KR102054157B1 - Micropile with Stress Constraining Member, Micropile Foundation improved Frictional Resistance and Construction Methods thereof - Google Patents

Abstract

The present invention relates to a micropile with a stress restraining part, a micropile foundation with improved frictional resistance, and a construction method thereof. The micropile includes at least one stress restraining part on a pile body with threads formed on the outer circumferential surface thereof to be positioned in response to the height of a rock formation. The stress restraining part includes: a through hole formed at the center of a body unit to penetrate the pile body; and an earth pressure flange integrally formed along the outer circumferential surface of the body unit. A pressing inclination surface inclined straight to be directed inwardly downwards is integrated into the outer circumferential surface of the earth pressure flange to convert an external load applied from above into a horizontal direction to transfer the horizontal load to a grout material in a drilled hole. Accordingly, since an external load applied from above can be effectively converted into a horizontal direction, the frictional resistance between the grout and the rock formation can be improved.

Description

Micropile with Stress Constraining Member, Micropile Foundation improved Frictional Resistance and Construction Methods

The present invention relates to a micropile having a stress restrictor and a micropile foundation having improved frictional resistance and a construction method thereof. More particularly, the present invention relates to a micropile having a frictional resistance and a construction method thereof. The stress restraint is provided, and the stress restraint is formed on the outer circumferential surface of the body by integrally forming an acupressure flange integrally provided with an inclined downwardly inclined inclined surface so as to be provided in the drilled hole by converting the external load loaded from the upper portion in the horizontal direction. The present invention relates to a micropile having a stress restrictor for transferring to a grout material, a micropile foundation with improved frictional resistance, and a construction method thereof.

In order to construct the foundation of various structures, a pile construction method is known in which a pile is provided by drilling a soil layer or a rock layer into an auger to fill a pile, or directly driving a pile from the top. Depending on the type of the file method, SIP (Soil-cement Injected Precast Pile), SIP (Special Auger & Injected Precast Pile), CIP (Cast-In Place Pile), PRC (Precast Reinforced Concrete), PRD (Percussion) Rotary Drill method, SGR (Space Grouting Rocket) method, JSP (Jumbo Special Pile Pattern) method and MicroPile method.

Among these methods, the micro pile method means a method of grouting the inside of a hole by using a small drilling machine to form a hole at a predetermined depth up to a support layer such as a rock layer, and having a non-displacement pile having a diameter of 300 mm or less. .

At this time, the micropile supports the load in a manner similar to the ground anchor in a state in which the support layer is indented. Specifically, the external load supported by the steel transfers the load to the ground by converting the grout into the frictional resistance of the ground. In this case, it can be assumed that the frictional resistance between the soft layer such as the soil layer and the grout and the end support force are negligible.

The micro pile method is a construction method with minimal impact on surrounding structures, ground, and environment, and has an advantage of easy construction in a narrow space that is difficult to access because construction or vibration is small and, above all, using small-scale equipment.

On the other hand, as a prior art document that partially improved the micro file method, "Stress distributed micro pile" of the Republic of Korea Patent Publication No. 10-2009-0089127 (published Aug. 21, 2009, hereinafter referred to as 'prior art document 1') ) Has been proposed.

The prior art document 1 is provided with a threaded tread bar 1, as shown in Figure 1a, but by screwing the stress distribution flange (2) to the tread bar (1) at regular intervals, the stress distribution flange (2) ) Was developed to transmit the external load to the ground (4) more effectively.

However, the stress dispersion flange 2 of the prior art document 1 is formed with an inclined surface such that its shape is widened toward the lower side, and a flat surface is formed at the lower side so that external load is more effectively dispersed, and the grout 3 and the tread bar 1 Although the frictional force could be expected to increase with the increase of the interlocking surface area between them, the external load was only transmitted downward by the plane, which is a major variable in forming the frictional resistance of the grout (3) and the ground (4), which are important for securing the bearing capacity. There was a limit that the applied horizontal load could not be effectively induced.

In addition, in the stress dispersion flange 2 of the prior art document 1, in order to inject the grout 3 later, the injection hose through-hole is formed separately, and the inefficiency generated in the process of injecting the hose is caused. .

Another prior art document has been proposed a "microfile" of the Republic of Korea Patent No. 10-1444225 (registered September 18, 2014, referred to as "prior art document 2").

The prior art document 2 is connected to the plurality of tread bars (1) via a coupler as shown in Figure 1b while ensuring the applicability to the depth while securing the center of the tread bar (1) provided inside the drilling hole In order to overcome the shortcomings of the micro piles, which are difficult to secure the tip support force, the tip spacer 6 is additionally provided at the tip end of the tread bar 1 so as to provide an external load on the support layer. We tried to reinforce our support.

