KR102509305B1 - Retaining wall using precast panel with foundation structure - Google Patents

Abstract

The present invention relates to a retaining wall structure having a foundation-integrated precast panel, and more particularly, by constructing a retaining wall using a foundation-integrated precast panel in which the foundation of the retaining wall and the precast panel are formed as a single structure, construction cost It relates to a retaining wall structure having a foundation-integrated precast panel capable of reducing energy consumption, shortening the construction period, and improving the structural rigidity, durability, and aesthetics of the retaining wall.
A retaining wall structure having a foundation-integrated precast panel according to the present invention includes a precast panel; and an underground reinforcing material buried in a slope and having an exposed portion connected to the precast panel, wherein the precast panel includes a foundation-integrated precast panel installed on the ground and a foundation-integrated precast panel stacked on top of the foundation-integrated precast panel. It is composed of a precast panel, and the foundation-integrated precast panel is characterized in that it includes a base part formed on the lower side to be seated on the ground, and a panel part extending upward to have a thinner thickness than the base part.

Description

Retaining wall structure with foundation integral precast panel {RETAINING WALL USING PRECAST PANEL WITH FOUNDATION STRUCTURE}

The present invention relates to a retaining wall structure having a foundation-integrated precast panel, and more particularly, by constructing a retaining wall using a foundation-integrated precast panel in which the foundation of the retaining wall and the precast panel are formed as a single structure, construction cost It relates to a retaining wall structure having a foundation-integrated precast panel capable of reducing energy consumption, shortening the construction period, and improving the structural rigidity, durability, and aesthetics of the retaining wall.

In general, in the course of various civil engineering works such as road construction, housing complex construction, waterway and embankment construction, a retaining wall structure is constructed to prevent collapse due to loss of soil in an embankment or incision site.

For example, as shown in FIG. 1, the retaining wall structure is an underground reinforcement installation step in which buried holes 8 and 8' are drilled in the incision and underground reinforcements 7 and 7' such as underground anchors are installed, retaining walls 100 and 100a A foundation block installation step of installing foundation blocks (1, 1') in a row after leveling the floor of the location to be constructed; Step of stacking and installing precast panels (2, 2') on top of foundation blocks (1, 1'), binding step of connecting underground reinforcement (7, 7') and precast panel (2), precast It is constructed by sequentially performing the finishing step of performing the backfilling work on the back of the panel.

In addition, the foundation blocks (1, 1') used in the above retaining wall structure reinforce the ground on which the precast panels (2, 2') will be installed during the construction of the retaining wall, thereby increasing the rigidity of the retaining wall to prevent collapse. It can perform the function of preventing, but has various problems as follows.

First, in the conventional retaining wall structure described above, foundation blocks (1, 1') must always be installed in a row along the installation area of the retaining wall structure before stacking of precast panels, so the manufacturing cost of the foundation block and the installation cost of the foundation block are added. This has the disadvantage of increasing the construction cost and lengthening the construction period.

And, as shown in Figure 1, the conventional retaining wall structure is structurally weak because the foundation blocks (1,1') and the precast panels (2,2') are different from each other, so that the lower part of the retaining wall where the load is concentrated is earthquake or When a displacement force is applied, there is a high risk of cracking or deformation, and in severe cases, there is a problem in that the retaining wall collapses due to separation of the precast panel or foundation block, overturning or damage of the foundation block.

In addition, the conventional retaining wall structure has a disadvantage in that the durability of the retaining wall is lowered because the structural rigidity is weak due to the stress concentration due to the rapid change in cross-sectional shape of the connection part between the foundation block (1,1') and the precast panel (2,2') there is.

In addition, in the conventional retaining wall structure, when the foundation blocks (1, 1') and the precast panels (2, 2') are made of different materials or with different patterns and patterns, the sense of aesthetics is poor due to heterogeneity, and these problems are solved. In order to solve this, additional work is required to bury the foundation blocks (1, 1') inside the original ground so that they are not exposed to the outside. (The Mountain Law restricts the height of one retaining wall to 5 meters). Since retaining walls of various sizes are required to appropriately adjust the height of one retaining wall, which is limited to 5 meters, there is a secondary problem of poor workability and increased construction cost. There are limitations that can be drawn.

