JP6450089B2 - Underground Obstacle Search Method and Underground Obstacle Search Device - Google Patents

Description

The present invention relates to a method for searching for underground obstacles, and more particularly to a method for searching for underground obstacles such as remaining piles by drilling a casing in a substantially horizontal direction and using magnetism. . The present invention also relates to an underground fault search apparatus for measuring magnetic data by inserting a magnetic sensor.

  When searching for obstacles in the ground using magnetism, conventionally, a cronen bit is attached to the tip of the casing in a substantially vertical downward direction to drill a casing, and then a hollow intubation tube is inserted into the casing. Insert, pull out the casing, inject a filler such as sand into the gap, form a survey hole, insert a magnetic sensor into the survey hole, measure magnetic data, and check the obstacles in the ground Was exploring. As described above, when the survey hole is formed substantially vertically downward, a filler such as sand can be injected into the gap portion using gravity, and the kronen bit functions as a check valve. Therefore, during drilling, it becomes possible to effectively prevent groundwater from entering the casing, and since the hole is drilled substantially vertically downward, the groundwater acts on the Kronen bit from below, Bits never get out.

  However, when drilling casings, forming survey holes, and surveying underground obstacles such as remaining piles, the underground obstacles are explored unless many survey holes are formed. There was a problem that could not be done.

  Such a problem can be solved by forming a survey hole in a substantially horizontal direction. However, in a conventional underground obstacle exploration method, a filler such as sand is injected into the void using gravity. There is a problem that the investigation hole is bent due to the gap. In addition, when the casing is pulled out, the underground hole or earth and sand in the ground flows from the tip of the hollow intubation tube and the investigation hole is blocked, so that the investigation hole cannot be formed as desired. there were.

Accordingly, an object of the present invention is to provide a method for exploring an obstacle in the ground using a magnetic sensor by forming a survey hole in a substantially horizontal direction. It is an object of the present invention to provide an underground fault survey apparatus for measuring the above.

An object of the present invention is to drill a hole in a substantially horizontal direction using a casing in which a kronen bit having a screw part at a rear end part is attached to a tip part. A guide pipe having an injection member provided with a screw part at the tip part and having a slit formed around the tip part is inserted, and the screw part of the clonen bit and the screw part of the injection member are connected. Screwed to connect the kronen bit and the injection member, pull out the casing, inject a filler into the injection member, and the casing is in contact with the slit of the injection member An underground obstacle characterized in that a gap formed between a ground part and an injection member is filled with the filler, and a magnetic sensor is inserted into the guide pipe to measure magnetic data. Exploration It is achieved by law. The injection member includes a connection joint connected to the guide pipe.

  According to the present invention, using a casing in which a kronen bit having a threaded portion at the rear end is attached to the tip, a hole is drilled in a substantially horizontal direction, and the guide pipe located in the formed survey hole is formed. Since it is configured to detect magnetic data by inserting a magnetic sensor and search for underground obstacles such as remaining piles, a number of surveys are conducted to search for underground obstacles such as remaining piles. There is no need to dig a hole, and therefore the cost and time required for exploring underground obstacles such as left piles can be greatly reduced.

  Further, according to the present invention, since the kronen bit is attached to the front end portion of the casing, it is possible to prevent water and earth and sand from entering the casing from the front end portion of the casing when the casing is drilled.

  Furthermore, according to the present invention, since the screw part of the cronen bit and the screw part of the injection member are screwed together and the cronen bit and the injection member are connected, the casing is pulled out. When the water is pulled out, it becomes possible to reliably prevent the groundwater from flowing into the injection member.

In a preferred embodiment of the present invention, the injection member comprises a perforated pipe in which the slit is formed, a sleeve rubber covering the slit of the perforated pipe, and the connection joint, and injects the filler. said from the slit of the perforated pipe pushing up the sleeve rubber when the filler is configured to discharge the slit DOO or al.

