KR20200092090A - Double pile assembly for reducing negative skin friction - Google Patents

Abstract

Disclosed is a double pile assembly for reducing negative friction. The double pile assembly for reducing negative friction of the present invention includes: a single pile embedded in the ground; a steel pipe casing surrounding an outer surface of an upper portion of the single pile; and a filling material filled between the single pile and the steel pipe casing, wherein the filling material is made of bentonite powder. According to the present invention, provided is the double pile assembly for reducing negative friction, which is configured to suppress a reduction in the magnitude of negative friction force while deformation caused by the negative friction force is prevented.

Description

Double pipe pile assembly for reducing friction in the sub-surfaces{DOUBLE PILE ASSEMBLY FOR REDUCING NEGATIVE SKIN FRICTION}

The present invention relates to a double-pipe pile assembly for reducing friction in the sub-surface, and more specifically, to a double-pipe pile assembly for reducing friction in the sub-surface when the deformation caused by the friction in the sub-surface is prevented and the reduction in the size of the main surface friction is suppressed. It is about.

A pile is a pillar that is inserted into the ground, and the pile exposed on the ground is connected to the structure. Usually, a structure such as a bridge or a pier of a bridge in the water It is also used as part.

In this regard, in Korea Registered Utility Model Publication 240339, a double pipe spacer is posted. Utility Model Publication No. 240339 refers to the inner surface of the steel pipe surrounding the predetermined penetration depth of the pile to reduce the minor frictional forces acting on the main surface of the pile and the surrounding surface of the pile when the surrounding ground of the pile sinks. In the spacer for a double pipe forming a gap between, the one side is installed on the inner surface of the steel pipe and the other side is provided with a spacer between a pair of support portions, and a roll and a roll mounted between the pair of support portions are rotatably supported by the support portion It is characterized by consisting of a shaft pin.

Utility Model Publication No. 240339 uses a spacer with a roll installed, so that even when the steel pipe is settled, it moves in a rolling motion with the main surface of the pile, so the frictional force on the pile is reduced, so that the pile can stably support the upper structure. There is an advantage.

However, in the Utility Model Publication No. 240339, the spacer has one side installed on the inner surface of the steel pipe, and the other side is provided with a spacer having a pair of support parts, a roll mounted between the pair of support parts, and a pair of rolls on the support part. Since it is composed of an axial pin that is rotatably supported, the external force is forced to be concentrated on the axial pin that is rotatably supporting the roll, so that the axial pin is easily deformed and the function of the spacer is lost.

Republic of Korea Utility Model Publication No. 240339 (Registration date: 2001.07.18)

An object of the present invention is to provide a double pipe pile assembly for reducing sub-surface friction, wherein deformation due to the sub-surface friction force is prevented while reducing the size of the main surface friction force is suppressed.

The above object is, according to the present invention, the terminal pile embedded in the ground; A steel pipe casing surrounding the upper outer surface of the terminal pile; And a filling material filled between the terminal pipe and the steel pipe casing, and the filling material is achieved by a double pipe pile assembly for reducing friction when the sub-surface is made of bentonite powder.

The inner surface of the steel pipe casing may be formed to form a zigzag shape along the circumferential direction.

In order to prevent leakage of the filling material through the lower end of the steel pipe casing, an annular protrusion is formed on the outer surface of the terminal pipe, and even if the steel pipe casing descends due to frictional force, a frictional force is applied to the terminal pipe below the annular protrusion. It can be made to work.

An annular spacer is interposed between the terminal tube and the steel pipe casing above the annular projection, and a passage through which the filling material passes is formed in the annular spacer, and the annular projection and the annular spacer are spaced by an elastic member. It can be made as possible.

A filling re-casing is interposed between the terminal pipe and the steel pipe casing above the annular spacer, and the filling material is filled between the terminal pipe and the filling re-casing, even if the steel pipe casing descends due to frictional force, the steel pipe It may be made to prevent leakage of the filling material through the top of the casing.

