JP2995430B2 - Drilling equipment for steel pipe pile with excavator for steel pipe pile and construction method of steel pipe pile - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a large-diameter (2 m or more)
The present invention relates to a steel pipe pile excavator used when installing a steel pipe pile to a large depth, a drilling device equipped with the excavator, and a method of constructing a steel pipe pile using the device, and in particular, The present invention relates to a construction suitable for construction in an urban area without hammering or vibration placing.

[0002]

2. Description of the Related Art As is well known, steel pipe piles are widely used for foundations on which horizontal forces act such as port structures such as piers and dolphins, and abutments and piers because they provide a large horizontal resistance. Also, the pile length can be easily adjusted, the pile head can be easily processed, it can be easily connected to the upper structure, and it is lighter than concrete piles, so it is easy to transport and handle. From the point of view, the frequency of use as a pile is increasing more and more.

[0003] As a construction method of sinking such a steel pipe pile into the ground, there have conventionally been a construction method of hammering or shaking with a hammer, and a construction method of excavating the inside of a steel pipe and sinking the steel pipe pile. Are known.

[0004]

However, the above-mentioned conventional method for constructing a steel pipe pile has the following problems to be solved. In other words, in the above-mentioned construction method, (1) If the diameter of the steel pipe to be laid is large, the machine for installing the steel pipe pile becomes large, and the vibration and noise also increase. Almost impossible.
Further, a machine for setting a large-diameter (2 m or more) steel pipe pile by hammering or vibration driving has not yet been developed. (2) The deeper the construction depth and the larger the diameter of the steel pipe, the greater the resistance of the side surface of the steel pipe, making it difficult to settle the steel pipe pile by hammering or vibration.

[0005] In addition, the above-described construction method has the following problems in addition to the problems described in (1) and (2) above. (3) The deeper the construction depth, the higher the tower for supporting the steel pipe, and the greater the risk of falling. (4) Because it is impossible to excavate beyond the inner diameter of the steel pipe,
In the case of a hard earthen layer, the resistance to the ground outside is large, and the pile cannot be laid down.

[0006] The invention has been made in view of the above circumstances, without adversely affecting such noise and vibration in the surrounding environment, comprising a steel pipe piles for an excavator capable of sinking a steel pipe having a large diameter and large depth It is an object of the present invention to provide a drilling device for a steel pipe pile and a method for constructing a steel pipe pile.

[0007]

To achieve the above object, according to the solution to ## steel pipe piles drilling device according to claim 1 of the present invention, the steel pipe pile
Excavator, and a suspended support member for suspending and supporting the excavator,
While supporting and suspending the suspension support member, the steel pipe is
And an upper support mechanism for pressing downward.
The pile excavator is configured to have a size that can be inserted into a steel pipe, and has a frame that is suspended and supported from above through a long suspension support member, and an excavation unit that is supported by the frame. and, the drilling unit, composed of a base end portion to the frame a rod shape and a drilling arm that is supported in a freely swinging, and drilling head provided at the lower end of the excavating arm, further, to the frame a swinging mechanism for swinging the swing the excavating arm, and stretch in a radial direction of the steel tube, and a plurality of jack portions having movable wheels up and down in contact with the inner wall of the steel tube is provided, the excavation Arm to the above frame
A cylindrical outer cylinder supported to swing freely, and
With a rotating shaft that is rotatable around the axis on the side
And providing the excavating head on the rotating shaft,
The outer cylinder is provided with a rotation drive mechanism that drives the rotation shaft to rotate.
The upper support mechanism is disposed on the upper end surface of the steel pipe.
Pushing force transmitting material, and the pushing force transmitting material
A drive mechanism including a jack for pressing the steel pipe downward,
The pushing force transmitting member is provided to support the suspension support member.
And a suspension support member support mechanism for lifting and lowering
It was done .

[0008] A second aspect of the present invention is a steel pipe pile excavator .
An excavator; a suspending support member for suspending and supporting the excavator;
While supporting and suspending the suspension support member, lower the steel pipe.
And an upper support mechanism for pressing the steel pipe pile
Excavator is sized to fit inside a steel pipe.
Is supported from above by a long suspension support member.
Frame and a digging section supported by the frame.
The excavation part is rotatably supported by the frame.
A rotating body that rotates around its axis
And a plurality of rod-shaped excavating shafts
In both cases, some shafts out of multiple
It is configured to be able to expand and contract in the radial direction of the steel pipe.
The tube expands and contracts in the radial direction of the steel pipe, and
Multiple jacks with wheels that can move up and down in contact
The upper support mechanism is provided at the upper end of the steel pipe.
Force transmitting member arranged on a surface, and the pressing force transmitting member
Drive including a jack for pressing the steel pipe downward through
A mechanism and the pushing force transmitting member, and the suspension support
A suspension support member support mechanism for supporting and raising and lowering the member.
It is composed of

According to a third aspect of the present invention, there is provided a method for constructing a steel pipe pile.
A method of constructing a steel pipe pile to be installed at a large depth on the ground,
It is characterized by comprising the following steps. a. A tubular steel pipe is placed on the ground, and the tip of the steel pipe is
Pushing the part to a predetermined depth. b. The steel of the drilling rig for steel pipe piles according to claim 1 or 2.
The pipe pile excavator is lowered to a predetermined depth by the suspension support member.
And set the excavator for steel pipe pile at a predetermined position in the steel pipe.
Process. c. While excavating by the excavating part of the excavator,
Step of pushing. d. After pushing the steel pipe to a predetermined depth,
At the upper end of the suspension support member supporting the pile excavator,
Of the above steel pipe and
The process of adding the next steel pipe. e. After the step d, the steps c and d are sequentially repeated a predetermined number of times.
By returning, the suspension support member and steel pipe are added
A step of vertically pushing a predetermined number of steel pipes in a row.

The method for constructing a steel pipe pile according to claim 4 is described in claim 3.
In the construction method of the steel pipe pile described in the
When excavation becomes necessary, stop pushing the steel pipe and suspend it.
Push down the excavator for steel pipe piles while lowering the suspension members
It is characterized by

[0011] The method for constructing a steel pipe pile according to claim 5 is described in claim 4.
In the construction method of the steel pipe pile described,
When the shaved portion reaches below the bottom of the steel pipe, the lower part of the steel pipe
Is excavated to the outside of the steel pipe in the radial direction.
You.

