JP2008095405A - Drilling device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drilling device easily installed and removed, the whole size of which can be reduced, and manufactured at low costs. <P>SOLUTION: The drilling device 1 comprises a self-travelling truck 20 (a carrying vehicle) provided with a cab back crane 10 having a tiltable arm 11 and a loading platform 21, a gate-type frame 30 (a strut) standing in a state of being supported by the arm 11, and an earth auger 40 (a drilling means) movable up and down along the gate-type frame 30. The gate-type frame 30 and the earth auger 40 are made movable by being loaded on the loading platform 21 of the truck 20. The earth auger 40 is made movable up and down along the gate-type frame 30 by fitting a front end part 11a of the arm 11 to an upper end part of the gate-type frame 30 and fitting a lifting wire hung from the arm 11 to the earth auger 40. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an excavation apparatus for excavating the ground.

Conventionally, as an excavating device for excavating a vertical hole in the ground, it is provided with a leader standing on the ground, an earth auger moving up and down along the leader, and a crawler crane for supporting the leader and the earth auger There is something that is.
In this conventional excavator, the upper end portion of the leader is supported by the support wire of the crawler crane, and the earth auger is supported by the lift wire of the crawler crane, and the lift wire is fed or wound up. The earth auger is configured to move up and down along the leader (see, for example, Patent Document 1).

JP 2002-38861 A (paragraphs 0041 to 0044, FIG. 6)

When carrying the above-described conventional excavator into the construction site, a truck for transporting the leader and the earth auger and a truck for transporting the crawler crane are required, and two transport vehicles are used. Therefore, there is a problem that the installation and removal work of the excavator becomes complicated.
In addition, since a crawler crane is used, there is a problem that even if a small-scale construction is performed such as when excavating a well, the entire apparatus becomes large and the manufacturing cost of the excavator increases. is there.

  Therefore, the present invention provides an excavation apparatus that solves the above-described problems, can easily perform installation and removal operations, can reduce the size of the entire apparatus, and can reduce manufacturing costs. Is an issue.

  In order to solve the above-mentioned problems, the present invention is an excavation apparatus for excavating the ground, in which the crane has a tiltable arm and a self-propelled transport vehicle including a loading platform, and is supported by the arm. And a digging means that can be moved up and down along the stanchion, the tip of the arm being detachable from the upper end of the stanchion, and the strut and the digging means are loaded on the loading platform of the transport vehicle. Attach the tip of the arm to the upper end of the column to erect the column, attach the lifting wire suspended from the tip of the arm to the excavation means, and feed the lifting wire Alternatively, the excavating means is configured to move up and down along the column by winding.

  In this configuration, the support is supported by the crane arm mounted on the transport vehicle, and the excavating means is lifted and lowered by the lifting wire of the crane. Therefore, excavation work can be performed without using a crane vehicle other than the transport vehicle. It can be carried out.

  Moreover, since the support | pillar and excavation means can be loaded on the loading platform of a conveyance vehicle and the whole apparatus can be moved by one conveyance vehicle, installation and removal work of an excavation apparatus can be performed easily.

  Moreover, the whole apparatus can be comprised compactly by utilizing the crane mounted in the conveyance vehicle. Note that when the excavation means is driven using a drive source such as a hydraulic device or a power supply device mounted on the transport vehicle for driving the crane, the manufacturing cost of the excavator can be reduced.

  Moreover, since the upper end part of the support | pillar is supported by the arm of a crane, without supporting a support | pillar with the wire of a crane, the crane provided with the one line of wire can be used. As a result, when performing small-scale construction such as when excavating a well, a general truck-mounted crane (cab back crane) can be used to configure the excavator, so the excavator can be reduced in size. And the manufacturing cost of the excavator can be reduced.

  In the excavating apparatus described above, the connecting shaft protrudes in the lateral direction at the distal end of the arm, the concave mounting groove into which the connecting shaft can be fitted at the upper end of the support, and the base end as the center of rotation. And a fixing bracket that can be rotated in the vertical direction, and with the connecting shaft fitted in the mounting groove, the fixing bracket is rotated in the vertical direction, and the fixing bracket is used as the connecting shaft. By covering, the connecting shaft can be fixed between the fixing bracket and the mounting groove.

