KR101147510B1 - Complex pile with improved end bearing capacity and piling method of complex pile using the same - Google Patents

Abstract

PURPOSE: A composite pile with improved end bearing capacity and a construction method using the same are provided to be used in a downtown area by minimizing noise and vibration. CONSTITUTION: A composite pile(100) with improved end bearing capacity comprises a PHC pile(110) and an insertion pipe(130) for a support layer. The PHC pile has a shoe plate(111) and PC wires(112). The PC wires are coupled to the shoe plate and are tensed. Concrete is placed in the PC wires and cured. The insertion pipe is fixed to the shoe plate of the PHC pile and is placed on a support layer having rigid strength to improve end bearing capacity.

Description

Complex pile with improved end bearing capacity and piling method of complex pile using the same}

The present invention relates to a composite pile having a reinforced tip support, and more specifically, to form a support pipe for inserting the support layer at the tip of the PHC pile, inserted into a drilled hole drilled into the ground, the PHC pile When inserted into the support layer below the hole, the penetration resistance of the insertion pipe for supporting layer penetration is reduced, and the strength of the hole below the hole is settled on the rigid support layer by passing through the support layer where the strength is weakened below the hole. The present invention relates to a composite pile having a reinforced tip support to secure tip support and a method of embedding a composite pile using the same.

In general, concrete pile foundation construction methods are classified into PHC pile construction method for producing piles in the factory and on-site pile construction method for constructing and constructing piles in the field. Among them, the PHC pile method injects cement milk into the drilled hole drilled by using a drilling PHC pile method and a screw auger, which directly installs the PHC pile directly to the ground, and inserts the PHC into the drill hole. After inserting the pile, it can be divided into a built-in PHC pile method, where the hammer is put on the head of the PHC pile and cured.

The driving PHC pile method is divided into a method of directly hitting the PHC pile and a method of direct hitting after the excavation of the line, which has the advantage that the surrounding ground is firmly compacted due to the vibration caused by the strike of the PHC pile, thereby increasing the bearing capacity. Due to the high noise and vibration generated during construction, its use is limited in rural areas adjacent to urban centers and barns.

In order to suppress the noise and vibration problems generated during the construction of the PHC pile is used embedded PHC pile method, while the embedded PHC pile method is possible to install the PHC pile in a low noise, low vibration state compared to the driving PHC pile method, As the slime remains at the bottom of the drilling hole while drilling the drilling hole with a screw auger such as a screw auger, the strength of the lower part of the drilling hole is weaker than that of the ground due to the stress relaxation. In order to secure economic feasibility in terms of construction cost compared to bearing capacity, it is important to construct the pile method so that the tip bearing capacity of the PHC pile is improved.

In general, the tip bearing capacity (Q _p ) of the PHC pile is calculated as the product of the tip bearing force per unit area (q _p ) and the PHC pile tip area (A _p ) acting on the PHC pile tip, and the tip bearing force per unit area is It is calculated as the product of the vertical stress (σ _v ) acting on the tip of the PHC pile and the bearing factor (N _q ) determined by the internal friction angle of the soil on which the PHC pile tip is seated.

Q _p = q _p A _p = (σ _v N _q ) A _p

Therefore, in order to increase the tip bearing capacity of the PHC pile, the tip area (A _p ) of the PHC pile must be increased or the tip bearing force (q _p ) per unit area acting on the tip of the PHC pile must be increased. It can be raised by deepening the penetration depth of the pile or by seating the PHC pile tip on a rigid support layer.

Also recently, head extension concrete piles using reinforcement plates have been registered in Korean Patent No. 0661123 to improve the tip bearing capacity of embedded piles.

The pre-registered patent is to extend the tip area of the PHC pile by attaching a tip expansion reinforcement plate to the tip of the PHC pile, and the edge area in contact with the slime compressed by the slap is increased or the slime remains as it passes through the slime. The tip support area of the PHC pile can be improved by increasing the tip area in contact with the weakened support layer in the lower part of the perforated hole, but the resistance of penetration increases due to the increased tip area. It is not able to pass, but it is placed on the top of the compressed slime, and even when the PHC pile is driven, it is difficult for the tip expansion reinforcement plate to pass through the weakened support layer in the lower part of the drill hole in which the slime and the slime remain, to reach the rigid support layer under the drill hole. As a result, there is a limit to the improvement of tip bearing capacity. There was a problem that could not be.