According to the present invention, by filling the filling material between the terminal and the steel pipe casing, it is possible to provide a double pipe pile assembly for reducing friction in the sub-surface when the deformation due to the frictional force in the sub-surface is prevented and the reduction in the size of the main surface friction is suppressed. do.

1 is an installation state diagram of a double pipe pile assembly for reducing friction on a minor surface according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the double pipe pile assembly for reducing friction of the minor peripheral surface of Figure 1;
3 is an installation state diagram of a double pipe pile assembly for reducing friction on the minor surface according to another embodiment of the present invention.
Figure 4 is a cross-sectional view of the double pipe pile assembly for reducing friction of the minor peripheral surface of Figure 3;
Figure 5 is an installation state of the double pipe pile assembly for reducing friction of the minor surface according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

The double pipe pile assembly for reducing friction of the sub-surface of the present invention is made to prevent the reduction in the size of the main-surface friction while suppressing deformation due to the sub-surface friction.

1 is an installation state diagram of a double pipe pile assembly for reducing friction on a minor surface according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of a double pipe pile assembly for reducing friction on a peripheral surface of FIG. 1.

1 and 2, the double pipe pile assembly 10 for reducing friction of the sub-surface according to an embodiment of the present invention is prevented from being deformed by the sub-surface frictional force while suppressing the reduction in the size of the main-surface frictional force. It is made as possible, and is composed of a terminal tube 100, a steel pipe casing 200, and a filling material 300.

The terminal pile 100 is a structure that is supported on a structure by being embedded in the ground in a soft ground, and is made of a friction pile that supports a load by friction with surrounding ground. A friction pile refers to a pile in which pile ends of the foundation pile do not reach the hard ground (base) and are suspended in the soft ground, so that most of the supporting force depends on the frictional force around the pile.

In the case of no subsidence, the bearing capacity of the pile consists of the sum of the end bearing capacity at the bottom of the pile and the skin friction force caused by the friction between the pile and the ground.

However, when piles are typed on soft and compressible soils such as soft clay, soft silt, and peat, there is a possibility that the soils will sink more than piles. Sedimentation of the ground layer can be caused by lowering of the water level in the ground, melting of frozen soil, and consolidation by self-weight (settling caused by the escape of water in the gaps between soil particles). When the soil around the pile is settled, the main surface of the pile is pulled down, and an additional downward force, that is, a negative skin friction force is generated.

The phenomenon of dragging and dropping piles stops when the depth increases, which is called the neutral point. At the upper part of the neutral point (N), a downward force acts on the main surface of the pile. This additional downward force causes structural failure or additional settlement of the pile.

That is, the point called the neutral point (N) is a point where the subsidence of the ground (1) does not occur more, and the friction force exists when the sub-ship pulls the pile above the neutral point (N), and the neutral point (N) Below, if you give it like the ground (1) without settlement, the friction force acts. At this time, the supporting force is calculated by subtracting the frictional force from the sum of the tip supporting force and the main surface frictional force, and the supporting force is lowered compared to the case of the ground (1) without settlement.

As shown in Figures 1 and 2, the steel pipe casing 200 is a configuration that receives the frictional force of the sub-plane instead of the terminal 100, forms a shape surrounding the upper outer surface of the terminal 100. 1(a), 3(a) and 5(a) show an example in which the lower end of the steel pipe casing 200 coincides with the neutral point N for easy understanding of the present invention.

Filling material 300 is configured to suppress the formation of friction between the terminal tube 100 and the steel pipe casing 200, and is filled between the terminal tube 100 and the steel pipe casing 200 during pile construction. Filling material 300 is made of bentonite (bentonite) powder. Bentonite powder serves to reduce the coefficient of friction between the terminal tube 100 and the steel pipe casing 200.

