JP2009002056A - Existing pile removing method and apparatus for use therein - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an existing pile removing method which facilitates the removal of an existing pile embedded in the ground and having a long length and heavy weight. <P>SOLUTION: A casing 2 having an excavating blade 1 for excavating the periphery of the existing pile 30 embedded in the ground G<SB>1</SB>is rotatively lowered by a casing rotating and lifting gear 6 to carry out excavation down to a predetermined depth. Then an existing pile cutting blade 3 arranged at the lower end 2a of the casing 2 is protruded from the internal surface of the lower end 2a to cut the existing pile 30, and a portion of the existing pile 30 above a cut section by the existing pile cutting blade 3 is gripped by a glave 78 of a gripping device 77 having the glave 78 that is hung from a crane and carries out opening/closing operation. Then the portion is taken away from an upper opening 80 of the casing 2, and thereafter the casing 2 is rotatively lowered. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an existing pile removing method and apparatus, and more particularly, to an existing pile removing method and apparatus for removing unnecessary piles buried in the ground.

  When rebuilding a building structure, it is necessary not only to dismantle and remove the old building structure, but also to remove the existing piles that are buried in the ground. Existing piles driven into the ground are firmly fixed to the ground for many years, and a huge pulling force is required to pull them out. Conventionally, when such an existing pile is pulled out and removed, the casing is rotated by an auger machine that moves up and down along the leader of the pile puller, and then the existing pile is excavated to the vicinity of its tip. A wire was tied to the upper end of the wire and pulled out by a crane.

However, the above method has a problem that the crane cannot withstand the weight of the existing pile when the length and weight of the existing pile become large. Moreover, it is necessary to make the casing attached to the pile puller and the pile puller larger, and there is a problem in that the cost required for pulling and removing the existing pile increases.
Therefore, conventionally, various existing pile removing devices and methods thereof have been proposed in order to enable drawing and removing such an existing pile having a large length and weight (see, for example, Patent Document 1).
In patent document 1, after excavating the circumference | surroundings of the existing pile with a casing, a wire saw apparatus is inserted in the space formed between the existing pile and the casing, and the existing pile is made predetermined length from the upper part with the wire saw apparatus. The existing pile removal method and its apparatus which are divided and removed by drawing are disclosed.
JP 2001-262570 A

However, the existing pile removing method and apparatus disclosed in Patent Document 1 have a disadvantage that the wire saw device only has a function of dividing the existing pile into predetermined lengths. Thereby, in order to pull out and remove the existing piles from the ground, there is a problem that it is necessary to tie a wire to the upper end portion of the existing piles and pull it out with a crane as in the past. As a result, there is a problem that the number of work steps is significantly increased as compared with the case where the existing pile is pulled out from the ground without being divided. Moreover, the operation | work which inserts a wire saw apparatus in the space formed between the existing pile and the casing also becomes a factor which increases an operation man-hour compared with the case where it pulls out from the ground as it is without dividing an existing pile.
Then, an object of this invention is to provide the existing pile removal method and its apparatus which can remove easily the existing pile which was embed | buried in the ground and whose length and weight are large. In addition, another purpose is to improve the efficiency of removing existing piles.

  In order to achieve the above object, an existing pile removing method according to the present invention is a state in which a casing having an excavating blade for digging the periphery of an existing pile buried in the ground is in a state where the casing is gripped and opened. The existing pile cutting is provided at the lower end so that it can be lowered and lowered by a casing rotating / lifting device that can be switched between, and excavated to a predetermined depth so that it can be projected and retracted from the inner surface of the lower end of the casing. A blade is protruded from the inner surface of the lower end to cut the existing pile, and then the upper end opening of the casing is opened, and a gripping device having a grab is suspended from the upper end opening by a crane. The upper end of the existing pile cut by the existing pile cutting blade is gripped by the grab of the gripping device and pulled up by the operation of the crane. Opening Extraction, followed, in the casing rotating lifting device, while rotating the casing is a method Yuku repeated sequentially cutting and extraction is lowered deeper from the predetermined depth.

  Further, the existing pile removing apparatus according to the present invention has a casing rotary lifting device installed on the ground, and an excavating blade for digging the periphery of the existing pile buried in the ground and is gripped by the casing rotary lifting device. A casing that can be switched between an opened state and an opened state, and an existing pile cutting blade that is provided at the lower end so as to be able to protrude and retract from the inner surface of the lower end of the casing and can cut the existing pile A blade drive mechanism for projecting and retracting the existing pile cutting blade, and a gripping device having a grab to suspend and insert the gripping device from the upper end opening of the casing, and the cutting portion of the existing pile that has been cut And a crane that pulls up the upper part while gripping the upper part with the grab.

