KR20070022995A - Composition anchor one thing practicable tension and compression - Google Patents

Abstract

The present invention connects high-strength steel to fix a structure of civil engineering or construction on the ground and uses it as an effective method to apply the restraint force and transverse load in the transverse or vertical direction to the structure with high tensile strength of the steel. It is a composite anchor that can be simultaneously tensioned and compressed, developed for the purpose of receiving at the same time,

In the present invention, the tension anchor is formed at the bottom and the compression anchor is formed at the top to combine the central portion of the tension anchor and the compression anchor integrally with a protective tube to constitute a single anchor characterized in that the composite anchor.

Tension Anchor Compression Anchor Combination Anchor Anchor Head Cap Grout Injection Borehole Guide Pipe Grout Supply Hoses Grout Injection Hole Spacer Metal Tightening Band Split Support Split Hole Female Thread Stepped Male Thread Wedge Steel Pipe Female Thread Hole Corrugated Pipe Space Protection Tube

Description

Composition anchor one thing practicable tension and compression

1 is a partial cross-sectional perspective view of the present invention

Figure 2 is a partial cutaway perspective view of the present invention

Figure 3 is a perspective view of a state in which the compression portion as an external reinforcement spring in the present invention

Figure 4 is a cross-sectional view of a state in which the compression portion as an external reinforcement spring in the present invention

Figure 5 is a perspective view of a state in which the compressed portion of the steel pipe in the present invention

Figure 6 is a cross-sectional view of a state in which the compressed portion of the steel pipe in the present invention

Figure 7 is a perspective view of a state in which the compressed portion combined with the steel pipe and the external reinforcement spring in the present invention

8 is a cross-sectional view of a state in which the compressed portion is combined with the steel pipe and the external reinforcement spring in the present invention

Explanation of Signs of Major Parts of Drawings

A: Tension Anchor B: Compression Anchor

C: compound anchor

1: anchor head cap 10: grout injection hole

11: passage 12: guide

30: grout supply hose 31: grout injection hole

40: spacer 41: metal tightening band

50: split support 51, 51a: split hole

52, 52a: female thread 53: stepped

54, 61, 61a: male 60, 60a: wedge

70: steel pipe 71: internal thread

72: hole 80: corrugated pipe

81: space part 85: sheath

86: resin layer 90: external reinforcement spring

The present invention connects high-strength steel to fix a structure of civil engineering or construction on the ground and uses it as an effective method to apply the restraint force and transverse load in the transverse or vertical direction to the structure with high tensile strength of the steel. It is a composite anchor capable of simultaneously tensioning and compressing developed for the purpose of receiving at the same time.

The use of anchors to minimize the harmful deformation of the ground by introducing prestress to the ground where shear failure is concerned has recently increased the number of construction cases that have been adopted at the construction site.

Ground anchors are classified as rock anchors and soil anchors according to the type of the ground to be installed, and tieback or tiedown depending on the direction in which they are installed. Are classified as).

These anchors are classified into low pressure anchors and high pressure anchors according to the grout pressure to be injected.

In addition, tension anchors or compression anchors are classified according to the way in which the anchor grout sieve is applied. Conventional tension anchors are mainly used in tension anchors. There is a drawback that is not proportional to the length, but it is considerably reduced, and the grout sieve is drawn or destroyed when sedimentary soil tension is settled with low soil restraint.

In addition, there is no uniformity according to the uncertainty in construction and skill of the operator during the construction of the anchor, there is a problem in the function of the waterproofing ability of the anchor body buried underground.

Compression anchors, which are often used in the roots by improving these problems, have excellent corrosion protection performances compared to tensile anchors, and thus are widely used as permanent anchors.

The disadvantages of the compression type anchor are that when the grout quality is poor, the pullout resistance is lowered, and when the anchor is installed without completely removing the slime when the anchor is installed on the ground, there is a concern that the grout may be defective.

The present invention is a composite using both the structure of the anchor and the anchorage of the anchorage anchorage and compression anchors of the anchorage of the anchoring ground of the anchorage of the anchorage of the anchorage of the anchorage of the anchorage of the anchorage of the anchorage of the anchorage of the anchoring surface of the anchorage The purpose is to develop a type anchor.