[0012]

According to the first aspect of the present invention, there is provided a drilling device for steel pipe piles.
Excavation while swinging the excavation arm.
And by the drilling head at the tip of this drilling arm with steel pipe
Since the entire surface is excavated, conventional hammering or shaking
Excavator itself becomes large, as in the case of dynamic driving
In urban areas without vibration and noise
Construction becomes possible.

Further , the excavating arm is swung.
The lower part of the steel pipe by the drilling head, due to the radial direction of the steel pipe
It can be drilled to the outside. In addition, the jack part
Excavator steel pipe diameter by adjusting the stroke appropriately
Position easily and accurately.
The key part abuts the steel pipe inner wall up and down
The lifting and lowering of the excavator itself is performed smoothly.

Further , the outer cylinder of the excavating arm is swung and swung.
And rotate the rotating shaft with the drilling head
The drilling arc is rotated by rotating the drive
Easily achieve swinging of the rocking head and rotation of the drilling head
be able to.

Further, the steel pipe of the excavator is provided by the upper support mechanism.
You can freely adjust the vertical position inside
Even if the ground to be excavated is soft or hard,
Excavation at an optimal position can be easily realized.
In particular, when the ground is hard, stop pushing the steel pipe to
Pre-digging while pushing down only the excavator with the port steel pipe
Can greatly reduce the frictional force around the steel pipe
Therefore, the steel pipe can be easily laid down.

Also, the suspension support member is provided on the pushing force transmitting member.
Supported by the suspended support member support mechanism
When lifting the suspension support member, the jack member
Wheels move up and down in contact with the inner surface of the steel pipe. Therefore,
The excavator is used to support the suspension support member at a fixed position above the steel pipe.
Excavation work can be performed with the
Work.

[0017] In the drilling device for steel pipe piles of claim 2 ,
Since the excavation portion has the same configuration as a cutter of a so-called shield excavator, the excavation surface can be excavated uniformly, and the time required for excavation can be greatly reduced as compared with the excavator of the first aspect. it can. Also, by projecting a part of the shaft to the outside of the steel pipe, it is possible to excavate the steel pipe to the outside in the radial direction. Furthermore, the excavator itself is smoothly moved up and down by adjusting the stroke of the jack portion appropriately in the radial direction of the steel pipe of the excavator and by abutting the jack portion up and down on the inner wall of the steel pipe.

Further, the steel pipe of the excavator is provided by the upper support mechanism.
You can freely adjust the vertical position inside
Even if the ground to be excavated is soft or hard,
Excavation at an optimal position can be easily realized.
In particular, when the ground is hard, stop pushing the steel pipe to
Pre-digging while pushing down only the excavator with the port steel pipe
Can greatly reduce the frictional force around the steel pipe
Therefore, the steel pipe can be easily laid down.

Further , a suspension support member is provided on the pushing force transmitting member.
Supported by the suspended support member support mechanism
When lifting the suspension support member, the jack member
Wheels move up and down in contact with the inner surface of the steel pipe. Therefore,
The excavator is used to support the suspension support member at a fixed position above the steel pipe.
Excavation work can be performed with the
Work.

In the method for constructing a steel pipe pile according to claim 3 ,
Since the steel pipe was pushed while excavating inside the steel pipe, even if the diameter of the steel pipe to be laid was large,
Unlike a conventional hammering or driving by vibration, there is almost no vibration and noise, and construction in an urban area is possible. In addition, since the construction is performed while adding the support steel pipe and the steel pipe, the force for pushing the support steel pipe and the steel pipe downward by the upper support mechanism can be reliably obtained.
Even if the construction depth becomes deep, construction can be performed easily and reliably. In addition, construction is performed while adding the support steel pipe and the steel pipe, and the lower end of the steel pipe is pushed down to a predetermined depth by the upper support mechanism when the first steel pipe is sunk, avoiding the danger of falling down of the steel pipe can do.

In the method for constructing a steel pipe pile according to claim 4 ,
When the ground is hard and pre-digging is required, pre-digging is performed while pushing down only the excavator, so that the frictional force around the steel pipe can be significantly reduced, so that the steel pipe can be easily laid down even when the ground is hard Can be done.

In the method for constructing a steel pipe pile according to claim 5 ,
When the excavated part reached below the bottom of the steel pipe, the lower part of the steel pipe was excavated to the radial outside of the steel pipe,
Further, the steel pipe can be easily settled.

[0023]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 5 show an embodiment of a steel pipe pile excavator according to the present invention. FIG. 1 is an elevational sectional view showing a steel pipe pile excavator 30A together with a steel pipe 10 to be laid, and FIG. It is an arrow view along the BB line.

The excavator 30A for steel pipe piles has
The excavation part 32 is supported by the lower part of the frame 31 which forms a skeleton of 0A. As shown in FIG. 2, the cross section of the frame 31 has a circular shape whose diameter is smaller than the inner diameter of the steel pipe 10. The frame 31 will be further described. The frame 31 includes an upper ring 33, a middle ring 34, and a lower ring 35 which are coaxially arranged, and a plurality of quadrangular prisms connecting these rings 33, 34, 35, respectively. The connecting members 36, 36,... And the connecting members 37, 37,.

Inside the upper ring 33 of the frame 31, a horizontal member 38 having a cross shape is fixed to the upper ring 33, and further reinforced by reinforcing steel members 39 fixed to the connecting members 36. I have. The lower end of a cylindrical support steel pipe (suspension support member) 40 that suspends and supports the frame 31 is connected to the center of the horizontal member 38. The upper end of the support steel pipe 40 extends to the ground where the steel pipe 10 has started to be laid, and is supported by an upper support mechanism 70 described later so as to be able to move up and down.