In a preferred embodiment of the present invention, the guide pipe is that made of vinyl chloride resin, a note inlet hose through the guide pipe is inserted into said injection member, by the injection hose, the filling material into the injection the member It is configured to inject, and a packer is provided near the discharge port of the injection hose so that the discharged filler does not flow into the guide pipe.

  According to a preferred embodiment of the present invention, since the magnetic sensor is arranged in the guide pipe made of vinyl chloride resin, the magnetic sensor is not affected by the magnetism of the member for exploring underground obstacles. , Magnetic data of obstacles in the ground can be detected as desired.

  In a preferred embodiment of the present invention, the packer in the vicinity of the discharge port of the injection hose forms a closed section with the front end packer and the rear end packer of the injection member with respect to the slit formed in the injection member. Two packers are provided.

  According to the present invention, a casing is drilled in a substantially horizontal direction, a magnetic sensor is inserted into a guide pipe of the formed underground obstacle exploration device, magnetic data is detected, a remaining pile, etc. Because it is configured to search for underground obstacles, it is not necessary to drill a number of survey holes to search for underground obstacles such as remaining piles. Costs and time required for exploring objects can be greatly reduced.

  Further, according to the present invention, since the kronen bit is attached to the front end portion of the casing, it is possible to prevent water and earth and sand from entering the casing from the front end portion of the casing when the casing is drilled.

  Furthermore, according to the present invention, since the casing is pulled out after connecting the kronen bit and the injection member, when the casing is pulled out, groundwater can be reliably prevented from flowing into the gap. Is possible.

  In addition, according to the present invention, after the casing is drilled, the injection member is screwed into the cronen bit, and the sleeve rubber covering the slit of the injection member is provided, so that water and earth are injected when the casing is pulled out. Inflow into the member can be prevented.

  Furthermore, according to the present invention, since the filler is filled from the tip side of the drilling hole toward the mouth of the casing drilling hole, no gap is generated around the guide pipe, and the underground obstacle search is integrated with the ground. A device can be arranged.

  In addition, according to the present invention, the filler does not enter the guide pipe by the packer, and it is possible to omit soil removal and cleaning work before exploration.

  Furthermore, in the present invention, when a vinyl chloride resin guide pipe is used as the guide pipe, since the magnetic sensor is disposed in the vinyl chloride resin pipe, the magnetic of the member for exploring underground obstacles is used. The magnetic data can be detected as desired by the magnetic sensor without being affected by the above.

  Further, according to the present invention, an injection member that is drilled in a substantially horizontal direction and includes a screw portion at a tip portion and a slit formed in the periphery in the casing in the drilling direction is connected to the tip portion. Since the guide pipe made of polyvinyl chloride resin is inserted and the guide pipe can be arranged in a substantially horizontal direction, the detected magnetic sensor data and the positional relationship on the drawing are examined more closely than in the case of a winding arrangement. The correction calculation work can be made much easier.

FIG. 1 is a schematic vertical cross-sectional view of a ground obstacle search device used for executing a ground obstacle search method according to a preferred embodiment of the present invention. FIG. 2 is a schematic longitudinal sectional view of the underground obstacle exploration device after the casing 1 is pulled out. FIG. 3 shows an underground obstacle exploration apparatus in which the filler is injected into the injection hose and the filler is injected into the gap through a number of slits formed in the connecting manchette tube. It is a longitudinal cross-sectional view.

  FIG. 1 is a schematic vertical cross-sectional view of a ground obstacle search device used for executing a ground obstacle search method according to a preferred embodiment of the present invention.

  As shown in FIG. 1, the underground obstacle exploration device according to this embodiment includes a casing 1, a guide pipe 2 made of vinyl chloride resin inserted into the casing 1 after being drilled in the casing 1. It has. An injection member 4 is connected to the distal end portion of the guide pipe 2 via a connection joint 3.

  A slit 6 a is formed in the injection member 4.

  The injection member 4 is formed by a perforated pipe 4 a in which a slit 6 a is formed, a sleeve rubber 6 b that covers the slit 6 a, and a connection joint 3 that is connected to the guide pipe 2.