In this configuration, since the mounting groove formed in the upper end portion of the support column is a concave groove, the connecting shaft of the arm can be easily inserted into and removed from the mounting groove.
Further, the connecting shaft can be easily fixed to the support column by rotating the fixing bracket provided at the upper end of the support column in the vertical direction.
Furthermore, since the lifting wire directly supports the excavating means without being hung on the support column, the lifting wire can be easily routed.
In this way, the crane, the strut, and the excavation means can be easily assembled or removed. Therefore, when excavation work is not being performed, the transport vehicle is quickly removed from the strut and the excavation means, and the transport vehicle is used. Since other work can be performed, work efficiency can be improved.

  In the above-described excavating apparatus, the strut is provided with tension applying means for rotating the excavating shaft about the axis in order to remove the excavating shaft connected to the excavating means, and the tension applying means is extendable and retractable. And a cylinder fixed to the column, an elevating pulley attached to the cylinder rod, and a pulling linear member stretched over the elevating pulley. One end of the tensile linear member With the other end attached to the outer peripheral surface of the excavation shaft, the cylinder rod is extended, and tension is applied to the pulling linear body stretched over the lifting pulley. A tensile force can be applied from the linear body in the circumferential direction of the excavation shaft to rotate the excavation shaft about the axis.

  Here, in the conventional excavator, in order to remove the excavation shaft connected to the excavation means, when the excavation shaft is rotated about the axis in the unlocking direction, the circumferential direction of the excavation shaft is caused by the crane wire. A tensile force is applied to Therefore, in the conventional excavator crane, it is necessary to provide another system wire in addition to the wire for raising and lowering the excavating means. Therefore, like a truck-mounted crane (cab back crane), Small cranes with wires cannot be used.

  On the other hand, in the above-described configuration, by extending the cylinder rod fixed to the support column, a tensile force is applied in the circumferential direction of the excavation shaft, and the excavation shaft is rotated about the axis in the fixing release direction. Can be made. Therefore, the excavating shaft can be removed from the excavating means without using the wire of the crane. As a result, a small crane having one system of wires, such as a truck-mounted crane (cab back crane), can be used, so that the excavator can be downsized and the manufacturing cost of the excavator can be reduced. can do.

According to the excavation apparatus of the present invention, excavation work can be performed without using a crane vehicle other than the transport vehicle.
Moreover, since the whole apparatus can be moved by one conveyance vehicle, installation and removal work can be performed easily.
Moreover, the whole apparatus can be comprised compactly by utilizing the crane mounted in the conveyance vehicle.
In addition, since a crane having a single line of wire can be used, when performing a small-scale construction, a general truck-mounted crane can be used to configure the excavator. Thereby, the excavator can be miniaturized and the manufacturing cost of the excavator can be reduced.

Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
In the present embodiment, a drilling device for drilling a vertical hole such as a well will be described as an example.
FIG. 1 is a side view showing the excavator of this embodiment. FIG. 2 is a front view showing the excavator of the present embodiment. FIG. 3 is a plan view showing a base frame in the excavator of the present embodiment. FIG. 4 is a view showing an arm of a crane and an upper frame member of a portal frame in the excavator of the present embodiment, and (a) is a plan view showing a state before the arm is attached to the upper frame member. b) is a plan view showing a state in which the arm is attached to the upper frame member. FIG. 5 is a view showing an aspect when the crane arm is attached to the upper frame member of the portal frame in the excavator of the present embodiment, and (a) is a cross-sectional view taken along line AA in FIG. FIG. 4B is a sectional view taken along line BB in FIG. FIGS. 6A and 6B are views showing a tension applying device in the excavating apparatus of the present embodiment, in which FIG. 6A is a side view, and FIG. 6B is a side view in a state where tension is applied to the pulling wire. FIG. 7 is a diagram showing a tension applying device in the excavating apparatus of the present embodiment, and is a plan view showing an aspect in which the auger screw is rotated.
In the following description, the front-rear and left-right directions correspond to the front-rear and left-right directions shown in the drawings.

[Overall configuration of excavator]
As shown in FIG. 1, the excavator 1 includes a self-propelled truck 20 (a “transport vehicle” in the claims) including a cab back crane 10 and a loading platform 21, and two left and right readers 31, 31 ( 2) and a ground auger 40 (excavated in the claims) that can be moved up and down along each of the readers 31, 31 of the portal frame 30. Means ").
2, a plurality of auger screws 50, 50 (“excavation shaft” in the claims) are connected to the output shaft 41 of the earth auger 40, and the auger screws 50, 50 are rotated about the axis. By doing so, the ground can be excavated.
In addition, a tension applying device 60 for rotating the auger screw 50 about its axis in order to remove the auger screw 50 connected to the earth auger 40 is provided at the lower end portion of the portal frame 30 (" A tensioning means ") is provided.