FIG. 1(b) shows a case in which soil around the pile assembly 10 is settled. At this time, a downward force, that is, a negative skin friction force, is generated on the main surface of the pile assembly 10 from above the neutral point N.

As described above, the steel pipe casing 200 is installed in a form surrounding the upper outer surface of the terminal pile 100. Therefore, the frictional force on the sub-surface acts only on the steel pipe casing 200, and only the steel pipe casing 200 is settled along with the surrounding ground 1. Therefore, the terminal pile 100 maintains the same supporting force as the ground 1 without settlement.

After the construction is completed, the bentonite powder changes to a gel state (water content of 2000% or more) while absorbing moisture from the surrounding ground (1). Accordingly, the bentonite powder serves as a lubricant to reduce friction between the terminal tube 100 and the steel pipe casing 200. That is, since the bentonite powder changed to a gel state is slippery, even if the steel pipe casing 200 sinks, it does not affect the terminal 100.

2, the inner surface of the steel pipe casing 200 forms a zigzag shape along the circumferential direction. Therefore, even if the steel pipe casing 200 and the terminal pipe 100 are in contact due to the partial horizontal force action when the surrounding ground 1 subsides, the terminal pipe 100 and the steel pipe by the zigzag type inner surface of the steel pipe casing 200 The contact surface between the casings 200 is reduced to minimize frictional force formation.

3 is an installation state diagram of a double pipe pile assembly for reducing friction on a minor surface according to another embodiment of the present invention, and FIG. 4 is a cross-sectional view of a double pipe pile assembly for reducing friction on a peripheral surface of FIG. 3.

As shown in FIG. 3, in the double pipe pile assembly 20 for reducing friction of the minor circumferential surface according to another embodiment of the present invention, an annular protrusion 110 may be formed on the outer surface of the terminal pile 100. The ground 1 under the annular projection 110 forms an additional support force that supports the annular projection 110 upwards.

At the lower end of the steel pipe casing 200, the annular protrusion 110 and the inner surfaces of the steel pipe casing 200 form a fine gap. Therefore, leakage of the filling material 300 through the lower end of the steel pipe casing 200 is prevented. Although not shown, a sealing member may be interposed between the annular protrusion 110 and the inner surface of the steel pipe casing 200.

As shown in Figure 1 (b), the double pipe pile assembly 10 for reducing friction on the minor surface according to an embodiment of the present invention, the steel pipe casing (200) during settlement of the ground (1) around the pile assembly (10) ) As the area covering the main surface of the terminal pile 100 increases below the neutral point (N), the frictional force of the main surface acting on the terminal pile 100 decreases in proportion to the distance the steel pipe casing 200 descends. Is done.

As shown in FIG. 3, the double pipe pile assembly 20 for reducing friction of the minor surface according to another embodiment of the present invention is formed by forming an annular protrusion 110 on the outer surface of the terminal pile 100, thereby making the steel pipe casing ( Even if 200) descends due to the frictional force, the ground 1 is provided between the terminal pile 100 and the steel pipe casing 200 below the annular protrusion 110, so that the terminal stake (110) is located below the annular protrusion 110. The main surface frictional force acting on 100) is maintained, as well as the additional support force of the soil under the annular projection 110 supporting the annular projection 110 upward.

3 and 4, an annular spacer 400 is interposed between the terminal stem 100 and the steel pipe casing 200 above the annular protrusion 110. The annular spacer 400 is configured to form a gap between the terminal tube 100 and the steel pipe casing 200, and is coupled to the terminal tube 100 or the steel tube casing 200. The annular spacer 400 is formed with a passage 401 through which the filling material 300 passes.

5 is an installation state diagram of a double pipe pile assembly for reducing friction on a minor surface according to another embodiment of the present invention.

As shown in FIG. 5, the double pipe pile assembly 30 for reducing friction of the minor surface according to another embodiment of the present invention, the terminal pipe 100 and the steel pipe casing 200 from above the annular spacer 400 A filling re-casing 600 may be interposed therebetween.