  A screw portion (not shown) formed at the tip end portion of the injection member 4 is screwed with a screw portion (not shown) formed at the rear end portion of the kronen bit 8 for drilling the ground with the casing 1. Are combined. As described above, the underground exploration device is formed of the kronen bit 8, the injection member 4, the connection joint 5, and the guide pipe 2 from the front end side in the drilling direction.

  When the underground obstacle exploration device is provided in the ground, first, the casing 1 in which the drive shoe 7 is screwed to the tip of the casing 1 and the kronen bit 8 is fitted to the engaging portion 7a of the drive shoe 7 is provided. Thus, the casing is drilled so that the underground obstacle exploration device is in a substantially horizontal direction in the ground.

  After the ground is drilled to a predetermined position, a screw portion (not shown) formed at the rear end portion of the kronen bit 8 and a screw portion (not shown) formed at the tip portion of the injection member 4 Are screwed together.

  Here, the tip end portion of the guide pipe 2 is connected to the rear end portion of the injection member 4 via the connection joint 3 in advance.

  Thus, the underground obstacle exploration device shown in FIG. 1 is assembled in a substantially horizontal direction in the ground.

  Next, the screwing of the casing 1 and the drive shoe 7 is released, and the casing 1 is pulled out.

  FIG. 2 is a schematic longitudinal sectional view of the underground obstacle exploration device after the casing 1 is pulled out.

  As shown in FIG. 2, as a result of the casing 1 being pulled out, a gap 10 is formed between the clonen bit 8, the drive shoe 7, the injection member 4, the connection joint 3, and the guide pipe 2 and the ground. .

  Next, an injection hose 11 for injecting the filler in the gap 10 is inserted into the injection member 4 through the guide pipe 2 and the connection joint 3.

  When the injection hose 11 is inserted and reaches a predetermined position, a filler such as cement bentonite is injected into the injection hose 11, and the sleeve rubber 6b is pushed up through the slit 6a formed in the injection member 4, It is injected into the gap 10. A packer 12 is provided near the discharge port 11 a of the injection hose 11 so that the discharged filler does not flow into the guide pipe 2.

  FIG. 3 is a longitudinal sectional view of the underground obstacle exploration device in which a filler is injected into the injection hose 11 and is injected into the gap 10 through the slit 6 a formed in the injection member 4. It is.

  In the vicinity of the discharge hole 11 b of the injection hose 11, a packer 12 is provided at a position sandwiching the discharge hole 11 b and the hole 11 b. That is, the packer 12 in the vicinity of the discharge port of the injection hose is closed by the packer 12a located on the front end side of the injection member and the packer 12b located on the rear end side with respect to the slit 6a formed in the injection member. It is a double packer that forms Therefore, since the filler is discharged from the slit 6a, the filler does not enter the guide pipe 2.

  Thus, when the gap 10 is filled with a filler such as cement bentonite, the guide pipe 2 is buried in the ground substantially without a gap in the horizontal direction.

  In magnetic exploration, a magnetic sensor is inserted into the guide pipe 2 to detect magnetic data.

  According to the present embodiment, the casing is drilled in a substantially horizontal direction, and a magnetic sensor (not shown) is inserted into the guide pipe 2 of the formed underground obstacle exploration device. It is not necessary to drill a number of survey holes in the vertical direction in order to search for underground obstacles. Therefore, the cost and time required for searching underground obstacles such as remaining piles can be greatly reduced. It becomes possible.

  In addition, according to this embodiment, the drive shoe 7 is screwed into the distal end portion of the casing 1, the screw portion formed at the distal end portion of the injection member 4, and the kronen bit 8 for drilling the ground. Since the kronen bit 8 is fitted to the locking portion 7a of the drive shoe 7 so that the screw portion formed with the rear end portion can be screwed together, the casing 1 It is possible to effectively prevent water and earth and sand from flowing into the casing 1 from the tip. Therefore, the underground obstacle searching device including the guide pipe 2 can be disposed at a desired position in the ground.