According to the existing pile removing method and apparatus of the present invention, the operation of dividing the existing pile into a predetermined length and the operation of pulling out can be performed relatively continuously with the existing pile cutting blade. Thereby, the various existing piles with large length and weight can be easily removed without increasing the number of work steps.
Moreover, the process of excavating the circumference | surroundings of an existing pile with a casing, the process of cutting an existing pile with an existing pile cutting blade, and the process of grasping and pulling up with a grab can be performed comparatively continuously. This eliminates the need to insert the existing pile cutting device into the space formed between the existing pile and the casing, compared with the case where a wire saw device is used. can do. In particular, there is no need to repeat the raising and lowering of the casing, and there is no need to repeat the removal and reattachment of the bolts connecting the plurality of casings.

Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments.
First, the structure of the existing pile removing apparatus according to the present invention will be described.
1 to 4 and 7, the existing pile removing device according to the present invention is used when removing an existing pile 30 buried in the underground G ₁ for the purpose of rebuilding a building structure or the like. It is a device.
The existing pile removing apparatus according to the present invention is capable of appearing and retracting from the casing 2 having the excavating blade 1 for digging the periphery of the existing pile 30 embedded in the underground G ₁ and the inner surface of the lower end portion 2a of the casing 2. The existing pile cutting blade 3 provided at the lower end 2a and capable of cutting the existing pile 30; the blade drive mechanism 8 for projecting and retracting the existing pile cutting blade 3; and supplying water to the lower end 2a of the casing 2 A tower part 27 having a swivel joint part 26 for supplying hydraulic oil to the blade driving mechanism 8..., A casing rotary lifting device 6 installed on the ground G ₀ , and a crane 70 (see FIG. 7). To do.

The casing 2 can be switched between a state of being gripped by the casing rotary lifting device 6 and a state of being opened. The casing 2 has a cylindrical shape, and is composed of a base casing 19 and a joint casing 20 that are connected to each other by a fastener such as a detachable bolt and nut. The foundation casing 19 is located at the lower end 2a of the casing 2, and is a portion where the existing pile cutting blades 3 ... and the blade drive mechanisms 8 ... are provided. Further, the length of the casing 2 can be adjusted by increasing or decreasing the number of connections.
Next, the casing rotation elevating device 6 that rotates and elevates the casing 2 includes a chuck portion 24 that grips the casing 2, a rotation mechanism that is not shown in the drawing that rotates the casing 2, and a plurality of elevating cylinders that elevate and lower the casing 2. 33 ... and so on.
The casing rotation elevating device 6 includes a gantry 18 installed on the ground G _0. The gantry 18 is erected on the base portion 34, the placement portion 17, and the base portion 34 and is attached to the placement portion 17. A plurality of leg portions 16...
The leg portions 16 are disposed at the four corners of the placement portion 17. The leg portion 16 has an elevating cylinder 37 inside, and is vertically extendable. The mounting portion 17 is moved up and down as the leg portions 16 expand and contract, and the mounting portion 17 and the base portion 34 approach and separate from each other. That is, the casing 2 held by the chuck portion 24 on the mounting portion 17 can be lifted and lowered by extending and contracting the leg portion 16 by the lifting cylinder 37.

The base portion 34 is provided with level adjusting portions 35 for adjusting the inclination of the casing rotation elevating device 6 with respect to the ground G ₀ and auxiliary chuck cylinders 36. The auxiliary chuck cylinders 36 are configured so that when the casing 2 is lowered to the state in which the leg portions 16 are contracted to the maximum, the depth portions of the casing 2 are maintained and the leg portions 16 are extended. Is provided. Specifically, the auxiliary chuck cylinders 36 are configured to grip the casing 2 in a state where the leg portions 16 are contracted most. And the chuck | zipper part 24 of the casing rotation raising / lowering apparatus 6 is made into an open state in the state which hold | gripped the casing 2 with this auxiliary chuck cylinder 36 .... In this way, the leg portions 16 can be easily extended without changing the depth position of the casing 2, and the lower end portion 2a of the casing 2 can be moved to a desired depth position regardless of the stroke of the leg portions 16. It is possible to descend. Conversely, the lower end 2a of the casing 2 can be raised to a desired depth position.