As described above, it is possible to eliminate the disadvantages of the tension anchor and the compression anchor at the same time, have the advantages at the same time, completely reduce the effect of progression, minimize the effects of slime in the ball, and minimize the displacement of the fixture, The length of the free field has been developed to enable elastic movement, so that the tensile and compressive forces can be obtained at the same time. The purpose is to develop anchors that can exert the required pull-out force on soil and weathered soil.

This will be described in detail based on the accompanying drawings.

The composite anchor of the present invention will have the characteristics of a tensile anchor and a compression anchor at the same time, in particular to develop a high pull on the soft ground, such as the surface of the soil layer.

1 is a partial cross-sectional perspective view showing the separation of the composite anchor is a configuration of the present invention, by forming a tension anchor (A) at the bottom and a compression anchor (B) at the top to form a tensile anchor (A) and compression anchor ( Combining the central portion of B) integrally constituted by one anchor is made of a composite anchor (C).

In the above, the center portion of the structure in which the tension anchor A portion and the compression anchor B portion are integrated is formed by a split bearing 50. The structure of the split bearing 50 is a tapered dividing hole 51 having an upper and lower narrow angle. ) Is formed to face in plurality, and the female screw 52 is formed at the tip of the dividing hole 51 to function as a tension anchor (A).

In the same partition support 50 as described above, a plurality of dividing holes 51a made of upper and lower light taper are opposed to the space surface between the tapered dividing holes 51 of the upper and lower narrow sides, and the female screw ( 52a) was made to be used as a function of the compression anchor (B).

To make the step 53 on the top of the split support 50 and the male screw 54 on the outer circumference to enable the tension and compression function at the same time.

In the complex anchor (C), the portion consisting of the tension anchors (A) is a tension function to the anchor head cap (1) of the lower portion and the divided bearing 50 of the middle portion.

And from the divided bearing 50 of the middle portion to the steel wire 20a of the end passing through the fixing unit 44 of the upper end functions as a compression anchor (B).

Referring to the structure of the tensile anchor (A) in this composite structure as follows.

In the lower anchor head cap (1), the lower end diameter is smaller than the upper end, and the grout hose coupling guide tube (12) made of the through hole (11) to be connected to the grout injection hole (10) drilled at the lower end of the anchor head cap ( 1) It is made to protrude slightly higher than the outer periphery of the top.

The lower part of the anchor head cap 1 has a smaller diameter than the upper part so that the grout is easily sprayed to the outside of the anchor head cap 1 during grout spraying, and the grout hose coupling guide tube 12 is It is somewhat higher than the body outer height of the anchor head cap 1.

The grout supply hose 30 having the grout injection hole 31 drilled through the passage 11 is inserted into the upper end of the anchor head cap 1 through the grout hose coupling guide tube 12. .

Coupling a plurality of steel wires 20 cut to a predetermined standard length in accordance with the standard in the coupling groove portion made of a plurality in the outer circumference of the spacer 40.

 The steel plate 20 and the grout supply hose 30 is inserted with a plurality of holes 21 and a control disc 23, which has a through hole 22 in the center thereof.

Then, the metal tightening band 41 is fixed to the middle of the steel wire 20 and the grout supply hose 30, and then the control disc 23a is coupled again.

The control disc 23 is to keep a plurality of steel wires 20 to maintain a constant interval and the metal tightening band 41 is coupled to the middle portion of the steel wire 20 is given a tight tightening to the steel wire 20 is loose Install to prevent

As described above, the steel wire 20 coupled to the anchor head cap 1 is coupled to the split support 50 penetrating a plurality of taper-shaped dividing holes 51 in the upper and lower narrow spaces at a certain distance.

The split hole 51 of the split support 50 is fixed to be coupled to the front end male screw 61 of the wedge 60 to which the female screw 52 is made at the upper end of the inner circumference to insert the steel wire 20.

Tensile anchor (A) is configured by combining the corrugated pipe 80 from the top of the anchor head cap (1) in the combined state as described above to the lower end of the split support (50).

In the above, the corrugated pipe 80 coupled to the split bearing 50 is coupled to the outer periphery of the split bearing 50 by a protective tube 85 and the upper end of the protective tube 85 is formed to be somewhat higher than the split bearing 50 to divide the split tube 50. The upper surface of the base 50 is filled with a resin solution, and then cured to form a resin layer 86.