Korean Patent Registration No. 10-0770250 "Retaining wall construction method and retaining wall structure accordingly" Korean Patent Publication No. 10-2016-0144111 "Foundation block for retaining wall and foundation ground reinforcement method of retaining wall using the same"

The present invention has been proposed in view of the above, and by constructing a retaining wall using a foundation-integrated precast panel in which the foundation of the retaining wall and the precast panel are formed as a single structure, the construction cost can be reduced and the period can be shortened. Its purpose is to provide a retaining wall structure having a foundation-integrated precast panel.

Another object of the present invention is to provide a retaining wall structure having a foundation-integrated precast panel capable of improving structural rigidity, durability, and aesthetics of the retaining wall by improving drainage characteristics.

Another object of the present invention is to provide a retaining wall structure having a foundation-integrated precast panel capable of maintaining the rigidity of the retaining wall by having seismic isolation characteristics that absorb and buffer vibration, impact force, etc. in the event of an earthquake or ground subsidence. To provide a retaining wall structure will be.

In order to achieve the above object, a retaining wall structure having a foundation-integrated precast panel according to the present invention includes a precast panel; and an underground reinforcing material buried in a slope and having an exposed portion connected to the precast panel, wherein the precast panel includes a foundation-integrated precast panel installed on the ground and a foundation-integrated precast panel stacked on top of the foundation-integrated precast panel. It is composed of a precast panel, and the foundation-integrated precast panel is characterized in that it includes a base part formed on the lower side to be seated on the ground, and a panel part extending upward to have a thinner thickness than the base part.

Preferably, the base portion, the base body formed to protrude forward than the front surface of the panel portion; A horizontal drain that is concave in the horizontal direction on the bottom surface of the base body; A horizontal drain formed on the rear surface of the base body so as to communicate with the horizontal drain; And a grout inlet formed on the front surface of the base body so as to communicate with the street drainage for injection of the grouting material; may be configured to include.

The integrated foundation precast panel includes a square integrated precast panel having a square front shape, and a triangular integrated precast panel installed in a corner portion adjacent to the square integrated precast panel and having a frontal shape formed in a triangular shape. It can be configured to include.

In addition, the precast panel for lamination includes a precast panel for rectangular lamination having a square frontal shape and a precast panel for triangular lamination installed at a corner portion adjacent to the rectangular precast panel and having a triangular frontal shape. It may consist of a panel.

The foundation-integrated precast panel has a transverse drain connection groove concave to connect the transverse drain to each other on the rear surface of the foundation, and a reinforcing hole formed in the panel portion. Concave to connect between the transverse drain connection groove A retaining wall structure having a foundation-integrated precast panel, characterized in that it comprises an induction drainage groove.

On the other hand, the retaining wall structure having a foundation-integrated precast panel according to the present invention includes a vertical reinforcing material buried so that the upper end is positioned in the horizontal drainage channel; and a seismic isolation cap installed on top of the vertical stiffener.

In addition, the retaining wall structure having a foundation-integrated precast panel according to the present invention may further include an insert nut coupled to an upper end of the vertical reinforcing member and inserted into the seismic isolation cap, the seismic isolation cap corresponding to the horizontal drainage It may include a seismic isolation protrusion protruding in a shape and having a nut fitting groove inserted into the insert nut, and a cap pad formed of a planar body extending around the seismic isolation protrusion.

In addition, the retaining wall structure having a foundation-integrated precast panel according to the present invention is a seismic isolation installed between the foundation-integrated precast panel and the precast panel bonding portion for lamination, and the bonding portion of the lamination precast panel stacked vertically pad; and a seismic isolation pad fitting groove recessed so that a part of the seismic isolation pad is exposed and inserted into the upper part of the base-integrated precast panel and the upper part of the precast panel for lamination.

In addition, the base portion and the panel portion may include a stone-shaped protrusion formed by protruding in a natural stone shape on the front surface or a natural stone coupled to the front surface.

According to the retaining wall structure having a foundation-integrated precast panel according to the present invention, the foundation-integrated precast panel in which the part performing the function of the foundation block and the part performing the precast panel function are formed as a single structure is placed on the lowest layer Therefore, as the retaining wall is constructed, it becomes unnecessary to manufacture or construct a separate foundation block, so the construction cost can be reduced, the period can be shortened, and the structural rigidity, durability and aesthetics of the retaining wall can be improved.