The base portion 34 is additionally provided with casing moving means 22 for horizontally moving the base casing 19 of the casing 2 so as to be close to and away from the gantry 18.
The casing moving means 22 has a casing loading / unloading section 38 that can be freely loaded and unloaded from the base portion 34 with the base casing 19 placed thereon, and a loading / unloading cylinder 39 for moving the casing loading / unloading section 38. Thereby, in the state where the leg portions 16 of the gantry 18 are most extended, the lower side of the mounting portion 17 (the mounting portion 17, the base portion 34, the plurality of leg portions 16 ... The base casing 19 can be inserted into the space formed between the two.
In the present invention, installing the casing rotation elevating device 6 on the ground G ₀ means not only directly on the ground G ₀ , but also via an iron plate or another base. The case where it is provided on the ground G ₀ is also included.

Next, the tower unit 27 is connected to the fixed frame 53 placed on the ground G ₀ , the column unit 56 erected on the fixed frame 53 and provided with the rail unit 59 in the vertical direction, and the rail unit 59. A lifting part 57 having a roller 58 to be joined and raising and lowering along the rail part 59; a winch 54 for winding a wire attached to the lifting part 57; and a turning cylinder 55 for turning the pillar part 56 ing. The swivel joint portion 26 is attached to the tip portion of the elevating portion 57. The elevating part 57 is moved up and down by the operation of the winch 54 and maintains the swivel joint part 26 connected to the upper end of the casing 2 while the casing 2 is rotated. In other words, the elevating part 57 moves up and down following the raising and lowering of the casing 2. Further, when the column portion 56 is turned by the turning cylinder 55, the connection between the swivel joint portion 26 and the casing 2 is released.
The swivel joint portion 26 is supplied with water and hydraulic oil such as the blade drive mechanism 8 supplied to the lower end portion 2a of the casing 2 from an external device (not shown) through a cable. The turning cylinder 55 is provided for turning the column portion 56 to move the position of the swivel joint portion 26 from directly above the casing 2. The turning cylinder 55 is connected to the base casing 19 and the extension casing 20 to form the casing 2 or when the existing pile 30 cut by the existing pile cutting blades 3 is pulled up to the ground. The 56 is turned about 90 ° to 180 °. Then, the swivel joint portion 26 is moved to a position that does not interfere with the work. In FIG. 7, the tower 27 and the like are not shown.

Next, the casing 2 will be described in detail.
In the casing 2 (more specifically, the basic casing 19), a cutting blade storage portion 28 is formed on the outer peripheral surface of the lower end portion 2a in the shape of an outer casing. Excavation blades 1 are provided on the lower surface side of the cutting blade storage portion 28 formed in the lower end portion 2a of the casing 2. Further, four existing pile cutting blades 3... Are pivotally attached to the cutting blade storage portion 28 so as to be swingable around the pivot shaft 9 in the vertical direction. And these four existing pile cutting blades 3 ... are provided so that it can protrude and retract from the inner surface of the lower end part of the casing 2.
The existing pile cutting blades 3 are projected from the inner surface of the lower end portion of the casing 2 at a predetermined depth, and the casing 2 is rotated in the direction of arrow A in FIG. It can be cut.

As shown in FIG. 4, the existing pile cutting blade 3 is composed of a pair of reinforcing bar cutting blades 4 and 4 for cutting the reinforcing bar 30a of the existing pile 30 (see FIG. 11) and a concrete 30b of the existing pile 30 (FIG. 10). And a pair of concrete cutting blades 5, 5 for cutting. The pair of rebar cutting blades 4 and 4 and the pair of concrete cutting blades 5 and 5 are arranged so that the same type is point-symmetric with respect to the center of the casing 2 in a bottom view. With this arrangement, the existing pile 30 can be cut with a good balance.
The reinforcing bar cutting blades 4 and 4 and the concrete cutting blades 5 and 5 are formed in a substantially sickle shape when viewed from the bottom. Among these, the concrete cutting blades 5 and 5 are formed in such a size that the lower end portion is located in the vicinity of the center of the casing 2 when the lower end portion is projected most from the inner surface of the casing 2.