The resin layer 86 is integrally coupled to the steel pipe 70 and the outer reinforcement spring 90 of the compression anchor (B) portion formed on the upper end of the split support (50).

Before joining the corrugated pipe 80, the steel wire 20a, which is used as the compression anchor B, is also cut into a length of a predetermined size and inserted into the split hole 51a made of the upper and lower beams of the split support 50. The wedge 60a is inserted near the end of the 20a and the female screw 52a at the bottom and the male screw 61a of the wedge 60a are fixed to each other.

In this manner, the steel wires 20a are fitted into all four division holes 51a.

As described above, when the steel wire 20a used as the compression anchor B portion is completely coupled to the dividing hole 51a by the wedge 60a, the upper end of the anchor head cap 1 at the lower end and the split support 50 are formed. Combine the corrugated pipe 80 with the protective tube 85 to be coupled to the outer peripheral edge of the bottom.

By integrating the corrugated pipe 80 integrally, the space portion 81 between the anchor head cap 1 and the split support 50 is sealed so that the steel wire 20 used for tensioning is not exposed to the outside.

As described above, the portion consisting of the corrugated pipe 80 is coupled to the anchor head cap (1) to the split bearing 50 is the tension anchor (A) portion.

Next, as a component of the compression anchor B, a male screw 54 is formed on the outer circumference of the upper end of the split support 50 coupled as a wedge 61a to a split hole 51a tapered in the shape of upper and lower beams. The lower female screw 71 of the steel pipe 70 drilled a plurality of holes 72 is screwed.

Next, a resin layer 86 is formed by filling and curing the resin liquid on the upper surface of the split support 50 of the inner space portion of the upper end of the protective tube 85 that is integrally coupled with the corrugated pipe 80 on the outer circumference of the steel pipe 70. The tension anchor (A) component and the compression anchor (B) component are integrated.

The hole 72 of the steel pipe 70 is a grout supplied to the inside during the grout injection operation is easily discharged to the outside of the steel pipe 70 is made to give fast workability and compactness even from the outside of the anchor.

Another embodiment of the compression anchor (B) is a resin layer that is filled and cured of the resin liquid in the upper part after the outer reinforcing spring 90 is placed on the upper stepped portion 53 of the split support 50 coupled to the protective tube 85. The 86 is integrally formed by the compression anchor B. As shown in FIG.

In another embodiment, the female thread 71 of the steel pipe 70 is combined with the male thread 54 of the split bearing 50, and the external reinforcing spring 90 is inserted into the outer circumference of the steel pipe 70. The steel pipe 70 and the external reinforcement spring 90 are simultaneously integrated with the resin layer 86 filled and cured by filling the resin solution on the inner upper end of the split support 50 by placing the upper stepped portion 53 in the upper part.

The inner part of the steel wire (20a) of the portion consisting of the compression anchor (B) to the metal grind the grout supply hose 30 is connected to the anchor head cap (1) of the lower portion and the hose 32 used for grout discharge It fastened with the band 41a.

Then, the mounting hole 44 is inserted into the steel wire 20a to be placed in the upper end of the outer reinforcement spring 90.

At this time, the upper portion of the steel pipe (70) is in contact with the fixing unit 44, the steel wire 20a of the upper portion of the fixing unit 44 is coupled to the spacer (40a) at regular intervals to combine the steel wire (20a) It was not entangled with each other.

The part configured as described above is to function as a compression anchor (B).

Referring to the present invention configured as described above in detail as an embodiment as a composite anchor (C) as follows.

At the time of construction of the composite anchor (C) of the present invention, after the construction work to install the casing first, and then drilled in the construction part for inserting the composite anchor (C) and then cleaning the perforated hole composite anchor (C) Insert).

Next, the grout, which is an injection material, is injected into the tensile anchor A portion and the compression anchor B portion.

In the grout injection, when grout is injected through the grout supply hose 30 discharged to the compression anchor B, the grout injected is continuously injected down the grout supply hose 30. When reaching the end of the through passage 11 of the cap 1 is discharged to the outside of the anchor head cap 1 through the grout injection hole 10 to bury the anchor head cap (1).

As such, the anchor head cap 1 is continuously buried from the outside, and at the same time, the grout is also injected into the grout injection hole 31 of the grout supply hose 30 drilled on the upper side of the grout hose coupling guide tube 12. The grout is also filled in the inner space 81 of.

