JP5890566B1 - Marked boring rod and boring hole trajectory correction method using this - Google Patents

Abstract

A boring hole trajectory correcting method that enables hole trajectory control dredging in drain boring. The present invention comprises a step of aligning and connecting the provided markers so that they are at the same position on the circumference when unit boring rods are connected, and a trajectory correction bit at one end of the connected rods. A step of adjusting the other end of the connected rods so that the trajectory correction bits are arranged in the trajectory correction direction, and a step of correcting the hole trajectory in the direction in which the trajectory correction bits are arranged. The unit boring rod is connected to both ends of the unit boring rod so that when the unit boring rod is connected, the mark provided on the circumference is at the same position on the circumference of each unit boring rod. The connection part is provided. [Selection] Figure 1

Description

  The present invention relates to a marked boring rod and a boring hole trajectory correcting method using the same, and more specifically, the labeled boring rod is applied to set a boring machine in a target direction, and the work needs to be corrected. In particular, the present invention relates to a marked boring rod for correcting a punch lot hole trajectory and a boring hole trajectory correcting method using the same.

Boring refers to an operation of excavating a cylindrical hole mainly in the ground such as a tunnel or a well. In Japanese, it is also expressed as a borehole or sakusei, and is used in various industrial and academic fields such as geological survey, agriculture, hydrology, civil engineering, oil, and natural gas.
There are large-scale bowling and small-scale bowling.
As a large-scale boring, there is a bowling for shale gas, and as a small-scale boring, there is a relatively short horizontal boring connecting manholes and manholes in sewage, which is also called a propulsion method.
In recent years, hole trajectory control has been demanded for both large-scale and small-scale boring. Boring technology for shale gas in particular involves high-accuracy hole trajectory control. It is supported.
Obviously, large-scale boring hole trajectory measurement is impossible by visual measurement, and a gyroscope or the like is mainly used.
When the gyroscope starts up, the gyroscope maintains its starting posture even if the case in which the gyroscope is inserted (the tip of the boring rod or casing to be measured) rotates, and detects the gyroscope's posture. By doing so, hole trajectory measurement is possible even in boring that bends from vertical to horizontal.
In accordance with the measurement, boring with excavating equipment that can be bent in the direction to be bent is performed, and 5,000 depths (lengths) are drilled.

Boring is an act of digging by adding propulsive force, rotational force, and sometimes striking force to a boring rod or casing, and in both cases, iron pipes (boring rods and casings) are used for excavation while connecting the iron pipes. Work is done.
Sewage pipes, which are small-scale sewage pipe buried boreholes, have high accuracy because the sewage pipes face upwards than planned or the middle part of the sewage pipes can be deformed up and down, causing problems such as the inability of filth to flow. Hole trajectory control is required.
In addition to dedicated surveying equipment (transit, etc.), visual inspection is often used for hole trajectory measurement used in sewage pipe buried boring.
A dedicated surveying instrument (transit, etc.) is used to check the hole trajectory by looking at the tip target (visible luminescent object) placed at the tip of the boring iron pipe. This is a method for confirming where the tip is located.
When these methods are bent from the bore iron pipe inner diameter, measurement becomes impossible.

One of the small-scale boring is collection / drainage boring.
This is for draining the groundwater collected at the drainage well, and high accuracy is required at the planned position.
There are various causes of accuracy degradation, that is, hole bending, due to natural factors such as geology and geological structure, type of machine used, output, due to drilling, mechanical operation, surveying error, etc. Although it is divided into two categories, natural factors account for about half.
However, since drain boring is easy to bend a hole, dedicated surveying equipment (transit etc.) used for small-scale boring and visual inspection cannot be used. Conventionally, it is due to the operator's skill to bring this close to the planned position, that is, , It was supposed to be a showcase for the operator's arms.

Japanese Patent Laid-Open No. 09-032449

  An object of the present invention is to provide a marked boring rod in drainage boring and a boring hole trajectory correcting method that enables hole trajectory control using the same.

