KR100992999B1 - Slope-reinforcement anchor for inducing soil nailing reinforcement effect and methode there of - Google Patents

Abstract

The present invention is a reinforced concrete column in which the steel wire of the free field connected to the anchor anchor is integrally formed with concrete, so that the soil nailing function can be simultaneously obtained at the same time because the soil strength is maintained by increasing the soil strength. It relates to a permanent anchor for slope reinforcement to obtain a nailing reinforcement effect and a construction method thereof.

According to the present invention, the permanent anchor for slope reinforcement to obtain the soil nailing reinforcement effect and the construction method, the packer is expanded by the air injected in the state in which the cage is installed into the drilling hole while the one end of the steel wire is wrapped in a hose and drilled After being in close contact with the hole, the anchoring agent of the reinforced concrete column formed by injecting concrete into the anchorage does not damage the tensile stress, and the concrete is placed on the steel wire of the free field, which is separated by a packer and is not wrapped with a hose, so that the tensile strength of the steel wire There is no reduction, so there is no need to re-tension, and the compression of the anchor and the hardened reinforced concrete column can not only improve the ground strength, but also achieve the effect of the soil nailing method while constructing the anchor.

Description

Slope-reinforcement anchor for inducing soil nailing reinforcement effect and methode there of}

The present invention relates to anchors for reinforcing slopes or slopes, and more specifically, reinforced concrete columns formed by injecting concrete into cages of anchor anchorages and reinforced concrete columns formed by injecting concrete into steel wires of free-fields. The present invention relates to a permanent anchor for slope reinforcement, and a construction method thereof, which obtains a soil nailing reinforcement effect so that the anchor function and the soil nailing function can be simultaneously obtained.

In general, as the industry develops, slope reinforcement methods are implemented to suppress slope collapse and sliding of mountainous areas occurring in road construction or complex construction, and this slope reinforcement method is used to reduce activity, increase resistance, It is divided into various kinds of surface protection method, and the like, and the representative of the resistance augmentation method is a rock bolt, anchor, soil nailing, step retaining wall.

In the slope reinforcement method, the anchor is used as a reinforcement to prevent floating of structures such as buildings and bridges as well as ground reinforcement. Specifically, anchor anchors are formed at the tip of the tension member embedded in the ground by cement paste or concrete injection. The anchor is a state in which the tension member and the structure are dynamically connected at the anchor head, and the force applied to the tension member is based on the principle of transmission to the ground through the anchor fixture and the anchor head structure.

These anchors are divided into anchorages and freefields, and the anchorages serve as support structures.

However, in the conventional anchor, the anchoring force is determined according to the anchorage embedded in the ground, but since the free field is formed as a space, there is a problem that the rigidity is not maintained while the anchoring force is decreased due to the reduction of the tensile force of the tension member.

In addition, since the mechanism for anchor anchoring is located at the center of the shaft of the anchorage and does not resist tensile stress, there is a problem that the anchorage is damaged.

In view of the above-mentioned conventional defects, the object of the present invention is to wrap the one end of the steel wire with a hose, the fixing agent of the reinforced concrete column formed by the concrete is poured into the anchorage is installed cage, the end of the anchorage In addition, the present invention provides a permanent anchor for slope reinforcement, and a construction method thereof, which achieves a nail nailing reinforcement effect to withstand tensile stresses from acupressure plate.

In addition, another object of the present invention, the reinforced concrete column formed by pouring concrete to the steel wire of the free field not wrapped with a hose to maintain the rigidity of the structure, the reinforced concrete column can not only increase the ground strength, but also anchor construction At the same time, the present invention provides a permanent anchor for slope reinforcement, and a construction method for reinforcing soil nailing, in which the effect of the soil nailing method can be obtained.