  Furthermore, according to this embodiment, since the filler is filled from the front end side of the drilling hole toward the mouth of the casing drilling hole, no gap is generated around the guide pipe 2, and the ground is integrated with the ground. A medium obstacle exploration device can be arranged.

  Further, according to the present embodiment, the filler does not enter the guide pipe by the packer, and it is possible to omit soil removal and cleaning work before the exploration.

  Furthermore, according to the present embodiment, since the magnetic sensor is arranged in the guide pipe 2 made of vinyl chloride resin, the magnetic sensor does not affect the magnetism of the member of the underground obstacle exploration device, and the desired value is obtained. As described above, magnetic data can be detected.

  Further, according to the present embodiment, the guide pipe 2 made of vinyl chloride resin can be arranged in a substantially horizontal direction, so that the detected magnetic sensor data and the position on the drawing are compared with the case of the winding arrangement. The correction calculation work for examining the relationship becomes much easier.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say.

  For example, in the above embodiment, the guide pipe 2 is made of vinyl chloride resin, but it is not always necessary to form the guide pipe 2 with vinyl chloride resin. The guide pipe 2 may be formed, and the guide pipe 2 may be formed of polypropylene resin or polyethylene resin instead of the vinyl chloride resin.

DESCRIPTION OF SYMBOLS 1 Casing 2 Guide pipe made from a vinyl chloride resin 3 Connection joint 4 Injection | pouring member 6a Slit 6b Slit 7 Drive shoe 7a Locking part of a drive shoe 8 Kronen bit 10 Cavity 11 Injection hose discharge port 11b Injection hose discharge port 12 Packer 12a Front end side packer 12b Rear end side packer

Claims (5)

Using a casing in which a cronen bit having a threaded portion at the rear end is attached to the leading end, a hole is drilled in a substantially horizontal direction, and a threaded portion is formed at the leading end in the casing in the drilling direction. A guide pipe having an injection member having a slit formed in the periphery thereof and connected to a distal end portion is inserted, and the screw portion of the kronen bit and the screw portion of the injection member are screwed together, and the krone And the injection member are connected, the casing is pulled out, a filler is injected into the injection member, and the ground portion where the casing is in contact via the slit of the injection member and the injection An underground obstacle exploration method for measuring magnetic data by filling a gap formed with a member with the filler and inserting a magnetic sensor into the guide pipe,
The underground injection method according to claim 1, wherein the injection member includes a connection joint connected to the guide pipe. The injection member is composed of a perforated pipe in which the slit is formed, a sleeve rubber that covers the slit of the perforated pipe, and the connection joint, and when the filler is injected, the injection member pushing up the sleeve rubber from the slit, underground obstacles exploration method according to claim 1 the filler is characterized by being configured to discharge said slit DOO or al.   The guide pipe is made of a vinyl chloride resin, and an injection hose is inserted into the injection member through the guide pipe, and the injection material is injected into the injection member by the injection hose. The underground obstacle search method according to claim 1 or 2, wherein a packer is provided in the vicinity of the discharge port of the hose so that the discharged filler does not flow into the guide pipe. The packer in the vicinity of the discharge port of the injection hose is a packer that forms a closed section with the front end side packer and the rear end side packer of the injection member with respect to the slit formed in the injection member. The underground obstacle exploration method according to claim 3 . A ground fault search device disposed in a substantially horizontal hole formed by pulling out a casing for hole removal removed from a kronen bit ,
It said Kronenburg bit having a threaded portion at the rear end portion,
An injection member provided with a screw part screwed into the screw part of the kronen bit at the tip part with respect to the drilling direction, and a large number of slits formed around it,
A guide pipe in which the injection member is connected to the tip ;
A magnetic sensor inserted into the guide pipe;
A filler filled in a gap formed between the ground portion where the pulled-out casing was in contact and the injection member ;
It said injection member is ground fault location device, characterized in that it comprises a connection fitting which is connected to the guide pipe.