KR100591367B1 - Slope reinforcement method and devece thereof - Google Patents

Abstract

The installation of shear stress and reinforcing steel and PC steel wire is applied to the insertion hole of the slope so that the shear and tensile force are applied simultaneously to double the supporting stress per insertion hole, which significantly reduces the number of insertion holes to be drilled. Since the shear force and the tensile force are applied at the same time, the slope reinforcement method is disclosed that can be applied to all layers, not limited to a specific ground, such as soil layer, rock layer or mixed layer mixed with soil layer and rock layer. The disclosed method includes drilling an insertion hole in a slope; Inserting an assembled reinforcement member including a deformed reinforcing bar, a PC steel wire, and an injection hose into the insertion hole; Grouting by injecting cement milk into the insertion hole through the injection hose; Installing an acupressure member at an inlet of a slope insertion hole; Tensioning the PC steel wire of the stiffener; And installing an end cap on the acupressure member.

Slope, Reinforcement, Deformed Steel Bar, PC Steel Wire, Grip

Description

Slope reinforcement method and slope reinforcement assembly used here {SLOPE REINFORCEMENT METHOD AND DEVECE THEREOF}

 1 is a process chart of the slope reinforcement method according to the invention,

 2 (a) to 2 (f) is a view for explaining the construction method of the slope reinforcement method according to the present invention,

Figure 3 is a cross-sectional view of the slope reinforcing material according to the present invention,

Figure 4 is an exploded perspective view of the chain body of the slope reinforcing material according to the present invention.

5 is a cross-sectional view taken along the line A-A of FIG.

* Description of the symbols for the main parts of the drawings *

10: deformed steel 20: PC steel wire

30: injection hose 40: pressure plate

50: anchorage 55: end cap

60: head 70: crimping grip

80: fixed plate 85: cover

90: fluid hose 53: chain gas

The present invention relates to a slope reinforcement method and a sloped reinforcement used therein, and more specifically, to install a shear stress and tensile force by simultaneously applying a shear stress material and a reinforcing steel as a shear stress material in the insertion hole of the slope to insert the shear force and the tensile force simultaneously. By doubling the supporting stress per hole, the number of insertion holes to be drilled can be drastically reduced and construction cost can be drastically reduced. Shear and tensile forces are applied at the same time, so it is limited to specific ground such as soil layer, rock layer or mixed layer mixed with soil layer and rock layer. The present invention relates to a slope reinforcement method applicable to all strata and to a slope reinforcement assembly used therein.

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 grouting cement milk after inserting a deformed reinforcing bar which is a shear stress material into an insertion hole drilled relatively tightly on a slope. It is characterized by the absence and is mainly applied to the soil layer. In addition, the earth anchoring method is a method of reinforcing the slope by tensioning the PC steel wire after inserting the PC steel wire which is a tensile stress material into the insertion hole drilled on the slope and grouting cement milk, 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.

Here, the present invention is an improved method of the soil nailing method, and in particular, the advantage of the earth anchoring method is selectively introduced into the soil nailing method. That is, in the conventional soil nailing method, since only the deformed steel is inserted as a reinforcing material into the insertion hole of the slope, the supporting stress of the reinforcing material per unit insertion hole is insufficient, and therefore, a plurality of insertion holes must be drilled tightly. There was a problem that the construction cost is greatly increased.

In addition, since the conventional soil nailing method uses only the deformed rebar as a shear stress material, the shear stress on the slope could be reinforced, but the tensile stress could not be reinforced, so it was not applied to a rock layer having a relatively large stress. . In particular, the ground layer, the rock layer, or the mixed layer in which the soil layer and the rock layer are mixed is complex and variously mixed, and considering the lighting that the soil layer investigation is not perfect, the conventional shear stress and tensile stress can not exhibit both at the same time When the soil nailing method is applied to a rock layer or a mixed layer, there is a problem in that it is impossible to maximize the deterrent force of slope activity.

Nevertheless, the increasing number of cases of rock nailing, in which the relatively easy-to-install soil nailing method is applied to the rock layer, has increased the stress (especially tensile stress) in the soil nailing method. It demands more to reinforce. Thus, in the Republic of Korea Patent Publication No. 2000-21523 as an example of the prior art, in the reinforcement reinforced slope stabilization method for foundation excavation of slopes and buildings, the general deformed reinforcement is inserted horizontally or vertically into the ground to introduce tensile stress into the ground Although one technique is disclosed, the technique has no record of being applied and constructed because it cannot exert more than expected effects because the prestress is applied to a deformed rebar having extremely low elongation and repulsive force.