[Track structure]
A truck 20 shown in FIG. 1 is a general small truck with a crane in which a cab back crane 10 is mounted between a cab 22 and a loading platform 21, and a hydraulic device and a power source for driving the cab back crane 10. Equipment.
Note that the truck 20 in FIG. 1 is arranged with the traveling direction in the left-right direction, and the truck 20 is viewed from the rear. The configuration of the truck 20 is not limited, and various known trucks with cranes can be used.

(Configuration of cab back crane)
As shown in FIG. 1, the cab back crane 10 has an arm 11 that can be tilted and expanded and that can turn in the horizontal direction. Since this cab back crane 10 uses a well-known vehicle-mounted crane, its detailed description is omitted.

As shown in FIG. 2, the cab back crane 10 has a system of lifting wires 12, and the lifting wires 12 are suspended from the distal end portion 11 a of the arm 11 (see FIG. 1). Further, a hook 13 is suspended from the lifting wire 12.
Further, the cab back crane 10 includes a hoisting machine (not shown) for feeding or hoisting the lifting wire 12, and by lifting or hoisting the lifting wire 12 by this hoisting machine, The hook 13 is configured to move up and down.

As shown in FIG. 4A, connecting shafts 11b and 11b project from the distal end portion 11a of the arm 11 in the left-right direction (lateral direction). The connecting shafts 11b and 11b are parts attached to the upper end portion of the portal frame 30 (see FIG. 1).
In addition, at the distal end portion 11a of the arm 11, support shafts 11c and 11c protrude in the left-right direction behind the connection shafts 11b and 11b, and each of the connection shaft 11b and the support shaft 11c arranged at the front and rear. The leading ends are connected by a support plate 11d. Thereby, since both ends of the connecting shaft 11b are supported, the supporting force is increased.

[Portrait frame structure]
As shown in FIG. 2, the portal frame 30 is a column for guiding the raising and lowering of the earth auger 40, which will be described later. Two readers 31, 31 suspended from the upper surface of the base frame 32, an upper frame 33 laid between the upper ends of the readers 31, 31, and a predetermined number of the readers 31, 31. And a work table 34 attached to the height of the work table 34.

(Configuration of base mount)
As shown in FIG. 3, the base gantry 32 has a quadrangular frame in plan view, and is provided at the lower end of each reader 31, 31. The base end portions of the readers 31 and 31 are attached to the upper surface of the base mount 32.
As shown in FIG. 3, an attachment portion 32 a for attaching the tension applying device 60 extends leftward at the left rear corner of the base gantry 32.
Further, the front frame member 32b of the base gantry 32 is fixed to the left and right frame members 32c and 32c by bolts (not shown), respectively, so that the front frame member 32b can be easily removed from the left and right frame members 32c and 32c. Can be removed.

(Configuration of reader)
The left and right readers 31, 31 shown in FIG. 2 are hollow columns having a square cross section (see FIG. 3), and are divided in the vertical direction. In the present embodiment, the left and right readers 31, 31 are each divided into four parts and connected by a pin joint.
In addition, the shape of each reader | leader 31 and 31 and the structure of a connection part are not limited, A various well-known structure can be used.

(Configuration of upper frame)
As shown in FIG. 2, the upper frame 33 is a plate-like member that is installed on the upper ends of the left and right readers 31, 31. As shown in FIG. 4A, a notch 33 a is formed in the center in the left-right direction at the rear edge of the upper frame 33. The notch 33a has a shape that allows the front portion of the tip portion 11a of the cab back crane 10 to enter (see FIG. 4B).

Further, on the upper surface of the upper frame 33, mounting brackets 33b and 33b are erected on the left and right sides of the notch 33a.
The mounting bracket 33b is composed of a pair of vertical plates 33b ₁ , 33b _{1. As} shown in FIG. 5A, the vertical plates 33b ₁ , 33b ₁ have concave mounting grooves 33c. Is formed. The mounting bracket 33b is provided with a fixing bracket 33d that is rotatable in the vertical direction.