In addition, the tip expansion reinforcement plate drives the PHC pile with very high energy so that the slime formed at the bottom of the drill hole and the weakened support layer under the drill hole where the slime remains can reach the rigid support layer under the drill hole. In this case, civil complaints occur as the noise and vibration increase during driving, which makes construction difficult in urban areas or in rural areas adjacent to barns.

In addition, since the PHC pile is inserted into the drilled hole, which is wider than the tip expansion reinforcement plate, the space between the outer diameter of the PHC pile and the inner diameter of the drilled hole is wider, which increases the amount of cement milk filled in the drilled hole. There was a problem falling.

In view of the above-described conventional defects, the object of the present invention is to attach a support layer penetration tube at the tip of the PHC pile and insert it into the drill hole, thereby reducing the resistance due to penetration during the hit. As a result, the insertion pipe for the support layer penetration passes through the weakened slime remaining in the drill hole and the lower strength of the lower drill hole in which the slime remains to reach the rigid support layer of the lower drill hole. In order to minimize the occurrence of vibration to provide construction in the city center is to provide a composite pile with a reinforced end support force and a method of embedding the composite pile using the same.

In addition, another object of the present invention, the insertion layer for the support layer penetration is inserted into the rigid support layer of the bottom of the drill hole in which the slime remains, and at the same time, the frictional force with the support layer is increased and the insertion tube for the penetration of the support layer is The present invention provides a method of embedding a composite pile having a reinforced tip support and a composite pile using the same, which may be blocked to improve the tip support of the PHC pile.

In addition, another object of the present invention, the insertion pipe for insertion of the support layer formed at the tip of the PHC pile is formed to be smaller than or equal to the outer diameter of the PHC pile is narrow space between the inner diameter of the drill hole and the outer diameter of the PHC pile is filled in the drill hole The amount of cement milk is reduced, the construction cost is reduced to provide an improved composite piles with reinforced tip support to improve the economics and the method of embedding the composite piles using the same.

The composite pile reinforced end support of the present invention,

A shoe plate is provided and is provided with a PC steel wire which is coupled to the shoe plate and is tense, and the concrete is poured onto the PC steel wire to be cured;

Inserted into the support layer penetration to be secured to the shoe plate of the PHC pile to pass through the slime remaining in the drill hole by the struck and the support layer weakened in the strength of the lower drill hole to be seated on the rigid support layer of the lower drill hole to strengthen the tip support It is characterized by including a tube.

In addition, the embedding method of the composite pile strengthening the tip bearing capacity of the present invention,

Forming a composite pile in which a support layer penetration tube is fixed to a shoe plate of a PHC pile;

Excavating the ground into which the composite pile is to be inserted with an excavation equipment to form a drill hole;

Filling cement milk into the boring hole and mixing it with the ground in the boring hole;

Inserting a composite pile into the drilled hole in which the cement milk and the ground are mixed;

The insertion layer for inserting the support layer of the composite pile into the perforated hole by passing through the weakened strength of the lower portion of the perforated hole in which the slime and the slime remain in the perforated hole of the compound pile is inserted into the perforated hole and the rigid support layer under the perforated hole Intruding into and seated in;

And curing the cement milk filled in the space between the outer circumferential surface of the composite pile inserted into the boring hole and the boring hole and the inner circumferential surface of the casing.

According to the present invention, after inserting the support layer penetration tube at the tip of the PHC pile and inserting it into the drill hole, the slime and slime in which the support layer penetration tube remains in the drill hole as the resistance due to penetration decreases at the time of struck. By passing through the weakened support layer in the lower part of the drilled hole, the strength of the lower part of the drilled hole is easily reached to the rigid support layer, thereby minimizing the occurrence of noise and vibration by the small struck energy and the small number of hits. Not only can it be installed, but it can also have the advantage of reducing air.

In addition, according to the present invention, the support layer penetration tube is inserted into the rigid support layer of the lower portion of the drill hole in which the slime remains, and at the same time, the frictional force with the support layer is increased, and the insertion tube for the support layer penetration is blocked by the internal soil. Since the tip bearing capacity of the PHC pile is improved, the user can not only improve the reliability of the product but also have the advantage of reducing the construction cost of the pile, thereby reducing the construction cost and improving the economics.