In addition, according to the retaining wall structure having an integrated foundation precast panel according to the present invention, a triangle integrated precast panel is installed on the left and right sides of the square integrated precast panel, and a triangular stacked precast panel is installed on the left and right sides of the square stacked precast panel. By installing the cast panel, it is possible to easily construct a retaining wall having a shape similar to the shape of the incision in the mountainous area, and there is an effect of reducing the construction cost and shortening the construction period as well as improving the aesthetics of the exterior.

On the other hand, according to the retaining wall structure having a foundation-integrated precast panel according to the present invention, the downward movement of groundwater flowing into the reinforcement fastening hole can be induced and drained by the induction drainage groove, so the exposed portion inserted into the reinforcement fastening hole It is possible to prevent corrosion of the fixing means coupled to the retaining wall, thereby improving the durability of the retaining wall. In addition, since the leakage of rust to the front surface of the reinforcement fastening hole is prevented, it is possible to improve the appearance by preventing the generation of stains on the front surface of the integrated precast panel.

And, according to the retaining wall structure having a foundation-integrated precast panel according to the present invention, an insert nut and a seismic isolation cap are installed at the top of the vertical reinforcing material, so even if earthquake, ground subsidence, excavation, and blasting vibration occur, the foundation is primarily It is possible to perform the primary seismic isolation action of absorbing and buffering, and it is possible to perform seismic isolation action in multiple stages by means of seismic isolation pads interposed between the integrated precast panel and the precast panel for lamination. has the effect of preventing and improving durability.

1 is a view for explaining a conventional retaining wall structure;
Figure 2 is a perspective view showing a foundation-integrated precast panel applied to a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention;
Figure 3 is a cross-sectional view showing a foundation-integrated precast panel applied to a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention;
4 is a cross-sectional view showing a construction state of a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention;
Figures 5a to 6b are views for explaining a modified example of a retaining wall structure having a foundation integrated precast panel according to an embodiment of the present invention, Figure 5a is a front view showing one form of a square foundation integrated precast panel Figure 5b is a front view showing another form of a square base integral precast panel, Figure 6a is a front view showing one form of a triangular base integral precast panel (110a), Figure 6b is a triangular base integral precast panel (110a) ) is a front view showing another form of
7 is an installation state diagram for explaining a modified example of a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention;
8 is a cross-sectional view showing a construction state of a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention;
Figure 9 is a perspective view for explaining foundation-integrated precast panels applied to a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention;
10 is an enlarged view of part A of FIG. 8;
11 is a perspective view showing a seismic isolation cap applied to a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention;
12 is an enlarged view of part B of FIG. 8;
13 is an exploded perspective view for explaining a seismic isolation pad applied to a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the accompanying drawings 2 to 13, but the same reference numerals are assigned to the same components in FIGS. 2 to 13 to be described.

On the other hand, in each drawing, detailed descriptions of configurations and actions and effects thereof that can be easily known to those skilled in the art from general technology are simplified or omitted. In addition, since the present invention is characterized by a retaining wall structure having a foundation-integrated precast panel, the related parts are shown and described mainly, and the description of the remaining parts is simplified or omitted.

Figure 2 is a perspective view showing a foundation-integrated precast panel applied to a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention, showing a shape appearing from the rear side. Figure 3 is a cross-sectional view showing a foundation-integrated precast panel applied to a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention, showing a cross section in an installed state. 4 is a cross-sectional view showing a construction state of a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention.

2 to 4, a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention includes a precast panel 100 forming a retaining wall and a precast panel 100 buried in a slope Including the underground reinforcement 200 to which the exposed portion 210 is connected, the precast panel 100 is composed of a foundation-integrated precast panel 110 and a precast panel 120 for lamination.

As shown in FIGS. 2 and 3, the foundation-integrated precast panel 110 is a precast panel installed on the ground corresponding to the lowest layer forming the retaining wall, and the concrete mortar is poured into a mold with a skeleton such as reinforcing bars. and cured, and the base part 112 and the panel part 114 are composed of a single body.