The middle ring 3 of the frame 31
The excavation part 32 is attached to the center part of 4. That is, the excavation section 32 is mainly configured by an excavation arm 48 extending downward from the middle ring 34 and an excavation head 51 provided at a tip end (lower end) of the excavation arm 48. Is attached to the middle ring 34 so as to swing freely. The excavating arm 48 includes an outer cylinder 49 and the outer cylinder 49.
And an inner cylinder (rotary shaft) 50 coaxially and rotatably inserted around an axis. The lower end of the inner cylinder 50 projects slightly below the outer cylinder 49, and the excavation head 51 is attached to the lower end. The excavating head 51 is composed of a substantially hemispherical head main body 51a and a number of bits 51b fixed to the surface of the main body 51a. The upper end surface of the head main body 51a is attached to the inner cylinder 50. I have. On the other hand, as shown in FIG.
And a spherical bulging portion 52 is formed at the mounting portion.
At the center of the middle ring 34, a bearing portion 53 for slidably supporting the spherical bulging portion 52 along its spherical surface is formed. With the above configuration, the excavating arm 48 can swing freely about the spherical bulging portion 52.

Further, the inner cylinder 50 of the excavating arm 48 is configured to rotate around an axis, and the rotation driving mechanism 45 has the following configuration. That is, the outer cylinder 4
As shown in FIGS. 3 and 4, an outer cylinder top plate 49a that protrudes in a circular flange shape is provided at the upper end of the cylinder 9. On the other hand, the upper end of the inner cylinder 50 is connected to the outer cylinder top plate 49a.
Projecting slightly higher than the outer cylinder top plate 49.
As in a, it protrudes outward in a flange shape. However, the overhang is not as large as the outer cylinder top plate 49a, and a gear 54 is formed on the outer peripheral portion. Further, hydraulic motors 55, 55 are provided on the outer cylinder top plate 49a, and pinions 55a, 55a (FIG. 4) driven by the hydraulic motors 55, 55 mesh with the gear 53. The hydraulic motor 55 and the pinion 55a may be only one set. Based on the above configuration, by driving the hydraulic motor 55, the inner cylinder 50 rotates around its own axis via the pinion 55a, whereby the excavation head 51 rotates.

The lower ring 35 is provided with a swing mechanism 56 for swinging the excavating arm 48. That is, as shown in FIG. 3 and FIG.
b, 49b are provided.
b, 49b, telescopic rods 57a, 57 of two hydraulic cylinders 57, 57 disposed opposite to each other with the outer cylinder 49 interposed therebetween.
57a are respectively pin-connected. Then, by extending one telescopic rod 57 of these two hydraulic cylinders 57 and 57 and retracting the other telescopic rod 57a, the excavation arm 48 is moved in one direction (left and right) around the spherical bulge 52. ).

As shown in FIG. 5, the hydraulic cylinders 57, 57 are mounted on a rectangular frame-type front-rear moving frame 58 provided on the lower ring 35. Lower ring 3
5, two rail pillows 59, 59 as shown in FIG.
Are provided in parallel, and these rail pillows 59, 5
Rails 60, 60 are laid on the upper surface of 9, respectively. The rail 60,
Two wheels 61 (FIG. 3) are provided on each of the left and right sides to engage with and roll on the wheel. With this configuration, the back-and-forth moving gantry 58 can move in the front-back direction along the rail 60. Here, the extending direction of the rail 60 is perpendicular to the hydraulic cylinders 57, 57.

Further, the back-and-forth moving base 58 and the lower ring 3
., Two hydraulic cylinders 62, 62,... Extending in the longitudinal direction of the rail 60 are provided on both sides (FIG. 5). The lower ring 35 and each piston rod 62
The distal end of a is pin-connected to the front-rear moving frame 58, respectively. The front / rear moving frame 58 can be moved along the rails 60 by extending and retracting the piston rods 62a of the hydraulic cylinders 62. In the swing mechanism 56 having the above-described configuration, the excavation arm 48 is swung right and left by the hydraulic cylinders 57 and 57, while the hydraulic cylinders 57 and 57 are rotated.
The excavating arm 48 is moved forward and backward about the spherical bulging portion 52 by operating the cylinders 57 and 62 since the excavating arm 48 is provided on the front and rear moving base 58 which is swung back and forth by the hydraulic cylinders 62 and 62. It swings right and left.

As shown in FIGS. 1 and 2, the middle ring 34 is provided with four jack portions 63 extending radially outward from the middle ring 34 at equal intervals in the circumferential direction. . The jack portion 63 includes a telescopic arm 63a that can expand and contract in the radial direction of the steel pipe 10, and a wheel 64 is rotatably attached to a distal end of the telescopic arm 63a. The wheel 64 abuts on the inner wall of the steel pipe 10a by extending the telescopic arm 63a to position the frame 31 in the radial direction within the steel pipe 10 and to move the frame 31 up and down when the frame 31 is moved up and down.
The inner wall 0 is rolled to guide the frame 31 up and down. In this embodiment, the jack 63 is used.
Although four are provided, at least three or more may be provided without being limited to this.

As shown in FIG. 1, a sediment transport pipe 65a is attached to the lower end of the excavating arm 48 by a fixing bracket 66 with its opening close to the excavating head 51. The excavation arm 48
This is to lift the excavated earth and sand together with mud to the ground.

FIGS. 6 and 7 show an excavator 30B provided with the excavator 30A. Reference numeral 70 denotes a support steel pipe 40 for supporting and raising and lowering the same, and pressing the steel pipe 10 downward. The upper support mechanism installed at the upper end of the steel pipe 10 is shown. This upper support mechanism 70
In the figure, reference numeral 71 denotes a pushing force transmitting member, which is placed horizontally on the upper end surface of the steel pipe 10. The upper ends of the tension members 72, 72,... Made of, for example, PC steel are fixed to the outer end of the pushing force transmitting member 71. The lower ends of the tension members 72 are fixed to the ground around the steel pipe 10. Each of the tension members 72 is provided with a jack (PC jack in this case) 73 for tensioning the tension member. In this embodiment, these tension members
A drive mechanism is composed of the jack 72 and the jack 73.

Above the pushing force transmitting member 71, there is provided a support steel pipe support mechanism 74 for supporting and raising and lowering the support steel pipe 40. This support steel pipe support mechanism 74 has a pair of upper and lower gripping plates 75a, 75b and gripping plates 76a, 76b sandwiching the support steel pipe 40 from the left and right. The lower gripping plates 76a, 76b transmit the pushing force. It is fixed to the upper surface of the member 71. Two pressing jacks 77, 77 are provided between the paired (upper) gripping plates 75a, 75b, and by operating these pressing jacks 77, 77 (FIG. 8), a pair of gripping jacks is formed. The plates 75a and 75b approach and separate from each other to grip and release the support steel pipe 40. Similarly, two pressing jacks 78, 78 are provided between the other (lower) gripping plates 76a, 76b that form a pair, and by operating these pressing jacks 78, 78 (FIG. 7), the gripping plates 76a, 76b are operated. , 76b support steel pipe 40
The gripping / releasing is performed.