Further, according to the present invention, unlike the Patent No. 0661123 in which the amount of cement milk filled in the drilling hole is greatly increased by using the tip expansion reinforcement plate to improve the tip bearing capacity of the pile, the support layer formed at the tip of the PHC pile Since the penetration tube is formed to be smaller than or equal to the outer diameter of the PHC pile, the space between the inner diameter of the drilling hole and the outer diameter of the PHC pile is narrow, which reduces the amount of cement milk charged in the drilling hole, thereby reducing the construction cost and improving economic efficiency. You can have this advantage.

1 is an exploded perspective view of a first embodiment of the present invention
2 is a perspective view of a first embodiment of the present invention;
3 is a cross-sectional view of the first embodiment of the present invention.
4 is a sectional view of another embodiment of the first embodiment of the present invention;
5 is a cross-sectional view of another embodiment of the first embodiment of the present invention.
6 is a cross-sectional view of another embodiment of the first embodiment of the present invention.
7 is a perspective view of still another embodiment of the first embodiment of the present invention;
8 is a cross-sectional view of FIG.
9 is a perspective view of still another embodiment of the first embodiment of the present invention;
10 is a bottom view of FIG. 9
11 is an exploded perspective view of a second embodiment of the present invention;
12 is a perspective view of a second embodiment of the present invention;
13 is a cross-sectional view of the second embodiment of the present invention.
14 is a sectional view of another embodiment of the second embodiment of the present invention;
15 is a sectional view of yet another embodiment of a second embodiment of the present invention;
16 is a sectional view of yet another embodiment of a second embodiment of the present invention;
17 is a perspective view of still another embodiment of the second embodiment of the present invention;
18 is a cross-sectional view of FIG.
19 is a perspective view of still another embodiment of a second embodiment of the present invention;
20 is a bottom view of FIG. 19
21 to 22 is a construction process diagram of the first and second embodiments of the present invention
23 to 24 are embedded state diagrams of the composite pile according to the first and second embodiments of the present invention
25 to 26 are graphs of the loading test results of the composite pile according to an embodiment of the present invention

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

The composite pile 100, the tip support capacity of the present invention is reinforced, is provided with a shoe plate 111, is provided with a PC steel wire 112 is coupled to the shoe plate 111 to tension, the concrete is in the PC steel wire 112 PHC pile 110 that is poured and cured, is fixed to the shoe plate 111 of the PHC pile 110, the slime 12 and the hole hole 11 remaining in the drilling hole 11 by struck It includes a support layer penetration tube 130 to pass through the weakened strength of the support layer 13 and the strength of the lower portion of the perforation hole 11 is seated in the rigid support layer 14 to strengthen the tip support force, more Specifically, it is as follows.

The reinforcing member 140 is fixed to the upper end of the support layer penetration tube 130 and the shoe plate 111 to reinforce the support layer penetration tube 130.

At least one radially penetrating the upper end of the support layer penetration tube 130 is configured to further include a slime outlet 150 to discharge the slime (12).

The insertion layer reinforcing member is fixed to the inner surface of the support layer penetration tube 130 to prevent deformation of the support layer penetration tube 130 and to increase the blocking effect of the support layer penetration tube 130 by the internal soil. It further comprises 160.

The interpolated reinforcement member 160, the cross-section is preferably any one of the date (-) shape, cross (+) shape, * shape, # shape.

The support layer penetration insertion tube 130 is coupled to the reinforcing member 140 so that the space 150 'for the discharge of the slime 12 is formed between the support layer penetration tube 130 and the shoe plate 111. It further comprises a groove 141.

The support layer penetration tube 130 is preferably formed of a steel pipe, 'H' steel, '+' steel.

Preferably, the length of the support layer penetration tube 130 is formed to be 0.5 to 3 times the diameter of the drilled hole in the ground 10.

The diameter of the support layer penetration tube 130 is preferably larger than the diameter of the hollow portion of the PHC pile 110 and smaller than 1.2 times the outer diameter.

Next will be described the manufacturing process of the present invention composite pile 100 configured as described above.

First, as shown in FIG. 3, the shoe plate 111 is tensioned in the state where the end portion of the PC steel wire 112 is coupled to the coupling hole 111a of the shoe plate 111 and moved to the tension hole 111b. After moving to tension the PC steel wire 112, the concrete is poured and cured to form a PHC pile 110, the PHC pile 110 is formed by a conventional method.