The present invention has been made to solve the above problems, an object of the present invention is to install a reinforcing material per unit insertion hole by using a combination of PC steel wire used as a tensile stress material in the earth anchor method as well as a deformed reinforcement in the insertion hole of the slope It is to provide a slope reinforcement method and a slope reinforcement assembly used therein that can be inexpensively constructed by reducing the number of insertion holes to be drilled by less than half by greatly increasing the support stress.

Another object of the present invention is to install not only the deformed reinforcing bar but also PC steel wire as a reinforcing material in the insertion hole of the slope, and to apply the tensile stress to the PC steel wire to reinforce the shear stress with the deformed steel bar and the tensile stress for the tensioned PC steel wire By reinforcing to provide a slope reinforcement method and slope reinforcement assembly that can be applied to all strata, including soil layer, rock layer and mixed layer mixed soil and rock layer.

The object of the present invention is the step of drilling the insertion hole in the slope; Inserting an assembled reinforcement member including a deformed reinforcing bar, a PC steel wire, and an injection hose into the insertion hole; Grouting by injecting cement milk into the insertion hole through the injection hose; Installing an acupressure member at an inlet of a slope insertion hole; It can be achieved by providing a slope reinforcement method characterized in that it comprises a step of applying a stress to the PC steel wire of the reinforcement, and covering the end cap on the acupressure member.

In addition, the object is one end is installed to penetrate through the pressure member, the other end is a deformed reinforcing bar is installed to flow in the fixed member; A PC steel wire spaced apart from the deformed reinforcement by a spacer and covered by a flow hose, one end of which is tensionably installed on the pressure member, and the other end of which is fixed to the fixing member; It can be achieved by providing a slope reinforcement assembly characterized in that it comprises an injection hose provided with a predetermined length so as to inject the cement milk into the insertion hole.

The object of the present invention described above will become more apparent from the preferred embodiment of the present invention described below with reference to the accompanying drawings.

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

1 is a process diagram of the slope reinforcement method according to the present invention, Figure 2 (a) to Figure 2 (f) is a view for explaining the construction method of the slope reinforcement method according to the present invention, specifically Figure 2 (a) 2 is a view in which the insertion hole is perforated on the slope, and FIG. 2 (b) is a view in which a reinforcement assembly including a reinforcing bar, a PC steel wire, and an injection hose is inserted in the insertion hole, and FIG. Fig. 2 (d) is a diagram in which a shiatsu member is installed at a slope insertion hole inlet, Fig. 2 (e) is a diagram in which PC steel wire is tensioned, and Fig. 2 (f) is an end cap on the shiatsu member. This is an installed drawing.

According to the present invention, first, the insertion hole H for inserting the reinforcing material with respect to the cutting slope to be reinforced is drilled a predetermined depth as shown in FIG. Here, as will be described above, according to the present invention, the number of the insertion holes is significantly reduced to at least half or less than the number of the insertion holes according to the conventional small nailing method, and thus the construction cost can be significantly reduced, which is according to the present invention. This is because the reinforcement consists only of deformed reinforcing bars to reinforce the shear stress, and the PC steel wire is also used to reinforce the tensile stress at the same time.

The perforated insertion hole (H) is inserted into the reinforcing material assembled with a deformed rebar, PC steel wire and injection hose.

The reinforcing material is shown in detail in FIG. 3, referring to this, the reinforcing material is provided with a reinforcing bar 10 installed at one end to penetrate the acupressure member and the other end to be movable to the fixing member; A PC steel wire 20 spaced apart from the deformed rebar by a spacer and covered by a flow hose, one end of which is tensionably installed on the acupressure member, and the other end of which is fixed to the fixing member; It is configured to include an injection hose 30 is provided a predetermined length so as to inject the cement milk into the insertion hole.

More specifically, the acupressure member includes a pressure plate 40, the fixing unit 50 and the end cap 55.