6 to 8 are provided between the upper gripping plates 75a and 75b and the lower gripping plates 76a and 76b.
Are provided, and by operating these upper and lower jacks 79 simultaneously, the upper grip plates 75a, 75b can be moved up and down in parallel. Has become.

In the support steel pipe support mechanism 74 having the above structure, when the support steel pipe 40 is raised, it is performed as follows. In a state in which the upper and lower jacks 79 are retracted, the support steel pipe 10 is gripped by the upper gripping plates 75a, 75b, and then the gripping plates 76a, 76
b is released and the upper and lower jacks 79 are extended to raise the support steel pipe 10 by one stroke of the jack. Next, the support steel pipe 40 is gripped by the gripping plates 76a and 76b, and then the gripping plates 75a and 75b are released. The support steel pipe 40 is raised by sequentially repeating the operation of retracting the upper and lower jacks 79.

When the support steel pipe is lowered, the support steel pipe 10 is gripped by the upper gripping plates 75a and 75b in the reverse operation, that is, in a state where the upper and lower jacks 79 are extended. 76a,
The support steel pipe 10 is lowered by one stroke of the jack by releasing the upper and lower jacks 79... After the release of the support steel pipe 40, and after the support steel pipe 40 is gripped by the gripping plates 76 a and 76 b, the gripping plates 75 a and 75 b are released. The operation of extending the upper and lower jacks 79... Is sequentially repeated to lower the support steel pipe 40.

The reference numeral 65b in FIG. 6 denotes a muddy water injection pipe. The muddy water injection pipe 65b and the earth and sand transport pipe 65a are connected to the earth and sand separation plant P via a power base D installed on the ground.

Next, a method of constructing a steel pipe pile using the steel pipe pile excavator B having the above configuration will be described. (1) First, as shown in FIG. 10, a steel pipe 10 is installed at a predetermined position on the ground. This is performed by suspending the steel pipe 10 using a normal crane. (2) Next, as shown in FIG. 11, the pushing force transmitting member 71 is installed on the distal end surface of the steel pipe 10, and the outer end of the pushing force transmitting member 71 has the upper end of the pulling members 72. And the lower ends of these tension members 72 are fixed to the ground. Thereafter, the pushing force transmitting member 71 is pressed downward by applying a tension to the tension members 72 by the PC jacks 73, whereby the lower end portion of the steel pipe 10 is pushed into the ground to a predetermined depth. By pushing the steel pipe 10 in this way, it is possible to avoid the danger of the steel pipe 10 tipping over, for example, where the ground is weak.

(3) Next, as shown in FIG. 12, the excavator 30A is lowered to a predetermined depth by the support steel pipe 40, and the excavator 30A is set at a predetermined position in the steel pipe 10. In this case, the support steel pipe support mechanism 74 is used to lower the excavator 30A inside the steel pipe 10. That is, first, the support steel pipe 40 is gripped only by the lower gripping plates 76a and 76b. For this purpose, the two pressing jacks 78, 78 may be retracted. The upper holding plates 75a, 75b are opened by extending the pressing jacks 77, 77, and in this state,
The upper and lower jacks 79 are simultaneously extended, thereby moving the upper grip plates 75a and 75b upward. Next, this time, the support steel pipe 40 is gripped by the upper gripping plates 75a, 75b, and the lower gripping plates 76a,
Release the gripping by the upper gripping plates 75a, 75b
Only the support steel tube 40 is held. If the upper and lower jacks 79 are simultaneously retracted in this state, the support steel pipe 40 is sent downward by the stroke, and the excavator 3
OA can be moved downward. Thereafter, the excavator 30A is sequentially sent downward by repeating the above operation, and the up and down position of the excavator 30A is adjusted.

When lowering the excavator 30A, the four jacks 63 are used to adjust the planar position of the frame 31 (position adjustment in the radial direction of the steel pipe 10). That is, before lowering the excavator 30A, the telescopic arms 63a of the jacks 63 are extended,
The wheel 64 provided at the distal end of the wheel abuts on the inner wall of the steel pipe 10. At this time, by appropriately adjusting the stroke of each telescopic arm 63a, the excavator 30A is positioned and fixed in the radial direction in the steel pipe 10. Also, since the wheels 64 of the excavator 30A are in contact with the inner wall of the steel pipe 10, the excavator 30A can move smoothly in the vertical direction, and the vertical position of the excavator 30A can be easily changed. Further, the support steel pipe 40 is pushed into
Supported by a support steel pipe support mechanism 74 provided at 71
When the support steel pipe 40 is raised and lowered,
Then, the support steel pipe 40 is supported at a fixed position above the steel pipe 10.
Will have. Therefore, the excavator 30A is reliably supported.
Excavation work can be performed in a state where it is done, and accurate excavation work can be performed.

(4) Next, after the excavator 30A is positioned as described above, as shown in FIG.
The steel pipe 10 is pushed in while excavating by the excavation part 32 of the excavator 30A. That is, by operating the excavating arm 48, the ground at the lower end of the steel pipe 10 is excavated. In the excavating arm 48, the excavating head 51 is rotated via the inner cylinder 50 by operating the hydraulic motors 55, 55. At the same time, the extensible rods 57a, 57a of the hydraulic cylinders 57, 57 attached to the outer cylinder 49 are alternately expanded and contracted alternately to swing the excavating arm 48 right and left around the spherical bulging portion 52. Further, the back-and-forth moving mount 58
Are moved back and forth on the rail 60 by repeatedly expanding and contracting the hydraulic cylinders 62. This allows
The excavation head 51 provided at the tip of the excavation arm 48 can excavate the entire cross section of the steel pipe 10. At the time of the excavation, the pipe 65b for injecting the muddy water into the steel pipe 10 is used.
The muddy water is injected from the ground, and the water level of the muddy water is kept high to prevent the collapse of the ground, so that the water pressure is always higher than the pressure of the excavated surface.

