JP2014196594A - Ground excavator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ground excavator which can improve handling performance by reducing an outside diameter of a casing while having a beacon part which transmits an excavation position to an on-ground receiver.SOLUTION: After excavating by progressing a casing 2 into the ground B, a beacon part 11 attached to a pipe conduit 3 is pulled by a removal jig 15 and removed from a pipe conduit rear end opening of the casing 2, then, an outer pipe is inserted into the pipe conduit 3, a tip cap 8 is pressed to a tip side from a pipe conduit rear end side and removed from the pipe conduit tip side opening 4, the casing 2 is pulled up to the ground while leaving the outer pipe in the ground B, an inner pipe is inserted into the outer pipe, a discharge port formed at the inner pipe is aligned at an injection port of the outer pipe, after that, and a soil improvement chemical is supplied to the inner pipe and injected into the ground B through the discharge port and the injection port.

Description

  The present invention relates to a ground excavation apparatus, and more particularly, to a ground excavation apparatus that has a beacon unit that transmits an excavation position to a receiver on the ground, and that can improve the handleability by reducing the outer diameter of a casing. Is.

  In order to strengthen the ground, a method of injecting a ground improvement chemical into a target ground using a double pipe is known (for example, see Patent Document 1). When injecting the ground improvement chemical into the ground by this method, first, using a tubular ground excavation casing, the ground is excavated by injecting water while jetting water from its tip. Next, the outer pipe is inserted into the pipe line of the casing that is buried in the insertion hole formed by excavating the ground. Next, the outer tube is installed in the ground by pulling the casing to the ground. Then, by moving the inner pipe inserted into the outer pipe line in the pipe axis direction, the discharge port provided in the peripheral wall of the inner pipe is aligned with the injection port provided in the peripheral wall of the outer pipe. The chemical liquid discharged from the discharge port is injected into the ground through the injection port.

  A beacon unit for transmitting the excavation position to a receiver on the ground is provided at the tip of the casing. As illustrated in FIGS. 9 and 10, in the conventional casing 21, the beacon unit 11 is provided adjacent to the pipe line 3 into which the outer pipe is inserted in a subsequent process. Therefore, the outer diameter of the casing 21 is larger than the value obtained by adding the inner diameter of the pipe line 3 and the thickness of the beacon portion 11, and there is a great restriction on reducing the diameter of the casing 21. When the outer diameter of the casing is large, the weight is increased, so that the handleability is lowered. Moreover, since the flexibility deteriorates when the outer diameter of the casing is large, the handleability is further lowered when bending and drilling holes.

JP 2009-2154 A

  The objective of this invention is providing the ground excavation apparatus which can make the outer diameter of a casing small and can improve a handleability, providing the beacon part which transmits an excavation position to the receiver on the ground.

  In order to achieve the above object, the ground excavation apparatus of the present invention proceeds in the ground when the ground is improved by injecting the ground improvement chemical solution into the ground using a double pipe consisting of an inner pipe and an outer pipe. In the ground excavation apparatus provided with a tubular casing that is pulled out to the ground after the outer pipe is inserted into the pipe after being excavated and then left in the ground, the outer pipe is detachably attached to the tip of the pipe of the casing. A tip cap that closes the opening of the pipe end in the attached state, a beacon part that is detachably attached to the pipe on the rear side of the position where the tip cap is attached, and a rear pipe A removal jig inserted from the end side, and the beacon part is pulled to the rear end part side of the pipe by the removal jig and is removed from the opening at the rear end part of the pipe. After being, the tip cap is pushed to the distal end side from the conduit rear end, characterized in that the structure to be removed from the pipe end opening.

  According to the present invention, since the beacon portion is detachably attached to the conduit of the casing, it is not necessary to secure a special space in the casing for installing the beacon portion. Therefore, the outer diameter of the casing can be significantly reduced. As the casing is reduced in diameter, the casing is reduced in weight and the flexibility is improved, so that the handleability is greatly improved.

  In addition, since the beacon part is attached to the rear side of the position of the tip cap attached to the pipe tip of the casing, when the excavation is attempted, dirt and sand from the opening of the pipe tip is blocked by the tip cap and the beacon. Department is protected. And after excavating the ground, the beacon part is removed from the pipe rear end opening, and then the outer pipe is inserted into the pipe, and then the tip cap is removed from the pipe front end opening, thereby bringing the outer pipe into the ground. The casing can be pulled out to the ground while remaining. Therefore, this casing can be used effectively when ground improvement is performed using a double pipe.