The permanent anchor for slope reinforcement of the present invention is an anchor for slope reinforcement,

A plurality of rods having a thread formed on both ends is provided, the pressure plate is coupled to the both ends of the rod is provided, the cage is provided with a packer guide plate coupled to the steel wire to support the packer to be located on the other end of the pressure plate Anchorages;

A free field connecting the anchorage with a steel wire;

Each packer in close contact with a perforation hole to separate the anchorage field and the free field and the free field and the ground;

The steel wire coupled to the anchorage is wrapped with a hose, the steel wire of the free field is characterized in that the reinforced concrete pillars are formed by concrete that is poured in sequence in the state not wrapped with a hose.

In addition, the present invention, the permanent anchor construction method for slope reinforcement, the permanent anchor construction method for slope reinforcement, the one end of the steel wire combined with the cage is formed with a hose to form a anchorage, the anchor for connecting the free field to the other end of the steel wire Forming a;

Injecting the anchor into a drilling hole formed in the ground;

Injecting air into the packer separating the anchorage field and the free field to closely contact the inner surface of the hole;

Injecting concrete into the anchorage separated by the packer so that the concrete is filled from the lower portion to the upper portion so that the anchoring body of the reinforced concrete column is formed;

Removing air injected into the packer separating the fixing field and the free field, injecting air into the packer separating the free field and the ground, and contacting the inner surface of the hole;

It is characterized in that it comprises a step of curing the reinforced concrete column by injecting the concrete to be filled from the bottom to the top in the free field separated by the packer.

According to the present invention, the permanent anchor for slope reinforcement to obtain the soil nailing reinforcement effect and the construction method, the packer is expanded by the air injected in the state in which the cage is installed into the drilling hole while the one end of the steel wire is wrapped in a hose and drilled After being in close contact with the hole, the fixing agent in the reinforced concrete lifter, which is formed by pouring concrete into the anchorage, can withstand the tensile stress that does not fall out of the ground, thereby having the advantage of exhibiting stable tensile force.

In addition, according to the present invention the permanent anchor for slope reinforcement and the construction method to obtain the soil nailing reinforcement effect, since the concrete is placed on the steel wire of the free field that is separated by the packer and is not wrapped with a hose, there is no need to re-tension because there is no decrease in tensile force of the steel wire In addition, the compression of the anchor and the reinforced concrete pillars will not only increase the ground strength, but also have the advantage of achieving the effect of the soil nailing method while constructing the anchor.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is an exploded perspective view of the present invention, Figure 2 is a combined state diagram of the present invention.

In the present invention, the permanent anchor for slope reinforcement is provided with a plurality of rods 111a having threads formed at both ends as anchors for slope reinforcement, and are provided with acupressure plates 112 and 112a fixed to both ends of the rods 111a. And a fixing unit having a cage 111 coupled to the steel wire 121 so as to be positioned at the other end of the pressure plate 112 'and including a packer guide plate 114 supporting the packer 130. 110 is configured, the free field 120 is connected to the anchorage 110 and the steel wire 121, the anchorage 110 and the free field 120 and the free field 120 and the ground Each packer 130 and 130 ′ in close contact with the drilling hole 10 are configured to separate the wires, and the steel wire 121 coupled to the fixing unit 110 is wrapped with a hose 111 ′, and the free field Steel wire 121 of 120 is formed so that reinforced concrete pillars are formed by concrete that is poured in sequence in the state not wrapped with a hose (111 ') This will be described in more detail as follows.

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The cage 111 is further provided with a cap 113 that is in close contact to receive and protect the steel wire 121 coupled to the pressure plate 112 is fixed to one end of the rod (111a).

The pressure plate (112, 112 '), the first coupling hole (112a) radially penetrates the edge so that the rod (111a) is coupled, the second coupling hole radially therein so that the steel wire 121 is coupled 112b is penetrated.

The packer guide plate 114 includes a hook 114b protruding to fix the packer 130 on one side while the steel wire coupling hole 114a penetrates radially therein so that the steel wire 121 is coupled thereto. Is formed.

The packer guide plate 114 further includes an inlet hole 114c and an outlet hole 114d penetrated to couple the concrete injection hose H1 and the discharge hose H2.

