JP2016030925A - Pile driving method and pile - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pile driving method and a pile that may be constructed readily and at a low cost.SOLUTION: A pile driving method includes a preparation step in which a plurality of nozzles is installed on a tip of a steel tube pile 1, a driving step in which the steel tube pile 1 is driven, and a foot consolidation step in which foot protection work is provided for the steel tube pile 1. In the pile driving step, the steel tube pile 1 is driven until the tip reaches a prescribed depth, by vibrating the steel tube pile 1 using a vibration hammer H while spraying high-pressure water Wfrom the nozzle. In the foot consolidation step, a solidification material 2 is injected from the nozzle around the tip of the steel tube pile 1 that has reached the prescribed depth, while keeping the steel tube pile 1 fixed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a pile placing method and the pile.

As a method of placing steel pipe piles on hard ground, there is a water jet combined vibro hammer method (hereinafter referred to as “JV method”).
The JV method is a method of placing a steel pipe pile with a plurality of injection nozzles attached to the tip while injecting high-pressure water from the injection nozzles, cutting the ground or moving gravel blocks, etc., and applying vibration with a vibro hammer. It is.

  In the JV method, the supporting ground of the steel pipe pile may be reduced by loosening the surrounding ground of the steel pipe pile due to the injection of high-pressure water and the vibration caused by the vibro hammer.

  In the JV method, when it is desired to increase the support capacity of the steel pipe pile, it is common to inject a solidification material such as cement milk into the pile tip to solidify the steel pipe pile.

  For example, in Patent Document 1, after a steel pipe pile is driven to a certain depth by the JV construction method, a steel pipe pile is driven to a predetermined depth by injecting cement milk from an injection nozzle instead of high-pressure water. A placement method is disclosed.

  Further, in Patent Document 2, a steel pipe pile is driven to a predetermined depth by the JV method, and then a cement milk is injected from a spray nozzle while pulling up the steel pipe pile, and a pile is driven again to push the steel pipe pile to a predetermined depth. A method is disclosed.

Japanese Patent No. 3564497 Japanese Patent No. 3850802

  The method for placing a pile of Patent Document 1 uses cement milk to cut the ground, so that the amount of cement milk used is enormous and the construction cost is expensive.

  Moreover, since the placing method of the pile of patent document 2 includes the process of pulling up a steel pipe pile several times and setting it, there exists a possibility that a hole wall may collapse or a steel pipe pile may be damaged. In particular, in the case of slant piles, construction may be difficult.

  From such a viewpoint, an object of the present invention is to propose a pile placing method and the pile that can be easily and inexpensively constructed.

  In order to solve the above-mentioned problems, a pile driving method according to the present invention includes a preparation step of installing a plurality of nozzles at the tip of the pile, a driving step of driving the pile, and a consolidation of the pile. The pile setting step, and in the placing step, high pressure water is sprayed from the nozzle while applying vibration by a vibro hammer to the pile until the tip of the pile reaches a predetermined depth. And the solidifying step is characterized in that a solidifying material is injected around the tip of the pile that has reached the predetermined depth from the nozzle while the pile is stationary.

  In addition, it is desirable that the method for placing the pile further includes a step of performing test construction in advance and calculating a planned injection amount of the solidified material.

According to this pile driving method, the solidified material is injected in a state where the pile is placed after the tip of the pile has reached a predetermined depth, so that there is no risk that the hole wall will collapse, and high quality is easily achieved. Construction can be performed.
Moreover, since the construction of the solidified material can be performed with the planned injection amount, it is possible to suppress the material cost from rising.

As for the said pile, it is desirable for the branch jet pipe for attaching a nozzle to the front-end | tip to be piped.
Moreover, it is desirable that the branch jet pipe can be attached to and detached from the high-pressure hose.

  According to the pile placing method and the pile of the present invention, it is possible to place the pile easily and inexpensively.

(A)-(d) is sectional drawing which shows each construction step of the placement method of the pile of this embodiment. It is a figure which shows the steel pipe pile of this embodiment, Comprising: (a) is a perspective view, (b) is XX sectional drawing of (a). It is a schematic diagram for calculating the design injection amount of a solidification material, (a) is a longitudinal cross-sectional view, (b) is a plane cross-sectional view. (A) And (b) is a figure which shows the example of the measuring method of the filling length of a solidification material.

