KR100308715B1 - A method for stabilizing the slope surface - Google Patents

Abstract

The present invention relates to a slope stabilization method for stabilizing slopes by forming a frame by quickly and easily as a unit member of a ready-made (PC) product when natural or artificial slopes are formed, and the base concrete on the floor to form slopes Placing, installing the front member having a certain length in the left and right length direction in front of the upper portion of the base concrete, and the rear member having a length at the same interval as the front member at the rear of the base concrete in the left and right length direction, A connecting member is formed on the ends of the front member and the rear member to be interconnected in the width direction so as to fill the soil between the upper and lower layer members, thereby forming a soil-seal portion in which the soil is exposed on the front surface, thereby forming one assembly frame body. In the stabilization, the assembly frame 60 in front The one end is supported and the other end is provided by a reinforcement anchor 70 for reinforcing the ground deeply to provide a slope stabilization method characterized in that the zoom.

Description

Slope stabilization method {A METHOD FOR STABILIZING THE SLOPE SURFACE}

The present invention is to stabilize the slopes by forming a frame by quickly and easily assembling in the field as unit members of the ready-made (PC) products when naturally formed slopes or artificial slopes formed by roads, railways and complexes are formed. The present invention relates to a slope stabilization method for installing a reinforcing anchor in a frame so that it can be structurally constructed firmly.

Conventional slope stabilization method stabilizes the slope by the construction method to assemble the unit blocks in the field by transporting the unit blocks in a predetermined form in advance to the work site.

As such, the conventional method of assembling and building unit blocks has no structural support that is deeply supported in the ground from which the unit blocks are cut. Not only is it vulnerable, but in this case, maintenance work is required again, so there was an uneconomical problem due to post-management costs.

In other words, the prior art is a technique that is assembled from the plate-shaped unit blocks and can not escape from the flat concept. Therefore, since the assembled blocks are only assembled in a plane, there is a problem in that the earth and sand flow down due to the rainy season or flood and are easily collapsed or lost.

Recently, in order to solve the above-mentioned problems, a three-dimensional concept of stabilizing slopes has been introduced by forming an assembly frame that is assembled from elongated unit members to be partially supported in the ground.

That is, the recent slope stabilization method, as shown in Figures 1a and 1b, the base concrete (1) is cast on the floor to form the slope, and the front member having a predetermined length in front of the base concrete (1) ( 2) in the left and right length direction, and the rear member (3) having a length at the same interval as the front member (2) in the upper rear of the base concrete (1) is also installed in the left and right length direction, and the front member ( 2) and connecting members (4) to be interconnected in the width direction on the end of the rear member (3) to fill the earth and sand between the upper and lower layer members to form the earth and sand portion 6 to expose the earth and sand on the front And to form the assembly frame (5) to be buried in the soil to be supported in the rear to stabilize the slope.

Such a recent one has the advantage of stabilizing the slope more firmly by introducing a three-dimensional concept of assembling a long unit member to form a single assembly frame so that the front surface is exposed to the slope and the rear side is embedded in the ground deeply supported It is true.

However, in recent years, as shown in Fig. 1B, the front and rear members 2, 3 and the connecting members 4 are simply flat and are pushed by the earth pressure, which is connected to the connecting parts. There is a problem that the assembly frame (5) collapses because it is easily removed.

Therefore, the object of the present invention is to build the assembly frame by using a ready-made product with a constant quality of the unit members disposed on the slope surface, the front surface is exposed to the slope surface and the rear side is supported in the ground, install a reinforcement anchor on the assembly frame By reinforcing, it is to provide a slope stabilization method that forms a structurally strong slope.