  The reinforcing bar cutting blades 4, 4 are formed smaller than the concrete cutting blades 5, 5. In this way, the existing pile cutting blade 3... Rebar cutting blades 4, 4 for cutting the reinforcing bar 30 a of the existing pile 30, and the concrete cutting blades 5, 5 for cutting the concrete 30 b of the existing pile 30. , The existing pile cutting blades 3 are in an optimum shape for cutting either the reinforcing bar 30a or the concrete 30b. That is, it is the structure which can shorten the working time at the time of cutting the existing pile 30 compared with the case where the kind of existing pile cutting blade 3 ... is single.

Further, each of the reinforcing bar cutting blades 4 and 4 and the concrete cutting blades 5 and 5 is provided with a fluid ejection hole 29 for ejecting water or cement milk.
Water is supplied to each fluid ejection hole 29 from the swivel joint portion 26 of the tower portion 27 through the water pressure line 32. Thus, by providing the fluid ejection holes 29 in the existing pile cutting blade 3, when cutting the existing pile 30, the cutting waste between the existing pile cutting blade 3 ... and the existing pile 30 is cut with water or cement milk. It can be discharged out of the section. Further, water or cement milk can be used as a cooling liquid for cooling the existing pile cutting blades 3.
When the connection between the swivel joint portion 26 and the casing 2 is released in order to turn the column portion 56, the coupler disposed in the connection portion between the swivel joint portion 26 and the casing 2 in the hydraulic pressure line 32 is connected. , Is supposed to cancel.

Next, the blade drive mechanism 8 has a function of causing the existing pile cutting blades 3 composed of the reinforcing bar cutting blades 4 and 4 and the concrete cutting blades 5 and 5 to protrude from the inner surface of the casing 2. 5 and 6, the blade driving mechanism 8 includes an actuator 11 having a rod 10 that can move up and down, a cylindrical moving direction changing female portion 13 provided at the tip of the rod 10, and a pivot shaft 9. And a moving direction changing male portion 15 that is interlocked.
The actuator 11 is a hydraulic cylinder, and one is provided corresponding to each existing pile cutting blade 3. The actuator 11 is disposed in the vertical direction along the peripheral surface of the casing 2. The actuator 11 is stored in a blade drive mechanism storage unit 40 provided on the upper surface side of the cutting blade storage unit 28. Further, hydraulic oil is supplied to the actuator 11 from the swivel joint portion 26 of the tower portion 27 through the hydraulic line 52.
When the connection between the swivel joint portion 26 and the casing 2 is released in order to turn the column portion 56, the coupler disposed in the connection portion between the swivel joint portion 26 and the casing 2 in the hydraulic line 52 is connected. , Is supposed to cancel.

  The moving direction changing male portion 15 is connected to the pivot shaft 9 of the existing pile cutting blade 3 and is provided at the upper end of the transmission shaft 41 disposed in the blade drive mechanism storage portion 40. The moving direction changing male part 15 has a shape in which a large number of spiral ridges 14 (four in the illustrated example) are formed on the outer peripheral wall of the cylindrical main body part. When the moving direction changing male part 15 is viewed in a cross-sectional view, the projecting ridge parts 14 are arranged at regular intervals (90 °) at equal central angles. It has a formed shape. When the moving direction changing male part 15 is viewed in a cross-sectional view, the projecting ridge parts 14 are arranged at regular intervals (90 °) at equal central angles.

The length of the moving direction converting female portion 13 is longer than the length of the moving direction converting male portion 15 in the axial direction (longitudinal direction). The moving direction changing female portion 13 is disposed in the blade drive mechanism housing portion 40 so that the closed upper side is pivotally attached to the tip of the rod 10 of the actuator 11 and the lower side is the opening end portion 46.
A large number (four in the example) of spiral grooves 12 are formed on the inner peripheral wall of the dynamic direction changing female portion 13 corresponding to the large number of protrusions 14 of the dynamic direction changing male portion 15. Has been. The moving direction changing female portion 13 is externally fitted to the moving direction changing male portion 15 so as to be vertically movable so that the protruding portion 14 is fitted into the groove portion 12. The vertical movement of the moving direction changing female part 13 is caused by the rotation of the moving direction changing male part 15 by the multiple spiral protrusions 14 and the groove parts 12 of the moving direction changing male part 15 of the moving direction changing female part 13. Converted to dynamic. And the existing pile cutting blade 3 rock | fluctuates by rotation of the moving direction conversion male part 15. FIG.