This embodiment demonstrates the case where a pile (steel pipe pile 1) is laid from the water surface to the water bottom, as shown in FIG.
The pile of this embodiment is a steel pipe pile 1. As shown in FIG. 2, a branch jet pipe 4 that can be attached to and detached from the high-pressure hose 5 is piped at the tip of the steel pipe pile 1.

As shown in FIG. 1, the steel pipe pile 1 is driven from the hoist ship C by a water jet combined vibro hammer method (JV method).
The steel pipe pile 1 is solidified by the solidifying material 2 in a state where the tip portion is inserted into the supporting ground.

As shown in FIG. 2, a plurality of nozzles 3, 3... For injecting high-pressure water and the solidified material 2 are installed at the tip of the steel pipe pile 1.
In this embodiment, a case where six nozzles 3, 3,... Are installed will be described, but the number of nozzles 3 is not limited.

The plurality of nozzles 3, 3,... Are attached to the distal end portion of the branch jet pipe 4, and are arranged at a predetermined interval with respect to the circumferential direction of the steel pipe pile 1.
The branch jet pipe 4 includes a main pipe 4a and branch pipes 4b, 4b, and 4b. In the present embodiment, the pair of branch jet pipes 4 are piped so as to face each other with the steel pipe 1 interposed therebetween, but the number and arrangement of the branch jet pipes 4 are not limited.

The branch pipe 4b is branched in two directions along the circumferential direction of the steel pipe pile 1 at one end of the main pipe 4a and the one branch pipe 4b extending in the axial direction of the steel pipe pile 1. Branch pipes 4b and 4b extending in the axial direction are provided.
In the present embodiment, the case where each branch jet pipe 4 includes three branch pipes 4b, 4b, and 4b will be described, but the number of branch pipes 4b is not limited. Further, the arrangement of the branch pipe 4b with respect to the main pipe 4a may be appropriately set according to the number of the branch pipes 4b.

The main pipe 4 a of the branch jet pipe 4 is detachably attached to the tip of the high-pressure hose 5 via a connecting jig 6.
The configuration of the connecting jig 6 is not limited. Further, the branch jet pipe 4 does not necessarily need to be detachably attached to the high-pressure hose 5.

  In addition, what is necessary is just to arrange | position the high pressure hose 5 and the connection jig | tool 6 as needed.

The nozzle 3 and the branch jet pipe 4 are fixed to the outer surface of the steel pipe pile 1 by welding. In addition, the fixing method of the nozzle 3 and the branch jet pipe 4 is not limited.
Moreover, in this embodiment, although the nozzle 3 is protected by the protection member 7, the protection member 7 should just be installed as needed.

Hereinafter, a method of placing the steel pipe pile 1 (pile placing method) will be described.
The pile placing method of the present embodiment includes an injection amount calculating step, a preparation step, a placing step, and a rooting step.

The injection amount calculation step is a step of performing test construction and calculating the planned injection amount of the solidified material 2.
Solidifying material 2 for filling the cut hole 8 and the steel pipe pile 1 Noto voids formed by cutting the ground G and support layer G _R, it varies by ground conditions and construction conditions.

Therefore, in this embodiment, the planned injection amount Q of the solidified material 2 corresponding to the field conditions is calculated by performing test construction.
In the present embodiment, cement milk is used as the solidifying material 2, but the material constituting the solidifying material 2 is not limited as long as the specific gravity is heavier than water.

First, the design injection amount Q ₀ of the solidified material 2 is calculated by Equation 1.
In Equation 1, A ₀ is the design filling cross-sectional area, L ₀ is the design filling length, D is the pile diameter, and T ₀ is the design filling thickness. Solidifying material 2 shall be injected at a thickness of each of the inside and outside of the steel pipe pile 1 T _0.

_{Q 0 = A 0 × L 0} ··· Formula 1
here,
_{A 0 = (D + T 0} × 2) 2/4 × π- (D-T 0 × 2) 2/4 × π

Next, test construction is performed and the actual filling length L is measured.
The test construction is performed by placing the steel pipe pile 1 and measuring the filling length L of the solidified material 2 based on the actual construction procedure described later.

