KR20070034287A - Ground Improvement Anchor Construction Method - Google Patents

Abstract

The present invention relates to a ground improvement anchor construction method, the configuration comprising: (a) forming a perforation by drilling to a predetermined depth and diameter in order to place an anchor body for forming a free chapter and a fixing chapter; (b) installing a plurality of casings at portions corresponding to the free ledger of the perforations; (c) inserting a double tube rod equipped with a jetting nozzle in the casing; (d) crushing the ground by spraying the cement paste at an ultra-high pressure through the jetting nozzle to a portion corresponding to the fixing part of the perforated portion, and mixing the crushed ground and the cement paste to form an improved ground; (e) curing the improved ground in which the crushed ground and cement paste are mixed; (f) perforating the cured improved ground again to form a re-perforated portion; (g) inserting an anchor body into the re-perforation part; And (h) injecting grout into the perforation to fix the anchor body to the ground. The surface area subjected to the principal surface friction by the improved ground having an increased diameter increases the principal surface friction. It is possible to obtain the acupressure resistance by the front part of the improved ground, and to receive the acupressure resistance and the frictional resistance by the principal surface friction at the same time, so that the ultimate pullout resistance can be further increased and the number of anchor bodies can be reduced. In addition, safe construction is possible, and due to the high pull-out resistance, the displacement of the surrounding ground is small, which does not affect the surrounding underground structures.

Ground anchor, construction method, jetting nozzle, double pipe rod, improved ground

Description

Construction method for soil improvement anchor system

1A to 1H are diagrams sequentially illustrating a method for constructing ground improvement anchors according to a preferred embodiment of the present invention.

Figure 2 is a cross-sectional view showing the ground anchors constructed by the ground improvement anchor construction method of Figures 1a to 1h.

3 is a cross-sectional view showing a tension member used in the anchor body of FIG.

4 is a cross-sectional view taken along line B-B in FIG.

5 is an enlarged cross-sectional view of a portion of FIG. 2;

6 is a load-displacement graph arranged by using a load measured by installing a tension load cell on a tensile steel bar of an anchor body cast by the method of constructing ground improved anchors of FIGS. 1A to 1H.

Figure 7 is an exploded perspective view showing a compression type anchor body used in the ground improvement anchor construction method according to a preferred embodiment of the present invention.

8 is a perspective view of the combination of FIG.

9 is a cross-sectional view of FIG. 8;

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

10: ground 11: drilling part

13: re-punching part 20: anchor body

21: tension member 22: stranded wire

23 polyethylene pipe 24 grease

25: spacer 26: corrugated pipe

27: wedge support 28: protective cap

29: polyethylene pipe 30: casing

40: double pipe rod 41: jetting nozzle

50: improved ground 60: grout

61: grout hose 70: anchor head

The present invention relates to a ground improvement anchor construction method.

Ground anchors are generally hypothesized among ground inserts having rod-shaped ground inserts such as ground anchors (also called ground anchors), rock anchors, rock bolts, or soil nailing that are inserted after drilling of ground or rock. There are two types of anchors and permanent anchors. Hypothetical anchor refers to a period of about 12 to 24 months of use after being buried in the ground, and permanent anchor refers to an anchor that is buried in the ground for more than 24 months or permanently. Permanent anchors must be permanently settled after being buried in the ground, so thorough preparation must be followed for treatment methods and load transfer methods. Ground anchors are divided into anchor, free and anchor heads. The fixing unit transmits the necessary load to the ground, the free unit transmits the given load to the fixing unit, and the anchor head fixes the given load to maintain the load on the free unit and the fixing unit. As the tension member used for the free portion and the fixing portion of the ground anchor, PC strand (steel strand) or steel rod is usually used. The structure for fixing the tension member uses a wedge method mainly using wedge cone in the case of a stranded wire, and a nut method mainly in the case of a steel bar.

In the case of placing such conventional ground anchors in soft ground such as weathered soil, even if the anchor body fixing length is increased to increase the ultimate pullout force, the ultimate pullout force is hardly increased due to the progressive fracture. In order to solve this problem, the number of anchor bodies has conventionally been increased. However, this increase in the number of anchors may narrow the gap between the anchors, which may affect the adjacent structure.

The present invention has been made in order to solve the above problems, the surface area subjected to the principal surface friction by the improved ground diameter is increased, so that high principal surface friction can be obtained, acupressure resistance is generated by the front surface of the improved ground In addition, it is possible to increase the ultimate pullout resistance as it can receive acupressure resistance and frictional resistance due to principal friction at the same time, and to reduce the number of anchors, so that it is economical and safe construction, and the displacement of the surrounding ground due to the high pullout resistance The purpose is to provide a method for constructing ground improved anchors that does not affect surrounding underground structures.

