KR101161214B1 - Reinforcement means for soft land and slope reinforcement methode using the same - Google Patents

Abstract

Soft layer reinforcement means according to the invention, one end is blocked and the other end is formed in an open pipe shape, one end of the body is located in the soft layer and the other end of the body is inserted into the soft layer to be exposed outside the soft layer The interior is then configured to be filled with reinforcement. In addition, the slope reinforcement method according to the present invention, the step of inserting the soft layer reinforcing means into the soft layer; Inserting a drill into the soft layer reinforcing means so that an end of the drill penetrates one end of the body and then enters into the rock layer, thereby forming an excavation hole in the rock layer; After pulling out the drill, injecting a reinforcing material into the excavation hole and the inside of the body.

When using the soft layer reinforcement means and the slope reinforcement method using the same, it is possible to effectively support the soft layer by ensuring a sufficient space filled with reinforcement grout inside the soft layer, the slope consisting of the soft layer and the rock layer more easily and firmly The advantage is that it can be reinforced.

Slope, reinforcement, soft layer, excavation, reinforcement

Description

Reinforcement means for soft land and slope reinforcement methode using the same}

The present invention relates to a soft layer reinforcement means and a slope reinforcement method using the same, and more particularly, the soft layer reinforcement is inserted to penetrate through the soft layer when reinforcing the slope consisting of the soft layer and the rock layer and is configured to secure a space in which the reinforcing grout is filled. The present invention relates to a slope reinforcing method that can reinforce a slope in which a soft layer and a rock layer are mixed by injecting a reinforcement grout over a means and a soft layer and a rock layer.

Slopes generated by large-scale land construction, roads, railways, etc., are caused by rainwater or snowmelt infiltration, deterioration of soil strength and weathering, resulting in local slope collapse and falling rocks, resulting in loss of life and property. Since it may cause damage, various slope reinforcement methods are being devised to prevent the collapse of the slope, and these slope reinforcement methods can be roughly classified into a soil nailing method and an earth anchor method.

The small nailing method is a method of reinforcing the slope by inserting a deformed reinforcing bar which is a shear stress material into the excavation hole drilled relatively tightly on the slope, and grouting the reinforcement grout, so that the tensile stress material is not used as a reinforcement material (PRESTRESS) It is characterized by the absence and is mainly applied to the soil layer.

In addition, the earth anchor method is a method of reinforcing the slope by inserting the PC steel wire, which is a tensile stress material into the excavation hole drilled on the slope, grouting the reinforcement grout, and then tensioning the PC steel wire, the slope by the tensile stress of the PC steel wire It is characterized by compressing, and is a method mainly applied to rock layers.

However, when the slope of the ground formed by the excavation or excavation of the ground is composed of a soft layer and a rock layer such as a soft soil, that is, when the sidewall of the rock layer is covered with the soft layer, the conventional soil nailing method or earth anchoring method as described above is used. There is a problem that can not reinforce the slope.

In detail, when the small nailing method is applied to a slope formed of a soft layer and a rock layer, the excavation hole formed in the soft layer is easily collapsed, so that a space for reinforcing grout is not sufficiently secured. In addition, when the earth anchoring method is applied to a slope composed of a soft layer and a rock layer, as described above, the excavation hole formed in the soft layer easily collapses as well as the surface of the slope consists of a soft layer. When compressed, there is a problem that the surface is deformed or collapsed.

The present invention has been proposed to solve the above problems, the soft layer reinforcement means that can ensure a sufficient space filled with a reinforcing material such as grout in the soft layer, and the slope made of the soft layer and the rock layer more easily and firmly reinforcement The purpose is to provide a slope reinforcement method that can be done.

Soft layer reinforcing means according to the present invention for achieving the above object,

Including a body formed in a pipe shape, one end is blocked and the other end is open,

One end of the body is located inside the soft layer and the other end of the body is inserted into the soft layer so as to be exposed to the outside of the soft layer and then the inside is filled with reinforcement.

The body is formed in a shape in which the circumference becomes smaller toward one end.

It further comprises an excavation blade mounted on the outer circumferential surface of the body, it is configured to be inserted into the soft layer as the body is rotated about a longitudinal central axis.

The excavation blade,

It is formed in a plate shape having a width in the direction crossing the longitudinal direction of the body is coupled to one side of the width direction in a spiral wrap around the outer circumferential surface of the body, it is mounted two or more to have a distance in the longitudinal direction of the body.