It is further provided with a fixing tie 115 for tying and fixing a plurality of rods (111a) respectively coupled to the first coupling hole (112a) radially penetrated to the pressure plate (112, 112 ').

In addition, the free field 120 is provided with a plurality of steel wires 121, one end of which is fixed to the fixing field 110, the coupling hole 122a is formed to receive and couple the plurality of steel wires 121 A ground pressure plate 122 is provided, and at least one spacer 123 for accommodating the steel wire 121 and not flowing therein is provided, and the steel wire 121 is coupled to support the packer 130 '. It is provided including a guide plate 124.

The spacer 123 preferably has a coupling groove 123a formed radially on an outer circumferential surface of the spacer 123 so as to receive and couple the steel wire 121.

It is preferable to further include a tie rod 125 for fixing the steel wire 121 coupled to the coupling groove 123a of the spacer 123.

The packer guide plate 124 includes a hook 124b protruding to fix the packer 130 'on one side while the steel wire coupling hole 124a penetrates radially therein so that the steel wire 121 is coupled thereto. Is formed.

The packer guide plate 124 further includes an inlet hole 124c and an outlet hole 124d that are penetrated to couple the concrete injection hose H1 and the discharge hose H2.

The following describes the manufacturing and construction process of the present invention configured as described above.

First, the end of the steel wire 121 connecting the anchorage field 110 and the free field 120 of the anchor 100, that is, the steel wire 121 located in the anchorage field 110, the hose of the cage 111 ( 111 ') is coupled to wrap, and the pressure plate 112 and 112' are coupled to the steel wire 121 to which the hose 111 'is coupled to face the second coupling hole 112b.

General fixing of the steel wire 121 is coupled to the second coupling hole (112b) of the pressure plate (112, 112 ') is preferably fixed using a wedge-shaped steel.

Further, in the state in which the nut N is fastened to the thread 111a of the cage 111, the ends of the plurality of rods 111a to which the nut N is fastened radially to the pressure plate 112 and 112 ′. After coupling to each protruded through the first coupling hole (112a), and fastened by fixing with a nut (N).

At this time, the cap 113 is coupled to the rod body 111a. The cap 113 is in close contact with the pressure plate 112 through the rod body 111a while accommodating an end portion of the steel wire 121 fixed by the wedge-shaped steel. And, the cap 113 in close contact with the pressure plate 112 is fixed by a nut (N) fastened to the thread of the rod (111a).

Here, the plurality of rods 111a respectively coupled to the first coupling holes 112a radially penetrated to the pressure plate 112 and 112 'may be bundled with the fixing tie 115 to prevent movement.

The packer guide plate 114 to which the packer 130 is coupled to the upper portion of the pressure plate 112 'is coupled, the steel wire 121 is coupled to the steel wire coupling hole 114a of the packer guide plate 114, the steel wire The coupling hole 114a is provided with a packing material to seal the space between the steel wire coupling hole 114a and the steel wire 121 to complete the assembly of the anchorage 110 while preventing the leaking concrete from leaking out.

In addition, the steel wire 121 of the free field 120 coupled to the fixing field 110 is coupled through at least one or more spacers 123 in a state in which the steel wire 121 of the free field 120 is not wrapped with the hose 111 ', which is a wire of the free field ( Since the concrete is directly poured into the curing 121 to obtain a nailing effect, the steel wire 121 is coupled to the coupling groove 123a formed radially in the spacer 123, the coupling groove 123a The combined steel wire 121 is fixed to the spacer 123 through the tie rod 125, the steel wire coupling hole 124a of the packer guide plate 124 is coupled to the end of the steel wire 121.

The steel wire coupling hole 124a is provided with a packing material to seal the space between the steel wire coupling hole 124a and the steel wire 121 to prevent the concrete from leaking out, and the hook 124b of the packer guide plate 124. Since the packer 130 'is coupled to the anchor 100 is completed as the assembly of the free field 120 is completed.