The ground improvement anchor construction method of the present invention for achieving the above object, (a) forming a perforation by drilling to a predetermined depth and diameter in order to pour the anchor body to form a free ledger and a fixing ledger on the ground; ; (b) installing a plurality of casings at portions corresponding to the free ledger of the perforations; (c) inserting a double tube rod equipped with a jetting nozzle in the casing; (d) crushing the ground by spraying the cement paste at an ultra-high pressure through the jetting nozzle to a portion corresponding to the fixing part of the perforated portion, and mixing the crushed ground and the cement paste to form an improved ground; (e) curing the improved ground in which the crushed ground and cement paste are mixed; (f) perforating the cured improved ground again to form a re-perforated portion; (g) inserting an anchor body into the re-perforation part; And (h) injecting grout into the re-perforation to fix the anchor to the ground.

In the above, it is preferable that the step (d) and (e) further comprises the step of remaining one or two of the plurality of casings on the upper end of the perforation, and removing the remaining casing. .

In the above, the diameter of the improved ground is preferably characterized in that formed from 60 centimeters to 100 centimeters.

In the above, the anchor body is formed to form a waterproof cap having a primary waterproof means and is accommodated therein to form a semi-circular reinforcement resin formed on the lower side, the upper portion of the reinforcement resin to prevent lubrication and corrosion A grease bowl to accommodate grease is seated, and a plurality of reinforcing wires are accommodated in the grease in a state where the coating is detached, and a reinforcement support is seated on the upper periphery of the waterproof cap. Drill a plurality of screw holes and tapered split holes, but form a female thread on the lower side of the split holes to engage with a male screw formed on the main surface of the tapered chuck. The main surface is formed with a plurality of O-ring grooves for providing a seat of the O-ring having a third waterproofing means, and the surface of the upper part of the division base There are a plurality of reinforcing wire holes and a circular waterproof packing in which a screw hole is drilled in the center, and a coating disc having a third waterproofing means is mounted on the upper surface of the waterproof packing, but the coating disc is provided in the plurality of reinforcing wire holes and in the center. It is preferable that a nut hole on which the nut can be seated is drilled, an inner reinforcing wire having a spring shape is inserted into an inner side of the reinforcing wire having a coating, and an outer reinforcing wire is formed outside the reinforcing wire.

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

1A to 1H are views sequentially showing a ground improvement anchor construction method according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view showing the ground anchors constructed by the ground improvement anchor construction method of Figures 1A to 1H. 3 is a cross-sectional view illustrating a tension member used in the anchor body of FIG. 2, FIG. 4 is a cross-sectional view taken along line BB of FIG. 2, and FIG. 5 is an enlarged cross-sectional view of a portion of FIG. 2.

The ground improvement anchor construction method of this embodiment consists of the following steps.

As shown in FIG. 1A, in order to pour the anchor body 20 forming the free long section and the fixing long section on the ground 10, the drill section 11 is formed by drilling with a predetermined depth and diameter. (step a)

When the perforated portion 11 is formed, as shown in FIG. 1B, a plurality of casings 30 are provided at a portion corresponding to the free long portion of the perforated portion 11. (step b)

Since the portion corresponding to the free ledger of the perforated portion 11 is several meters (m), a plurality of casings 30 are installed in series.

After installing the casing 30, as shown in FIG. 1C, the double tube rod 40 having the jetting nozzle 41 mounted therein is inserted into the casing 30. (step c)

After inserting the double tube rod 40, as shown in FIG. 1D, the cement paste is crushed by ultra-high pressure through a jetting nozzle 41 to a portion corresponding to the fixing part of the perforated portion 11, and the ground is crushed. And cement paste are mixed to form an improved ground (50). (step d)

When the d step is described in detail, the cement paste is sprayed through the jetting nozzle 41 using an extremely high pressure jet flow of about 200 kg / cm ² to 700 kg / cm ² , and the jetting nozzle 41 rotates once or 1.5 times. When the double tube rod 40 is raised to a certain height, the operation is repeated continuously to crush the ground of the portion corresponding to the fixing part of the perforations 11. The crushed ground is mixed with cement paste to form the improved ground 50.

The diameter of the improved ground 50 thus formed is preferably 60 centimeters to 100 centimeters, and in this embodiment, the diameter of the improved ground 50 is 80 centimeters.

After the step (d), as shown in FIG. 1E, one or two of the casings 30 installed in the perforation part 11 are present on the upper end of the perforation part 11 and the remaining casings are removed. Preferably, the step further includes.

In this embodiment, one casing 30a was left, and the other casing was removed. When one or two of the casings were left in this way, two days to three days to cure the improved ground 50 described below. By leaving the casing 30a at the time of leaving, the position under construction can be displayed.

After one casing 30a is left and the other casing is removed, as shown in FIG. 1E, the improved ground 50 in which the crushed ground and the cement paste are mixed is cured. (Step e) Curing of the improved ground 50 is 2 to 3 days is sufficient.