However, since the through-hole 5a recessed on the outer circumferential surface of the center spacer 5 is formed so as to inject the grout 3, there is a limit in effectively transferring the external load to the grout 3. Since the earth 6 is simply located on the upper part of the support layer, there is a limit in that the grout 3 and the ground 4, which are important for securing the bearing force, do not have any function in forming the frictional resistance.

In addition, prior art document 2, as in the prior art document 1, the construction hassle and the inefficiency generated in the process of injecting the hose remaining by separately forming the through-hole 5a formed in the center spacer 5 still remained. .

The present invention has been proposed to solve the above problems, it is possible to improve the frictional resistance of the grout and the rock layer by allowing the external load to be effectively converted in the horizontal direction, which is generated during the process of providing a pile in the hole The problem of interference with the rock layer can be solved, and the workability is secured in the process of injecting grout after the pile is provided, and the shape and arrangement of the stress restraints coupled to the pile can be easily changed according to the depth of the soil layer or the characteristics of the rock layer. It is an object of the present invention to provide a micropile equipped with a stress constrainer and a micropile foundation with improved frictional resistance and a construction method thereof.

In order to solve the above problems, at least one micropile (MP) provided with the stress restraint of the present invention is located on the pile main body 10 having the tread 11 formed on an outer circumferential surface thereof to correspond to the height of the rock layer G2. The stress restraint 20 is provided, and the stress restraint 20 has a through hole 22 formed therein so that the pile body 10 passes through the center of the body portion 21, and Acupressure flange 23 is integrally formed along the outer circumferential surface, and a pressure inclined surface 24 inclined linearly downward inward is integrally formed on the outer circumferential surface of the acupressure flange 23 so as to convert an external load loaded from the upper side into a horizontal direction. Is formed to be transmitted to the grout material (GR) provided in the drilling hole (H), the acupressure flange 23 is formed along the outer circumferential surface of the body portion 21, spirally by varying the position gradually in the vertical direction Formed into a structure, the pile saw A support ring 50 having a flange seating groove 51 formed therein is provided at a lower portion of the stress restraint 20 provided at the lower end of the sieve 10 to accommodate the acupressure flange 23 protruding downward from the body portion 21. The restraint nut 30 is coupled to a lower portion of the support ring 50.

In addition, a restraint nut 30 may be coupled to a lower portion of the stress restraint 20 provided in the pile body 10 to restrain the position of the stress restraint 20.

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In addition, the acupressure flange 23 of the spiral structure integrally formed in the body portion 21 of the stress restraint 20 may be formed to form a pitch (pitch).

In addition, the pile main body 10 is provided with a plurality of stress restraints 20 so as to correspond to the height of the rock layer G2, so that the pitch of the acupressure flange 23 is continuous, and the pile main body ( The restraint nut 30 may be coupled to a lower portion of the stress restraint 20 provided at the lower end of 10 to restrain the position of the stress restraint 20.

In addition, the pile body 10 is provided with a plurality of stress restraints 20 so as to correspond to the height of the rock bed layer G2, and the cylindrical spacer 40 is provided between the stress restraints 20. The restraint nut 30 may be coupled to a lower portion of the stress restraint 20 provided at the lower end of the pile body 10 to restrain the position of the stress restraint 20.

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The stress restraint 20 provided at the top of the pile body 10 may be positioned such that an upper end of the shiatsu flange 23 corresponds to a height at which the rock layer G2 starts.

On the other hand, the micro pile (F) is provided in the interior of the drilling hole (H) formed in the ground (G) of the present invention and the grout material (GR) is injected into the drilling hole (H) is formed. The micro pile (MP) is provided with at least one stress restraint 20 to be located in correspondence with the height of the rock layer (G2) in the pile body 10, the tread 11 is formed on the outer peripheral surface, the stress restraint Sphere 20 has a through-hole 22 is formed so that the pile body 10 penetrates in the center of the body portion 21, the acupressure flange 23 is integrally formed along the outer circumferential surface of the body portion 21, The outer circumferential surface of the acupressure flange 23 is integrally provided with a pressure inclined surface 24 that is inclined downward to the inner side as a grout material GR provided in the drilling hole H by converting an external load loaded from the upper side in a horizontal direction. So that the frictional resistance between the grout material GR and the rock layer G2 is improved. The acupressure flange 23 is formed along the outer circumferential surface of the body portion 21, and is gradually formed in a spiral structure by varying positions in the vertical direction, and is provided at a lower end of the pile body 10. A lower portion of the restraint 20 is provided with a support ring 50 having a flange seating groove 51 formed therein so as to receive the acupressure flange 23 protruding downward from the body portion 21, and a lower portion of the support ring 50. Restriction nut 30 is characterized in that coupled to.