It is explanatory drawing which illustrates the state which excavates the ground using the ground excavation apparatus of this invention. It is a front view which illustrates the front-end | tip part of the casing of FIG. It is explanatory drawing which illustrates a removal jig | tool with the AA cross section of FIG. It is BB sectional drawing of FIG. FIG. 6 is a cross-sectional view (corresponding to FIG. 4) illustrating the tip of the casing with different flow path specifications. It is explanatory drawing which illustrates the state which the engaging part of the beacon part removed from the engaging hole of the casing. It is explanatory drawing which illustrates the state which the beacon part moved to the pipe rear end part side. It is explanatory drawing which illustrates the state which pressed the front-end | tip cap from the pipe rear-end part side to the front-end | tip part side. It is a front view which illustrates the front-end | tip part of the conventional casing. It is CC sectional drawing of FIG.

  Hereinafter, the ground excavation device of the present invention will be described based on the embodiments shown in the drawings.

  The ground excavation apparatus 1 of the present invention illustrated in FIGS. 1 to 4 is used for ground improvement by injecting a ground improvement chemical into the ground using a double pipe composed of an inner pipe and an outer pipe. The ground excavation apparatus 1 includes a tubular casing 2 having both ends opened, a tip cap 8 that is detachably attached to a pipe tip of the casing 2, and a pipe line behind the position where the tip cap 8 is attached. 3 is provided with a beacon section 11 that is detachably attached to the head 3 and a removal jig 15 that is inserted from the rear end side of the pipe. Then, after the beacon portion 11 is pulled by the removal jig 15 toward the rear end portion of the pipe line and removed from the rear end opening 5 of the pipe line, and after the beacon part 11 is removed, the tip cap 8 is moved to the rear end of the pipe line. It is configured to be pressed from the section side to the distal end side and removed from the pipe distal end opening 4.

  The casing 2 is made of metal, for example, and is driven by the drilling machine 18 to advance in the ground B and excavate. The tip of the casing 2 has a shape that is obliquely cut and cut. An annular tip blade 7 is attached to the inclined surface of the tip.

  As illustrated in FIG. 3, a ball fitting hole 3 b is formed on the peripheral surface of the distal end portion of the pipe line 3 of the casing 2. In the ball fitting hole 3b, a ball 10 that functions as a stopper for fixing the tip cap 8 is movably provided. The opening of the surface of the casing 2 of the ball fitting hole 3b is plugged with a bolt. A plurality of the ball fitting holes 3b and the balls 10 are provided on the circumferential surface of the pipe line 3 at intervals in the circumferential direction. For example, ball fitting holes 3b and balls 10 are provided at three locations at equal intervals in the circumferential direction.

  As illustrated in FIG. 4, the engagement hole 3 a is formed in the peripheral surface of the pipe line 3 on the rear end side from the position where the ball fitting hole 3 b is formed. In this embodiment, the engagement hole 3 a penetrates the peripheral wall of the casing 2, and the opening on the surface of the casing 2 is plugged with a bolt, but the peripheral surface of the pipe line 3 is not penetrated through the peripheral wall of the casing 2. It can also be indented specifications.

  Further, a flow path 6 a having one end opened on the peripheral surface of the pipe line 3 of the casing 2 and the other end opened on the front end surface of the casing 2 is formed. The other end opening of the flow path 6a is a jet outlet 6b.

  A peripheral surface protrudes from the periphery of the disc-shaped main body of the tip cap 8 toward the rear end of the casing 2, and a ball hole 9 is formed on this peripheral surface. The number of the ball holes 9 corresponds to the number of the ball fitting holes 3b, and is formed at a position facing the ball fitting holes 3b when the tip cap 8 is attached to the pipe tip of the casing 2. An O-ring is fitted on the peripheral surface of the tip cap 8, and the tip cap 8 is attached to the pipe tip of the casing 2 when the O-ring contacts the peripheral surface of the pipe 3. The pipe front end opening 4 is closed.

  In this embodiment, the tip cap 8 is also formed with a flow path 6a. This flow path 6a penetrates the peripheral surface of the tip cap 8 back and forth, and the tip opening is a jet outlet 6b.

  It is a body 12 columnar body of the beacon part 11, and the outer diameter of the body 12 is slightly smaller than the inner diameter of the pipe line 3. The beacon unit 11 has a transmission unit 13 that transmits the excavation position (tip position of the casing 2) to the receiver 20 on the ground. The portion of the body 12 corresponding to the transmission unit 13 is formed of a material (resin or the like) that allows radio waves to pass. In addition, when the beacon part 11 is attached to the pipeline 3, the part of the casing 2 corresponding to the transmission part 13 is also formed of a material (resin or the like) that allows radio waves to pass therethrough.