The acupressure plate 40 is a member that is in close contact with the slope to provide a reaction force against the tensile force when tensioning the PC steel wire 20, the first deformed reinforcing bar through which the deformed reinforcing bar 10 is installed in the center is formed In addition, the first PC steel wire through-hole 42 through which the PC steel wire 20 is installed adjacent to the first deformed rebar through-hole 41 is formed. In addition, the injection hose insertion hole 43 for inserting the injection hose 30 for injecting the cement milk is formed at a predetermined position of the pressure plate 40. Here, the number of through-holes of the first PC steel wire is naturally formed equal to the number of PC reinforcing bars installed mixed with the deformed rebar.

As shown in the drawing, the fixing unit 50 is installed in close contact with the outer surface of the pressure plate 40 and prevents the tensioned PC steel wire 20 from being restored. There is formed a second deformed rebar through hole 51 through which the deformed rebar 10 penetrated through the first deformed rebar through hole 41, and adjacent to the second deformed rebar through hole 51, the first PC steel wire A second PC steel wire through hole 52 through which the PC steel wire 20 penetrated through the through hole 42 is formed.

Here, the second PC steel wire through-hole 52 is inserted with a tapered chain body 53 is a combination of a plurality of chain pieces (53-1) as shown in Figure 4, accordingly, the second PC steel wire through hole 52 is also formed to be tapered. Accordingly, when the PC steel wire 20 is pulled by a separate oil pressure (the other end is grouted and fixed), the PC steel wire 20 is reduced in diameter while being tensioned, and accordingly, the tapered chain body 53 is also tapered to the second PC. When drawn into the steel wire through-hole 53, the chain body 53 continuously presses the PC steel wire 20 by tightening the elastic ring 53-2 so that the PC steel wire can be kept in a tensioned state.

Then, when the PC steel wire 20 is tensioned, the end cap 55 is coupled to the pressure plate 40 as a finishing material.

On the other hand, the fixing member includes a head 60, the pressing grip 70, the fixing plate 80 and the cover 85, the head 60 has a groove 61 is formed in the center as shown have. The groove 61 is configured to allow the deformed reinforcing bar 10 to flow so that the tensile force applied to the PC steel wire 20 does not interfere with the deformed reinforcing bar 10, and if both ends of the deformed reinforcing bar 10 are fixed In this case, when a tensile force is applied to the PC steel wire 20, the deformed reinforcing bar 10 is to prevent a bending phenomenon by applying a relatively compressive force. In addition, an insertion hole 62 into which the PC steel wire 20 is inserted is formed adjacent to the recess 61. As shown in FIG. 5, an injection of cement milk into the head may be injected into the head. The hole 63 is formed.

In addition, the crimping grip 70 is crimped on the outer circumference of the PC steel wire 20 protruding through the insertion hole 62 to firmly grip the PC steel wire 20, and the head on the crimping grip 70. 60 and the fixing plate 80 is coupled to the bolt (B) is coupled. Therefore, since the crimping grip 70 is firmly gripped at the outer circumference of the PC steel wire, and the crimping grip 70 is fixed between the head 60 and the fixing plate 80 by the bolt B, the PC The steel wire is kept firmly fixed by the fixing member. In addition, the head 60 is coupled to the cover 85 to protect the assembly when inserted into the insertion hole.

On the other hand, the outer circumference of the PC steel wire 20 is covered with a flow hose 90, which is when the PC steel wire 20 is the flow hose 90 when the cement milk is grouted to tension the PC steel wire 20 This is to allow tension within the flow. In addition, a predetermined length of the injection hose 30 for injecting the cement milk into the insertion hole is provided, the injection hose 30, the deformed reinforcing bar 10 and the PC steel wire 20 by the spacer (G). Maintain proper spacing. Here, the free field means a portion where the tension of the PC steel wire is allowed, and in the opposite concept, the fixing field means the end of the insertion hole as a portion that does not allow the tension of the PC steel wire. Therefore, when the PC steel wire is tensioned, the PC steel wire of the free field portion is tensioned from the anchorage point.

The reinforcing bar 10, the PC steel wire 20, and the injection hose 30 fixed at regular intervals by the spacer G of the slope reinforcement configured as described above are first inserted into the hole H as shown in FIG. After insertion, as shown in FIG. 2 (c), the cement milk is injected into the insertion hole through the injection hose 30 to grout.