The excavated earth and sand is sent together with the muddy water through the sediment transport pipe 65a to a sediment separation plant P installed on the ground, where the muddy water is returned to the excavation hole (steel pipe 10) through the muddy water injection pipe 65b. Here, the lower end of the sediment transport pipe 65a is attached to the lower end of the excavation arm, and
Since the opening of “a” is close to the excavation head 51, the opening moves on the entire excavation surface in the same manner as the excavation head 51, so that the remaining of excavated earth and sand can be reliably reduced. .

With the above excavation operation, the steel pipe 10 is pushed into the ground as shown in FIG. To push the steel pipe 10 in, the PC jack 73 is used to pull the tension members 72, 7.
Are pressed, thereby pressing the pushing force transmitting member 71 downward. Thereby, the steel pipe 10 is press-fitted downward. At this time, if the support steel pipe 40 is gripped by the support steel pipe support mechanism 74, the excavator 30A is also pressed downward together with the steel pipe 10. Normally,
As described above, the steel pipe 10 and the excavator 30A can be simultaneously pushed in, that is, ground excavation and press-fitting of the steel pipe 10 can be performed simultaneously.

On the other hand, when the ground to be excavated is particularly hard and preliminary excavation is required, as shown in FIG.
Stop the 0 injection and perform only excavation. In this case, the excavator 30A is pushed down by pushing in the support steel pipe 40 using the support steel pipe support mechanism 74. Further, if necessary, when the excavating head 51 of the excavator 30A reaches below the bottom of the steel pipe 10, further excavation is performed to excavate the lower part of the steel pipe 10 to the outside in the radial direction of the steel pipe 10. In this case, the hydraulic cylinders 57, 62
Of the excavation head 51 by slightly increasing the stroke of
Moves to the outside of the steel pipe 10, so that the outside of the steel pipe 10 can be easily excavated. Further, when the ground to be excavated is soft, as shown in FIG. 9B, sediment is drawn into the steel pipe 10 to such an extent that the steel pipe 10 does not cause natural settlement. Then, the excavator 30A is set at this depth to perform excavation.

(5) Next, after the steel pipe 10 is pushed into a predetermined depth, the upper supporting mechanism 70 (the pushing transmission member 7) is pressed.
1, the tension member 72, the jack 73 and the support steel pipe support mechanism 74) are removed, and then, as shown in FIG.
The next support steel pipe 4 is provided at the upper end of the support steel pipe 40.
0 'is added, and then the next steel pipe 10' is added to the upper end of the steel pipe 10 as shown in FIG. In this state, the upper end of the support steel pipe 40 'is
0 'protrudes upward by a predetermined length.

Next, as shown in FIG. 17, the upper support mechanism 70 is installed again at the upper end of the steel pipe 10 ', and the steel pipe 10 is pushed in while being excavated by the excavation section 32 in the same manner as (4). (FIG. 18) and the above (5)
By repeating the process of adding the support steel pipes 40 and the steel pipes 10 in the same manner as described above, a predetermined number of the steel pipes 10 are continuously pushed up and down (FIG. 19). Thereafter, the excavator 30A is raised by raising the support steel pipe 40 by the support steel pipe support mechanism 74 (FIG. 2).
0) When the joint of the support steel pipe 40 reaches above the support steel pipe support mechanism 74, the joint is disassembled and the upper support steel pipe 40 is removed (FIG. 21). Further, the excavator 30A is continuously raised, and the support steel pipes 40 are sequentially removed.

When the disassembly and removal of all the supporting steel pipes 40 to be connected are completed and the excavator 30A reaches the uppermost position (FIG. 22), the excavator 30A and the upper support mechanism 70 are removed as an integral unit (FIG. 22). 23), move them to the next steel pipe pile or temporary storage (not shown) of the excavator. Thereafter, when the inside needs to be filled with concrete or the like from the viewpoint of strength or the like, a tremy pipe (not shown) is installed in the steel pipe 10, and concrete K is poured into the steel pipe 10 as shown in FIG. Set up. Although not shown, a reinforcing bar may be provided inside the steel pipe 10 as necessary.

According to the excavator 30B having the excavator 30A and the method of constructing a steel pipe pile using the excavator 30B, the following effects can be obtained. Since the steel pipe 10 is pushed in while excavating the inside of the steel pipe 10 by the excavator 30A, even if the diameter of the steel pipe to be laid is increased, the excavator is driven as in the conventional hammer driving or vibration driving. The construction itself can be performed in an urban area without increasing the size of the apparatus itself and with little vibration or noise. The construction is performed while the support steel pipe 40 and the steel pipe 10 are added together, and the force for pushing the support steel pipe 40 and the steel pipe 10 downward can be reliably obtained by the upper support mechanism 70. Therefore, even when the construction depth is deep, the application is easily and reliably performed . Can be engineered.

When the first steel pipe 10 is laid down, the lower end of the steel pipe 10 is pushed down to a predetermined depth by the upper support mechanism 70, so that the steel pipe 10 is overturned. Such dangers can be avoided. The vertical position of the excavator 30A in the steel pipe can be freely adjusted by the upper support mechanism 70, so that excavation at an optimum position for the construction of the steel pipe pile is easy even if the ground to be excavated is soft or hard. Can be realized. In particular, in the case of a soil layer or the like which is difficult to excavate in a normal method, the excavation can be performed while the pushing of the steel pipe 10 is stopped and only the excavator 30A is pushed down by the support steel pipe 40, that is, pre-digging can be performed. Can be easily installed. Further, if necessary, when the excavation head 51 of the excavation part 32 reaches below the bottom of the steel pipe 10 during the pre-digging, the lower part of the steel pipe 10 is excavated to the radial outside of the steel pipe 10. Therefore, the steel pipe 10 can be more easily laid down.

Since the excavated soil is fluid-transported by the excavated arm of the excavated portion 32, the excavated arm is provided with a lower end portion and the excavated earth transport pipe 65a extends on the ground. Therefore, even if the excavation depth becomes deep, the construction time is not greatly increased. The muddy water is introduced from the muddy water injection pipe 65b into the steel pipe 10, and the muddy water surface is kept high so as to always keep the muddy water pressure higher than the excavated surface pressure. Construction can be performed.