Installation process of the present invention completed in the above process, as shown in Figure 3, to couple the anchor 100 to the drilled hole 10 in the ground, the anchorage 110 of the anchor 100 After being inserted into the drilling hole 10 first, the free field 120 is coupled.

At this time, the concrete injection hose (H1) is coupled to the inlet holes (114c, 124c) penetrated through the packer guide plates 114 and 124 of the fixing station 110 and the free field 120, the packer guide plate Outlet holes 114d and 124d penetrated through the 114 and 124 outlet hoses H2 should be coupled.

When the anchor 100 is coupled to the drilling hole 10, as shown in Figures 4 to 6, injects air into the packer 130 through a separate air inlet (not shown), to the injected air The packer 130 is expanded and coupled to the packer guide plates 114, 124, inlet holes 114c, 124c of the anchorage field 110 and the free field 120 while being in close contact with the inner circumferential surface of the drilling hole 10. The concrete is injected into the fixing station 110 through the concrete injection hose (H1).

Concrete injected into the anchorage 110 is filled in the cage 111 and the drilling hole 10 located in the anchorage 110, the concrete filled in the drilling hole 10 and the cage 111 is a hose ( 111 ') is filled to accommodate the end of the wrapped steel wire 121 and the cage 111 while being in close contact with the packer guide plate 114 and at the same time as the discharge hose (H2) coupled to the outlet hole (114d) When the air and the filling is located in the concrete is discharged, the end of the injection hose (H1) and the discharge hose (H2) in the suspended state of the concrete is moved to the free field 120 to cure.

Here, the cage 111 of the anchorage 110 and the steel wire 121 located in the anchorage 110 become a frame of concrete filled in the anchorage 110.

When the concrete filled in the fixing station 110 is cured, as shown in Figure 7 to 10, in the air injected into the packer 130 in a separate air inlet (not shown) in the state to extract the air Air is injected into the packer 130 '.

The packer 130 ′ is inflated by the injected air and injected concrete through the injection hose H1 located in the free field 120 while being in close contact with the inner circumferential surface of the drilling hole 10 to the free field 120. Fill.

The concrete filled in the free field 120 is a steel wire 121 that is not wrapped around the hose 111 'and a spacer 123 fixed to the tie rod 125 while the steel wire 121 is coupled to the coupling groove 123a. ) Is filled to accommodate the packer guide plate 124 and at the same time as the discharge hose (H2) coupled to the outlet hole (124d) is discharged air and the concrete is completed in the free field 120 is discharged, the steel wire ( 121) and the spacer 123 is to be a frame of the concrete of the free field 120, the injection hose (H1) and the discharge hose (H2) outside the free field 120 in the state of stopping the injection of the concrete Move to and cure.

When the concrete injected into the free field 120 is cured, after removing the air of the packer 130 ', the ground pressure plate 122 while coupling the steel wire 121 of the free field 120 to the coupling hole (122a) ) In the state in close contact with the perforation hole 10, the ground pressure plate 122 and the steel wire 121 may be fixed by a separate fixture.

The ground strength is applied by applying a tensile force to the fixing agent through the ground pressure plate 122, which is the anchor head, for anchoring the anchor 100 to the ground by the fixing body, that is, the concrete pillar formed by the above process. While increasing, the concrete pillars cured in the free field 120 will be able to support.

As described above, the present invention, although described by the limited embodiments and drawings, terms or words used in the present specification and claims are not limited to the ordinary or dictionary meanings and should not be interpreted, the technical spirit of the present invention It must be interpreted to mean meanings and concepts. Therefore, the configuration shown in the embodiments and drawings described herein are only one embodiment of the present invention, and do not represent all of the technical spirit of the present invention, various changes within the scope of the claims of the present invention It should be understood that there may be equivalents and variations.