The present invention is a boring rod for hole trajectory control,
A unit boring rod connectable in the longitudinal direction;
A connecting portion formed of screws provided at both ends of the unit boring rod;
A marker provided on the circumference of the unit boring rod adjacent to the connecting portion at both ends of the unit boring rod ;
Including
The mark is a circular or polygonal hole provided on the circumference of the unit boring rod.

By the screw, when the boring rod of two unit was screwed, the circumferential position of the label provided at both ends of the boring rod screwed the two units are in the same position in the circumferential direction It is characterized by.

The marker is a circular or polygonal outer circle with a diameter of 10 mm provided on the circumference of the unit boring rod, and a hole with a diameter of 10 mm, and is provided adjacent to a connecting portion between two unit boring rod ends. Features.

Further, the present invention, when provided label are linked to two unit boring rod, the circumferential position of the label provided on the tube ends of the two unit boring rod connected is on the circumference same Aligning and connecting to position,
Attaching a trajectory correction bit to the leading edge of one end of the coupled unit boring rods ;
The trajectory correction bit is attached to the most distal end of one end of the connected unit boring rods, and the bit having a tooth shape is a free end of the trajectory correction bit. Adjusting at the other end of the boring rod provided in part and connected so that a hole is dug in the direction in which the bit is provided ;
Adjusting at the other end of the connected boring rods so that a trajectory correcting bit at the extreme end of one end of the boring rod is arranged in the trajectory correcting direction;
A step of correcting the hole trajectory in the direction in which the trajectory correction bits are arranged; and
Consists of
The mark is a circular or polygonal hole provided on the circumference adjacent to the connecting portion at both ends of the unit boring rod. When the two unit boring rods are connected, the two unit borings connected to each other The circumferential position of the rod sign is the same in the circumferential direction, and when correcting the hole trajectory, based on the circumferential deviation of the circumferential position of the two connected unit boring rod signs The boring hole trajectory is corrected .

  At both ends of the unit boring rod, there are connecting units for connecting the unit boring rods so that when the unit boring rod is connected, the markings provided on the circumference are at the same position on the circumference of each unit boring rod. It is provided.

  The mark is a circular or polygonal hole provided on the circumference of the unit boring rod.

The trajectory correction bits are attached to the leading edge portion of one end of the unit boring rod linked, the bit is a tooth of the circular ring portion of the tube cross-section of the trajectory correction bit tip is a free end of the trajectory correction bits It is provided in a part and is characterized in that a hole is dug in the direction in which the bit is provided.

The marker is provided adjacent to a connecting portion at both ends of the unit boring rod, and a circular or polygonal circumscribed circle having a diameter of 10 mm provided on the circumference of the unit boring rod is a hole having a diameter of 10 mm. And

  According to the present invention, when unit boring rods are connected, the punch mark on the outer periphery of each unit boring rod is located at the same position on the outer periphery of the boring rod, and the hole locus correction bit is attached to the tip of the rod. It can be confirmed at the base of the boring mouth, and the borehole trajectory can be corrected in the drainage boring by turning the bit in the direction to be corrected.

It is a figure which shows horizontal boring. It is a figure which shows water collection boring. It is a figure which shows drainage boring. It is a figure which shows the hole locus | trajectory measurement by visual observation. It is a figure which shows the boring rod for hole locus | trajectory control of this invention. It is a figure which shows a bit.

The present invention provides a boring rod with a mark in drain boring and a boring hole trajectory correcting method that enables hole trajectory control utilizing the same.
Recently, landslide damage due to heavy rain has occurred frequently. As a method for preventing landslide damage, there is a method of reducing the groundwater pressure in the landslide site, and one of the methods is draining boring.
Water draining boring includes horizontal boring shown in FIGS. 1 and 2 and water collecting boring constructed from within the water collecting well.
Horizontal boring is draining boring performed from the surface, and water collecting boring is draining boring performed from within a drainage well or drain tunnel.
Drainage boring is a boring that is constructed in order to drain the groundwater collected at the drainage well.
Drainage boring is usually drilled from the drainage well to the outside, but since the tip position is limited, high drilling accuracy is required.