Thereafter, as shown in FIG. 2 (d), the acupressure member is installed at the inlet of the insertion hole H to assemble the deformed reinforcing bar 10, the PC steel wire 20, and the injection hose 30. More specifically, as described above, the deformed rebar 10 is inserted into the first deformed rebar through hole 41 of the shiatsu plate 40 and then sequentially inserted into the second deformed rebar through hole 51 of the anchorage 50. The PC steel wire 20 is inserted into the first PC steel wire through hole 42 of the pressure plate 40, and then the second deformed steel reinforcing hole 52 of the anchorage 50 into which a plurality of chain pieces 53 are inserted. Are inserted sequentially). In addition, the injection hose 30 is inserted into the injection hose insertion hole 43 of the pressure plate.

As such, when the acupressure member is installed at the inlet of the insertion hole, the PC steel wire 20 is tensioned through a separate oil press. Then, the PC steel wire is fixed in the tensioned state by the pressure of the chain body 53 after being stretched by a predetermined length after being flowed in the flow hose in the free field to the point of the grouted anchorage, thereby compressing the slope relatively.

Thereafter, the end plate 55 is coupled to the acupressure plate 40 to complete the construction according to the slope reinforcement method according to the present invention.

According to the present invention, since the insertion hole of the cut slope in which the shear stress material and the reinforcing steel material of the PC steel wire are used in combination with the tensile stress material is applied simultaneously with the shear force and the tensile force, the supporting stress per insertion hole can be doubled. Compared to the small nailing method, the number of insertion holes can be reduced to less than a cut, so the construction cost can be significantly reduced. In addition, since the shear force and the coercive force are applied at the same time, it can be applied to all strata regardless of the soil layer, rock layer or mixed layer mixed with the soil layer and the rock layer.

As described above, the slope reinforcement method and the slope reinforcement assembly used in the present invention are inserted into the insertion hole of the slope by using a combination of the heterogeneous reinforcing steel and the PC steel wire of the tensile stress material to insert the shear and tensile force at the same time By multiplying the supporting stress per hole, the number of insertion holes to be drilled can be significantly reduced, and construction cost can be drastically reduced. Shear and tensile forces are applied at the same time, so it is not limited to specific ground such as soil, rock, or soil. It can be effective.

Claims (4)

Drilling an insertion hole in a slope; Inserting a slope reinforcing assembly including a deformed reinforcing bar, a PC steel wire, and an injection hose into the insertion hole into the insertion hole; Grouting by injecting cement milk into the insertion hole through the injection hose; Installing an acupressure member at an inlet of a slope insertion hole; Tensioning the PC steel wire of the stiffener; And installing an end cap on the acupressure member, The deformed rebar is installed so that one end thereof penetrates the acupressure member, and the other end is installed to be movable to the fixing member, and the PC steel wire is spaced apart from the deformed rebar by a spacer and covered by a flow hose, and one end of the acupressure member It is installed in a tensionable manner, the other end is fixed to the fixing member, the injection hose is a slope reinforcement method characterized in that it is installed to inject the cement milk into the insertion hole. A deformed rebar, one end of which is installed to penetrate the acupressure member and the other end of which is movable to the fixing member; A PC steel wire spaced apart from the deformed reinforcement by a spacer and covered by a flow hose, one end of which is tensionably installed on the pressure member, and the other end of which is fixed to the fixing member; Slope reinforcement assembly comprising a injection hose provided with a predetermined length so as to inject the cement milk into the insertion hole. According to claim 2, wherein the acupressure member is In the center is formed a first release reinforcing bar through which the reinforcing bar is installed, the first PC steel through hole is installed through the PC steel wire adjacent to the first deformed reinforcing hole, the injection hose is inserted into a predetermined position An acupressure plate having an injection hose insertion hole formed therein; A second deformed rebar through hole is formed in the center through which the deformed rebar passes, and a tapered second PC steel wire through hole through which the PC steel wire is installed adjacent to the deformed rebar through hole is formed, and a plurality of wedges are provided in the second PC steel through hole. A fixing unit in which a tapered chain body in which a piece is combined is inserted; And Slope reinforcement assembly characterized in that it comprises an end cap coupled to cover the pressure plate. The method of claim 2, wherein the fixing member In the center is formed a groove through which the deformed steel can flow so that the deformed steel is not interfered by the tensile force applied to the PC steel wire, the insertion hole is formed to be inserted into the PC steel wire adjacent to the groove, the injection hole formed head; A compression grip compressed on an outer circumference of the PC steel wire inserted through the insertion hole; A fixing plate bolted to the head to fix the PC steel wire in which the crimping grip is crimped to the outer circumference; And Slope reinforcement assembly, characterized in that it comprises a cover coupled to the head.

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