If the curing of the improved ground (50) is made after 2 to 3 days, as shown in Figure 1f, the drilled through the interior of the cured improved ground (50) again to form a re-perforated portion (13). (step f)

After the re-perforation 13 is formed, as shown in FIG. 1G, the anchor body 20 is inserted into the re-perforation 13. (step g)

In the present embodiment, the tension member 21 used for the anchor body 20 of the ground anchor is cold drawn to remove the stress and cover the 7-wire wire strand (spand) 22, as shown in FIG. The outer periphery of the seven-wire strand 22 is protected by a polyethylene (PE) pipe 23, and the inside of the polyethylene pipe 23 is filled with grease 24. Six such tension members 21 are provided in this embodiment, which is only one embodiment.

As shown in FIG. 4, the six tension members 21 configured as described above are provided with a spacer 25 in the polyethylene pipe 29 to hold the gap between the six tension members 21.

As shown in FIG. 5, the lower part of the polyethylene pipe 29 is protected by the corrugated pipe 26, and the lower end of each tension member 21 has six wedge cones fixed to the wedge support 27. 27a), respectively, and the fixing structure of the strand 21 using the wedge cone 27a is widely used in the related art and various methods are well known. The lower portion of the wedge support 27 is provided with a protective cap 28 to protect the tension member 21 therein.

After inserting the anchor body 20 into the re-perforation part 13, as shown in FIG. 1H, the grout 60 is injected into the re-perforation part 13 to fix the anchor body 20 to the ground 10. (step h)

The grout 60 generally consists of cement, water and admixtures.

The grout hose 61 for injecting the grout 60 is located between six tension members 21, as shown in FIG. 4, and is usually polyethylene (PolyEthylene; PE) capable of withstanding a pressure of up to 20 bar. Use a hose. In addition, the grout hose 61 should be a diameter capable of smoothly transporting the grout.

When a predetermined seal for hardening of the grout 60 elapses, the tension member 21 is tensioned with a predetermined load to stabilize the anchor head 70 so as to stabilize it.

As shown in FIG. 2, the anchor body 20 constructed as described above is divided into a fixing book, a free book and an anchor head, and the fixing book transmits necessary loads to the ground, and the free book fixes a given load. It transfers to the ledger and anchors the head to fix the given load to maintain the load on the free and the fixing ledger.

The fixing ledger of the anchor body shown in the drawings of the present specification is 5m, the free ledger is 10m, but this is only one embodiment.

6 shows the results of experiments by installing a tension load cell on the tensile steel bar of the anchor body cast by the ground improvement anchor construction method of the present invention as described above. 6 is a load-displacement graph arranged by using a load measured by installing a tension load cell on a tension steel bar of an anchor body cast by the ground improvement anchor construction method of FIGS. 1A to 1H.

In the graph of Figure 6 (a) is a conventional anchor body receiving only frictional resistance, (b) is an anchor body placed in the ground improvement anchor construction method of the present invention receiving both the pressure resistance and the frictional resistance at the same time.

As can be seen from the graph of FIG. 6, the anchor body placed by the ground improvement anchor construction method of the present invention in which acupressure resistance is generated with respect to the same pulling force is considerably larger in drawing load and does not lead to sudden breakage, and displacement is also suppressed. Able to know.

The construction method of the ground anchor as described above has a high elastic recovery capacity, convenient construction and high stability.

As the surface area subjected to principal friction is increased by the improved ground whose diameter is enlarged, high principal friction is obtained.

In addition, acupressure resistance is generated by the front part of the improved ground, so that it can simultaneously receive acupressure resistance and frictional resistance due to principal friction, thereby increasing the ultimate pullout resistance and reducing the number of anchors. This is possible.

Furthermore, due to the high pull resistance, the displacement of the surrounding ground is small and does not affect the surrounding underground structures.

On the other hand, the anchor body used in the above ground improvement anchor construction method is generally used in the conventional anchor construction, but when explaining the preferred embodiment of the anchor body used in the ground improvement anchor construction method of the present invention are as follows. .

For reference, the anchor body shown in Figures 7 to 9 of the present specification is described in detail in the "structure of the compressed anchor" of the present patent application No. 0184170, the inventor of the present invention in the construction method of the present invention For the specific structure of the anchor used, reference is made to the above-mentioned publication.

Figure 7 is an exploded perspective view showing a compression type anchor used in the ground improvement anchor construction method according to a preferred embodiment of the present invention, Figure 8 is a combined perspective view of Figure 7, Figure 9 is a cross-sectional view of FIG.

As shown in FIGS. 7 to 9, the waterproof cap 82 is formed on the outside of the anchor body 81, and the semicircular reinforcement resin 83 for reinforcing the waterproof cap 82 is filled and cured.