Fixing the support layer penetration insertion tube 130 to the shoe plate 111 of the PHC pile 110 formed as described above, the support layer penetration insertion tube 130 is preferably fixed by welding with the shoe plate 111, As shown in FIG. 4, the inner surface of the support layer penetration tube 130 and the shoe plate 111 and the outer surface of the support layer penetration tube 130 and the shoe plate 111 may be reinforced by the reinforcing member 140. have.

Here, as shown in Figure 5, at least one or more slime outlet 150 may be formed radially on the upper end of the support layer penetration tube 130, as shown in Figure 6, for the support layer penetration In the state in which the slime discharge port 150 is formed in the insertion tube 130, the reinforcement member 140 may be reinforced. As shown in FIGS. 7 to 8, the coupling groove 141 of the reinforcement member 140 is provided. It is also possible to form a space 150 'for discharging the slime 12 between the support layer penetration tube 130 and the shoe plate 111 by combining the support layer penetration tube 130.

In addition, as shown in FIGS. 9 to 10, when the support layer penetration tube 130 is inserted into the support layer 14 having a rigid strength under the hole 11, the support layer penetration tube 130 is inserted. (-), (+), (*), () On the inner surface of the support layer penetration tube 130 so as to prevent the deformation and to increase the blocking effect of the support layer penetration tube 130 by the internal soil. #) The manufacturing of the composite pile 100 is completed while fixing the interpolated reinforcement member 160 which is one of shapes.

In addition, the composite pile 100 ′, the tip support of the present invention is reinforced, as shown in FIGS. 11 to 12, the shoe plate 111 is provided and is coupled to the shoe plate 111 to be tensioned with the PC steel wire 112. ) Is provided, and the PC steel wire 112 is formed by the concrete is cast PHC pile 110 is cured, and is fixed to the head of the insertion pipe 130 for the support layer penetration while the bolt (B) or the shoe plate 111 Prevents deformation of the support layer penetration insertion tube 130 by the hitting energy applied to the PHC pile 110 by welding, and inserts the insertion layer 130 for the tidal energy applied to the PHC pile 110. The connection plate 120 is configured to securely transfer to the support layer, which is fixed to the connection plate 120 and the strength of the slime 12 remaining in the drilling hole 11 and the lower hole of the drilling hole 11 due to stiffening ( 13) through the hole 11 is seated on the rigid support layer 14 of the lower strength of the perforation hole 11 to strengthen the tip support force It is configured to include a support layer penetration tube 130 so as to be described in more detail as follows.

The reinforcing member 140 is fixed to the upper end of the support layer penetration tube 130 and the connection plate 120 to reinforce the support layer penetration tube 130.

At least one radially penetrating the upper end of the support layer penetration tube 130 is configured to further include a slime outlet 150 to discharge the slime (12).

The insertion layer reinforcing member is fixed to the inner surface of the support layer penetration tube 130 to prevent deformation of the support layer penetration tube 130 and to increase the blocking effect of the support layer penetration tube 130 by the internal soil. It further comprises 160.

The interpolated reinforcement member 160, the cross-section is preferably any one of the date (-) shape, cross (+) shape, * shape, # shape.

The support layer penetration insertion tube 130 is coupled to the reinforcing member 140 so that the space 150 'for the discharge of the slime 12 is formed between the support layer penetration tube 130 and the shoe plate 111. It further comprises a groove 141.

The support layer penetration tube 130 is preferably formed of a steel pipe, 'H' steel, '+' steel.

Preferably, the length of the support layer penetration tube 130 is formed to be 0.5 to 3 times the diameter of the drilled hole in the ground 10.

The diameter of the support layer penetration tube 130 is preferably larger than the diameter of the hollow portion of the PHC pile 110 and smaller than 1.2 times the outer diameter.

The following describes the manufacturing process of the present invention composite pile 100 'configured as described above.

First, as shown in FIG. 13, the shoe plate 111 is tensioned in the state where the end portion of the PC steel wire 112 is coupled to the coupling hole 111a of the shoe plate 111 and moved to the tension hole 111b. After moving to tension the PC steel wire 112, the concrete is poured and cured to form a PHC pile 110, the PHC pile 110 is formed by a conventional method.

Fixing the connecting plate 120 to the head of the support layer penetration insertion tube 130 in close contact with the shoe plate 111 of the PHC pile 110 formed as described above, the support layer penetration insertion tube 130 is a connection plate ( It is preferable to be fixed by welding with 120, the connecting plate 120 must pass through the through-hole 121 in the same line with the coupling hole (111a) of the shoe plate 111.