The soft layer reinforcing means according to the present invention is inserted into the soft layer so that one end of the body passes through the soft layer and reaches the rock layer.

A steel wire whose one end is fixedly coupled to the rock layer through the inside of the body and the other end is drawn out of the body;

An earth retaining plate coupled to the other end of the steel wire to be in close contact with the other end of the body;

.

Slope reinforcement method according to the present invention,

Inserting the soft layer reinforcing means having the above structure into the soft layer;

Inserting a drill into the soft layer reinforcing means so that an end of the drill penetrates one end of the body and then enters into the rock layer, thereby forming an excavation hole in the rock layer;

After withdrawing the drill, injecting reinforcement into the excavation hole and the body;

It includes.

The step of inserting the soft layer reinforcement means into the soft layer is configured to insert the soft layer reinforcement means into the soft layer until one end of the body passes through the soft layer and contacts the rock layer.

Injecting the reinforcing material,

Located inside the excavation hole of the steel wire and withdrawing the other end of the steel wire to the outside of the body, it is configured to inject a reinforcement into the excavation hole and the inside of the body,

After the curing of the reinforcing material is completed, placing the retaining plate on the other end of the body and the other end of the steel wire to the earthing plate to keep the steel wire in the tension state, the step of contacting the earthing plate to the other end of the body ;

It further includes.

When using the soft layer reinforcement means and the slope reinforcement method using the same, it is possible to effectively support the soft layer by ensuring a sufficient space filled with reinforcement grout inside the soft layer, the slope consisting of the soft layer and the rock layer more easily and firmly The advantage is that it can be reinforced.

Hereinafter, embodiments of the soft layer reinforcing means and the slope reinforcing method according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a soft layer reinforcing means according to the present invention.

Soft layer reinforcing means according to the present invention is for drilling a soft ground material such as swamp or mud, as shown in Figure 1, one end (lower in Figure 1) is blocked and the other end (top in Figure 1) is open pipe It is configured to include a body 100 formed in a shape.

The body 100 is formed in a pipe shape so as to have an inner space in which the reinforcing material G, such as grout, may be filled (see FIGS. 2 to 6), and the one end of the body 100 is inserted into the soft layer 10 at the tip. . In this case, the body 100 is not inserted into the soft layer 10 until the other end is opened, but is inserted only to the extent that the other open end can be exposed to the outside of the soft layer 10.

As such, when the body 100 is inserted into the soft layer 10, the interior of the body 100 is maintained in an empty state in which no soil or foreign matter is introduced, and the user may have an internal space of the body 100. It can be secured to the reinforcement (G) injection space, such as grout. Thus, the effect that can be obtained by securing the reinforcing material (G) injection space in the soft layer 10 will be described in detail with reference to Figures 2 to 6 below.

At this time, when the soft layer 10 is in a very soft state such as a swamp, the body 100 may be pushed in as it is, but when the soft layer 10 has a certain degree of firmness such as soft soil, the body ( By pushing the method 100, it may be difficult to insert the body 100 into the soft layer 10.

Therefore, the soft layer reinforcing means according to the present invention, the outer peripheral surface of the body 100 so that the body 100 can be excavated into the soft layer 10 as the body 100 is rotated about the longitudinal center axis It further includes an excavation blade 110 provided in. At this time, the excavation blade 110 is formed in a plate shape having a width in the direction crossing the longitudinal direction of the body 100 is coupled so that one side of the width direction spirally wraps the outer peripheral surface of the body 100, the excavation When the blade 110 is formed over the entire outer circumferential surface of the body 100, not only is it difficult to manufacture the body 100 and the excavation blade 110, but also the re-processing of the excavation blade 110 when the excavation blade 110 is to be re-processed This has the disadvantage of being difficult. Therefore, the drilling blade 110 is preferably mounted more than two to have a separation distance in the longitudinal direction of the body 100, as shown in FIG.

At this time, the body 100 to be more easily introduced into the soft layer 10, the excavation blade 110 to dig the soft layer 10 of the two or more excavation blade 110 first (lower drilling blade in Figure 1) ) Is preferably formed to have a narrow width, the body 100 may be formed in a shape that is smaller in the circumference toward one end of the side that is first introduced into the weak layer 10, that is, a wedge shape.