The upper portion of the reinforcement resin 83 is seated on the copper bowl 85 to accommodate the lubrication action, the fourth waterproof means and the grease 84 to prevent corrosion, and the grease 84 has a plurality of reinforcement wires 86 It is received with the coating detached.

The lower side of the parting support 87 is seated on the peripheral edge 81 ′ of the inner upper side of the waterproof cap 82.

A screw hole 87a is drilled in the center of the split support 87, and a plurality of tapered split hole 87b is drilled around the screw hole 87a, but a female thread is formed below the split hole 87b. It is fastened to the male screw (88a) formed on the main surface of the tapered chuck 88, the reinforcement wire 86 is inserted into the chuck 88 is fixed by a bolt.

A plurality of O-ring grooves 87c are provided on the upper main surface of the partition support 87 to provide a seat of the O-ring 89 having the means for tertiary waterproofing.

On the surface of the partition support 87, a plurality of reinforcing wire holes 90a and a circular waterproof packing 90 in which a screw hole 90b is perforated are seated, and on the surface of the waterproof packing 90, secondary The coating disc 91 having waterproof means is seated, and the coating disc 91 is formed with a plurality of reinforcing wire holes 91a and a nut hole 91b on which a nut 92 can be seated in the center. A spring-shaped inner reinforcement line 93 is inserted into the inner side of the reinforcement line 86 having the coating, and an outer reinforcement of the spring shape reinforcing the outer side of the reinforcement line 86 is inserted. Install the wire 94.

In the anchor body as described above, the entire anchor body plays the role of a free field, and thus the plastic displacement is very small compared to the conventional anchor because of its superior elastic recovery ability.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications of the present invention without departing from the spirit and scope of the invention described in the claims below. Or it may be modified.

The construction method of the ground anchor of the present invention as described above has a high elastic recovery capacity, convenient construction and high stability.

As the surface area subjected to principal friction is increased by the improved ground whose diameter is enlarged, high principal friction is obtained.

In addition, acupressure resistance is generated by the front part of the improved ground, so that it can simultaneously receive acupressure resistance and frictional resistance due to principal friction, thereby increasing the ultimate pullout resistance and reducing the number of anchors. This is possible.

Furthermore, due to the high pull resistance, the displacement of the surrounding ground is small and does not affect the surrounding underground structures.

On the other hand, using a compression anchor, since the entire anchor body plays the role of a free field, the plastic recovery is very small, because the elastic recovery ability is higher than conventional anchors.

Claims (4)

(A) forming a perforation by drilling to a predetermined depth and diameter in order to place the anchor body to form a free tenon and a fixing tenon on the ground; (b) installing a plurality of casings at portions corresponding to the free ledger of the perforations; (c) inserting a double tube rod equipped with a jetting nozzle in the casing; (d) crushing the ground by spraying the cement paste at an ultra-high pressure through the jetting nozzle to a portion corresponding to the fixing part of the perforated portion, and mixing the crushed ground and the cement paste to form an improved ground; (e) curing the improved ground in which the crushed ground and cement paste are mixed; (f) perforating the cured improved ground again to form a re-perforated portion; (g) inserting an anchor body into the re-perforation part; And (h) injecting grout into the re-perforation to fix the anchor body to the ground; the ground improvement anchor construction method comprising a. The method of claim 1, Between steps (d) and (e), One or two of the plurality of casings on the upper end of the perforated portion, and the ground improvement anchor construction method further comprising the step of removing the remaining casing. The method according to claim 1 or 2, Ground improvement anchor construction method characterized in that the diameter of the improved ground is formed from 60 centimeters to 100 centimeters. The method according to claim 1 or 2, Outside the anchor body to form a waterproof cap having a primary waterproof means and is accommodated therein to form a semi-circular reinforcement resin formed on the lower side, the upper portion of the reinforcement resin to accommodate grease to prevent lubrication and corrosion The copper bowl is seated, the plurality of reinforcing wires are accommodated in the state in which the coating is detached, and the reinforcement support is seated on the upper periphery of the inner side of the waterproof cap, and the center of the reinforcement support is a screw hole and a tapered shape Punch a plurality of dividing holes in the hole, and form a female screw on the lower side of the dividing hole so as to be fastened with a male screw formed on the main surface of the tapered chuck. A plurality of O-ring grooves forming a seat of the O-ring having a waterproof means are formed, and a plurality of beams are provided on the surface of the division base. A circular waterproof seal with a threaded hole in the line hole and the center is seated, and a surface of the upper part of the waterproof packing is seated with a coating disk having a third waterproofing means, and the coating disk has a plurality of reinforcing wire holes and nuts in the center. The ground hole anchor construction method, characterized in that the nut hole is drilled, the inner reinforcement line of the spring shape is inserted into the inner side of the reinforcement line is formed, the outer reinforcement line is formed on the outer side of the reinforcement line.

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