On the other hand, the construction method FM of the micro pile foundation F of this invention penetrates through the soil layer G1 of the ground G, and forms the hole H to a predetermined depth so that it may reach the rock layer G2. Hole forming step (S10); A through hole 22 is formed in the center of the body portion 21 so that the pile body 10 penetrates. Acupressure flange 23 is integrally formed along the outer circumferential surface of the body portion 21. On the outer circumferential surface of) is provided integrally inclined pressure inclined surface 24 to be inward downward, the acupressure flange 23 is formed along the outer circumferential surface of the body portion 21, gradually changing the position in the vertical direction A stress restraint providing step (S21) through which the pile main body (10) passes through the through hole (22) by using at least one stress restraint (20) formed in a helical structure; A stress restraint positioning step of positioning the stress restraint 20 to correspond to the height of the rock layer G2; And a support ring 50 having a flange seating groove 51 formed therein so that the acupressure flange 23 protruding downward from the body portion 21 is received at a lower portion of the stress restraint 20 provided at the lower end of the pile body 10. And a stress restrainer restraining step (S23) for coupling the restraining nut (30) to the lower portion of the support ring (50). Micro file insertion step (S30) for inserting the micro file (MP) in the drilling hole (H); And a grout material injection step (S40) for curing by injecting grout material GR into the drilling hole H.

In addition, the drilling hole forming step (S10), the casing intrusion step (S11) for injecting the casing (CS) to a lower position on the ground (G); And a drilling step (S12) of drilling the inside of the casing (CS) using the drilling mill.

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The stress restraint positioning step S22 may be positioned such that an upper end of the acupressure flange 23 formed at the uppermost stress restraint 20 corresponds to a height at which the rock layer G2 starts.

The pile body is provided with at least one stress restraint to be positioned corresponding to the height of the rock layer, wherein the stress restraint is integrally provided with an inclined pressure inclined surface which is inclined inward downward to the outer circumferential surface of the acupressure flange and has an external load loaded thereon horizontally. By effectively turning in the direction, the frictional resistance of the grout and the rock layer can be further improved.

In addition, the azimuth flange of the stress constraint sphere is formed along the outer circumferential surface of the body, it is formed in a spiral structure by gradually changing the position in the vertical direction, so that it is possible to rotate and insert in the process of providing a micro pile in the drilling hole The interference problem of the inner circumferential surface of the hole can be solved.

In addition, since the grout material can be easily injected along the spiral structure of the acupressure flange, there is an advantage that a separate injection hole is not required in the process of injecting the grout material after the pile is provided.

Furthermore, since the shape or arrangement of the stress restraint sphere can be variously formed according to the depth of the soil layer or the rock layer characteristics, it is possible to apply flexibly according to the construction conditions.

In addition, a plurality of stress restraints are continuously provided to form a continuous pitch of the respective acupressure flanges so that the external load can be converted to the horizontal direction more stably and evenly.

In this case, when a plurality of stress restraints are provided such that the pitch of the acupressure flange is continuous, it can be utilized as auger of the drilling device in the drilling step, thereby reducing construction errors and securing construction properties.

In addition, by placing the upper end of the acupressure flange of the stress restraint provided on the top of the pile body so as to correspond to the height at which the rock layer starts, the length of the stress restrained anchorage may be maximized, thereby forming an optimum frictional resistance.

1a and 1b show a microfile according to the prior art;
Figure 2 is a perspective view showing a micro pile provided with a stress constraint in accordance with an embodiment of the present invention.
Figure 3 is a cross-sectional view showing the basis using a micro pile according to an embodiment of the present invention.
Figure 4 is a perspective view of a micro pile provided with a stress constraint according to another embodiment of the present invention.
5 is a perspective view showing a stress constraint according to another embodiment of the present invention.
6 is a cross-sectional view showing a basis using a micro pile according to another embodiment of the present invention.
7 and 8 are perspective views illustrating a micropile having a plurality of stress restraints according to various embodiments of the present disclosure.
9 is a block diagram illustrating a construction method of a pike-based pile according to an embodiment of the present invention.

Hereinafter will be described in detail with reference to the drawings a preferred embodiment of the micro pile (MP) with a stress restraint of the present invention and the micro pile base (F) with improved frictional resistance and its construction method (FM).

Figure 2 is a perspective view showing a micro pile (MP) provided with a stress constraint according to an embodiment of the present invention. As shown in FIG. 2, the micro pile MP of the present invention has a through hole to allow the pile main body 10 to penetrate the center of the pile main body 10 and the body portion 21 having a tread 11 formed on an outer circumferential surface thereof. 22) includes a stress restraint 20 to be formed and bound.

