and is continuous in the vertical direction on the back side, and protrudes in this reinforcing rib. It is formed with a connecting bracket connected to the fill reinforcement.

The wall panel of claim 2 is an anchor plate formed in a substantially U-shape and directly buried in the reinforcing ribs, and a connection hole for connecting the fill reinforcement material to the anchor plate. The connecting plate is formed to be long and thin in the vertical direction.

In the wall panel of the third aspect, in the first or second aspect, the expansion rib protrudes in an obtuse angle or substantially arc shape.

The reinforcement soil structure of claim 4 according to the present invention is provided with a plurality of wall panels at the front end of the fill layer adjacent to each other in the up and down direction and the left and right directions along the normal surface of the fill layer. And the ends thereof are connected to the wall panel through the connecting brackets.

1 to 3 illustrate one embodiment of the present invention, in which the fill layer 1 is formed by uniformly voltage-filling a fill made of a current generating material or the like, and the front end of the fill layer 1 is formed. A plurality of wall panels 2 are disposed adjacent to each other vertically and horizontally along the normal surface of the fill layer 1.

In addition, the fill reinforcement material 3 is provided in several layers in the fill layer 1, and each fill reinforcement material 3 is connected to the wall panel 2 through the connection bracket 4, respectively.

The wall panel 2 is formed in a substantially rectangular plate shape, and expansion ribs 2a and 2a protruding in the same plane are protruded from the left and right edges thereof, respectively. In addition, two strands of reinforcing ribs 2b and 2b are continuously formed in parallel in the vertical direction.

The expansion ribs 2a are formed in a substantially trapezoidal shape when viewed from the front to the lower side in the center of the wall panel 2. The reinforcing ribs 2b are each formed in a ladder shape or in a substantially rectangular shape in cross section from both ends of the wall panel 2 toward the inside.

In addition, it is preferable that the edge rib b protrudes into the obtuse angle or substantially arc shape as shown in FIG.2 (b). As a result, even if there is an imbalance in the earth pressure applied to the upper and lower wall panels at the time of the fill voltage, and even if the wall panels 2 adjacent to each other in the vertical plane are displaced due to floating settlement or the like, the edge portion b of the expansion rib 2a Becomes difficult to destroy. In the conventional panels, the corner portions are broken because these portions form a rectangular shape. In particular, this breakdown in thin panels is a big problem in terms of stability.

Moreover, the joint part 2c and 2d are formed in the peripheral part of the wall panel 2, respectively. The joint part 2c is formed continuously in the circumferential direction at the bottom edge end and one side edge end, and the joint part 2d is respectively formed at the upper edge end and the other side edge end.

The joints 2c and 2d are joined when the wall panel 2 is installed adjacent to each other in the up-down direction and the left-right direction (see FIGS. 2 (d) and (e)), so that the adjacent wall panel 2 By providing a gap between (2) and providing a certain range of mobility, a half-joint is formed so that the wall panel 2 may not shift to the outward direction while preventing stress concentration.

This facilitates positioning of the wall panel 2 when the wall panel 2 is provided. In addition, during the voltage of the fill, a part of the fill is leaked out between the adjacent wall panels 2 and 2 due to the large earth pressure from the fill layer 1, and the wall panel 2 is displaced outwardly. It can be prevented and a stable wall is possible despite being a thin wall panel.

Several connecting brackets 4 protrude from the rear side of the reinforcing ribs 2b at predetermined intervals in the vertical direction. In addition, as shown in Figs. 3A to 3C, the connecting bracket 4 is formed in a substantially U shape and is buried at a predetermined interval in the vertical direction in the concrete of the reinforcing rib 2b. It is formed of a long anchor plate 4a and two connecting plates 4b fixed to the protruding portions of the anchor plate 4a and protruding in parallel to the rear side of the wall panel 2. The connecting plates 4b are formed with connecting holes 4c elongated in the vertical direction, respectively.

Since the connecting bracket 4 having the anchor plate 4a having an U-shaped end can be fixed in concrete, particularly against drawing, the two connecting plates 4b are accurately and parallel to the reinforcing ribs 2b. Also, it is effective for firm attachment.

The end portion of the fill reinforcing material 3 is connected to the connecting bracket 4 thus formed by the connecting bolt 5 passing through the connecting hole 4c.

Thus, the connection part (a) of the wall panel (2) and the fill stiffener (3) in the present invention has an extremely simple structure and maintains symmetry, so even if the position of the connection part (a) changes according to the compression of the fill An indefinite stress does not occur in the connecting portion (a), resulting in a rigid structure that does not easily cause wall displacement or breakage.

This advantage is even greater when the reinforcing ribs 2b are continuous in the vertical direction, and the connecting portion (connection bracket 4) having a slide function protrudes from the reinforcing ribs 2b.

Filling reinforcing material (3) is formed of reinforcing bars, band steel, reinforcing lattice, geotextile, and the like, in particular, formed of reinforcing bars, connecting plate (3a) protrudes at the end of the connecting bracket (4), acupressure plate (6) at the opposite end ) Is attached.

In addition, a connecting hole 3b through which the connecting bolt 5 can be inserted is formed in the connecting plate 3a.

The filling reinforcement 3 made of reinforcing bars is inserted into the connecting plate 3a between the connecting plates 4b and 4b of the connecting bracket 4 and connected to the connecting hole 4c and the connecting hole 3b. Tightening the bolt 5 is connected to the back part of the wall panel 2 via the connection bracket 4, respectively.

In such a configuration, each fill reinforcing material 3 is particularly connected to the reinforcing ribs 2b formed through the connecting bracket 4, so that it can reliably resist even a large earth pressure at the voltage of the fill layer 1. Can be.