When the connecting plate 120 is fixed to the head of the support layer penetration tube 130, the connecting plate 120 is in close contact with the shoe plate 111, the through-hole 121 and the shoe plate 111 of the connecting plate 120 Of the coupling holes 111a are connected in the same line and the bolt (B) is coupled to the through hole 121 of the connecting plate 120, and then rotated in one direction bolt (B) to the coupling hole (111a) The coupling plate 120 is tightly coupled to the shoe plate 111 by fastening, or the connection plate 120 is coupled to the shoe plate 111 by welding the connection plate 120 to the shoe plate 111. will be.

Here, as shown in FIG. 14, the inner surface and the shoe plate 111 of the support layer penetration tube 130 and the outer surface and the shoe plate 111 of the support layer penetration tube 130 are reinforced with the reinforcing member 140. 15, at least one slime discharge port 150 may be radially formed at an upper end of the support layer penetration tube 130, and as shown in FIG. 16, a support layer. It may be reinforced with the reinforcing member 140 in a state in which the slime discharge outlet 150 is formed in the insertion pipe 130 for penetration, and as shown in FIGS. 17 to 18, the coupling groove of the reinforcing member 140 ( 141 may be coupled to the support layer penetration tube 130 to form a space 150 ′ for discharging the slime 12 between the support layer penetration tube 130 and the shoe plate 111.

In addition, as shown in FIGS. 19 to 20, when the support layer penetration tube 130 is inserted into the support layer 14 having a rigid strength below the drilling hole 11, the support layer penetration tube 130 is inserted. (-), (+), (*), () On the inner surface of the support layer penetration tube 130 so as to prevent the deformation and to increase the blocking effect of the support layer penetration tube 130 by the internal soil. #) The manufacturing of the composite pile 100 'is completed while fixing the interpolated reinforcement member 160 which is one of shapes.

To buy the composite pile 100, 100 'produced by the above process to the ground 10, as shown in Figure 21 to 22, the ground to be inserted into the composite pile 100 (100') ( 10) to excavate with an excavation equipment to form a drilling hole 11, the drilling hole 11 is preferably formed to be 1.1 to 1.2 times the size of the outer diameter of the composite pile 100 (100 '), the drilling The slime 12 is formed in the bottom surface of the hole 11.

The thickness of the slime 12 is deeper than the depth of the drill hole 11, the smaller the strength of the ground 10 becomes thicker, using a drilling equipment such as screw auger 20 in the ground (10) When forming the (11), the area where the strength of the lower portion of the perforated hole 11 is weakened also depends on the type of support layer, so in weathered rocks, the strength is weakened from the bottom of the perforated hole 11 to about three times the diameter of the perforated hole 11. In the case of soft rock, the strength is weakened from the bottom of the drill hole 11 to about 0.5 times the diameter of the drill hole 11, so that the insertion pipe 130 for penetration of the support layer of the composite pile 100 and 100 'is suitable for the type of ground. Therefore, it is preferable that the length of 0.5 to 3 times the diameter of the drilling hole 11 is formed.

This is because when the length of the support layer penetration tube 130 is too short, the PHC pile 110 having a larger cross-sectional area and a larger penetration resistance than the support layer penetration tube 130 remains in the drilling hole 11. ), And because the slime 12 must pass through the support layer 13 in which the strength of the lower portion of the lower hole 12 is weakened, the energy consumption and the number of hits may be unnecessarily increased. When the length of the insertion tube 130 is too long, when the support layer penetration tube 130 is inserted into the rigid support layer 14 of the lower portion of the drilling hole 11, PHC pile 110 having a large cross-sectional area is This is because the tip support force may be reduced because the floating hole is not in close contact with the bottom of the drilling hole 11, and the material cost of the support layer penetration insertion tube 130 is expensive, which is uneconomical.

In addition, when the ground 10 is not viscous or has a low viscosity, such as sand, when excavating the drilling hole 11, the diameter of the PHC pile 110 to prevent the sediment of the inner surface of the drilling hole 11 to collapse Since the casing (11 ') of 1.1 to 1.2 times of the use, the diameter of the support layer penetration tube 130 is larger than the diameter of the hollow portion of the PHC pile 110, smaller than 1.2 times the outer diameter of the casing (11 ') It can be inserted inside.