The stress constraint 20 is bound to the pile body 10 through the through hole 22 formed in the center of the body portion 21, the tret is formed on the inner peripheral surface of the through hole 22 is the pile body It is preferable to be screwed with the tread 11 of (10), it may be bound by the restraining nut 30 to be described later.

Meanwhile, as shown in FIG. 3, the body portion 21 of the stress restriction sphere 20 is preferably formed to have a diameter corresponding to the inner diameter of the drilling hole H formed in the ground G. In the case where at least one stress restraint 20 is bound to the pile main body 10 in the perforated hole H, it is preferable to be located in correspondence with the height of the rock layer G2 of the ground G.

In general, the micro pile MP transfers the load to the ground G by converting the external load into friction resistance between the grout material GR and the ground G, which will be described later. At this time, the stress constraint 20 is simply to form a protrusion on the outer peripheral surface of the micro pile (MP) to increase the frictional resistance by the engagement of the micro pile (MP) and the grout material (GR), or simply to simplify the upper stress Rather than to disperse, the upper surface serves to increase the magnitude of the main surface friction force acting between the contact surface of the grout material GR and the surrounding ground G.

Specifically, the stress restraint 20 is provided with acupressure flange 23 integrally along the outer circumferential surface of the body portion 21. The azimuth flange 23 of the stress restraint 20 receives a compressive force based on an external load loaded from the upper side to press the ground G and the grout material GR downward. At this time, since the pressure inclined surface 24 inclined linearly downward to the inner circumferential surface of the acupressure flange 23 is integrally provided, it is provided in the drilling hole H by converting the compressive force due to the external load loaded from the upper portion in the horizontal direction. It transfers to grout material GR which becomes. As a result, the grout material GR and the surrounding ground G around the stress restrictor 20 are restrained in the vertical and horizontal directions, and the frictional force is increased by the stress restraint in the anchorage where the frictional resistance is exerted.

The technical effect of the present invention will be described based on a specific arithmetic value based on the micropile MP according to an embodiment.

Size of ultimate circumferential frictional resistance according to the type of soil

As can be seen in Table 1, the soft rock that can be assumed to be the rock layer G2 is calculated in the range of 1 to 1.5 MPa in the magnitude of shear stress due to the range of the extreme principal friction resistance.

Graph showing ground stress state and no-stress stress source without stress constraint

However, it is difficult to expect the internal horizontal restraint pressure of the drilling hole H. Therefore, as shown in the Mohr stress source (ⓐ region) of Table 2, the horizontal restraint pressure is not designed as a general micro pile as a separate stress restraint. The improvement of shear stress due to this can be ignored.

Therefore, when ignoring the shear stress improvement value due to the horizontal restraint pressure, the shear stress τ of the soft rock is 1 MPa, and in practice, 0.7 to 1 MPa can be used on the safer side.

At this time, according to the micropile MP of the present invention, since the stress restraint 20 is installed at a position corresponding to the rock layer G2 such as weathered rock or soft rock, when the axial force acts on the micropile MP, As a result, the stress restrictor 20 more effectively restrains the surrounding rock layer G2. If the grout material surrounding the micro pile (MP) is assumed to be concrete, the bearing pressure acting on the concrete can be assumed as the allowable compressive stress or allowable bearing stress of the concrete, and the bearing pressure acting on the concrete is 0.25 f _ck .

On the other hand, assuming that the angle formed in the state in which the pressure inclined surface 24 of the acupressure flange 23 formed in the stress restraint 20 of the present invention is cut out is 45 °, it is assumed that f _ck = 24 MPa. The surface has a stress of q = 6 MPa.

Graph showing ground stress state and more stress source for stress restraint section

As shown in the mower stress source, as shown in the Mohr stress source (ⓑ region) of Table 3, the result is a stress state with σ ₃ '= 4.2 MPa and σ ₁ ' = 6.2 MPa.

Graph showing the ground stress state and the moor stress source in the frictional zone

Thus, τ _{max, c} = 3.6 in the frictional force improvement section in which the frictional resistance is improved by the stress restraint due to the vertical stress in the lower part of the stress constraining hole 20 as in the Mohr stress source (ⓒ region) of Table 4 above. Maximum friction of MPa can be expected.