Figure 1a and Figure 1b is an illustration of a state of building a conventional sloped assembly frame

Figure 2 is an exemplary cross-sectional view of the inclined surface constructed in accordance with the present invention

Figure 3 is a front view of the slope surface constructed in accordance with the present invention

Figure 4 is a perspective view showing a coupling state of the assembly frame according to the present invention

Figure 5 is a perspective view of another embodiment showing the assembly frame assembly state according to the present invention

Figure 6 is a side view of another embodiment of the inclined surface constructed in accordance with the present invention

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

10: basic concrete 20: front member 30: rear member

31: length panel 32: unit block 40: connecting member

50: fastening rod 60: assembly frame 61: earth and sand part

70: reinforcing anchor a: fastener b: coupling groove

c: sloped groove

Hereinafter, the technical configuration of the present invention will be described.

In the slope stabilization method of the present invention, the foundation concrete 10 is placed on the floor to form the slope, and the front member 20 having a predetermined length in front of the foundation concrete 10 is installed in the horizontal direction, and the foundation The rear member 30 having a length at the same interval as the front member 20 at the upper rear of the concrete 10 is also installed in the left and right directions, and on the ends of the front member 20 and the rear member 30. Installing a connecting member 40 to be interconnected in the width direction to fill the earth and sand between the upper and lower layer members to form the earthenware portion 61 to expose the earth and sand on the front surface to form one assembly frame 60 to slope In stabilizing

One side end is supported on the front of the assembly frame 60, the other end is provided by a reinforcement anchor 70 for reinforcing the deep inside the ground to provide a slope stabilization method characterized in that the zoom.

Therefore, the present invention has an advantage of stabilizing the inclined surface by preventing the assembly frame 70 from being forwardly supported while the reinforcing anchor 70 fixed to the rear of the assembly frame supports the assembly frame 60. .

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

Figure 2 shows an example of the laminated construction when the height of the slope is low, the form is built on a slope of low height where the earth pressure is not large, Figure 6 is a laminated construction when the height of the slope is high For example, when the height of the inclined surface is high, the earth pressure not only increases, but also increases the self-weight of the unit members. The anchors 70 are installed. The reinforcing anchors 70 support one side of the front member 20 and the other side of the reinforcement anchors are buried to a predetermined depth of the ground to firmly fix the earth pressure and load of the unit members. It is to endure.

In addition, each of the connecting parts connected between the front and rear members 20 and 30 and the connecting member 40 drills a fastening hole a in the vertical direction up and down, and fastens the fastening rod 50 to slip between the members. It is to be integrally fastened so as not to fall out to build a solid assembly frame 60 to stabilize the slope.

Here, the fastening bar 50 may be one steel bar integrally extended to the upper and lower parts, or may be used by connecting every predetermined height. In this case, if the connection is not carried out separately welding, just plug it into the fastening hole (a). In addition, the lower end of the fastening rod 50 may or may not be fixed to the base concrete 10.

On the other hand, in the embodiment of the present invention, as shown in Figures 2 and 3, the fastening bar 50 uses one steel bar that is integrally extended to the upper and lower parts, but the lower end is fixed to the foundation concrete 10 It is showing. Therefore, since the lower end of the fastening rod 50 is firmly fixed to the foundation concrete 10, the earth pressure can be smoothly transmitted to the foundation concrete 10.

Looking at the shape of each structural member used in the above embodiment, first, the front member 20 is a quadrangular member formed in the longitudinal direction as shown in Figure 4, the fastening hole (a) at both ends thereof up and down It is a structural member that is drilled in the direction.

The front member 20 is formed to be inclined downward to the outside to be fitted into the inclined groove (c) inclined upward on the upper surface of the outer end of the connecting member 40 to increase the frictional force against earth pressure.

Two types of the rear member 30 are used according to soil conditions. In the section in which earth pressure is applied, length panels 31 having a rectangular parallelepiped shape are used, as shown in FIG. As shown in FIG. 5, a unit block 32 having a small hexahedron shape is used in a section in which earth pressure is low.

That is, since the length panels 31 are embedded in the earth and sand portion to support them, it is preferable to use them in a section in which a lot of earth pressure is required, and the unit block 32 is relatively earth pressure because it only serves to adjust the height. It is preferable to use in the section which takes less time.