The cement milk 30 is filled in the drilling hole 11 and the casing 11 ′, and the cement milk 30 is injected to be positioned at the front end portion of the drilling hole 11 and the casing 11 ′. The front end cement milk 31 and the main surface cement milk 32 to be injected so as to be located in the main surface portion can be injected separately, the front end cement milk 31 is the main surface cement to improve the end bearing capacity It is desirable to be able to maintain a higher strength than the milk 32.

When the composite pile 100, 100 'is inserted into the drilling hole 11 and the casing 11' filled with the cement milk 30 in the above process, the cement milk 30 is the composite pile 100 (100) It is moved into the space between the outer circumferential surface of ') and the inner circumferential surface of the drilling hole 11 and the casing (11') is filled.

When the composite pile 100 and 100 'inserted into the drilling hole 11 and the casing 11' is struck, the insertion pipe 130 for penetration of the support layer of the composite pile 100 and 100 'is drilled into the drilling hole. (11) and the strength of the lower portion of the drilling hole 11 through the slime 12 remaining in the casing 11 'and the lower support layer 13 of the lower portion of the drilling hole 11 in which the slime 12 remains. Is intruded into the rigid support layer 14.

At this time, the insertion layer reinforcement member 160 and the support layer penetration tube fixed in the shape of any one of the (-), (+), (*), (#) shape on the inner surface of the insertion layer penetration tube 130. When the 130 passes through the slime 12 and the support layer 13 in which the strength of the lower portion of the drill hole 11 is weakened, the intercalation reinforcement member 160 and the support layer penetration insertion of the inner surface of the support layer penetration tube 130 are inserted. The frictional force with the inner soil located in the tube 130 is expressed, and the effective friction area increases to increase the occlusion effect of the insertion layer 130 for the penetration of the support layer due to the internal soil, thereby leading to the end of the insertion tube 130 for the penetration of the support layer. Since the compaction of the ground and the surrounding ground becomes larger, it is possible to further increase the tip bearing capacity and the principal surface friction of the composite pile (100) (100 '), and when the PHC pile (110) is struck, the support pipe penetration tube (130) This can prevent the bending or deformation.

In addition, the slime 12 located in the support layer penetration tube 130 is discharged to the hollow portion of the center of the PHC pile 110 and at the same time the slime 12 not discharged to the hollow portion of the PHC pile 110 is for the support layer penetration. Since the slime discharge port 150 formed radially on the upper end of the insertion tube 130 and the space 150 ′ formed between the insertion tube 130 and the shoe plate 111 for penetration of the support layer are easily discharged into the drilling hole 11. As the support layer penetration tube 130 is filled with solid soil only, the stiffness of the soil is increased, and the support layer penetration tube 130 is hardened by the reduction of the penetration resistance. Easy to penetrate into (14), the friction between the inner soil of the support layer penetration tube 130 and the support layer penetration tube 130 increases, and the ground pressure between the soil and the shoe plate 111 of the PHC pile 110 Of the composite piles 100 and 100 ' Which it will be damaged.

In particular, when attaching the support layer penetration insertion tube 130 having a larger diameter than the PHC pile 110 to the tip of the PHC pile 110, by using a front end expansion reinforcement plate as shown in Patent No. 0661123 If the space 150 ′ is not formed between the 130 and the shoe plate 111, the ground pressure area between the distal end reinforcement plate and the inner soil of the support layer penetration tube 130 is increased to increase the composite pile 100 (100). The penetration resistance of ') increases, but when the space 150' is formed between the support layer penetration tube 130 and the shoe plate 111, the ground pressure is reduced only between the shoe plate 111 and the soil inside the pipe smaller than the tip expansion reinforcement plate. Because of this action, the penetration resistance of the composite pile 100 (100 ') is reduced, so that the insertion pipe 130 for penetration of the support layer easily penetrates into the rigid support layer 14, so that the cross-sectional area of the inner soil in which the tip bearing force is exerted is also increased. The tip bearing capacity can be improved.

Here, the connecting plate 120 of the composite pile 100 ′ is described as being coupled by the fastening of the shoe plate 111 and the bolt (B), but fixed by welding to connect the support layer 120 is fixed to the upper end of the support plate penetration Preventing the insertion tube 130 is deformed by the energy applied to the PHC pile 110, and can also efficiently transfer the energy applied to the PHC pile 110 to the support layer penetration tube 130, The reinforcing member 140 fixes the upper end of the support layer penetration tube 130 and the shoe plate 111 and the upper end of the support layer penetration tube 130 and the connecting plate 120 to support the insertion layer 130 of the support layer penetration. In addition to preventing the deformation by the energy applied to the PHC pile 110, it is also possible to efficiently transfer the energy applied to the PHC pile 110 to the support layer penetration tube 130.