The mounting groove 33c is formed at the upper end edge of each of the vertical plates 33b ₁ and 33b ₁ of the mounting bracket 33b, and is a concave groove in a side view. The mounting groove 33c is formed so that the lower half of a connecting shaft 11b of the arm 11 to be described later is fitted. Further, the mounting groove 33c is formed so that the rear side edge portion is lower than the front side edge portion, and the connecting shaft 11b can be easily inserted from the rear side.

The fixing bracket 33d is a substantially U-shaped member in a side view, and is disposed between the vertical plates 33b ₁ and 33b ₁ . FIG. 5A shows a state in which the fixing bracket 33d is opened.
Proximal end 33d ₁ of the fixed bracket 33d is in front of the mounting groove 33c is pivotally supported on the vertical plates _33b 1, 33b _1, fixing clasp 33d as the rotation around the base end portion 33d _1, It is freely rotatable in the vertical direction.
Further, the distal end portion 33d ₂ of the fixing brackets 33d has a through hole 33d ₃ are formed. As shown in FIG. 5B, the through hole 33d ₃ is configured to communicate with a through hole 33e formed in the vertical plate 33b ₁ when the fixing bracket 33d is rotated and closed. Yes.

As shown in FIG. 5B, when the fixing bracket 33d is rotated and closed with the lower half of the connecting shaft 11b of the arm 11 fitted in the mounting groove 33c, the fixing bracket 33d is closed. Is configured so that the intermediate portion thereof covers the upper half of the connecting shaft 11b.
Then, in the closed state by rotating the fixing clasp 33d, the through-hole 33d ₃ of the distal end portion 33d ₂ of the fixing bracket 33d, the through-hole 33e and the pin 33f of the vertical plate 33b ₁ of the mounting bracket 33b by inserting, it is possible to fix the tip 33d ₂ of the fixing brackets 33d to the vertical plate 33b _1.
As a result, the connecting shaft 11b is fixed between the fixing bracket 33d and the mounting groove 33c, and the tip 11a (see FIG. 1) of the arm 11 is attached to the upper end of the portal frame 30. It becomes.

(Workbench configuration)
As shown in FIG. 1, the work table 34 is a scaffold that is fixed to a predetermined height of each of the readers 31, 31. Can do. In addition, the worker is configured to hang a ladder (not shown) on the work table 34 and get on the work table 34 from the ground.
The configuration of the workbench 34 is not limited, and the shape and mounting position thereof are appropriately set in consideration of workability.

[Configuration of Earth Auger]
As shown in FIG. 2, the earth auger 40 includes a drive motor 42 having an output shaft 41 whose axial direction is arranged vertically, and a slide portion 43 slidably attached to each reader 31, 31. 43, and the drive motor 42 is supported by the slide portions 43, 43.

(Configuration of drive motor)
The drive motor 42 is an existing hydraulic motor, and is configured to be driven by hydraulic pressure generated by a hydraulic device (not shown) mounted on the track 20 (see FIG. 1). The drive motor 42 can be started and stopped by operating an operation switch (not shown) provided on the track 20.
The configuration of the drive motor 42 is not limited, and various known drive devices can be used.

  An annular hanging bracket 44 is provided on the upper surface of the drive motor 42. By attaching the hook 13 suspended from the lifting wire 12 to the hanging bracket 44, the drive motor 42 is suspended between the readers 31 and 31 by the lifting wire 12. .

In addition, an electric winch 45 capable of feeding or winding a suspension wire (not shown) is attached to the lower front portion of the drive motor 42.
The electric winch 45 is used for lifting the auger screw 50 when the auger screw 50 is assembled to the drive motor 42. The electric winch 45 is an existing winch that is driven by electric power from a power supply device (not shown) mounted on the truck 20 (see FIG. 1), and the configuration thereof is not limited.

(Slide configuration)
The slide portion 43 has an outer end portion fitted on the reader 31 and an inner end portion attached to the outer peripheral surface of the drive motor 42. The slide portion 43 moves vertically along the reader 31 in conjunction with the elevation of the drive motor 42. Configured to move in the direction.