In addition, even if the ground reinforcement material 3 has subsided due to sedimentation due to compression under voltage or over time after construction, the end of the ground reinforcement material 3 slides downward along the connection hole 4c of the connection tool 4 to the wall surface. Since stress does not concentrate on the connection part a of the panel 2 and the fill reinforcement material 3, breakage of the connection part a, displacement of the wall panel 2, etc. can be prevented reliably.

As a result, it is possible to use an extremely stable thin wall panel with a slide function, enabling the construction of reinforced earth retaining walls excellent in workability and economy.

In this structure, the panel thickness of the portion having the reinforcing ribs 2b can be reduced to 17 centimeters or less and the thickness of the other portion to 10 centimeters or less.

Next, the construction method will be briefly described with reference to FIG.

① At first, one end of wall panel 2A is provided, and the ground layer 1a is formed evenly while laying up to the position of the lower connection bracket 4A on the rear side.

② Next, place a group of fill reinforcement 3A on the fill layer 1a. Then, the end of the fill reinforcing material (3A) is connected to the connecting bracket (4A). At that time, insert the connecting plate 3a of the fill reinforcing material 3A between the connecting plates 4b and 4b of the connecting bracket 4A, and connect the connecting bolt 5 to the connecting holes 4c and 3c. By tightening, the end portion of the fill reinforcing material 3A is connected to the connecting bracket 4A.

At this time, it is also possible to adjust the verticality of the wall panel (2) by providing a turn bagle (7) in the fill stiffener (3).

③ Next, fill the filling reinforcement material (3A) to the upper connection bracket (4B) position and carefully voltage to form the fill layer (1b).

④ Next, install two levels of fill reinforcement material (3B) on the fill layer (1b). Then, the end of the fill reinforcing material (3B) is connected to the connecting bracket (4B).

In the same manner, the two-stage and three-stage wall panels 2B and 2C and the fill stiffeners 3B and 3C are alternately installed with the fill to build the entire reinforced soil structure.

In this construction, in particular, even if the ground reinforcement material 3 has subsided due to the voltage of the fill area, the end surface of the ground reinforcement material 3 can slide downward along the connection hole 4c of the connection bracket 4, so that the wall panel 2 ) And the stress is not concentrated in the connection portion (a) of the fill stiffener (3), the connection portion (a) is not broken or the wall panel (2) is not deformed.

The wall panel according to the present invention has the above-described configuration, and in particular, it is possible to form as thin as possible other than the part having the reinforcing ribs, so that the production cost can be reduced due to the material savings and the weight reduction Workability is improved.

In addition, since the fill reinforcement is connected to the thickly formed reinforcing rib through the connection bracket (connecting part), it is possible to reliably and firmly resist a large earth pressure at the time of the voltage of the fill layer, which is extremely stable in strength.

In addition, the connecting bracket (sliding part) having a slide function is protruded from the reinforcing ribs arranged in a vertically and horizontally symmetrical form on the panel forming a substantially rectangular plate shape, and the connecting bracket (connecting part) forms a simple structure of the right and left symmetrical. Therefore, even if the fill reinforcement moves along the hole of the connection part, it does not cause an indefinite change of stress, so that a rigid and stable wall surface can be formed by using the connection bracket having the minimum size.

In addition, even if the ground reinforcement material is settled by compression under voltage or over time after construction, the end of the ground reinforcement material slides downward along the longitudinally formed connection hole of the connection bracket, thereby stressing the connection between the wall panel and the ground reinforcement material. Since this concentration is not concentrated, the connection between the wall panel and the fill reinforcement can be ruptured or the displacement of the wall panel can be reliably prevented.

In addition, the wall panel is formed in a substantially rectangular shape, and expansion ribs are provided at the left and right ends thereof, and the expansion ribs protrude in an arc shape or an obtuse angle, so that even if the panel is thin, the parts are not damaged. have.

In addition, the reinforcement soil structure according to the present invention has a rigid reinforcement soil structure that is difficult to be destroyed while the wall panel itself maintains the left and right blanks, while having mobility and enabling the movement of the connection portion under the reinforcement reinforcement in compliance with the compression of the fill vertical direction. It is possible.

Claims (5)

In the wall panel installed adjacent to the top and bottom and left and right directions along the normal surface of the fill layer, it forms a substantially rectangular plate shape, and has an extended rib projecting in the same plane at the left and right edge ends, and on the back side. A wall panel comprising a reinforcing rib continuous in the up and down direction, and a connection bracket protruding from the reinforcing rib and connected to a fill reinforcing material installed in the fill layer. The method of claim 1, The connecting bracket is formed in a substantially U shape when viewed from above and is anchor plate embedded in the reinforcing rib, fixed to the anchor plate and protruded to the back side of the wall panel, and the connecting hole for connecting the fill reinforcement material in the vertical direction. Wall panel, characterized in that consisting of a connecting plate is formed long and thin. The method according to claim 1 or 2, Extended ribs protrude in an obtuse angle or approximately arc shape. A plurality of wall panels of claim 1 or 2 are installed at the front end of the fill layer adjacent to the top and bottom and left and right directions along the normal surface of the fill layer. Reinforcement earth structure, characterized in that made by connecting to the wall panel through a connecting bracket. The wall panel of claim 3 is installed at the front end of the fill layer, adjacent to the up and down direction and the left and right directions along the fill layer, and several fill reinforcement materials are installed in the fill layer. Reinforcement earth structure, characterized in that made by connecting to the wall panel.