  The method for measuring the filling length L is not limited. For example, a method of forming the boring hole 9 along the peripheral surface of the steel pipe pile 1 and measuring the filling length L based on the core sample obtained thereby ( 4) and a plurality of strain gauges 10, 10,... Are installed at a predetermined interval at the tip of the steel pipe pile 1, and a loading test is performed on the steel pipe pile 1, and the strain distribution of the steel pipe pile 2 is determined. May be performed by a method of measuring (see FIG. 4B) or the like.

  In addition, when a load is given to the axial direction of the steel pipe pile 1, as shown in FIG.4 (b), there exists a tendency for distortion to change a lot in the range solidified with the solidification material 2. FIG. Therefore, the filling length L can be estimated by ascertaining the measurement point at which the strain amount greatly changes.

  When the filling length L is measured, a planned injection amount Q corresponding to the raw ground G is calculated using the filling length L.

  As shown in FIG. 1 and FIG. 2, the preparation process includes installing a guide frame 11 at a place where the steel pipe pile 1 is placed, and a plurality of nozzles 3, 3. 4 is a step of installing 4.

The guide frame 11 is formed using a plurality of guide piles 12, 12,.
Shirubekui 12 while applying vibration by vibro-hammer H using a floating crane C, and Da設the ground G and the support layer G _R.
The guide frame 11 of this embodiment can hold the steel pipe pile 1 at a predetermined angle. That is, the steel pipe pile 1 is held by the guide frame 11 in an inclined state with respect to the vertical line.

The nozzles 3, 3,... (Branch jet pipe 4) are installed on the steel pipe pile 1 in advance on land.
When the installation of the guide frame 11 is completed, the high-pressure hose 5 is connected to the branch jet pipe 4 attached to the steel pipe pile 1, and the steel pipe pile 1 is arranged in the guide frame 11. The high-pressure hose 5 is extended from a pump P mounted on the hoist ship C.
In addition, the timing which attaches the nozzle 3 etc. to the steel pipe pile 1 and the place which performs attachment work are not limited.

Pouring step is a step of Da設nozzles 3,3, ... the steel pipe pile 1 installed within the ground G and the support layer G _R.
Pouring the steel pipe pile 1, as shown in shown in FIG. 1 (b) and (c), the nozzle 3,3 while applying vibration by vibro-hammer H, by injecting high pressure water W _J only tip ends of This is performed until the tip of the steel pipe pile 1 reaches a predetermined depth. In the present embodiment, pouring the steel pipe pile 1 to the tip portion of the steel pipe pile 1 is embedment in supporting layer G _R.

That, pouring the steel pipe pile 1, as well as cutting the ground G and support layer G _R by high-pressure water W _J, a steel pipe pile 1 while applying vibration by vibro-hammer H to the cutting hole formed by high-pressure water W _J pressed To do.
High pressure water W _J is pumped through the high pressure hose 5 from a pump P mounted on floating crane C.

Incidentally, the steel pipe pile 1 is Da設the ground G and the support layer G _R in a state inclined relative to the vertical line.
The pressure of the high pressure water W _J is appropriately set according to the strength of the ground G and the support layer G _R.

The root consolidation process is a process for solidifying the steel pipe pile 1.
The distal end portion of the steel pipe pile 1, After inserting a predetermined length in the supporting layer G _R, stops the vibro-hammer H, stops injection of the steel pipe pile 1.

Then, while maintaining the state in which position the steel pipe pile 1 (without moving the steel pipe pile 1 vertically), for injecting hardening agent 2 from the nozzle 3 in place of the high-pressure water W _J. The solidifying material 2 is injected only from the tip of the nozzle 3.
The solidified material 2 injected from the nozzle 3 is injected into the periphery of the tip of the steel pipe pile 1 (the outer periphery and the inner periphery of the steel pipe pile 1), as shown in FIG. The solidified material 2 discharged from the tip portion is filled while keeping the applied pressure from the tip of the steel pipe pile 1 through the inner and outer peripheries of the steel pipe pile 1 and the hole wall of the cutting hole 8 and expelling water from below to above. The Therefore, the gap between the inner and outer circumferences of the steel pipe pile 1 and the hole wall of the cutting hole 8 is substantially uniform over the circumference of the steel pipe pile 1. Furthermore, if cement milk having a higher specific gravity than water is used as the solidifying material 2, buoyancy acting on the steel pipe pile 1 can be expected to be substantially uniform.