[Configuration of tension applying device]
A tension applying device 60 shown in FIG. 2 is a device for rotating the auger screw 50 about an axis in order to remove the auger screw 50 connected to the earth auger 40.
Here, the auger screw 50 is disposed slightly above or below the connection between the auger screw 50 and the output shaft 41 by slightly rotating in the direction opposite to the rotation direction during excavation (fixing release direction). The auger screws 50 and 50 are configured to be able to be disconnected.
In addition, a rotation shaft 51 for attaching a spanner 70 (see FIG. 7) for rotating the auger screw 50 is provided at the upper end of the auger screw 50.

As shown in FIG. 6A, the tension applying device 60 includes a rod 61 a that can be vertically expanded and contracted, and a cylinder 61 in which a base end portion of a cylinder body 61 b is fixed to an attachment portion 32 a of a base mount 32. The elevating pulley 63 attached to the upper end of the rod 61a, the fixed pulley 64 attached to the outer peripheral surface of the cylinder body 61b, and the pulling wire 65 stretched over the elevating pulley 63 and the fixed pulley 64 (claims) "Linear body for tension" in the range).
A plurality of mounting holes 61c for mounting the fixed pulley 64 are formed in the vertical direction on the outer peripheral surface of the cylinder body 61b, so that the mounting height of the fixed pulley 64 can be adjusted.

Further, the pulling wire 65 is hung on the upper side of the outer peripheral groove of the elevating pulley 63 and is hung on the lower side of the outer peripheral groove of the fixed pulley 64.
Further, one end 65a (left end) of the pulling wire 65 is fixed to a bracket provided on the outer peripheral surface of the cylinder 61 using a fixing metal fitting (not shown) such as a cotter. In this way, one end 65 a of the pulling wire 65 is fixed to the base frame 32 via the cylinder 61.

  Further, the other end 65b (right end) of the pulling wire 65 is, as shown in FIG. 7, a grip portion of the spanner 70 assembled to the rotating shaft portion 51 of the auger screw 50 using a fixing metal fitting such as a wire clip. It is attached to the tip. In this way, the other end 65 b of the pulling wire 65 is attached to the outer peripheral surface of the auger screw 50 via the spanner 70.

  Then, as shown in FIG. 6B, the rod 61a of the cylinder 61 is extended, and tension is applied to the pulling wire 65 stretched over the lifting pulley 63 and the fixed pulley 64, as shown in FIG. Furthermore, the grip portion of the spanner 70 can be pulled toward the cylinder 61 by the pulling wire 65. In this way, the auger screw 50 can be rotated in the fixing release direction by applying a tensile force in the circumferential direction of the auger screw 50.

  In the present embodiment, the pulling wire 65 is used as a linear body for applying a tensile force to the auger screw 50. However, the linear body spanned between the lifting pulley 63 and the fixed pulley 64 is a wire. It is not limited and various linear bodies, such as a chain and a rope, can also be used.

[Drilling method using excavator]
Next, the excavation method using the excavator of this embodiment described above will be described.
FIG. 8 is a front view showing a mode in which the earth auger is pulled up using a suspension pulley in the excavation method using the excavator of this embodiment.

(Carrying excavator)
First, when carrying the excavator 1 shown in FIG. 1 into the construction site, the portal frame 30 and the earth auger 40 are removed from the cab back crane 10 and loaded on the loading platform 21 of the truck 20. Further, the excavator 1 is carried into the construction site by moving the truck 20 and moving the entire apparatus while the auger screw 50 and the work tool are loaded on the loading platform 21 of the truck 20.

(Installation of drilling equipment)
At the construction site, the cab back crane 10 is used to place the base frame 32 of the portal frame 30 on the ground, and the readers 31 are assembled to the base frame 32. Thereafter, using the cab back crane 10, the earth auger 40 is assembled to each of the readers 31, 31 and the work table 34 is attached to each of the readers 31, 31. Further, the portal frame 30 is assembled by installing the upper frame 33 on each of the readers 31, 31 using the cab back crane 10.

Subsequently, as shown in FIG. 4A, the front part of the tip part 11 a of the arm 11 of the cab back crane 10 is rearwardly inserted into a notch part 33 a formed in the upper frame body 33 of the portal frame 30. As shown in FIG. 5 (a), the lower half of each connecting shaft 11b, 11b formed at the tip 11a of the arm 11 is inserted into the mounting groove 33c formed at each mounting bracket 33b, 33b. To fit each.
At this time, since the mounting groove 33c is formed so that the rear edge is lower than the front edge, the connecting shaft 11b is moved from the rear side of the upper frame 33 to the front, so that the connecting shaft 11b can easily enter the mounting groove 33c.