1 is an exploded perspective view of the present invention

2 is a combined state of the present invention

3 is a state diagram for coupling the present invention to the drilling hole

4 to 6 is a state diagram of filling the concrete in the anchorage of the present invention

7 to 10 is a state diagram in which the concrete is injected into the free field of the present invention

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

100: anchor 110: anchorage

111: cage 112,112 ': pressure plate

113: Cap 114: Packer Guide

115: fixed tie 120: free field

121: steel wire 122: ground pressure plate

123: Spaser 124: Packer Guide Edition

130,130 ': Packer

Claims (11)

As an anchor for slope reinforcement, A plurality of rods having a thread formed on both ends is provided, the pressure plate is coupled to the both ends of the rod is provided, the cage is provided with a packer guide plate coupled to the steel wire to support the packer to be located on the other end of the pressure plate Anchorages; A free field connecting the anchorage with a steel wire; Each packer in close contact with a perforation hole to separate the anchorage field and the free field and the free field and the ground; The steel wire of the anchorage is wrapped with a hose, the steel wire of the free field is reinforced for slope reinforcement to obtain the reinforcement of the soil nailing, characterized in that the reinforced concrete pillars are formed by concrete, each of which is poured in sequence in a state not wrapped with a hose Permanent anchor. delete The method according to claim 1, Permanent reinforcement for slopes to obtain a soil nailing reinforcement effect, characterized in that it further comprises a cap in close contact to receive and protect the steel wire coupled to the pressure plate fixed to one end of the rod. The method according to claim 1, The acupressure plate, the first coupling hole radially penetrates the edge so that the rod body is coupled, the second coupling hole radially penetrates inside so that the steel wire is coupled Permanent reinforcement for slope reinforcement to obtain the nailing reinforcement effect anchor. The method according to claim 4, Permanent anchor for slope reinforcement to obtain a nail nail reinforcing effect, characterized in that it further comprises a fixing tie for tying and fixing a plurality of rods respectively coupled to the first coupling hole radially penetrated to the pressure plate. The method according to claim 1, wherein the free field, A plurality of steel wires having one end fixed to the anchorage; A ground pressure plate having a coupling hole formed to receive and couple the plurality of steel wires; At least one spacer for accommodating the steel wire so as not to flow; Permanent anchor for slope reinforcement to obtain the nailing reinforcement effect, characterized in that the steel wire is coupled to include a packer guide plate for supporting the packer. The method according to claim 6, The spacer is a permanent anchor for slope reinforcement to obtain a soil nailing reinforcing effect, characterized in that the coupling groove is formed radially on the outer circumferential surface so as to receive and combine the steel wire. The method according to claim 6 or 7, Permanent anchor for slope reinforcement to obtain a nail nail reinforcement effect, characterized in that it further comprises a tie rod for fixing the steel wire coupled to the coupling groove of the spacer. The method according to claim 1 or 6, The packer guide plate is a slope reinforcement for obtaining a nail nail reinforcement effect, characterized in that it comprises a hook protruding to fix the packer on one side while the steel wire coupling hole penetrates radially therein so that the steel wire is coupled. Permanent anchor. The method according to claim 9, Permanent reinforcing permanent anchor to obtain a nail nail reinforcement effect, characterized in that the packer guide plate further comprises an inlet hole and an outlet hole through which the concrete injection hose and the discharge hose is coupled. As a permanent anchor construction method for slope reinforcement, Wrapping the one end of the steel wire joined by a cage to form a anchorage, and forming an anchor connecting the free field to the other end of the steel wire; Injecting the anchor into a drilling hole formed in the ground; Injecting air into the packer separating the anchorage field and the free field to closely contact the inner surface of the hole; Injecting concrete into the anchorage separated by the packer so that the concrete is filled from the lower portion to the upper portion so that the anchoring body of the reinforced concrete column is formed; Removing air injected into the packer separating the fixing field and the free field, injecting air into the packer separating the free field and the ground, and contacting the inner surface of the hole; The permanent anchor construction method for slope reinforcement to obtain a soil nailing reinforcement effect comprising the step of injecting the concrete to fill the free field separated by the packer from the bottom to the top to cure the reinforced concrete column.

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