In the above process, while the PHC pile 110 and the shoe plate 11 of the composite pile 100 and 100 ′ are in close contact with the bottom surface of the drilling hole 11, the insertion pipe 130 for penetration of the support layer penetrates the lower portion of the drilling hole 11. When the strength is penetrated and seated in the rigid support layer 14, the cement milk 31 for the tip is moved into the space between the outer circumferential surface of the composite pile 100, 100 'and the inner circumferential surface of the drilling hole 11 and the casing 11'. ) And the purchase process of the composite pile 100, 100 'by curing the cement surface 32 for the main surface is completed.

As shown in FIGS. 23 to 24, the insertion pipe 130 for penetration of the support layer of the composite pile 100 and 100 ′ is inserted into the support layer 14 having a rigid strength under the perforation hole 11 to be seated therein. , The tip support of the composite pile 100, 100 'is improved to be able to stably support the load acting on the top of the PHC pile 110.

In addition, as shown in Figures 25 to 26, as a result of performing two site pile loading tests to investigate the tip bearing capacity of the composite pile 100 (100 ') embedded as described above, PHC pile in weathered rock (110) The composite pile 100, 100 'with the support layer penetration tube 130 having a length 1 times the outer diameter is 100 compared to the PHC pile 110 without the support layer penetration tube 130 is attached. Composite pile 100 (100 ') having a support layer penetration tube (130) having a length of one and two times the outer diameter of the PHC pile (110) in the soft rock layer exhibited 1.5 times greater tip strength of the embedded pile. The composite pile 100 (100 ') is the installation of the pile because the tip support capacity of the embedded pile is 2 times and 2.8 times larger than the PHC pile 110 without the support layer penetration pipe 130 attached thereto. It can contribute to reducing construction costs by reducing the number.

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

100,100 ': Composite pile 110: PHC pile
120: connecting plate 130: insertion pipe for supporting layer penetration
140: reinforcing member 150: slime discharge port
150 ': space 160: interpolated reinforcement member

Claims (22)