Further, as shown in FIG. 5B, the fixing bracket 33d is rotated and closed in the vertical direction in a state where the connecting shaft 11b of the arm 11 is fitted in the mounting groove 33c, thereby fixing the fixing bracket 33d. Is placed on the upper half of the connecting shaft 11b.
Further, by fixing the distal end portion 33d ₂ of the fixing bracket 33d to the mounting bracket 33b, the connecting shaft 11b is in the state of being sandwiched between the fixing bracket 33d and the mounting groove 33c. As a result, the distal end portion 11 a of the arm 11 is attached to the upper end portion of the portal frame 30.

  Further, as shown in FIG. 2, the hook 13 provided on the lifting wire 12 of the cab back crane 10 (see FIG. 1) is hooked on the hanging bracket 44 of the ground auger 40, so that the lifting wire 12 is grounded. 40 is suspended.

Further, the earth auger 40 is raised to a predetermined height by winding up the lifting wire 12 by a hoisting machine (not shown). Then, a hanging wire (not shown) of the electric winch 45 of the earth auger 40 is attached to the upper end portion of the auger screw 50, and the auger screw 50 is caused by winding up the hanging wire of the electric winch 45. Then, the upper end portion of the auger screw 50 is connected to the output shaft 41 of the drive motor 42.
At this time, the worker can work from the work table 34 (see FIG. 1) attached to the readers 31 and 31 at a predetermined height, thereby improving work efficiency and improving work safety. Can be improved.

Similarly, the other auger screw 50 is pulled up using the electric winch 45, and the upper end portion of the auger screw 50 is connected to the lower end portion of the auger screw 50 connected to the output shaft 41.
In addition, the number which connects the auger screw 50 is not limited, It sets suitably so that a desired depth can be excavated.

(Drilling work)
When excavating the ground, the hoisting machine (not shown) of the cab back crane 10 (see FIG. 1) while rotating the output shaft 41 of the drive motor 42 shown in FIG. 2 and rotating the auger screw 50 around the axis. As a result, the lifting wire 12 is fed out and the earth auger 40 is lowered. Thereby, the lower end part of the auger screw 50 contacts the ground, and the vertical hole is excavated.

(Draw out the auger screw)
After excavating the vertical hole in the ground, the auger screw 50 is pulled up from the ground by winding up the lifting wire 12 shown in FIG. 2 by a hoisting machine (not shown) of the cab back crane 10 (see FIG. 1). .

Here, in the hard ground, the pulling force required to pull out the auger screw 50 from the ground becomes large, and it becomes difficult to pull up the auger screw 50 by the lifting wire 12 of the cab back crane 10 (see FIG. 1). May end up.
In such a case, as shown in FIG. 8, the hanging bracket 44 (see FIG. 2) is removed from the drive motor 42 of the earth auger 40, and a suspension pulley 80 is attached to the upper surface of the drive motor 42. Then, one end of the suspension wire 81 is attached to the hook 13, the suspension wire 81 is passed over the suspension pulley 80, and the other end of the suspension wire 81 is attached to the support bracket 33 g provided on the lower surface of the upper frame body 33. Thus, by providing the fulcrum on the upper frame 33 of the portal frame 30, the tensile force acting on the earth auger 40 can be doubled.

Further, when the earth auger 40 is removed from the auger screw 50 with the upper end portion of the auger screw 50 protruding from the ground, and the portal frame 30 is temporarily moved with the auger screw 50 left on the ground. 3, the front frame member 32b of the base gantry 32 is removed, and the base gantry 32 is formed into a U shape in plan view, whereby interference between the base gantry 32 and the auger screw 50 can be prevented.
Since the front frame member 32d of the base gantry 32 is fixed to the left and right frame members 32c and 32c by bolts (not shown), the front frame member 32b can be easily removed from the left and right frame members 32c and 32c. it can.

(Removal of auger screw)
Next, a method for removing the auger screw 50 from the earth auger 40 will be described.
As shown in FIG. 7, the other end 65 b of the pulling wire 65 of the tension applying device 60 is attached to the tip of the grip portion of the spanner 70 assembled to the rotating shaft portion 51 of the auger screw 50.