In addition, a pair of guided protrusions 42 and 42 in the longitudinal direction of the moving direction changing female portion 13 are formed on the outer peripheral wall of the moving direction changing female portion 13. Each guided protrusion 42 engages with a guide groove 43 in the vertical direction formed on the inner wall of the blade drive mechanism housing 40. As a result, the moving direction changing female portion 13 can move smoothly in the vertical direction while being restricted from moving in the horizontal direction.
Further, the opening end portion 46 of the moving direction changing male portion 15 is covered (via a seal member such as packing) with a lid portion 45 having an insertion hole 44 for insertion of the transmission shaft 41. The insertion hole 44 and the transmission shaft 41 are sealed with a seal member 47 such as an O-ring.
In this way, the moving direction changing male part 15 is sealed by the moving direction changing female part 13 and the lid part 45, and this sealed space is filled with a lubricant such as machine oil. . This lubricant prevents wear of the ridges 14 of the moving direction changing male part 15 and the grooves 12 of the moving direction changing female part 13 and enables smooth movement.

  In addition, the rotation of the moving direction changing male part 15 is smoothly performed so that an excessive load is not applied to the protrusions 14 of the moving direction changing male part 15 with the vertical movement of the moving direction changing female part 13 described above. As shown in the figure, the swaying angle θ of the ridge 14 of the moving direction changing male part 15 (passes through the swaying line of the ridge 14 and one point above it, and the central axis of the moving direction changing male 15 is The angle formed with the plane perpendicular to the plane (see FIG. 5) is preferably set in the range of 55 ° to 65 °. If θ is smaller than 55 °, an excessive load is applied to the ridges 14 and the rotation of the moving direction changing male part 15 may be awkward. If θ exceeds 65 °, the conversion efficiency when converting the vertical movement of the moving direction converting female portion 13 into the rotation of the moving direction converting male portion 15 becomes very poor.

  Next, the crane 70 will be described. In FIG. 7, a vehicle 72 having an endless track 71 has a boom 73 extending obliquely upward so that it can be raised and lowered, and two winders 74 and 75 are mounted. One of the two winders 74, 75 is for raising and lowering the hanging hook 76, and the other is for operation (control). Reference numeral 77 denotes a gripping device, which is suspended from a suspension hook 76. The gripping device 77 has two grabs 78 and 78 that open and close each other, and the grabs 78 and 78 are operated by the operation (control) of the rope fed from the other of the hoisting machines 74 and 75. As shown in FIG. 7, among the existing piles 30 inserted through the upper end opening 80 of the casing 2 provided with the upper diameter-expanded tapered guide tube 79 and cut by the cutting blade 3 The part above the cutting part is gripped by the grabs 78, 78 and pulled up in the gripped state. (In FIG. 7, the ropes for opening and closing the grabs 78 and 78 are not shown.) That is, as shown by the arrow E in FIG. 12, the grabs 78 and 78 are opened from the upper end opening 80 of the casing 2. The gripping device 77 in a state (not shown) is inserted, and the cut short pile portion 30S above the cutting portion 30T cut by the cutting blade 3 is closed with the grabs 78 and 78 inserted and lowered to each other. Then, it can be gripped, pulled up from the gripped state as indicated by arrow F, and carried out of the casing 2 as shown in FIGS.

  Next, FIG. 11 shows an example of the gripping device 77, in which FIG. 11 (A) is a front view in an open state, and FIG. 11 (B) is a side view thereof. In FIG. 11, 81 is a hanging rope, and 82 is a grab opening / closing operation rope. This gripping device 77 has a crosspiece frame 85 composed of a fixed frame 83 and a movable frame 84, and a grab 78 is pivotally attached to the lower end of the fixed frame 83 by a pivot shaft 86 so as to be swingable and openable. As the movable frame 84 moves up and down, the grabs 78 and the movable frame 84 are pivotally connected by links 87 and pins 88 and 89 so that the grabs 78 and 78 swing open and close. The machine casing 85 is suspended by the suspension rope 81. The rope 82 is suspended over a plurality of rotating sheaves 90 and 95 on the fixed frame 83 and the movable frame 84, respectively, and the rotating sheave 95 of the movable frame 84 is removed from the rotating sheave 95 of the fixed frame 83 by loosening the rope 82. The grabs 78 and 78 are released. By the pulling operation of the rope 82, the movable frame 84 moves so that the rotary sheaves 95, 95 of the movable frame 84 approach the rotary sheaves 90, 90 of the fixed frame 83, and the grab 78 is closed. Grabs 78 and 78 are bivalve shells, and are inserted into and extracted from a cylindrical (circular cross-section) gap 91 between the existing pile 30 and the inner peripheral surface of the casing 2 as shown in FIG. (Drawer) It is formed in a plan view shape and size.