However, as shown in Table 1, since there is a difference in the ultimate circumferential frictional resistance depending on the type of rock layer (G2) of the ground (G), the design maximum frictional force for each ground (G) by applying the safety side will be applied differently. That is, the maximum frictional force calculated by the allowable concrete compressive stress is 3.6MPa, but in the case of soft rock, the ultimate circumferential frictional resistance is 1.5MPa, so the design maximum frictional force (τ _max) is 1.5MPa. Similarly, weathered rock is 1.0 MPa and hard rock is 2.5 MPa. E Therefore, considering that the extreme principal friction of the rock layer applied in the existing practice is 0.4 ~ 0.6MPa for weathered rock and 0.7MPa ~ 1.0MPa for soft rock, respectively, much greater frictional resistance can be expected by stress constraint when applying the present invention. Therefore, the bearing capacity can be improved.

On the other hand, the ground (G) can be assumed to be so weak as to neglect the frictional resistance between the soft layer (G1) such as soil layer and the grout material (GR) and the end support. Therefore, the stress restraint 20 has a position of the rock layer G2 as the anchorage in which the stress restraining effect can be expected instead of the soft layer G1 in order to transmit the external load to the grout material GR. It is preferable to provide so as to correspond to.

Furthermore, the stress restraint 20 provided at the top of the pile body 10 is preferably positioned such that the upper end of the shiatsu flange 23 corresponds to the height at which the rock layer G2 starts.

The restraint nut 30 may be coupled to a lower portion of the stress restraint 20 provided in the pile main body 10 to restrain the position of the stress restraint 20, and additionally shown in FIGS. 2 and 3. In addition, it is preferable to include the restraining nut 30 to restrain the up and down. In this case, it is not necessary to form a separate tread in the through hole 22 formed in the body portion 21 of the stress restraint 20.

The soil layer G1 in which the frictional force is not calculated is a free field portion in which the stress restraint effect is hardly exhibited even when the stress is restrained by the stress restraint 20. Therefore, it is difficult to expect the frictional resistance to be improved in the fixing field. Therefore, since the stress restraint 20 is preferably located in the firm anchorage of the ground G, the upper end of the acupressure flange 23 is positioned to correspond to the height at which the rock layer G2 starts, thereby improving frictional resistance. You can expect

On the other hand, as shown in Figure 4 and 5 as another embodiment the acupressure flange 23 of the stress restriction sphere 20 is formed along the outer peripheral surface of the body portion 21, and gradually positioned in the vertical direction Alternatively it can be formed in a spiral structure.

As the acupressure flange 23 is formed in a spiral structure as a whole, it is possible to rotate and insert it in the process of providing the micro pile MP in the hole H, which may be generated between the inner circumferential surfaces of the hole H. The problem of interference can be solved beforehand, and the workability can be secured.

In addition, since the grout material (GR) can be easily injected along the spiral structure of the shiatsu flange 23 at a later construction, it is not necessary to form a separate injection hole in the process of injecting the grout material (GR) after the pile is provided. There are advantages in manufacturing and construction.

Furthermore, the acupressure flange 23 of the spiral structure integrally formed in the body portion 21 of the stress restraint 20 may be formed to form a pitch, shown in Figures 5 and 6 As described above, since the acupressure flange 23 is formed at only 360 degrees by varying the height thereof, the external load can be more stably and evenly converted to the horizontal direction without causing an eccentricity in a specific direction.

In addition, as shown in FIG. 7, when the plurality of stress restraints 20 are continuously provided, pitches of the spiral structure of the acupressure flange 23 may be continuously formed, so that the ground If the ultimate circumferential frictional resistance of the rock layer G2 of G) is weak, a continuous spiral structure can be formed. In addition, according to the embodiment, it can be utilized as auger of the drilling device in the drilling step of the drilling hole (H), it is possible to reduce the construction error due to the difference in diameter with the drilling hole (H) and ensure the workability.

On the other hand, in the embodiment in which a plurality of stress restraints 20 are provided so as to correspond to the height of the rock layer G2 and the pitch of the acupressure flange 23 is continuous, the pile main body 10 is provided. The restraint nut 30 may be coupled to a lower portion of the stress restraint 20 provided at the lower end of the stress restraint 20 to restrain the position of the stress restraint 20.

As a result, various shapes or arrangements of the stress restraints 20 may be formed according to the depth of the soil layer G1 or the rock layer G2 characteristics, and thus, there is an advantage in that flexible application is possible depending on the construction conditions.

As another embodiment in which a plurality of stress restraints 20 are provided, a plurality of stress restraints 20 are provided in the pile main body 10 so as to correspond to the height of the rock layer G2 as shown in FIG. 8. The cylindrical spacer 40 may be provided between the stress restrictors 20.

That is, the cylindrical spacer 40 has a structure in which the pile main body 10 penetrates at the center thereof, and when the proper spacing of the stress restraints 20 is designed according to the characteristics of the rock layer G2, the cylindrical spacer 40 is designed. ) Is provided between the upper and lower adjacent stress restraints 20, whereby the stress restraints 20 can be arranged at specific intervals. At this time, the restraint nut 30 is coupled to the lower portion of the stress restraint 20 provided at the lower end of the pile body 10 to restrain the position of the stress restraint 20.