  The beacon portion 11 has an engagement portion 14 a that moves in the radial direction of the body 12 and protrudes outward from the outer peripheral surface of the body 12. The engaging portion 14a is constantly urged by an urging member such as a spring so as to protrude outward from the outer peripheral surface of the body 12.

  There are a plurality of engaging portions 14a, and it is preferable that they are arranged at equal intervals in the circumferential direction. The engagement holes 3a are formed at positions corresponding to the engagement portions 14a by the number corresponding to the engagement portions 14a. Therefore, when the engaging portion 14 a protrudes outside the outer peripheral surface of the body 12, the engaging portion 14 a is engaged with the engaging hole 3 a formed on the peripheral surface of the pipe 3. . A locking portion 14 b is provided at the rear end portion of the beacon portion 11. The locking portion 14b is provided in the vicinity of the axial center (radial center) of the body 12.

  The removal jig 15 is an elongated rod-like body, and is inserted from the pipe rear end side through the pipe rear side opening 5 of the casing 2. A crochet-like locking claw 16 is provided at the tip of the removal jig 15. In this embodiment, it has the centering mechanism 17 which centers the latching claw 16 to the axial center (radial direction center) of the pipe line 3. As the centering mechanism 17, for example, a plurality of rollers arranged at intervals in the circumferential direction on the side surface of the elongated rod-shaped body removal jig 15 and biased in a direction protruding radially outward of the elongated rod-shaped body Etc. can be used.

  In addition, as illustrated in FIG. 5, the specification may be such that the channel 6 a is formed only in the tip cap 8. In the case of this specification, when the casing 2 is press-fitted into the ground B, water is jetted only from the tip of the tip cap 8 (jet port 6b).

  When excavating the ground B using the ground excavating apparatus 1 and injecting the ground improvement chemical into the ground, first, the distal end cap 8 is inserted into the distal end portion of the pipe line 3 of the casing 2. Next, the beacon part 11 is inserted into the pipe line 3 from the pipe rear end opening 5. In that case, the front-end | tip part of the body 12 of the beacon part 11 is inserted in the front-end | tip cap 8, and the inner peripheral side opening of the ball hole 9 is plugged up. The beacon part 11 is fixedly attached to the pipe line 3 by engaging the engaging part 14a with the engaging hole 3a.

  In addition, without providing the engagement hole 3a in the peripheral surface of the pipe line 3, the engagement part 14a protruded outside the outer peripheral surface of the body 12 of the beacon part 11 is crimped to the peripheral surface of the pipe line 3. The beacon unit 11 can be fixedly attached to the pipeline 3.

  Next, the ball 10 is inserted into the ball fitting hole 3b, and the ball 10 is fitted into and engaged with the ball fitting hole 3b and the ball hole 9. By the engagement of the ball 10, the tip cap 8 is fixedly attached to the tip portion of the conduit 3.

  Next, the casing 2 to which the distal end cap 8 and the beacon portion 11 are attached is extended from the hole drilling machine 18 into the ground B as illustrated in FIG. In FIG. 1, the insertion hole S is bent in the middle, but the insertion hole S may be formed in the vertical direction. The traveling direction of the casing 2 can be changed by rotating the casing 2 around the axis and changing the direction of the tip blade 7.

  When the casing 2 is press-fitted into the ground B, water is supplied into the casing 2. The supplied water is jetted from the jet outlet 6 b through the flow path 6 a formed on the peripheral surfaces of the casing 2 and the tip cap 8. The ground B is smoothly excavated by the jetted water. Since the beacon unit 11 (transmission unit 13) has a waterproof structure, this water does not enter. While excavating the ground B with the casing 2, the excavation position is sequentially transmitted from the transmission unit 13 of the beacon unit 11 to the receiver 20 on the ground.

  In the present invention, since the pipe tip end opening 4 of the casing 2 is closed by the tip cap 8, it is possible to prevent the earth and sand of the ground B from entering the pipe 3 during excavation. Thereby, the beacon part 11 is fully protected. Further, since the ball 10 is fitted into and engaged with the ball engaging hole 3b and the ball hole 9, the tip cap 8 is firmly fixed to the conduit 3 and is difficult to come off.

  After the insertion hole S is formed up to the predetermined position, the removal jig 15 is inserted from the pipe rear end side as illustrated in FIG. Then, the locking claw 16 is locked to the locking portion 14 b of the beacon portion 11. By providing the centering mechanism 17, it becomes easy to lock the locking claw 16 to the locking portion 14b.