Next, an existing pile removing method according to the present invention will be described with reference to FIGS.
First, as shown in FIG. 8, a frame 18 having a plurality of legs 16 ... and which is attached to the portion 17 mounting a base portion 34 and the mounting portion 17 is placed on the ground G _0. In this way, the casing rotary lifting device 6 is installed on the ground G ₀ , and the tower portion 27 (see FIG. 9) is installed beside the mount 18 of the lifting device 6.
Then, the casing loading / unloading portion 38 of the casing moving means 22 attached to the base portion 34 of the gantry 18 is brought out, and the (existing pile cutting blade 3 and blade driving mechanism 8 are provided thereon). ) Place the basic casing 19. Further, the legs 16 of the gantry 18 are kept in the most extended state.

Then, the base casing 19 is inserted into the lower side of the mounting portion 17 from between the plurality of leg portions 16 of the gantry 18 at the casing loading / unloading portion 38 of the casing moving means 22.
Further, the joint casing 20 is lifted by the hook 76 of the crane 70, and the joint casing 20 is vertically penetrated from the upper side of the casing rotating / lifting device 6 to the casing rotating / lifting device 6 and the mounting portion 17. Then, the joint casing 20 and the foundation casing 19 are connected by bolts or bolt / nut coupling, and the casing 2 is constituted by the foundation casing 19 and the joint casing 20 thus connected (FIGS. 7 and 9). reference).

  Next, as shown in FIG. 9, the casing 2 is gripped by the chuck portion 24 of the casing rotating / lifting device 6 and the swivel joint portion 26 is connected to the upper end of the casing 2 so that the casing rotating / lifting device 6 is illustrated. While rotating the casing 2 (in the direction of arrow D in FIG. 9) with the omitted rotation mechanism, the lifting cylinder 33 of the casing rotating lift 6 and the leg 16 of the gantry 18 are contracted (arrow B in FIG. 9). , C direction), the casing 2 is lowered. As a result, the excavating blades 1 formed on the lower end 2a of the casing 2 dig around the existing pile 30, and the casing 2 descends. At this time, the raising / lowering part 57 of the tower part 27 descends following the movement of the casing 2. Since the casing 2 is lowered by contracting not only the elevating cylinders 33 of the casing rotary elevating device 6 but also the leg portions 16 of the gantry 18, the descending stroke can be increased and efficient work can be performed. When the leg portions 16 are in the most contracted state, the auxiliary chuck cylinders 36 are used to extend the leg portions 16 while keeping the depth position of the casing 2 unchanged. Further, as the digging progresses deeper, the extension casing 20 is added, and the length of the casing 2 is increased.

Next, as shown in FIG. 10, when excavating to a predetermined depth H, the casing 2 is stopped from being lowered. And among the existing pile cutting blades 3 ... provided on the lower end 2a so as to be able to protrude and retract from the inner surface of the lower end 2a of the casing 2 while rotating the casing 2 (arrow D direction in FIG. 10), FIG. The pair of reinforcing bar cutting blades 4, 4 shown in Fig. 4 are projected from the inner surface of the lower end 2a, and the reinforcing bars 30a of the existing pile 30 are cut from the peripheral surface side.
Next, the pair of concrete cutting blades 5 and 5 shown in FIG. 4 are protruded from the inner surface of the lower end portion 2a of the casing 2 to cut the concrete 30b of the existing pile 30 from the peripheral surface side.

  When the existing pile 30 is completely cut by the cutting blade 3 (concrete cutting blades 5 and 5), the rotation in the direction of arrow D is stopped and the swivel joint portion 26 and the like is rotated (turned) as indicated by arrow J in the figure. Then, the upper end opening 80 of the casing 2 is opened. For example, FIG. 1 shows a turning cylinder 55, which is swung in the direction of arrow J together with the entire column portion 56 by the expansion and contraction of the cylinder 55 to remove the swivel joint portion 26 and the like from the position above the upper end opening 80. (evacuate.