As shown in FIG. 8, the cylindrical spacer 40 may be manufactured in a telescoping structure so that its length may be flexibly changed. The length of the cylindrical spacer 40 may be relatively fixed by a key coupling structure at a specific length. Can be made.

On the other hand, when the acupressure flange 23 of the stress restrictor 20 is manufactured to form a spiral structure, some acupressure flange 23 may be formed to protrude upward or downward from the body portion 21.

Therefore, when fixing the stress restraint 20 provided at the lower end of the pile main body 10 with the restraining nut 30, the flange is configured to accommodate some acupressure flanges 23 protruding from the body portion 21. A bearing ring 50 having a seating groove 51 is additionally provided, and the restraint nut 30 may be coupled to the lower portion of the bearing ring 50. As a result, interference between the acupressure flange 23 and the restraint nut 30 can be prevented from occurring, and a stable fixing structure of the stress restraint 20 can be formed.

On the other hand, the micro pile foundation F of the present invention includes the micro pile MP described above inside the boring hole H formed in the ground G, and the grout material GR is attached to the boring hole H. It is formed by injection, the micro pile (MP) is provided with at least one stress restraint (20) to be located in correspondence with the height of the rock layer (G2) in the pile body 10, the tread 11 is formed on the outer peripheral surface. . In addition, the description which overlaps with respect to embodiment of the microfile MP is abbreviate | omitted.

As described above with respect to the micro pile (MP), the through holes 22 are formed in the stress restraint 20 so that the pile body 10 penetrates at the center of the body portion 21, and Acupressure flange 23 is integrally formed along the outer circumferential surface.

At this time, the outer circumferential surface of the acupressure flange 23 is integrally provided with a pressure inclined surface 24 which is inclined downwardly inwardly to integrally grout material (GR) provided in the drilling hole (H) by switching the external load loaded from the upper to the horizontal direction The frictional resistance between the grout material GR and the rock layer G2 may be improved. The technical effects are as shown in Table 4.

On the other hand, according to the embodiment, when the plurality of stress restraints 20 are continuously provided as shown in Fig. 7, since the pitch of the spiral structure of the acupressure flange 23 can be formed continuously When the ultimate main surface frictional resistance of the rock layer G2 of the ground G is relatively low, a continuous spiral structure may be formed to provide a micro pile foundation F having sufficient frictional resistance. At this time, by continuously providing a plurality of stress restraints 20 in the construction process, it can be utilized as auger of the drilling device in the drilling step of the drilling hole (H), the construction error according to the difference in diameter with the drilling hole (H) Can reduce the workability.

On the other hand, the construction method (FM) of the micro pile foundation (F) of the present invention is a hole forming step (S10), micro pile forming step (S20), micro pile insertion step (S30) and grout as shown in FIG. It may include a re-injection step (S40).

First, the drilling hole forming step (S10) is a step of forming the drilling hole (H) to a predetermined depth to pass through the soil layer (G1) of the ground (G) to the rock layer (G2). The drilling hole forming step (S10) is a casing (CS) by using a casing penetration step (S11) and a drilling mill to inject a casing (CS) to a lower portion of the ground (G) to form a base (F). It may include a drilling step (S12) for drilling the inside of the.

Generally, the fabricator may be an auger, but according to the embodiment, based on the spiral structure of the acupressure flange 23 formed by continuously providing a plurality of stress restraints 20 as shown in FIG. 7A. The auger can be used to replace the auger.

After the micro pile forming step (S20) is carried out in the center of the body portion 21, the through-hole 22 is formed so as to penetrate through, the acupressure flange 23 along the outer peripheral surface of the body portion 21 Is integrally formed, and the pile main body 10 is provided with at least one stress restrictor 20 having a pressure inclined surface 24 that is inclined to be inwardly downwardly formed on the outer circumferential surface of the acupressure flange 23. In this step, the file MP is formed. On the other hand, the micro pile forming step (S20) may include a stress restraint providing step (S21), a stress restraint positioning step (S22) and a stress restraint restraining step (S23).

Specifically, the step of providing the stress restraint (S21) is a step of penetrating the pile body 10 through the through hole 22 of the stress restraint 20, the stress restraint 20 is the body portion 21 It is bound to the pile body 10 via the through hole 22 formed in the center of the. On the other hand, it is preferable that a tread is formed on the inner circumferential surface of the through hole 22 and screwed with the tread 11 of the pile main body 10, and depends on the restraint nut 30 to be described later without forming a separate tread. It can also be bound.