The connecting member 40 is a member that connects the front member 20 and the rear member 30 to each other, as shown in Figures 4 and 5, so that the front and rear members are coupled to the upper and lower ends thereof. Coupling grooves (b) are respectively formed, in particular, the groove in which the front member 20 is coupled to the front portion is formed with an inclined groove (c) inclined upwards to increase the bearing force when the front member 20 is subjected to earth pressure It will increase the bonding force.

The construction procedure according to the above embodiment will be described.

The foundation concrete 10 is a structural part that delivers the load of the earth and sediment materials of the upper portion to the ground, and first excavates the ground to some extent on the floor surface to be constructed to pour concrete.

At this time, when placing the foundation concrete 10 is fixed by installing fastening rods 50 that extends vertically long at a predetermined interval. The fastening rods 50 are installed separately from the front row for fixing the front member 20 and the rear row for fixing the rear member 30.

That is, as shown in FIGS. 2 to 5, the front members 20 are fitted into the front row of the fastening rods 50, and the rear members 30 are fitted into the rear row. In addition, the front and rear ends of the connecting members 40 are fitted to the front and rear heat of the fastening rod 50, respectively. These fastening rods 50 are to function to fasten each member structurally integral.

When the basic concrete 10 operation is completed as described above, each member is stacked alternately for each of the upper and lower layers.

That is, as shown in Figures 3, 4 and 5, the lower layer member is first installed, it is installed by inserting the fastening rods 50 in the front row through the fitting holes (b) bored at both ends of the front member 20. But every other one is installed one by one, the rear member 30 is also fitted to the fastening rods 50 immediately after the front member 20 in the same manner.

And by connecting the connecting member 40 to the fastening rod 50 to interconnect the left and right ends of the front and rear members 20, 30, the lower layer member installation is completed.

Then, the upper layer member is installed, and the front member 20 is installed such that both ends thereof are caught on the upper left and right front members of the lower layer. And the rear member 30 is also installed so that both ends thereof over the lower left and right rear members already installed, and the connecting member 40 is also installed to be connected between the front and rear members in the same manner as above.

According to the present invention, the members are stacked alternately by upper and lower layers by a predetermined height in the same manner, and then the reinforcing anchor 70 according to the present invention is constructed and the above operation is repeatedly performed to make the slope more structurally stable. On the other hand, the present invention fills the earth and sand between the upper and lower layer members on the front surface of the assembly frame 60 to form the earth and sand portion 61 to expose the soil on the front surface within the earth and sand portion 61. Planting trees or grass can improve the aesthetic appearance.

As described above, the present invention is connected to the front and rear members and the connecting member, unlike the conventional one which is easily pushed away by earth pressure because the unit members are simply formed flat and there is no structural part connected and bound between the members. By fastening the fastening holes vertically and vertically for each connecting part, and fastening them integrally with fastening rods, and by installing reinforcing anchors at certain heights of the assembly frame, a solid assembly frame can be constructed to stabilize the slope more efficiently. It works.

Claims (4)

Claim 1 has been deleted. Claim 2 has been deleted. Claim 3 has been deleted. The foundation concrete 10 is placed on the floor to form the slope, and the front member 20 having a predetermined length in front of the upper portion of the foundation concrete 10 is installed in the horizontal direction, and the upper portion of the foundation concrete 10 in the rear The rear member 30 having a length at the same interval as the front member 20 is also installed in the left and right length direction, and connected to each other in the width direction on the ends of the front member 20 and the rear member 30. In order to stabilize the inclined surface by forming a single assembly frame 60 while providing a connection member 40 to form a soil portion 61 to expose the soil to the front by filling the soil between the upper and lower layer members, Slope surface stabilization method characterized in that the one side end is supported on the front of the assembly frame 60, the other end is reinforced by installing a reinforcement anchor (70) to be settled deep inside the ground.