FIGS. 25 to 28 show a second embodiment of a steel pipe pile excavator according to the present invention. This excavator 30C for steel pipe piles is provided with an excavation part 32 at the lower part of a frame 31 similarly to the excavator 30A for steel pipe piles, and the configuration of the frame 31 and the excavation part 32 is the same as that of the excavator 30A. Is different from

The frame 31 'of the steel pipe pile excavator (hereinafter, abbreviated as "excavator") 30C is generally configured to have only the upper ring 33 in the frame 31 of the excavator 30A. It has become. The same components as those of the excavator 30A are denoted by the same reference numerals. This frame 31 'is also suspended and supported from above via a support steel pipe 40.

At the lower part of the frame 31 ', a bearing portion 8 is provided.
The excavation part 81 is rotatably provided through the “0”. As shown in FIG. 26, the excavation portion 81 includes a cylindrical rotating body 81a rotatably supported by the bearing portion 80,
It is provided at the lower end of the rotating body 81a and mainly includes four cross-shaped excavating shafts 82 extending horizontally outward (FIG. 28). Each of them has a number of bits 82a. Further, these four excavating shafts 82 rotate around a vertical axis together with the rotating body 81a. Further, these four excavation shafts 82 are usually slightly shorter than the inner diameter of the steel pipe 10 as shown in FIG. 26, and the two excavation shafts 82 'and 82' at the opposing positions are shown in FIGS. As shown in FIG.
The distal ends 82b, 82b are configured to extend and protrude outward from the outer diameter of the steel pipe 10.

When pre-digging is necessary, if the excavating shaft 82 of the excavator 30C reaches below the bottom of the steel pipe 10, if necessary, the tips 82b, 82b are extended to extend the The lower part of the steel pipe 10 is excavated to the outside in the radial direction of the steel pipe 10 by projecting outward from the diameter.

Further, as shown in FIG. 26, the earth and sand transport pipe 65a in the excavator 30C is disposed through the inside of the support steel pipe 40, and the excavation shafts 82.
Are branched into a plurality of conduits 65c... At the positions along the excavating shafts 82.
In this manner, by providing a plurality of earth and sand intake ports along the excavation shafts 82 and changing the distances from the respective center points, the intake ports draw circular orbits with the rotation of the excavation shafts 82. It can move and suck in all the earth and sand. Reference numeral 83 denotes a seabel joint, which prevents the earth and sand transport pipe 65a from being twisted or the like even when the excavating shaft 82 rotates.

Further, on the upper surface of the frame 31 ',
As shown in FIGS. 25 to 27, four jack portions 63 having the same configuration as that of the excavator 30A are provided at regular intervals in the circumferential direction by fixing members 85. The jack portion 63 extends the telescopic arm 63a so that the wheel 64 abuts against the inner wall of the steel pipe 10 to position the excavator 30C in the radial direction in the steel pipe 10, and to move the excavator 30C up and down. The inner wall of the steel pipe 10 is rolled to guide the excavator 30C up and down. A reaction force receiving member 8 for receiving a reaction force of the jacks 63 is provided at the center of the upper surface of the frame 31 '.
6 are fixed. Although four jacks 63 are provided in this embodiment, at least three or more jacks 63 may be provided.

Further, on the outer peripheral surface of the frame 31 ',
Four auxiliary jacks 84 having telescopic arms 84a projecting radially outward of the steel pipe 10 are provided at equal intervals in the circumferential direction. These auxiliary jacks 84 abut against the inner wall of the steel pipe 10 and support the frame 31 ′ by abutting against each other to prevent the rotation of the frame 31 ′ due to the rotational reaction force of the excavation section 81. Thus, the auxiliary jacks 84 are provided, and the jack portions 63 are further provided.
Are brought into contact with the inner wall of the steel pipe 10, whereby the rotation of the frame 31 'can be reliably prevented.

The excavator 30C is provided with the excavator 3
0A, the supporting steel pipe 40 is suspended and supported by the supporting steel pipe 40.
0, and a power base D and a sediment separation plant P are further provided to constitute a drilling rig as a whole.

The procedure for constructing the steel pipe pile by the excavator equipped with the excavator 30C is almost the same as that of the excavator 30A. According to the excavator 30C, since the excavation surface is uniformly excavated similarly to the cutter of a so-called shield excavator, the time required for excavation can be significantly reduced as compared with the excavator 30A. Shaft 8
The reaction force due to the rotation of 2 is supported by pressing the wheel 64 of the jack part 63 against the inner wall of the steel pipe 10 and by operating the auxiliary jack 64 to press the tip part against the inner wall of the steel pipe 10. Can be.

Further, the tip portions 8 of the shafts 82 ', 82'
By protruding the 2a and 82a, a portion below the steel pipe 10 can be pre-drilled larger than the outer diameter of the steel pipe 10. Thereby, the peripheral frictional force of the steel pipe 10 can be significantly reduced, and the steel pipe 10 can be easily laid down. At that time, the tip portions 82a,
In the state where 82a is extended, there is a portion where the excavation bit 81 does not exist on the shafts 82 'and 82'. However, since the excavation bit 81 of the other fixed shafts 82 and 82 excavates the portion, no excavation remains. . Needless to say, the effect obtained by using the excavator 30A described above can be obtained.

Further, in the above embodiment, when the steel pipe 10 is laid, the pushing force transmitting member 71 is placed on the steel pipe 10,
A tension member 72 is attached to the pushing force transmission member 71, and a tension is applied to the PC jack 73 to the tension member 72,
The pressing force transmitting member 71 was pressed downward, but the reaction force receiving member 87 was disposed above the pressing force transmitting member 10 as shown in FIG. 29, for example. A push-in jack 88 may be provided between the base member 71 and the reaction force receiving steel material 87, and the reaction force receiving steel material 87 may be anchored with a PC steel wire 89 or the like in order to obtain a downward force. Note that the reaction force receiving steel material 87 is not shown so as to not fall down when the jack is replaced, but the support S is performed by a steel material or the like. The pushing of the steel pipe 10 is performed by shrinking the jack 88 when the jack 88 is completely extended, setting the steel pipe 10 having a length corresponding to the contracted length of the jack 88, and pushing the steel pipe 10 by the jack 88 again. The steel pipe 10 can be easily attached by using a joint socket 90 or the like.