The stress restraint positioning step (S22) which is carried out afterwards is a step of positioning the stress restraint 20 to correspond to the height of the rock layer G2. More preferably, the upper end of the acupressure flange 23 formed in the stress restraint 20 provided at the top may correspond to the height at which the rock layer G2 starts.

The soil layer G1 in which the frictional force is not calculated is a free field portion in which the stress restraint effect is hardly exhibited even when the stress is restrained by the stress restraint 20. Therefore, it is difficult to expect the frictional resistance to be improved in the fixing field. Therefore, since the stress restraint 20 is preferably located in the ground where the ground G is firm, the upper end of the acupressure flange 23 is positioned to correspond to the height at which the rock layer G2 starts, so that the frictional resistance may be improved. It becomes possible.

In some embodiments, the plurality of stress restrictors 20 may be provided to correspond to the height of the rock layer G2. The stress restraint 20 may be disposed so that a pitch is continuously formed, and a cylindrical spacer 40 may be provided between the stress restraints 20 to be spaced at a predetermined interval.

The cylindrical spacer 40 is preferably made of a telescoping structure so that its length can be flexibly changed, and after adjusting the length of the cylindrical spacer 40 to a specific length, the key coupling structure The length may be fixed to the relative length, it may be provided so that the pile body 10 penetrates.

In addition, the stress restraint restraining step S23 is a step of coupling the restraint nut 30 to the lower portion of the stress restraint 20. A support ring 50 in which a flange seating groove 51 is formed at a lower portion of the stress restraint 20 provided at the lower end of the pile body 10 to accommodate the acupressure flange 23 protruding downward from the body portion 21. Is provided, the restraint nut 30 may be coupled to the lower portion of the support ring 50.

On the other hand, the micro file insertion step (S30) is a step of inserting the micro file (MP) in the drilling hole (H). At this time, when the acupressure flange 23 of the stress restriction sphere 20 is formed along the outer circumferential surface of the body portion 21, and gradually formed in a spiral structure in the vertical direction, the hole (H) Since it is possible to insert and rotate in the process of providing a micro pile (MP) to the interference problem of the inner peripheral surface of the drilling hole (H) can be solved.

The grout material injection step (S40) is carried out after the step of curing by injecting the grout material (GR) into the hole (H). At this time, when the acupressure flange 23 is formed in a helical structure, the grout material (GR) can be easily injected along the spiral structure in the process of injecting the grout material (GR) after having a micro pile (MP) There is an advantage in construction and manufacturing does not need to form a separate injection hole.

The micro pile (MP) equipped with the stress restraint according to the present invention described above, the micro pile base (F) with improved frictional resistance and its construction method (FM), the person skilled in the art It will be appreciated that the present invention may be embodied in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the foregoing description, and the meanings of the claims and All changes or modifications derived from the scope and equivalent concept should be construed as being included in the scope of the present invention.

MP: Micro file 10: The file body
11: Tread 20: Stress Restraint
21: body part 22: through hole
23: Acupressure flange 24: Pressure inclined surface
30: Retaining nut 40: Cylinder type spacer
50: support ring 51: flange seating groove
F: Foundation GR: grout materials
G: Ground H: Hole
G1: Soil layer G2: Rock bed
FM: micro pile basic construction method
S10: drilling hole forming step S11: casing penetration step
S12: drilling step S20: micro pile forming step
S21: step for providing the stress restraint step S22: step for determining the stress restraint point
S23: step of restraint of stress constraint S30: step of inserting micro file
S40: grout material injection step

Claims (13)