  In a state where the locking claw 16 is locked to the locking portion 14b, the detaching jig 15 is pulled toward the rear end of the pipe, so that the engaging portion 14a resists the urging force by the urging member and the body 12 Moves radially inward and disengages from the engaged engagement hole 3a. Therefore, as illustrated in FIG. 7, the beacon unit 11 is pulled and moved toward the pipe rear end by the removal jig 15 and is removed from the pipe rear end opening 5. When the beacon part 11 moves to the pipe rear end side, the ball 10 fitted in the ball fitting hole 3b and the ball hole 9 is detached from the ball fitting hole 3b. As a result, the tip cap 8 can move freely with respect to the casing 2.

  Next, as illustrated in FIG. 8, the outer pipe 19 is inserted from the pipe rear end opening 5. The distal end cap 8 is pressed from the rear end side of the duct toward the distal end side with the distal end portion of the inserted outer pipe 19 and removed from the duct distal end opening 4. Instead of the outer tube 19, a dedicated pressing jig can be inserted into the conduit 3 to press and remove the tip cap 8.

  Next, the outer pipe 19 is installed in the ground B by pulling out the casing 2 to the ground while leaving the outer pipe 19 in the ground B. An inlet is formed in the peripheral wall of the outer tube 19. As is well known, the inner pipe is inserted into the outer pipe 19 installed in the ground B, and the discharge port formed in the inner pipe is aligned with the inlet of the outer pipe 10, and then the ground is improved on the inner pipe. The chemical solution is supplied and injected into the ground B through the discharge port and the injection port.

  As described above, according to the present invention, since the pipe line 3 of the casing 2 is skillfully used as a place for attaching the beacon part 11, a special space for installing the beacon part 11 is secured in the casing 2. There is no need. Therefore, the outer diameter of the casing 2 can be significantly reduced. As the diameter of the casing 2 is reduced, the casing 2 is reduced in weight and the bendability is improved, so that the handleability is greatly improved.

  Further, during excavation, even if the earth and sand S try to enter from the pipe front end opening 4, the end cap 8 is blocked and the beacon unit 11 is protected. And after excavating the ground B, the beacon part 11 can be removed from the pipe rear end opening 5, and the tip cap 8 can be removed from the pipe tip end opening 4. The casing 2 can be pulled out to the ground while remaining in B. Therefore, the casing 2 can be effectively used when ground improvement is performed using a double pipe.

DESCRIPTION OF SYMBOLS 1 Ground excavation apparatus 2 Casing 3 Pipe line 3a Engagement hole 3b Ball fitting hole 4 Pipe front-end | tip part opening 5 Pipe rear-end opening 6a Flow path 6b Outlet 7 Tip blade 8 Tip cap 9 Ball hole 10 Ball 11 Beacon Part 12 Body 13 Transmission part 14a Engagement part 14b Locking part 15 Removal jig 16 Locking claw 17 Centering mechanism 18 Drilling machine 19 Outer pipe 20 Receiver 21 Conventional casing B Ground S Insertion hole

Claims (4)

When improving the ground by injecting the ground improvement chemical solution into the ground using a double pipe consisting of an inner pipe and an outer pipe, the outer pipe is inserted into the pipe after being excavated through the ground, In the ground excavation apparatus having a tubular casing that is pulled out to the ground while leaving the outer pipe in the ground,
A tip cap that is detachably attached to the pipe tip of the casing, and closes the pipe tip opening in the attached state, and is detachable from the pipe on the rear side of the position where the tip cap is attached. A beacon part attached to the pipe rear end side, and the beacon part is pulled to the pipe rear end side by the removal jig from the pipe rear end opening. The ground excavation device is configured to be removed and removed from the pipe front end opening by pressing the front end cap from the pipe rear end side to the front end side after the beacon part is removed. .   The beacon portion is provided at the rear end portion of the beacon portion, and is engaged with the detaching jig and is moved to the beacon portion in the radial direction and protrudes outside the outer peripheral surface of the beacon portion. The ground excavation device according to claim 1, further comprising a locking portion that moves the engagement portion radially inward of the beacon portion by being pulled toward a rear end side.   The engagement portion engages with an engagement hole formed in an inner peripheral surface of the pipe line when the engagement portion protrudes outside the outer peripheral surface of the beacon portion. End cap of ground excavation casing.   The ground excavation according to claim 2 or 3, wherein a locking claw that locks the locking portion and a centering mechanism that centers the locking claw on the axis of the pipe line are provided on the removal jig. apparatus.

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