The foundation part 112 is formed on the lower part of the foundation-integrated precast panel and is seated on the ground, and the horizontal drainage 1122, horizontal A drainage hole 1123 and a grout inlet 1124 are formed.

The base body 1121 is composed of an inclined connection portion 1125 formed obliquely at the connection portion with the panel portion 114, and a vertical portion 1126 formed downward below the inclined connection portion 1125, the inclined connection portion ( 1125 performs a function of improving structural stability by preventing stress concentration by connecting the panel portion 114 and the base body 1121 so that the cross-sectional changes are smoothly connected.

The horizontal drainage 1122 is recessed to have a substantially trapezoidal shape as a groove that is recessed in the horizontal direction on the bottom surface of the base body 1121.

The transverse drain 1123 is provided to allow rainwater or groundwater on the rear surface of the retaining wall to flow toward the horizontal drain 1122, and is formed on the rear surface of the base body 1121 to communicate with the horizontal drain 1122. Here, the number of horizontal drains 1123 is not particularly limited, but as shown in FIG. 2, it is preferable to form two spaced apart on the lower part of the rear surface.

The grout inlet 1124 is formed on the front surface of the base body 1121 to communicate with the horizontal drainage 1122 for injection of the grouting material. The grout inlet 1124 serves as an inlet when a drainage channel is unnecessary depending on the installation location and installation conditions of the retaining wall, and fills the horizontal drainage channel 1122 with grouting material, thereby increasing the stiffness of the retaining wall.

In addition, the grout inlet 1124 is formed such that an inlet is provided at a boundary point between the inclined connection portion 1125 and the vertical portion 1126 of the base body 1121. In this way, if the grout inlet 1124 has an inlet formed at the protruding portion of the boundary point, the grouting material injection process can be performed smoothly, and appearance defects due to external exposure of the grout inlet can be prevented in advance.

On the other hand, the foundation-integrated precast panel 110 has a stone-shaped protrusion 116 protruding in the shape of a natural stone on the front surface so as to realize an eco-friendly retaining wall, or it can be configured by combining natural stones on the front surface. .

The panel portion 114 is a portion that extends upward to have a thinner thickness than the base portion 112, and there is no particular limitation on the formation height, but in this embodiment, the height dimension is three times that of the base portion 112. is formed to have That is, the base portion 112 is formed to have a height of 500 mm, and the panel portion 114 is formed to have a height of 1,500 mm.

In addition, a reinforcing member fastening hole 1144 is formed in the panel portion 114 in which the exposed portion 210 is inserted in the center and fastened by a fixing means (not shown) such as a fixing nut.

In addition, at the upper end of the panel unit 114, a fitting groove 1146 into which a fitting protrusion 122 of a precast panel stacked on top is inserted is concave.

On the other hand, the precast panel 120 for lamination is formed in a known shape and is a concrete panel laminated with at least one layer on top of the integrated precast panel 110 as shown in FIG. 4, and has the same thickness as a whole. As formed, it has a rectangular shape of a structure in which a base protruding convexly in the front direction is not provided.

In the precast panel 120 for lamination, reinforcement fastening holes 123, fitting protrusions 122, fitting grooves 124, and the like are formed in a panel body 121 having a substantially square shape. In addition, the laminated precast panel 120 may be formed by forming a stone-shaped protrusion 126 protruding in the shape of a natural stone on the front surface to implement an eco-friendly retaining wall, or combining natural stones on the front surface.

Hereinafter, the operation of the retaining wall structure having the integrated foundation precast panel according to an embodiment of the present invention will be briefly described.

The construction method of a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention is carried out similarly to the well-known retaining wall construction method, and the steps of cutting the original ground to form a cut slope, underground such as underground bolts A set of retaining walls is constructed, including the step of burying the reinforcing material 200, the step of forming the foundation, the step of laminating the panels, the step of connecting the reinforcing material in the ground, and the back filling step.

A second cut slope is formed below the foundation of the thus formed retaining wall within the lower stress range of the pre-constructed retaining wall according to various consideration conditions such as the height of the original ground, and the second cut slope is formed by the same method. At least one lower retaining wall is constructed in such a way as to form a

In the step of forming the cut slope, the original ground is cut to have an angle determined by site conditions, construction drawings, and specifications using a construction machine such as an excavator to form the cut slope (a).