Filling material casing 600 is a configuration that prevents the leakage of the filling material 300 through the upper end of the steel pipe casing 200, and is formed between the terminal pipe 100 and the steel pipe casing 200 by forming a pipe shape. The filling material 300 is filled between the terminal tube 100 and the filling material casing 600 from the top of the annular spacer 400.

The annular protrusion 110 and the annular spacer 400 are spaced by the elastic member 500. That is, the annular spacer 400 is not coupled to the terminal tube 100 and the steel pipe casing 200. The elastic member 500 is provided as a compression spring and may be interposed between the annular protrusion 110 and the annular spacer 400.

As shown in Figure 3 (b), the double pipe pile assembly 20 for reducing friction of the minor surface according to another embodiment of the present invention, the filling material 300 during settlement of the ground (1) around the pile assembly 20 A (in proportion to the distance the steel pipe casing 200 descends) has the disadvantage of leaking through the top of the steel pipe casing 200.

As shown in FIG. 5, the double pipe pile assembly 30 for reducing friction of the minor surface according to another embodiment of the present invention, the terminal pipe 100 and the steel pipe casing 200 from above the annular spacer 400 Since the filling re-casing 600 is interposed between the steel pipe casing 200 and the steel pipe casing 200 is lowered by frictional force, as the vertical spacing of the annular protrusion 110 and the filling re-casing 600 is maintained, the pile assembly 30 When the surrounding ground 1 sinks, leakage of the filling material 300 through the upper end of the steel pipe casing 200 is prevented (suppressed).

5(b) and 5(c) show that when the steel pipe casing 200 descends, the annular spacer 400 descends somewhat due to the frictional force between the steel pipe casing 200 and the annular spacer 400, and then the elastic member 500 It shows the state of rise again by resilience.

According to the present invention, by filling the filling material between the terminal and the steel pipe casing, it is possible to provide a double pipe pile assembly for reducing the friction of the secondary surface, which is prevented from being deformed due to the frictional force of the secondary surface, while reducing the size of the frictional surface. do.

In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and it is common knowledge in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: pile assembly
100: terminal block 400: annular spacer
110: annular projection 401: passage
200: steel pipe casing 500: elastic member
300: filling material 600: filling material casing
1: Ground
N: neutral point

Claims (5)

Terminal stakes embedded in the ground;
A steel pipe casing surrounding the upper outer surface of the terminal pile; And
It includes a filling material filled between the terminal pipe and the steel pipe casing,
The filling material is a double tube pile assembly for reducing friction in the subsurface, characterized in that it is made of bentonite (bentonite) powder. According to claim 1,
The inner surface of the steel pipe casing is a double pipe pile assembly for reducing friction in the minor circumferential surface, characterized in that a zigzag shape is formed along a circumferential direction. According to claim 1,
To prevent leakage of the filling material through the lower end of the steel pipe casing, an annular protrusion is formed on the outer surface of the terminal pipe,
Even if the steel pipe casing is lowered by the frictional force on the secondary surface, a double pipe pile assembly for reducing secondary surface friction is characterized in that a main surface frictional force acts on the terminal stem below the annular protrusion. According to claim 3,
An annular spacer is interposed between the terminal tube and the steel pipe casing above the annular projection,
A passage through which the filling material passes is formed in the annular spacer,
The annular projection and the annular spacer is a double pipe pile assembly for reducing friction on the minor circumferential surface characterized in that the gap is maintained by the elastic member. According to claim 4,
A filling re-casing is interposed between the terminal tube and the steel pipe casing above the annular spacer,
The filling material is filled between the terminal and the filling material casing,
Even if the steel pipe casing is lowered by the frictional force of the secondary pipe casing, the double pipe pile assembly for reducing secondary surface friction characterized in that the leakage of the filling material through the upper end of the steel pipe casing is prevented.

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