[0063]

As described in the foregoing, according to the steel pipe piles for drilling device according to claim 1 of the present invention, drilling arm frame is supported in a freely swinging swing, drilling head to the tip of the excavating arm Is provided, so that the entire surface inside the steel pipe can be easily and reliably excavated. Also, since the excavator itself is configured to have a size that can be inserted into the steel pipe, even if the diameter of the steel pipe to be submerged becomes large, the Can be constructed in an urban area without increasing the size and with almost no vibration and noise. Further, since the excavation arm swings and swings, the lower portion of the steel pipe can be excavated by the excavation head to the outside in the radial direction of the steel pipe. Further, by appropriately adjusting the stroke of the jack portion, it is possible to easily and accurately position the excavator in the radial direction of the steel pipe, and the wheel of the jack portion comes into contact with the inner wall of the steel pipe movably up and down. The excavator itself can be moved up and down smoothly. Also, press the suspension support member.
By the suspension support member support mechanism provided on the
Because it is supported and raised and lowered,
For this purpose, support the suspension support member at a fixed position above the steel pipe.
And Therefore, excavation is performed with the excavator securely supported.
Work can be performed and accurate excavation work can be performed.

[0064] Further, it consists of the drilling arm and the outer cylinder and rotatably provided rotation axis to the outer tube, provided with a rotation driving unit to rotate the rotary shaft to the outer cylinder provided with a drilling head to the rotating shaft Therefore, swinging of the excavation arm and swinging of the excavation head can be easily realized.

The steel pipe of the excavator is provided by the upper support mechanism.
You can freely adjust the vertical position inside
Even if the ground to be excavated is soft or hard,
Excavation at an optimal position can be easily realized.
Especially in the soil layer where it is difficult to drill
Stop pushing steel pipe and drill by support steel pipe
Excavation while pushing down only the machine, that is, pre-digging
Can greatly reduce the frictional force around the steel pipe.
Therefore, the steel pipe can be easily laid down.

According to the drilling device for steel pipe piles of the second aspect,
Like the so-called shield excavator cutter,
Since it is composed of a rotating body and multiple drilling shafts,
The drilling device according to claim 1, wherein the surface can be dug uniformly.
Drastically reduce the time required for excavation
Can be. Also, a part of the drilling shaft is
Because it is telescopic, a part of the shaft is outside the steel pipe.
Excavation to the outside in the radial direction of the steel pipe by projecting to the side
can do. In addition, the stroke of the jack
Adjust the position of the excavator in the radial direction of the steel pipe by making appropriate adjustments.
Can be performed easily and accurately, and
Dig because the hook abuts the inner wall of the steel pipe so that it can move up and down
The cutter itself can be moved up and down smoothly.

Further , the suspension support member is provided on the pushing force transmitting member.
Supported by the suspended support member support mechanism
Therefore, when raising and lowering the suspension support member,
The member will be supported at a fixed position above the steel pipe. Yo
Drilling work with the excavator securely supported.
Excavation work can be performed reliably. It is also excavated by the upper support mechanism.
It is possible to freely adjust the vertical position within the steel pipe of the milling machine.
It is possible to use steel pipes even if the ground to be excavated is soft or hard.
Easy excavation at the optimal position for pile construction
it can. In particular, such as the Dotan layer, which is difficult to excavate with ordinary methods
, Stop pushing the steel pipe and
Drilling while pushing down the excavator only,
Drilling can significantly reduce the frictional force around the steel pipe
And the steel pipe can be laid down easily.
You.

According to the method for constructing a steel pipe pile according to the third aspect, since the steel pipe is pushed in while excavating the inside of the steel pipe by the excavator, the conventional hammer driving method can be performed even if the diameter of the steel pipe to be submerged becomes large. Or, as in the case of casting by vibration, there is almost no vibration or noise, and construction in an urban area is possible. In addition, since the construction is performed while adding the support steel pipe and the steel pipe, the force for pushing the support steel pipe and the steel pipe downward by the upper support mechanism can be reliably obtained.
Even if the construction depth becomes deep, construction can be performed easily and reliably. In addition, construction is performed while adding the support steel pipe and the steel pipe, and the lower end of the steel pipe is pushed down to a predetermined depth by the upper support mechanism when the first steel pipe is sunk, avoiding the danger of falling down of the steel pipe can do.

[0069] According to the construction method of the steel pipe pile according to claim 4, when the ground is needed is hard予掘, since to perform予掘while pressing down only excavator to stop pushing the steel pipe In addition, the peripheral frictional force of the steel pipe can be greatly reduced, so that the steel pipe can be easily laid down even when the ground is hard.

According to the method for constructing a steel pipe pile according to the fifth aspect , when the excavated portion of the excavator for a steel pipe pile reaches below the bottom of the steel pipe, the lower part of the steel pipe is excavated to the outside in the radial direction of the steel pipe. As a result, the steel pipe can be easily settled.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing one embodiment of an excavator for steel pipe piles of the present invention.

FIG. 2 is a sectional view taken along line BB in FIG.

FIG. 3 is a longitudinal sectional view showing a swinging mechanism of the excavator according to the embodiment.

FIG. 4 is a view taken along the line CC in FIG. 3;

FIG. 5 is a sectional view taken along line DD in FIG. 3;

FIG. 6 is a cross-sectional view showing a drilling device provided with an excavator according to one embodiment.

FIG. 7 is a cross-sectional view illustrating a main part of an excavator equipped with an excavator according to one embodiment.

8 is a sectional view taken along line EE in FIG. 7;

FIG. 9 is a longitudinal sectional view showing positions of the excavator when the ground is hard and when the ground is soft.

FIG. 10 is a longitudinal sectional view showing a state where a steel pipe is placed on the ground.

FIG. 11 is a longitudinal sectional view showing a state where the lower end of the steel pipe is pushed into the ground.

FIG. 12 is a longitudinal sectional view showing a state where an excavator is set in a steel pipe.

FIG. 13 is a longitudinal sectional view showing a state where the excavator is excavating.