In the step of burying the underground reinforcement, as shown in FIG. 4, the drilling position is marked on the cutting slope (a), the drilling angle and drilling depth are determined, and then the buried hole is drilled by a drilling machine. Assemble an underground bolt (usually called a soilnail) to correspond to the depth of the buried hole, connect the grouting injection hose, insert it into the buried hole, perform grouting work, and cure it to make the underground bolt as an underground reinforcing material. complete the burial At this time, the underground reinforcement 200 should be buried to have an exposed portion 210 of a predetermined length on the cutting slope (a). In addition, the step of burying the underground reinforcement material is not limited to the above-described method, and may be performed by various well-known soil rail construction methods.

As shown in FIG. 4, the foundation formation step is performed to prepare a foundation for supporting the integrated precast panel 110, and includes drilling on the lower surface of the cut slope (a), drilling into the drilled hole. It can be fixed by inserting an underground anchor 310.

And, in the foundation formation step, as shown in FIG. 3, when a separate underground anchor is not required to be installed, the foundation is formed by pouring and curing the discarded concrete layer 300 to form a uniform foundation surface.

In the panel stacking step, the horizontal drainage 1122 of the integrated precast panel 110 is installed on the foundation formed by the underground anchor 310 so that it is in place. At this time, when the drainage of the retaining wall is unnecessary, the rigidity of the retaining wall can be increased by filling the horizontal drainage channel 1122 with grouting material through the grout inlet 1124 and integrating it with the underground anchor 310.

In particular, according to the present invention, as the foundation-integrated precast panel 110 is installed on the lowermost layer of the retaining wall, it is not necessary to separately construct the foundation block, so the construction cost can be reduced and the construction period can be shortened.

Meanwhile, in the panel lamination step, the precast panel 120 for lamination is stacked on top of the integrated precast panel 110 to have multiple rows.

The underground reinforcement connection step is a step of binding the exposed portion 210 of the underground reinforcement 200 to the foundation integrated precast panel 110 and the precast panel 120 for lamination, and the backfilling step is the foundation integrated precast panel ( 110) and filling and compacting the filler between the back surface of the precast panel 120 for lamination and the cut slope.

The filling material introduced in the backfilling step is preferably gravel for smooth drainage, and a drainage pipe (not shown) may be buried for smooth drainage before performing this backfilling step.

When one end of the retaining wall is completed with a predetermined height as shown in FIG. 4 through each step as described above, the second cutting slope (a ') is formed within the lower stress range of the retaining wall, and the second cutting slope (a '), at least one lower retaining wall is repeatedly formed through the same steps as the formation process of the upper retaining wall described above.

Hereinafter, a modified example according to the present invention will be described, but detailed descriptions of elements similar to those shown in the above-described embodiment will be omitted, and elements having differences will be mainly described.

Figures 5a to 6b are views for explaining a modified example of a retaining wall structure having a foundation integrated precast panel according to an embodiment of the present invention, Figure 5a is a front view showing one form of a square foundation integrated precast panel Figure 5b is a front view showing another form of a square base integral precast panel, Figure 6a is a front view showing one form of a triangular base integral precast panel (110a), Figure 6b is a triangular base integral precast panel (110a) ) is a front view showing another form of 7 is an installation state diagram for explaining a modified example of a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention, showing a shape appearing from the front in the installed state.

5A to 7, a retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention is composed of a foundation-integrated precast panel 110 and a precast panel 120 for lamination, The integrated precast panel 110 may be formed in various shapes such as a triangular shape in addition to a square shape, and the integrated precast panels formed in different shapes may be constructed as a retaining wall alone or in combination.

For example, the foundation-integrated precast panel 110 is installed in contact with the square foundation-integrated precast panels 110 and 110' formed in a square front shape and the square foundation-integrated precast panel, and the front shape is formed in a triangular shape. Precast panels 110a and 110a' may be provided.

In addition, the square base-integrated precast panel 110 may be formed to have various horizontal and vertical sizes. For example, the square integrated precast panel includes a basic square integrated precast panel 110 having a horizontal and vertical size of 1,500 mm x 2,000 mm, and a large square integrated precast panel having a horizontal and vertical size of 2,250 mm x 2,000 mm. It may be made of a panel 110' or the like.