In addition, the body 100 has a length as large as the thickness of the soft layer 10 so that the other end may remain exposed to the outside of the soft layer 10 even though one end reaches the rock layer 20 through the soft layer 10. Or slightly longer than the thickness of the soft layer 10.

2 to 6 are cross-sectional views sequentially showing the construction step of the slope reinforcement method according to the present invention.

When reinforcing the slope using the soft layer reinforcing means configured as described above, first, as shown in FIG. 2, the soft layer reinforcing means having the structure as mentioned above is inserted into the soft layer 10, and FIG. 3. Insert the drill 200 into the interior of the soft layer reinforcement means as shown in the excavation hole 22 in the rock layer 20. The drill 200 is excavated through the blocked end of the body 100 to the rock layer 20 by the excavation hole 22 is formed in the rock layer 20.

At this time, when the side wall of the body 100 is damaged by the drill 200 in the process of passing through the drill 200 through one end of the body 100, the earth and sand of the soft layer 10 into the interior of the body 100 Is introduced into the body 100 there is a fear that the reinforcement (G) injection space is not sufficiently secured. Therefore, the inner diameter of the body 100 is preferably formed larger than the outer diameter of the drill 200.

After the formation of the excavation hole 22 in the rock layer 20 is completed, the drill 200 is withdrawn as shown in FIG. 4, and the excavation hole 22 is formed through the inside of the body 100 as shown in FIG. 5. Injecting the reinforcing material injection pipe 300 into the interior of the excavation hole 22 to inject the reinforcing material (G) from the inner space of the body 100. When the injection of the reinforcing material (G) is completed, as shown in FIG. 6, the excavation hole 22 and the inside of the body 100 are completely filled with the reinforcing material G. When the curing of the reinforcing material G is completed, the soft layer reinforcement is completed. Means are integrally coupled with the rock layer 20 by the reinforcing material (G), the soft layer 10 is supported by the soft layer reinforcing means has the advantage that the phenomenon of flowing down or collapse is reduced.

As described above, when the slope reinforcement method of the present invention is used, a sufficient amount of reinforcing material G can be injected into the relatively hard rock layer 20 as well as the soft layer 10 that is relatively soft. 10) There is an advantage that the reinforcing effect is increased.

On the other hand, in the process of inserting the soft layer reinforcing means into the soft layer 10, if one end of the body 100 and the rock layer 20 is not in contact with each other and a gap occurs, the drill 200 is withdrawn after the formation of the excavation hole 22 When the soil layer of the soft layer 10 through the drill 200 through the hole formed in one end of the body 100 may be introduced into the interior of the body 100.

Accordingly, when the soft layer reinforcing means is inserted into the soft layer 10, the soft layer reinforcing means is inserted into the soft layer 10 until one end of the body 100 passes through the soft layer 10 and contacts the rock layer 20. Do.

7 and 8 are cross-sectional views sequentially showing the construction step of the second embodiment of the slope reinforcement method according to the present invention.

The slope reinforcement method according to the present invention does not end up injecting and curing the reinforcing material G in the body 100 and the excavation hole 22 as shown in FIGS. 2 to 6, but the conventional earth anchoring method. It may be configured to reinforce the soft layer 10 more firmly by incorporating the technology.

That is, the slope reinforcement method according to the present invention, when the reinforcing material (G) is injected into the excavation hole 22 and the body 100 after forming the excavation hole 22 as shown in Figures 2 to 4 , As shown in FIG. 7, a process of positioning the inner end of the steel wire 400 at one end of the excavation hole 22 and drawing the other end of the steel wire 400 out of the body 100 is added to the reinforcing material (G). When curing of the) is completed, as shown in FIG. 8, the earth plate 500 is positioned at the other end of the body 100, and the other end of the steel wire 400 is maintained at the other end of the steel wire 400 to maintain the tension state. Coupled to the plate 500, it may be configured to further include the step of bringing the earth plate 500 in close contact with the other end of the body (100). The other end of the steel wire 400 may be directly coupled to the earth plate 500, or may be coupled to a separate fastening means 510 that is tightly fixed to the outer surface of the earth plate 500 as in this embodiment.

In this case, when a very large tensile force is applied to the steel wire 400, that is, when the other end of the steel wire 400 is coupled to the earthen board 500 in a state in which the steel wire 400 is pulled taut, the earthing plate 500 Compressed to the other end of the body 100 by the tensile force of the silver steel wire 400, the surface of the soft layer 10 is compressed by the retaining plate 500, the reinforcement of the soft layer 10 can be made more sure. There is an advantage.