A shoe plate is provided and is provided with a PC steel wire which is coupled to the shoe plate and is tense, and the concrete is poured onto the PC steel wire to be cured;
The hollow part of the PHC pile is fixed to the shoe plate of the PHC pile and passes through the slime remaining in the drill hole and the strength of the lower portion of the drill hole is weakened, and the strength of the lower portion of the drill hole is seated on the rigid support layer to strengthen the tip bearing force. Composite piles with reinforced tip support, characterized in that it comprises an insertion tube for supporting layer penetration is formed in a diameter larger than the diameter, less than 1.2 times the outer diameter.
A shoe plate is provided and is provided with a PC steel wire which is coupled to the shoe plate and is tense, and the concrete is poured onto the PC steel wire to be cured;
It is fixed to the head of the support layer penetration tube and is coupled to the shoe plate by bolts or welding to prevent deformation of the support layer penetration tube due to the stiffening energy applied to the PHC pile and to prevent the stiffening energy applied to the PHC pile. A connecting plate for securely transmitting to the insertion tube;
It is fixed to the connecting plate and passes through the slime remaining in the drill hole due to the stiffening and the support layer where the strength of the lower hole is weakened, and the strength of the lower hole is seated on the rigid support layer to strengthen the tip bearing force, so as to reinforce the tip bearing force. Composite piles with reinforced tip support, characterized in that it comprises a support layer penetration tube formed of a diameter larger than 1.2 times the outer diameter.
The method according to claim 1,
A composite pile having a reinforced tip support, characterized in that it further comprises a reinforcing member fixed to the upper end and the shoe plate of the support layer penetration tube for reinforcing the support layer penetration tube.
The method according to claim 2,
A composite pile having a reinforced tip support, characterized in that it further comprises a reinforcing member fixed to the upper end and the connecting plate of the support layer penetration tube for reinforcing the support layer penetration tube.
The method according to claim 1 or 2,
At least one radially penetrating radially through the upper end portion of the support layer penetration tube for discharging the composite pile further comprises a slime discharge port for discharging the slime.
The method according to claim 1 or 2,
It is fixed to the inner surface of the support layer penetration tube to prevent deformation of the support layer penetration tube, and further comprises an interpolated reinforcement member to increase the occlusion effect of the support layer penetration tube by the soil. Composite pile with reinforced tip support.
The method of claim 6,
The interpolated reinforcement member, the cross-section is a straight (-) shape, cross (+) shape, * shape, composite shape with reinforced tip support, characterized in that any one of the # shape.
The method according to claim 3 or 4,
Composite support reinforced end support is characterized in that it further comprises a coupling groove coupled to the support layer penetration tube to the reinforcing member to form a space for the discharge of the slime between the support layer penetration tube and the shoe plate.
The method according to claim 1 or 2,
Insertion pipe for the support layer penetration, composite piles reinforced tip support, characterized in that formed of steel pipes, 'H' section steel, '+' section steel.
The method according to claim 1 or 2,
The length of the insertion pipe for the penetration of the support layer, composite piles with reinforced tip support, characterized in that formed in 0.5 to 3 times the diameter of the drilled hole in the ground.
delete Forming a composite pile in which a support layer penetration tube is fixed to a shoe plate of a PHC pile;
Excavating the ground into which the composite pile is to be inserted with an excavation equipment to form a drill hole;
Filling cement milk into the drilling hole;
Inserting a composite pile into the drill hole filled with the cement milk;
The insertion layer for inserting the support layer of the composite pile into the perforated hole by passing through the weakened strength of the lower portion of the perforated hole in which the slime and the slime remain in the perforated hole of the compound pile is inserted into the perforated hole and the rigid support layer under the perforated hole Intruding into and seated in;
And a step of hardening cement milk filled in the space between the outer circumferential surface of the composite pile inserted into the boring hole and the inner circumferential surface of the boring hole and the casing.
Coupling a connection plate fixed to the head of the support layer penetration tube to the shoe plate of the PHC pile by bolts or welding to form a composite pile;
Excavating the ground into which the composite pile is to be inserted with an excavation equipment to form a drill hole;
Filling cement milk into the drilling hole;
Inserting a composite pile into the drill hole filled with the cement milk;
The insertion layer for inserting the support layer of the composite pile into the perforated hole by passing through the weakened strength of the lower portion of the perforated hole in which the slime and the slime remain in the perforated hole of the compound pile is inserted into the perforated hole and the rigid support layer under the perforated hole Intruding into and seated in;
And a step of hardening cement milk filled in the space between the outer circumferential surface of the composite pile inserted into the boring hole and the inner circumferential surface of the boring hole and the casing.
The method of claim 12,
Composite pile embedding method of strengthening the end support force is characterized in that it further comprises a reinforcing member fixed to the upper end and the shoe plate of the support layer penetration tube for reinforcing the support layer penetration tube.
The method according to claim 13,
The composite pile embedding method of claim 1, further comprising a reinforcing member fixed to the upper end of the support layer penetration tube and the connecting plate to reinforce the support layer penetration tube.
The method according to claim 12 or 13,
At least one radially penetrating radially through the upper end portion of the support layer penetration tube for discharging the composite pile buried method characterized in that it further comprises a slime outlet for discharging the slime.
The method according to claim 12 or 13,
It is fixed to the inner surface of the support layer penetration tube to prevent deformation of the support layer penetration tube, and further comprises an interpolated reinforcement member to increase the occlusion effect of the support layer penetration tube by the soil. Composite pile embedding method with reinforced tip support.
18. The method of claim 17,
The interpolated reinforcing member, the cross-section is a straight (-) shape, cross (+) shape, * shape, composite shape embedding method of reinforced tip support, characterized in that any one of the # shape.
The method according to claim 14 or 15,
Comprising the pile support reinforced reinforced tip characterized in that it further comprises a coupling groove coupled to the support layer penetration insert tube to the reinforcing member to form a space for the discharge of slime between the support layer penetration tube and the shoe plate Method.
The method according to claim 12 or 13,
Insertion pipe for the support layer penetration, composite pile embedding method with a reinforced tip support, characterized in that formed of a steel pipe, 'H' steel, '+' steel.
The method according to claim 12 or 13,
The length of the insertion pipe for the penetration of the support layer, composite pile embedding method of strengthening the tip support, characterized in that formed in the ground 0.5 to 3 times the diameter of the drilled hole.
The method according to claim 12 or 13,
The diameter of the insertion pipe for the penetration of the support layer is larger than the diameter of the hollow portion of the PHC pile, less than 1.2 times the outer diameter of the composite pile buried method reinforced reinforced support method.

Images