In addition, two reinforcing material fastening holes 1144 are spaced apart and formed at regular intervals in order to secure a stable bearing capacity in the large square base integrated precast panel 110'.

The triangular base-integrated precast panels 110a and 110a' are formed in a substantially rectangular shape, and have a horizontal and vertical (height) size of 3,000 mm x 2,000 mm.

In addition, as shown in FIG. 6A, the triangular integrated precast panel is formed so that the right angle side is located on the right side and is closely installed on the left side of the square integrated precast panel 110. The left type triangular integrated precast panel ( 110a) and, as shown in FIG. 6B, it is formed so that the right angle side is located on the left side and is installed in close contact with the right side of the square base-integrated precast panel 110. has been

On the other hand, the precast panel 120 for lamination is installed in contact with the square lamination precast panel 120 having a square front shape and the square lamination precast panel and having a triangular front shape formed in a triangular shape. A cast panel may be provided.

In addition, the square precast panel 120 for lamination can be formed to have various horizontal and vertical sizes, and as shown in FIG. (120 ') and the like.

In addition, the triangular laminated precast panels 120a and 120a' are formed in a rectangular shape, but as shown in FIG. 7, the right angle side is located on the right side, and is closely installed on the left side of the square laminated precast panel 120 A left-handed triangular laminated precast panel 120a and a right-handed triangular laminated precast panel 120a' formed so that the right angle side is located on the left side and closely installed on the right side of the square laminated precast panel 120. Consists of.

On the other hand, the retaining wall structure having a foundation-integrated precast panel according to a modified example of an embodiment of the present invention is on the lowest layer of the retaining wall without installing a separate foundation block on the ground, as described in the operation description of the above-described embodiment. A retaining wall is formed by installing foundation-integrated precast panels 110, 110', 110a, and 110a', and stacking the precast panels 120, 120', 120a, and 120a' for stacking on top of the precast panels to have multiple rows.

At this time, the square base integrated precast panel 110 is constructed by installing left and right triangular base integral precast panels 110a and 110a' on the left and right sides, and the square laminated precast panel 120 ), left and right triangular stacked precast panels 120a and 120a' can be installed on the left and right sides, so it is possible to easily construct a retaining wall similar to the shape of the incision in the mountainous area. Accordingly, there is an advantage in that construction cost can be reduced, the construction period can be shortened, and the aesthetics of the exterior can be improved.

Hereinafter, another embodiment according to the present invention will be described, but detailed descriptions of elements similar to those shown in the above-described embodiment will be omitted, and elements having differences will be mainly described. And, in the following other embodiments, any structure that can be employed among the components shown in the components shown in one embodiment may be selectively applied, and detailed descriptions or drawings are omitted. In addition, since the operation description of another embodiment according to the present invention is similar to the above-described embodiment, only the differences are briefly described.

Figure 8 is a cross-sectional view showing a construction state of a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention, Figure 9 is a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention It is a perspective view for explaining applied base-integrated precast panels. 10 is an enlarged view of part A of FIG. 8, and FIG. 11 is a perspective view showing a seismic isolation cap applied to a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention.

8 to 11, a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention is a precast panel 100 forming a retaining wall and buried in a slope, as in the above-described embodiment and includes an underground reinforcement 200 to which the exposed portion 210 is connected to the precast panel 100, and the precast panel 100 is composed of a foundation-integrated precast panel 110 and a precast panel 120 for lamination. It is configured, but it is characterized in that it is configured to have seismic isolation characteristics that absorb and buffer vibration and impact forces accompanying earthquakes, shocks, ground subsidence, etc. while improving the drainage characteristics of groundwater.

In the foundation-integrated precast panel 110, the base portion 112 and the panel portion 114 are configured as a single body, as in the above-described embodiment, but as shown in FIGS. 8 and 9, the base portion 112 Connecting between the horizontal drain connection groove 117 in the form of a groove connecting the horizontal drain holes 1123 to each other on the back side of the back surface of the reinforcing material fastening hole 1144 formed in the panel portion 114 and the cross drain connection groove 117 An induction drain groove 118 in the form of a groove is formed with a recess.