On the other hand, when using the steel wire 400 and the retaining plate 500, the reinforcement (G) may be filled throughout the excavation hole 22 and the entire body 100, as shown in Figure 8, the steel wire 400 The reinforcing material G may be injected only into a portion of the excavation hole 22 in an amount sufficient to fix one end of the steel wire 400 to the rock layer 20 so that the prestressed portion becomes longer.

As shown in FIG. 8, when the reinforcing material G is filled in the excavation hole 22 and the entire body 100, the body 100 may be more stably coupled to the rock layer 20, and the reinforcing material ( When the G) is injected only inside the excavation hole 22, the size of the prestress applied to the entire steel wire 400 is increased, and thus the retaining plate 500 may be in close contact with the body 100 with a greater force. There is this. Therefore, the injection amount of the reinforcing material (G) can be freely adjusted according to the characteristics of the ground or the type of construction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

1 is a perspective view of a soft layer reinforcing means according to the present invention.

2 to 6 are cross-sectional views sequentially showing the construction step of the slope reinforcement method according to the present invention.

7 and 8 are cross-sectional views sequentially showing the construction step of the second embodiment of the slope reinforcement method according to the present invention.

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

10: soft layer 20: rock bed

22: excavation hole 100: the body

110: excavation blade 200: drill

300: reinforcing material injection pipe 400: steel wire

500: earth plate 510: fastening means

Claims (10)

One end is blocked and the other end includes a body 100 formed in an open pipe shape, One end of the body 100 is located inside the soft layer 10 and the other end of the body 100 is inserted into the soft layer 10 so as to be exposed to the outside of the soft layer 10 is filled with a reinforcing material (G). Features, An excavation blade 110 is disposed on an outer circumferential surface of the body 100, and the excavation blade 110 is configured to be inserted into the soft layer 10 as the body 100 is rotated about a longitudinal central axis. The excavation blade 110, It is formed in a plate shape having a width in the direction crossing the longitudinal direction of the body 100 is coupled to one side in the width direction spirally wraps the outer peripheral surface of the body 100, spaced apart in the longitudinal direction of the body 100 Soft layer reinforcement means, characterized in that more than one is mounted to have a distance. The method of claim 1, The body 100 is weak layer reinforcement means, characterized in that formed in a shape that becomes smaller toward one end. delete delete The method of claim 1, Soft layer reinforcing means, characterized in that the width of the two or more excavation blade 110 is inserted first into the soft layer (10) first narrow width. The method of claim 1, Soft layer reinforcement means, characterized in that one end of the body 100 is inserted into the soft layer (10) to pass through the soft layer (10) to reach the rock layer (20). The method of claim 1, A steel wire 400 having one end fixedly coupled to the rock layer 20 through the inside of the body 100 and the other end drawn out of the body 100; An earth retaining plate 500 coupled to the other end of the steel wire 400 to be in close contact with the other end of the body 100; Soft layer reinforcement means characterized in that it further comprises. Inserting a soft layer reinforcement means having a structure according to any one of claims 1, 2, 5, and 6 into the soft layer (10); The drill 200 is inserted into the soft layer reinforcing means so that the end of the drill 200 penetrates one end of the body 100 and then is introduced into the rock layer 20, thereby excavating the rock layer 20. Forming a ball 22; After pulling out the drill 200, injecting a reinforcing material (G) in the excavation hole 22 and the inside of the body 100; The step of injecting the reinforcing material (G) is located in one of the excavation hole 22 of the steel wire 400 and withdraw the other end of the steel wire 400 to the outside of the body 100 after the excavation hole 22 It is configured to inject the reinforcing material (G) inside and the body 100, After curing of the reinforcing material (G) is completed, the earth plate 500 is located at the other end of the body 100 and the other end of the steel wire 400 to maintain the tension line 400 the earth plate ( 500), and the step of adhering the earthen board 500 to the other end of the body 100; the slope reinforcement method further comprising. 9. The method of claim 8, Inserting the soft layer reinforcing means into the soft layer 10, the soft layer reinforcing means is inserted into the soft layer 10 until one end of the body 100 is in contact with the rock layer 20 through the soft layer 10. Slope reinforcement method characterized in that the configuration. delete

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