Then, the rod 61a of the cylinder 61 is extended, and tension is applied to the pulling wire 65 spanned by the lifting pulley 63 and the fixed pulley 64, whereby the grip portion of the spanner 70 is moved to the cylinder 61 side by the pulling wire 65. Be drawn to.
In this way, by applying a tensile force in the circumferential direction of the auger screw 50, the auger screw 50 is rotated in the unlocking direction, and the auger screw 50 is removed from the earth auger 40 or another auger screw 50.

  In the tension applying device 60 shown in FIG. 7, the height of the other end 65 b of the pulling wire 65 attached to the outer peripheral surface of the auger screw 50 is adjusted by adjusting the mounting height of the fixed pulley 64. Therefore, it is not necessary to adjust the height of the rotating shaft portion 51 of the auger screw 50, and the working efficiency can be improved.

(Removal of drilling equipment)
The front end 11a of the cab back crane 10 shown in FIG. 1 is removed from the upper frame 33 of the portal frame 30, and the cab back crane 10 is used to mount the portal frame 30, the earth auger 40, the auger screw 50, and the work tool. It is loaded on the loading platform 21 of the truck 20. Then, the excavator 1 is removed from the construction site by running the truck 20 and moving the entire apparatus.

[Effect of drilling equipment]
In the excavator 1 of this embodiment shown in FIG. 1, the portal frame 30 is supported by the cab back crane 10 of the truck 20, and the earth auger 40 is moved by the lifting wire 12 (see FIG. 2) of the cab back crane 10. It is raised and lowered. Further, the entire frame can be moved by loading the portal frame 30, the earth auger 40 and the auger screw 50 on the loading platform 21 of the truck 20.
In this way, excavation work can be performed without installing a crane vehicle other than the truck 20, and the entire apparatus can be moved by one truck 20, so that the excavator 1 can be installed and removed. Can be easily performed.

  Further, since the cab back crane 10 mounted on the truck 20 is used and the earth auger 40 is driven using a hydraulic device and a power supply device mounted on the truck 20, the entire apparatus is configured compactly. And the manufacturing cost of the excavator 1 can be reduced.

  In addition, since a crane having a single line of wire for raising and lowering the earth auger 40 can be used, a general cab back crane 10 is used when performing small-scale construction such as excavating a well. The excavator 1 can be configured by using it. Thereby, the excavator 1 can be downsized and the manufacturing cost of the excavator 1 can be reduced.

Further, as shown in FIG. 4, the connecting shaft 11 b of the arm 11 of the cab back crane 10 is fitted into a concave mounting groove 33 c formed in the upper frame body 33 of the portal frame 30, and the upper frame body 33. The connecting shaft 11b can be fixed in the mounting groove 33c by rotating the fixing bracket 33d provided in the vertical direction.
In this configuration, the connecting shaft 11b of the arm 11 can be easily inserted into and removed from the concave mounting groove 33c.
Further, the connecting shaft 11b can be easily fixed in the mounting groove 33c by rotating the fixing bracket 33d in the vertical direction.
Further, as shown in FIG. 2, the lifting wire 12 directly supports the earth auger 40 without being passed over the upper frame 33 of the portal frame 30, so that the lifting wire 12 can be easily handled. Can be done.

In this way, the arm 11 and the gate frame 30 and the lifting wire 12 and the earth auger 40 can be easily detached, so the portal frame 30 and the earth auger 40 can be easily removed from the track 20 (see FIG. 1). Can be desorbed.
Therefore, when excavation work is not performed, the portal frame 30 can be made to stand on the ground with a wire or rope extending from the ground, and the cab back crane 10 can be quickly removed from the portal frame 30 and the earth auger 40. Thereby, since other work can be performed using the track 20, work efficiency can be improved.

  Further, when removing the auger screw 50 connected to the earth auger 40, as shown in FIG. 6B, the cylinder 61 of the tension applying device 60 provided at the lower end of the portal frame 30 is extended. As shown in FIG. 7, the auger screw 50 can be rotated about the axis in the fixing release direction, so that the auger screw 50 can be connected to the earth auger without using the cab back crane 10 (see FIG. 1). 40 can be removed. Thereby, since a small crane can be used, the excavator 1 can be reduced in size and the manufacturing cost of the excavator 1 can be reduced.