The injection amount of the solidifying material 2 is the planned injection amount Q calculated in the injection amount calculation step.
The solidified material 2 is pumped from a plant (not shown) mounted on the hoist ship C via a pump P.

After injecting the solidified material 2 with the planned injection amount Q, the connecting jig 6 is operated in water to remove the high-pressure hose 5 from the branch jet pipe 4 and collect it.
The recovered high-pressure hose 5 is cleaned using a cleaning machine (not shown) and used for placing other steel pipe piles 1.

According to the pile placing method and the steel pipe pile 1 of this embodiment, since the solidification material 2 is injected in a state where the steel pipe pile 1 is fixed, it is possible to increase the pile tip support force and the pile peripheral surface friction force. .
Moreover, since the solidification material 2 is injected in a state where the tip of the steel pipe pile 1 has reached a predetermined depth, there is no fear that the hole wall of the cutting hole will collapse, and high-quality construction can be performed easily.

Moreover, in the case of the slant pile which pressurizes and injects using cement milk as the solidification material 2, a buoyancy can be anticipated with respect to the steel pipe pile 1, and the filling thickness is kept substantially uniform over the circumference of the steel pipe pile 1. Can do.
Therefore, the steel pipe pile 1 can be driven with high quality regardless of the ground conditions and the construction conditions.

Moreover, since the injection amount of the solidification material 2 is set based on the test construction, the pile tip support force and the pile peripheral surface friction force can be more reliably ensured.
In addition, by performing the construction of the solidifying material 2 with a pre-planned injection amount, the injection amount of the solidifying material 2 can be suppressed to a necessary minimum, and consequently, the material cost can be prevented from rising. .

Further, since the branch jet pipe 4 is arranged at the tip of the steel pipe pile 1, the branch jet pipe 4 can be manufactured in the same size without being affected by the length of the steel pipe pile 1, and the branch pipe is branched over the entire length. The amount of steel used can be reduced compared to the case where the pipe 4b is provided.
Since the branch jet pipe 4 can be separated from the high-pressure hose 5, the high-pressure hose 5 can be collected and diverted.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and the above-described components can be appropriately changed without departing from the spirit of the present invention.
For example, although the said embodiment demonstrated the case where it casts in the state which inclined the steel pipe pile 1, the steel pipe pile 1 does not necessarily need to incline.

Moreover, although the said embodiment demonstrated the case where the steel pipe pile 1 was constructed from the water surface to the water bottom using the hoist ship, the pile placing method of the present invention is suitable for construction from a pier or the like and construction on the ground. Can also be adopted.
Moreover, you may drive the steel pipe pile 1 using the pile driving ship provided with the guide.
The calculation of the planned injection amount of the solidified material may be performed as necessary and may be omitted.
The guide frame may be used as necessary and is not necessarily used.

The kind of pile to be placed by the pile placing method of the present invention is not limited to a steel pipe pile.
The injection range of the solidifying material is not limited and may be set as appropriate.

DESCRIPTION OF SYMBOLS 1 Steel pipe pile 2 Solidification material 3 Nozzle 4 Branch jet pipe 4a Main pipe 4a
4b branch pipes 5 high pressure hose 6 connected jig 7 protection member 8 cutting holes 9 borehole 10 strain gauge 11 Shirubewaku 12 Shirubekui A ₀ designed filling the cross-sectional area C floating crane D pile diameter G Ground G _R supporting layer H vibro-hammer L filled Long L ₀ Design filling length P Pump T ₀ Design filling thickness W _J High pressure water

Claims (4)

A preparation step of installing a plurality of nozzles at the tip of the pile;
A placing process for placing the pile;
A pile-setting method comprising: a root-setting step for root-setting the pile,
In the placing step, the pile is driven until the tip of the pile reaches a predetermined depth by spraying high-pressure water from the nozzle while giving vibration to the pile by vibro hammer,
In the root-solidifying step, a pile driving method is characterized in that a solidifying material is injected around the tip of the pile that has reached the predetermined depth from the nozzle in a state where the pile is placed.   The method for placing a pile according to claim 1, further comprising a step of performing test construction and calculating a planned injection amount of the solidified material. A pile for carrying out the pile placing method according to claim 1 or 2,
A pile having a branch jet pipe at the tip.   The pile according to claim 3, wherein the branch jet pipe is detachable from a high-pressure hose.

Images