When the grout filled in this way comes up to the place forming the compression anchor B after passing through the split support 50, the grout flows into the steel pipe 70 through the hole 72 of the steel pipe 70 and is filled. Filled inside the steel pipe 70 When some pressure is applied to the inside of the steel pipe 70, pressure is leaked to the outside through the internal hose 32, and stable filling operation in the internal space is possible.

When the filling is completed due to the grout injection as described above, if the casing is removed during the construction and the grout is cured, the tension member is tensioned and settled, thereby finishing the last head protection work.

The present invention as described above is very simple in construction, does not require work such as pressurization or packer installation, and the grout is injected into the entire anchor length at once.

In addition, the structure minimizes the effects of progressive fracture and slime in the ball, reducing the tensile displacement of the anchor body and allowing the free length to be elastic.

Claims (10)

A tension anchor is formed at the bottom, and a compression anchor is formed at the top, and the tension anchor and the center of the compression anchor are integrally combined with a protective tube, which is composed of a single anchor. anchor. The split support according to claim 1, wherein the divided bearings, in which the tensile anchor portion and the compressed anchor portion are integrated, form a plurality of tapered dividing holes of the upper and lower narrow sides facing each other, and a female screw is formed at the distal end of the split hole. A complex anchor capable of simultaneously tensioning and compressing, characterized by having a plurality of taper-shaped dividing holes facing each other in the taper-shaped partition hole facing each other, and forming a female screw at the lower entrance. The method according to claim 1, wherein a stepped portion is formed at the upper end of the split support coupled to the central portion integrating the tension anchor and the compression anchor, and a male screw is formed on the outer circumference to engage with the female screw of the steel pipe drilled in a plurality of parts of the body, and a protective tube on the outer surface of the split support A combination anchor capable of simultaneously tensioning and compressing, characterized in that to be integrated into a resin layer filled and cured by filling the resin liquid in the inner bottom of the steel pipe. The method of claim 1, wherein the protective layer is coupled to the outer peripheral surface of the split support coupled to the central portion integrating the tension anchor and the compression anchor, the outer reinforcing spring is placed on the upper end step portion, and then the resin layer filled and cured of the resin liquid is integrated on the upper end portion. A composite anchor capable of both tension and compression at the same time, characterized in that it is integrated with a compression anchor. The method of claim 1, wherein the protective tube is integrally formed on the outer circumferential surface of the split bearing coupled to the central portion of the tension anchor and the compression anchor, and the steel pipe and the outer reinforcing spring are inserted into the upper end of the split bearing in order, and the resin liquid is filled therein. A composite anchor capable of both tension and compression at the same time as the hardened resin layer integrates a steel pipe and an external reinforcement spring together with a protective pipe at the same time. The outer anchor head cap according to claim 1, wherein the lower anchor head cap has a diameter smaller than that of the upper end, and a grout hose coupling guide tube is formed to connect with the grout jet hole drilled at the lower end of the anchor head cap. A composite anchor capable of simultaneously tensioning and compressing the joint by inserting a grout supply hose through which a grout injection hole is inserted into the through passage by inserting a spacer at the upper end of the guide tube for joining the grout hose. The wedge inserted into the steel wire which is connected to the anchor head cap of the lower part in the tapered shape of the tapered shape of the upper and lower narrow side of the divided bearing so that the female screw and the male screw are combined to be the center of the tension anchor. Composite anchors capable of both tension and compression at the same time. The wedge inserted into the steel wire which is connected to the anchor head cap of the lower part in the tapered shape of the tapered shape of the upper and lower narrow side of the divided bearing so that the female screw and the male screw are combined to be the center of the tension anchor. A composite anchor capable of both tension and compression at the same time. The wedge fixed near the end of the steel wire is inserted into the split hole made of the upper and lower beam deposits of the split bearing, and the female screw of the lower part and the male screw of the wedge are combined to fix the center of the compression anchor. A composite anchor capable of simultaneously tensioning and compressing. The method of claim 1, wherein the grout supply hose connected to the lower anchor head cap portion of the steel wire of the portion consisting of the compression anchor and the hose used for discharging the grout are fastened with a metal tightening band. Composite anchors capable of simultaneous tensioning and compression.

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