[Other Embodiments]
The embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various design changes can be made without departing from the spirit of the present invention. For example, the excavator 1 of the present embodiment is configured such that the earth auger 40 moves up and down along the portal frame 30 having the two readers 31 and 31, as shown in FIG. You may comprise so that the earth auger 40 may go up and down along this support | pillar.

  Moreover, in the excavation apparatus 1 of this embodiment, the earth auger 40 is used as the excavation means, and the auger screw 50 is attached to the earth auger 40 to excavate the vertical hole. It is not limited and various well-known apparatuses can be used. For example, the upper end of a cylindrical casing can be attached to the output shaft of the drive motor, the surrounding pile can be excavated by the rotating casing, and the existing pile can be cut off from the ground. Thus, the excavator of the present invention can also be used for a pile removing operation.

It is the side view which showed the excavation apparatus of this embodiment. It is the front view which showed the excavation apparatus of this embodiment. It is the top view which showed the base mount frame in the excavation apparatus of this embodiment. It is the figure which showed the arm of the crane in the excavator of this embodiment, and the upper frame material of the gate type | mold frame, (a) is the top view which showed the state before attaching an arm to an upper frame material, (b) is an arm. It is a top view of the state which attached to the upper frame material. It is the figure which showed the aspect when attaching the arm of the crane in the excavator of this embodiment to the upper frame material of a portal frame, (a) is AA sectional drawing of Fig.4 (a), (b) is a figure. It is BB sectional drawing of 4 (b). It is the figure which showed the tension | tensile_strength provision apparatus in the excavation apparatus of this embodiment, (a) is a side view, (b) is a side view of the state which provided tension | tensile_strength to the wire for tension | pulling. It is the figure which showed the tension | tensile_strength provision apparatus in the excavation apparatus of this embodiment, and is the top view which showed the aspect which rotates an auger screw. It is the front view which showed the aspect which pulls up an earth auger using a suspension pulley in the excavation method using the excavation apparatus of this embodiment.

Explanation of symbols

1 Excavator 10 Cab Back Crane (Crane)
DESCRIPTION OF SYMBOLS 11 Arm 11a Tip part 11b Connecting shaft 12 Lifting wire 13 Hook 20 Truck (conveyance vehicle)
21 Loading platform 30 Gate frame (support)
31 Leader 32 Base frame 33 Upper frame 33c Mounting groove 33d Fixing bracket 34 Work table 40 Earth auger (excavation means)
41 Output shaft 50 Auger screw (drilling shaft)
60 Tension applying device (tension applying means)
61 Cylinder 63 Lifting pulley 65 Pulling wire 70 Spanner

Claims (3)

A drilling device for excavating the ground,
A self-propelled transport vehicle including a crane having a tiltable arm and a loading platform;
A support column erected in a state supported by the arm;
A drilling means capable of moving up and down along the support column,
The tip of the arm is detachable from the upper end of the support column, and the support column and the excavation means can be loaded on the loading platform of the transport vehicle and moved.
The tip of the arm is attached to the upper end of the support column to erect the support post, and the lifting wire suspended from the tip of the arm is attached to the excavating means, and the lifting wire is fed out. Alternatively, the excavator is configured so that the excavating means moves up and down along the support column by winding. A connecting shaft protrudes in the lateral direction at the tip of the arm,
The upper end of the support column is provided with a concave mounting groove into which the connecting shaft can be fitted, and a fixing bracket that is rotatable in the vertical direction around the base end.
With the connecting shaft fitted in the mounting groove, the fixing bracket is rotated in the vertical direction, and the fixing bracket is put on the connecting shaft, whereby the connecting shaft is attached to the fixing bracket and the fixing bracket. The excavator according to claim 1, wherein the excavator is configured to be fixed between the mounting groove. The strut is provided with tension applying means for rotating the excavation shaft about the axis in order to remove the excavation shaft connected to the excavation means,
The tension applying means includes
A cylinder having a telescopic rod and fixed to the column;
An elevating pulley attached to the rod of the cylinder;
A linear body for tension stretched over the elevating pulley,
One end of the pulling linear body is fixed to the support column, and the other end is attached to the outer peripheral surface of the excavation shaft, the rod of the cylinder is extended, and the tension is stretched over the lifting pulley. A tension is applied to the wire body for pulling, and a tensile force is applied from the pulling wire body in the circumferential direction of the excavation shaft to rotate the excavation shaft about the axis. The excavation device according to claim 1 or 2, characterized in that.

Images