The horizontal drain connection groove 117 effectively collects groundwater flowing into the rear surface and drains it via the horizontal drain 1123 and the horizontal drain 1122, thereby preventing the durability of the retaining wall due to groundwater from deteriorating in advance. there is.

In particular, the guiding drainage groove 118 induces the downward movement of groundwater flowing into the reinforcement fastening hole 1144 and drains the reinforcing material through the cross drain connection groove 117, the horizontal drain 1123 and the horizontal drain 1122. Corrosion of a fixing means (not shown) such as a fixing nut, a fixing plate, etc. coupled to the exposed portion 210 inserted into the fastening hole 1144 can be prevented, so that the durability of the retaining wall can be improved. In addition, since rust is prevented from flowing out to the front of the reinforcing material fastening hole 1144, it is possible to prevent stains from being generated on the front of the foundation-integrated precast panel 110 in advance to improve aesthetics.

In addition, although not specifically shown in the drawings, the base-integrated precast panel 110 may have a nonwoven fabric installed on the rear surface to block the inflow of foreign substances.

On the other hand, referring to FIGS. 10 and 11, a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention is buried in the ground in a vertical direction for supporting the foundation-integrated precast panel 110, A vertical stiffener 410 whose upper end is positioned in the horizontal drainage 1122, an insert nut 420 coupled to the upper end of the vertical stiffener 410, and a seismic isolation cap 430 inserted into the insert nut 420 for seismic isolation. ) is composed of

The seismic isolation cap 430 includes a seismic isolation protrusion 431 protruding in a cross-sectional shape (approximately trapezoidal shape) corresponding to the street drainage 1122 and having a nut fitting groove 433 inserted into the insert nut 420, and the seismic isolation protrusion 431. It is composed of a cap pad 432 extending in a planar shape around 431.

12 is an enlarged view of part B of FIG. 8, and FIG. 13 is an exploded perspective view for explaining a seismic isolation pad applied to a retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention.

12 and 13, the retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention has a seismic isolation effect on the upper portion of the foundation-integrated precast panel 110 and the upper portion of the precast panel 120 for lamination. A seismic isolation pad 500 for is configured.

The seismic isolation pad 500 can be formed in various ways without particular limitations in shape and material as long as it can support the precast panel 120 for lamination and absorb and buffer vibration and impact. For example, the seismic isolation pad 500 is formed in a rectangular parallelepiped shape by a synthetic rubber elastic pad having a compressive force of 2.5 Mpa or more. At this time, the synthetic rubber elastic pad is composed of neoprene rubber pad (DNP, Neoprene PAD).

In addition, the base-integrated precast panel 110 and the precast panel 120 for lamination have seismic isolation pad fitting grooves 600 concave so that the seismic isolation pad 500 is inserted into the top.

Here, the seismic isolation pad fitting groove 600 is concave in a shape corresponding to the seismic isolation pad 500, and a lower portion of the seismic isolation pad 500 (hatched portion in FIG. 13) is inserted and the remaining portion is exposed upward. It is formed as deep as possible.

In addition, a plurality of seismic isolation pad fitting grooves 600 may be formed, and in this embodiment, three are spaced apart at regular intervals.

On the other hand, the foundation-integrated precast panel 110 protrudes below the precast panel 120 for lamination, and the support is formed in the fitting groove 1146 into which the fitting protrusion 122 is inserted so that the formed support (not shown) can be inserted. The insertion groove 119 is recessed.

In addition, the precast panel 120 for lamination is formed with reinforcement fastening holes 123, fitting protrusions 122, fitting grooves 124, etc. in the panel body 121 having an approximate square shape, as in one embodiment. , a rod-shaped support (not shown) protruding downward, and a support insertion groove (not shown) recessed upward so that the support is inserted.

8 to 13, in the retaining wall structure having a foundation-integrated precast panel according to another embodiment of the present invention, an insert nut 420 and a seismic isolation cap 430 are installed on top of a vertical stiffener 410 Therefore, even if earthquake, ground subsidence, excavation and blasting vibration occur, it can perform the primary seismic isolation action of primarily absorbing and buffering action at the foundation. In addition, a secondary seismic isolation action is performed by the seismic isolation pad 500 interposed between the upper part of the integrated precast panel 110 and the lower part of the precast panel 120 for lamination, and the precast panel for lamination ( 120), a multi-stage seismic isolation action can be sequentially performed by the seismic isolation pad 500 interposed between them. As a result, collapse or cracking of the retaining wall can be prevented in advance and durability can be improved.