Next, as shown in FIGS. 7, 11, and 12, the gripping device 77 having the grabs 78, 78 is suspended by the crane 70 (the suspension hook 76 or the suspension rope 81), And (preferably after attaching the guide cylinder 79), the outer peripheral surface of the upper end 30d of the existing pile 30 and the casing are inserted from the upper end opening 80 of the casing 2 in the direction shown by the arrow E in FIG. The lower half of the two grabs 78 and 78 are inserted into a cylindrical gap 91 formed between the inner peripheral surface of the two and the existing pile is operated by operating the grab opening / closing operation lobe 82 shown in FIG. If the rope 81 is pulled up in the direction of arrow F in FIG. 12 while grasping (holding) the upper end portion 30d, the cut short pile portion 30S is separated at the cutting portion T (shown in FIGS. 12 to 13). As such, it can be removed from the casing 2 and removed. Is lowered as shown by an arrow K in FIG. 13, it is possible to lay the Tankui portion 30S on the ground G _0. In this case, base housing 19 and Tsugiashi casing 20 that has entered the ground G ₁ as shown in FIG. 13 is stationary as it is, there is no need to increase temporarily.

  Next, while being suspended by the crane 70, another additional casing 20 is lowered from the upper side to the upper end of the lower additional casing 20 as indicated by an arrow L, and connected by bolt / nut coupling, etc. Further, in the tower portion 27, the swivel joint 27 and the like are raised as indicated by an arrow M, and then turned as indicated by an arrow J 'so as to enter the upper end opening of the extension casing 20 which has just been added. Attach the swivel joint 27 etc. to the lid.

  Thereafter, as shown in FIG. 14, the casing 2 is lowered further from the predetermined depth H while rotating the casing 2 as indicated by the arrow D (as described above) by the casing rotating / lifting device 6. Thereafter, the same steps as described above with reference to FIGS. 10 to 13 are repeated, and the existing piles 30 are successively cut from the upper side to the lower side by a predetermined length at the cutting portion 30T, and the cut short pile portion 30S is cut. Take out from the casing 2. At that time, the casing 2 repeats lowering and stopping, but there is no need to raise it at all. If the existing pile 30 is taken out over the entire length (or a desired length), finally, the casing 2 may be pulled up (pulled out) by the casing rotary lifting device 6.

The present invention is not limited to the above-described embodiment, and the design can be changed without departing from the gist of the present invention. For example, in the present embodiment, the case where the existing pile cutting blades 3... Have two types of cutting blades, concrete cutting blades 5 and 5 and reinforcing bar cutting blades 4 and 4 is exemplified. Not limited to this, the existing pile cutting blade may be constituted by one type of cutting blade.
Further, in the present embodiment, the case where the casing moving means 22 having the casing insertion / removal portion 38 that can be freely taken in and out from the base portion 34 with the base casing 19 placed thereon is illustrated, but the present invention is not limited thereto, and the casing is not limited thereto. A general forklift may be used as the moving means.

As described above, the existing pile removing method of the present invention opens the casing 2 having the excavating blade 1 for digging the periphery of the existing pile 30 embedded in the underground G ₁ from the state in which the casing 2 is gripped. The casing rotary elevating device 6 that can be switched to a state is lowered while rotating, excavated to a predetermined depth, and provided at the lower end 2a so as to be able to protrude and retract from the inner surface of the lower end 2a of the casing 2. The existing pile cutting blade 3 is protruded from the inner surface of the lower end 2a to cut the existing pile 30, and then the upper end opening 80 of the casing 2 is opened, and the upper end opening 80 is grabbed. A gripping device 77 having 78 is inserted while being suspended by the crane 70, and a portion above the cutting portion of the existing pile 30 cut by the existing pile cutting blade 3 is inserted into the gripping device 77. Grabbed by grab 78 and operated by crane 70 above This is a method in which the casing is lifted and taken out from the upper end opening 80, and then the casing rotating and lifting device 6 is rotated further down from the predetermined depth while rotating the casing 2 to sequentially repeat cutting and taking out. The troublesome operation of once lifting the joint casing 20 and screwing (separating) a number of bolts or bolts and nuts and then screwing them can be omitted. In this way, it is possible to easily remove the existing piles 30 by dividing them into predetermined lengths and sequentially take them out from the ground G ₁ , reduce the number of work steps, and easily remove various existing piles 30. Can do. In particular, a method of pulling out the short pile portion 30S cut by the cutting blade 3 at the lower end portion 2a of the casing 2 together with the extension casing 20 of the casing 2 (method already proposed by the present inventor in Japanese Patent Application No. 2006-042681) Compared to the above, manual work such as screwing and screwing of a large number of bolts (bolt / nut coupling) for connecting the joint casings 20 to each other can be omitted, and the work efficiency can be drastically improved as a whole.