The present invention relates to a micro pile (MP) embedded in the inside of the drilling hole H formed in the ground (G)
The pile body 10 having the tread 11 formed on an outer circumferential surface thereof is provided with at least one stress restraint 20 so as to correspond to the height of the rock layer G2, and the stress restraint 20 has a body portion 21. The through hole 22 is formed so that the pile body 10 penetrates at the center thereof, and the acupressure flange 23 is integrally formed along the outer circumferential surface of the body portion 21, and on the outer circumferential surface of the acupressure flange 23. The pressure inclined surface 24 which is inclined in a straight downward direction is integrally formed so as to be transferred to the grout material GR provided in the drilling hole H by converting the external load loaded from the upper portion in the horizontal direction. 23 is formed along the outer circumferential surface of the body portion 21, it is formed in a spiral structure by gradually changing the position in the vertical direction, and of the stress restraint 20 provided at the lower end of the pile body 10 The lower portion protrudes downward from the body portion 21 A support ring 50 having a flange seating groove 51 is provided to accommodate the flange 23, and a stress restraint member is provided in which a restraining nut 30 is coupled to a lower portion of the support ring 50. Micro files.
The method of claim 1,
The micro pile provided with the stress restrainer, characterized in that the restraint nut (30) is coupled to the lower portion of the stress restraint (20) provided in the pile body (10) to restrain the position of the stress restraint (20).
delete The method of claim 1,
The micro pile provided with the stress restrainer, characterized in that the acupressure flange 23 of the spiral structure integrally formed in the body portion 21 of the stress restraint 20 is configured to constitute a pitch. .
The method of claim 4, wherein
The pile main body 10 is provided with a plurality of stress restraints 20 so as to correspond to the height of the rock layer G2, so that the pitch of the acupressure flange 23 is continuous, and the pile main body 10 is provided. The micro file with the stress restrainer, characterized in that the restraint nut (30) is coupled to the lower portion of the stress restraint (20) provided at the bottom of the restraint to restrain the position of the stress restraint (20).
The method of claim 4, wherein
The pile body 10 is provided with a plurality of stress restraints 20 so as to correspond to the height of the rock layer G2, and a cylindrical spacer 40 is provided between the stress restraints 20. The micro pile provided with the stress restrainer, characterized in that the restraint nut 30 is coupled to the lower portion of the stress restraint 20 provided at the bottom of the pile body 10 to restrain the position of the stress restraint 20. .
delete The method of claim 1,
The stress restraint 20 provided at the top of the pile body 10 has a micro pile with stress restraints, which is positioned such that the upper end of the acupressure flange 23 corresponds to the height at which the rock layer G2 starts. .
The present invention relates to a micro pile foundation (F) in which a micro pile (MP) is provided inside a drilling hole (H) formed in the ground (G), and a grout material (GR) is injected into the drilling hole (H).
The micro pile MP is provided with at least one stress restraint 20 so as to correspond to the height of the rock layer G2 on the pile main body 10 having a tread 11 formed on an outer circumferential surface thereof. 20 is a through hole 22 is formed so that the pile body 10 penetrates in the center of the body portion 21, the acupressure flange 23 is integrally formed along the outer circumferential surface of the body portion 21, the acupressure The outer circumferential surface of the flange 23 is integrally provided with a pressurized inclined surface 24 inclined downwardly inward to be transferred to the grout material GR provided in the drilling hole H by converting the external load loaded from the upper portion in the horizontal direction. The frictional resistance between the grout material GR and the rock layer G2 is formed to be improved, and the acupressure flange 23 is formed along the outer circumferential surface of the body portion 21, and gradually changes in position in the vertical direction. Is formed in a structure, of the pile body 10 The lower portion of the stress restraint 20 provided at the end is provided with a support ring 50 formed with a flange seating groove 51 to accommodate the acupressure flange 23 protruding downward from the body portion 21, the support ring Micro pile foundation, characterized in that the restraint nut (30) is coupled to the lower portion of the (50).
Regarding the construction method (FM) of the micro pile foundation (F),
A punching hole forming step (S10) of forming a punching hole (H) at a predetermined depth to penetrate the soil layer (G1) of the ground (G) to reach the rock layer (G2);
A through hole 22 is formed in the center of the body portion 21 so that the pile body 10 penetrates. Acupressure flange 23 is integrally formed along the outer circumferential surface of the body portion 21. On the outer circumferential surface of) is provided integrally inclined pressure inclined surface 24 to be inward downward, the acupressure flange 23 is formed along the outer circumferential surface of the body portion 21, gradually changing the position in the vertical direction A stress restraint providing step (S21) through which the pile main body (10) passes through the through hole (22) by using at least one stress restraint (20) formed in a helical structure; A stress restraint positioning step of positioning the stress restraint 20 to correspond to the height of the rock layer G2; And a support ring 50 having a flange seating groove 51 formed therein so that the acupressure flange 23 protruding downward from the body portion 21 is received at a lower portion of the stress restraint 20 provided at the lower end of the pile body 10. And a stress restrainer restraining step (S23) for coupling the restraining nut (30) to the lower portion of the support ring (50).
Micro file insertion step (S30) for inserting the micro file (MP) in the drilling hole (H); And
Grout material injection step (S40) for curing by injecting grout material (GR) into the hole (H);
Micro file basic construction method comprising a.
The method of claim 10,
The drilling hole forming step (S10),
Casing intrusion step (S11) for injecting the casing (CS) to a lower position on the ground (G); And
Punching step (S12) for drilling the inside of the casing (CS) using the mill factory value;
Micro file basic construction method comprising a.
delete The method of claim 10,
The stress constraint positioning step (S22),
Micro pile foundation construction method characterized in that the upper end of the acupressure flange (23) formed in the stress restraint (20) provided in the uppermost position corresponding to the height of the rock layer (G2) start.

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