Although the configuration and operation of the retaining wall structure having a foundation-integrated precast panel according to an embodiment of the present invention described above has been described, this is exemplary and those skilled in the art do not deviate from the technical spirit of the present invention. It will be understood that it is possible to substitute and modify some of the above-described embodiments within the scope not specified.

Therefore, it should be understood that the protection scope of the present invention extends to the invention described in the claims and equivalents thereof.

100: precast panel 110: foundation integrated precast panel
110a, 110a': triangular foundation integral type precast panel
112: base 1121: base body
1122: horizontal drain 1123: horizontal drain
1124: grout inlet 114: panel part
117: horizontal drain connection home 118: induction drain home
120: precast panel for lamination 120a, 120a': triangular lamination type precast panel
121: panel body 122: fitting protrusion
123: reinforcement fastening hole 124: fitting groove
200: underground reinforcement 210: exposed part
300: Abandoned concrete layer 410: Vertical reinforcement
420: insert nut 430: seismic isolation cap
500: seismic isolation pad 600: seismic isolation pad insertion groove

Claims (8)

precast panels; And an underground reinforcing material buried in the slope and connected to the exposed part to the precast panel;
The precast panel is composed of a foundation-integrated precast panel installed on the ground and a laminated precast panel laminated on top of the foundation-integrated precast panel,
The foundation-integrated precast panel includes a foundation portion formed on the lower side to be seated on the ground, and a panel portion extending upward to have a thinner thickness than the foundation portion,
The base part, a base body formed to protrude forward from the front surface of the panel part, a horizontal drain concave in the horizontal direction on the bottom surface of the base body, a horizontal drain formed on the rear surface of the base body to communicate with the horizontal drain, and grouting Including; a grout inlet formed on the front surface of the base body to communicate with the horizontal drainage for injection of ash;
The foundation-integrated precast panel has a transverse drain connection groove concave to connect the transverse drain to each other on the rear surface of the foundation, and a reinforcing hole formed in the panel portion. Concave to connect between the transverse drain connection groove A retaining wall structure having a foundation-integrated precast panel, characterized in that it comprises an induction drainage groove.
delete According to claim 1,
The integrated foundation precast panel includes a square integrated precast panel having a square front shape, and a triangular integrated precast panel installed in a corner portion adjacent to the square integrated precast panel and having a frontal shape formed in a triangular shape. including,
The precast panel for lamination includes a precast panel for lamination with a square frontal shape formed in a rectangular shape, and a precast panel for triangular lamination installed at a corner portion adjacent to the precast panel for rectangular lamination and a frontal shape formed in a triangular shape. A retaining wall structure having a foundation integral precast panel, characterized in that it comprises.
delete According to claim 1,
Vertical stiffeners buried so that their upper ends are positioned in the horizontal drainage channels; and
A retaining wall structure with a foundation-integrated precast panel comprising a; seismic isolation cap installed on top of the vertical reinforcement.
According to claim 5,
An insert nut coupled to an upper end of the vertical stiffener and inserted into the seismic isolation cap,
The seismic isolation cap includes a seismic isolation protrusion protruding in a shape corresponding to the horizontal drainage and having a nut fitting groove inserted into the insert nut, and a cap pad formed of a planar body extending around the seismic isolation protrusion. Retaining wall structure with integrated foundation precast panels.
According to claim 5,
a seismic isolation pad installed between the base-integrated precast panel and the binding portion of the precast panel for lamination, and the binding portion of the precast panel for lamination stacked vertically; and
A retaining wall with a foundation-integrated precast panel comprising a recessed seismic isolation pad fitting groove so that a part of the seismic isolation pad is inserted into the upper portion of the foundation-integrated precast panel and the upper portion of the precast panel for lamination so that a part of the seismic isolation pad is exposed. structure.
According to claim 1,
Retaining wall structure with a foundation integrated precast panel, characterized in that the foundation portion and the panel portion include a stone protrusion formed by protruding in a natural stone shape on the front surface or a natural stone coupled to the front surface.

Images