In addition, the existing pile removing device according to the present invention has a casing rotating / lifting device 6 installed on the ground G ₀ and an excavating blade 1 for digging around the existing pile 30 buried in the underground G _1. A casing 2 that can be switched between a state of being held and released by a casing rotating / lifting device 6 and a lower end portion 2a that can be moved in and out of the inner surface of the lower end portion 2a of the casing 2 are provided. The existing pile cutting blade 3 capable of cutting the existing pile 30, the blade drive mechanism 8 for projecting and retracting the existing pile cutting blade 3, and the gripping device 77 having a grab 78 are suspended to hold the gripping device 77 above. A crane 70 that is inserted from the upper end opening 80 of the casing 2 and is lifted in a state where the grab 78 holds the portion above the cutting portion of the existing pile 30 that has been cut. Dividing the existing pile 30 into a predetermined length The task of sequentially taking out from the middle G ₁ can be performed easily and efficiently. In addition, various existing piles 30 having a large length and weight can be easily removed. In particular, in the device of the method of pulling out the short pile portion 30S cut at the lower end portion 2a of the casing 2 together with the extension casing 20 of the casing 2 (which the inventor has already proposed in Japanese Patent Application No. 2006-042681). In comparison, a large number of bolts for connecting the joint casings 20 to each other and manual operations such as screwing and screwing of bolts and nuts can be omitted, and the overall work efficiency can be remarkably improved.

It is a front view which shows the existing pile removal apparatus which concerns on one Embodiment of this invention. It is a principal part side view. It is a principal part sectional top view of a tower part. It is a bottom view of a casing. It is a principal part cross-section side view around a blade drive mechanism. It is a principal part sectional top view of a blade drive mechanism periphery. It is a partial cross section perspective explanatory view showing the whole composition. It is a cross-sectional side view for drawing-out removal process of an existing pile. It is a cross-sectional side view for drawing-out removal process of an existing pile. It is a cross-sectional side view for drawing-out removal process of an existing pile. It is a figure which shows an example of a holding apparatus, Comprising: (A) is a front view, (B) is a side view. It is a cross-sectional side view for drawing-out removal process of an existing pile. It is a cross-sectional side view for drawing-out removal process of an existing pile. It is a cross-sectional side view for drawing-out removal process of an existing pile.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Excavation blade 2 Casing 2a Lower end part 3 Existing pile cutting blade 6 Casing rotation raising / lowering device 8 Blade drive mechanism
30 Existing pile
30S Cut short pile
30T cutting part
70 crane
77 Gripping device
78 Grab
80 Upper end opening G ₀ ground G ₁ underground

Claims (2)

Switching the casing (2) having the excavating blade (1) for digging around the existing pile (30) buried in the ground (G ₁ ) between the state in which the casing (2) is gripped and the state in which it is opened The lower end portion (6) of the lower casing (6) is rotated and lowered to be excavated to a predetermined depth, so that the lower end (2a) of the casing (2) can be projected and retracted. The existing pile cutting blade (3) provided in 2a) is projected from the inner surface of the lower end (2a) to cut the existing pile (30), and then the upper end opening ( 80) is opened, and a gripping device (77) having a grab (78) is inserted from the upper end opening (80) while being suspended by a crane (70), and the existing pile cutting blade (3) The part above the cutting part of the existing pile (30) cut by the And lifted by the operation of the crane (70) and taken out from the upper end opening (80). Thereafter, the casing (2) is removed by the casing rotating elevator (6). A method for removing an existing pile, wherein the pile is further lowered from the predetermined depth while being rotated, and cutting and taking out are repeated sequentially. A casing rotary lifting device (6) installed on the ground (G ₀ );
Underground switched between a state of being open in a state of being gripped by the casing rotating lifting device (6) which has a digging edge (1) for digging around the (G ₁₎ to the buried existing pile (30) A casing (2) that can be freely moved, and a lower end (2a) of the casing (2) that is provided at the lower end (2a) so as to be able to protrude and retract and can cut the existing pile (30). An existing pile cutting blade (3), a blade drive mechanism (8) for projecting and retracting the existing pile cutting blade (3), and a gripping device (77) having a grab (78) are suspended to hold the gripping device (77 ) Is inserted through the upper end opening (80) of the casing (2) and the portion of the existing pile (30) that has been cut is pulled up with the grab (78) holding the portion above the cut portion. A crane (70),
An existing pile removing device characterized by comprising:

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