FIG. 14 is a longitudinal sectional view showing a state where the first steel pipe has been laid down.

FIG. 15 is a longitudinal sectional view showing a state where a support steel pipe is added.

FIG. 16 is a longitudinal sectional view showing a state where steel pipes are added.

FIG. 17 is a longitudinal sectional view showing a state where the upper support mechanism is set again.

FIG. 18 is a longitudinal sectional view showing a state where the excavator is excavating.

FIG. 19 is a longitudinal sectional view showing a state where the third and subsequent steel pipes have been laid down.

FIG. 20 is a longitudinal sectional view showing a state where the excavator is raised.

FIG. 21 is a longitudinal sectional view showing a state where a support steel pipe is being dismantled and removed.

FIG. 22 is a longitudinal sectional view showing a state where the excavator is pulled up to the uppermost part of the steel pipe.

FIG. 23 is a longitudinal sectional view showing a state where a predetermined number of steel pipes have been laid down.

FIG. 24 is a longitudinal sectional view showing a state in which concrete is poured into a steel pipe.

FIG. 25 is a cross-sectional view showing an excavator according to a second embodiment of the present invention.

26 is a sectional view taken along line FF in FIG. 25.

FIG. 27 is a longitudinal sectional view of the excavator showing a state where the excavation shaft is extended.

FIG. 28 is a sectional view taken along line GG in FIG. 27.

FIG. 29 is a longitudinal sectional view in the vicinity of the upper portion of a steel pipe for explaining another method of depositing the steel pipe.

[Explanation of symbols]

 Reference Signs List 10 steel pipe 30A, 30C steel pipe pile excavator 30B steel pipe pile excavator 31, 31 'frame 32, 81 excavator 40, 40' support steel pipe 45 rotation drive mechanism 48 excavation arm 49 outer cylinder 50 inner cylinder (rotating shaft) 51 Excavating head 52 Spherical bulging part 56 Swinging mechanism 63 Jack part 70 Upper supporting mechanism 74 Support steel pipe supporting mechanism 81a Rotating body 82, 82 'Excavating shaft

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Kenichi Nakagawa 1-3-2 Shibaura, Minato-ku, Tokyo Shimizu Corporation (72) Inventor Hiroyuki Kubo 1-2-3 Shibaura, Minato-ku, Tokyo Shimizu (56) References JP-A-3-233019 (JP, A) JP-A-54-119705 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) E02D 7 / 00 E21B 7/20

Claims (5)

(57) [Claims] An excavator for a steel pipe pile and a suspended support for the excavator.
A suspending support member that supports the suspending support member and
And an upper support mechanism that presses the steel pipe downward.
The excavator for steel pipe piles is configured to have a size that can be inserted into a steel pipe, and is supported by the frame from a frame suspended from above through a long suspension support member, and supported by the frame. and a drilling unit, and consists of the excavation, and excavation arm having a base end portion to the frame without a rod is movably supported swing, and drilling head provided at the lower end of the excavating arm ,
Further, the frame has a swinging mechanism for swinging the excavating arm and a wheel that expands and contracts in the radial direction of the steel pipe and that can move up and down in contact with the inner wall of the steel pipe. > Provide the number of jacks and attach the excavating arm to the frame
A cylindrical outer cylinder supported swingably by the
And a rotating shaft provided rotatably around the axis inside the
And the drilling head is provided on the rotating shaft.
The outer cylinder is provided with a rotation drive mechanism for rotating the rotation shaft.
Only it becomes and, the upper support mechanism, push disposed on the upper end face of the steel tube
Pushing force transmitting member, and the steel pipe via the pushing force transmitting member
Drive mechanism including a jack for pressing the
Provided on the force transmitting member, supporting the suspension
And a suspension support member supporting mechanism for lowering
Steel pipe for drilling and wherein the that. 2. An excavator for a steel pipe pile, and a suspended support for the excavator.
A suspending support member that supports the suspending support member and
And an upper support mechanism that presses the steel pipe downward.
The excavator for steel pipe piles has a size that can be inserted inside the steel pipe.
And is suspended from above via a long suspension support member.
Frame supported and excavation supported by the frame
The excavating part is rotatably supported on the frame.
A rotating body that is held and rotates around an axis, and
Consists of a plurality of rod-shaped excavating shafts extending flat outward
And some of the shafts
The steel pipe is configured to be able to expand and contract in the radial direction of the steel pipe.
The frame expands and contracts in the radial direction of the steel pipe, and
A plurality of jigs having wheels that can move up and down in contact with the inner wall
A jack portion is provided, and the upper support mechanism is provided with a pusher disposed on an upper end surface of the steel pipe.
Pushing force transmitting member, and the steel pipe via the pushing force transmitting member
Drive mechanism including a jack for pressing the
Provided on the force transmitting member, supporting the suspension
And a suspension support member supporting mechanism for lowering
Steel pipe for drilling and wherein the that. 3. A steel pipe in which a steel pipe pile is installed on the ground to a large depth.
A method for constructing a pile, comprising the following steps:
Steel pipe pile construction method. a. A tubular steel pipe is placed on the ground, and the tip of the steel pipe is
Pushing the part to a predetermined depth. b. The steel of the drilling rig for steel pipe piles according to claim 1 or 2.
The pipe pile excavator is lowered to a predetermined depth by the suspension support member.
And set the excavator for steel pipe pile at a predetermined position in the steel pipe.
Process. c. While excavating by the excavating part of the excavator,
Step of pushing. d. After pushing the steel pipe to a predetermined depth,
At the upper end of the suspension support member supporting the pile excavator,
Of the above steel pipe and
The process of adding the next steel pipe. e. After the step d, the steps c and d are sequentially repeated a predetermined number of times.
By returning, the suspension support member and steel pipe are added
A step of vertically pushing a predetermined number of steel pipes in a row. 4. A method for constructing a steel pipe pile according to claim 3.
When excavation is required due to the hard ground,
Stop pushing the suspension member down
Depressing excavator for steel pipe pile
Construction method. 5. The method for constructing a steel pipe pile according to claim 4.
The excavator of the steel pipe pile excavator reaches below the bottom of the steel pipe.
Excavated the lower part of the steel pipe to the outside in the radial direction of the steel pipe.
A method for constructing a steel pipe pile.