In boring, bending occurs depending on the geology and the conditions of the strata. Therefore, the boring machine's feed force, rotation speed, etc. are changed so that it digs straight.
The reason why bending occurs in horizontal boring is that in the case of a soft stratum, the stratum is soft and cannot support the weight of the rod tip, and the rod tip tends to bend downward. Further, in the case of a strata that tends to collapse, collapsible sediment and excavated sediment accumulate in the lower part, and the tip of the rod tends to bend upward.
In addition, there are bending due to rotation, due to excessively large feeding force, and due to changes in the hardness of the formation.

As a small-scale example, there is an example of sewage pipe embedded boring. In this case, the diameter of the sewage pipe connecting the manhole and the manhole is 30 to 50 cm, and the length is 30 to 50 m.
If the tip of the sewage pipe faces upward from the plan, or if the slack occurs in the middle part, it will hinder the flow of filth, so highly precise hole trajectory control is required.
In sewage pipe buried boring, hole trajectory measurement is often performed visually. As shown in FIG. 4, the visual inspection is a method of checking the position of the boring tip by looking into the boring iron pipe with the naked eye.
A dedicated surveying instrument (transit, etc.) may be used, and the hole trajectory is confirmed by looking at the tip target (e.g., luminous object) placed at the tip of the boring iron pipe. When the bend becomes large, measurement becomes impossible.

An example of large-scale boring is shale gas drilling.
The key to shale gas mining is that the establishment of this technology, which is a borehole trajectory control technology, is said to be extremely large.
Since shale gas mining boring extends to several thousand meters deep in the ground, naturally, boring hole trajectory measurement is impossible by visual measurement, and a gyroscope or the like is mainly used.
In addition to visual inspection and gyroscope, hole trajectory measurement includes a method of obtaining the hole trajectory by measuring the direction of gravity (measured with a leveling device) and the direction of magnetic force (the magnet points to magnetic north).

As mentioned above, drilling is controlled by hole trajectory, and it is difficult to apply hole trajectory correction technology to prevent landslides. Catchment boring, drainage well, drainage boring method (collection / drainage) Bowling).
It is extremely effective to lower the groundwater level as a countermeasure against landslides, and this collection and drainage boring is often used to prevent landslides, connecting drainage pipes between drainage wells and drainage wells, and surface drainage pipes from drainage wells. It is constructed for the purpose of laying.
This collection / drainage boring has a tube diameter of 100 mm to φ125 mm, a drainage boring depth of around 100 m, and when the diameter is 100 mm, the length: diameter ratio is 1,000 times, and it can be said to be a medium-scale boring.
Small-scale boring provides easy and high-accuracy hole trajectory control by visual inspection, and provides an economic effect commensurate with its scale. With large-scale boring, hole trajectory control in the target direction can be performed with high-precision equipment such as a gyroscope. It has been done and has great economic effects such as resource acquisition.

However, in medium-scale boring, simple and inexpensive hole trajectory control boring cannot be used, and hole trajectory control boring with an expensive gyroscope or the like and high-accuracy hole trajectory correction linked therewith cannot be used.
In addition, landslide drainage boring has a difficult problem for boring, such as hard rock (rock mass) and soft rock (clay, sand, etc.) mixed in the target stratum.

The present invention intends to establish as a hole trajectory control technique the operation of hitting the tip of a drainage boring, which has been entrusted to the operator's arm in the past, as a hole trajectory control technique. It is characterized by correction.
As shown in FIG. 5, the hole trajectory control boring rod 1 of the present invention is
A connecting portion 4 provided at both end portions 2 and 3 of the unit boring rod 1;
And a marker 5 provided adjacent to the connecting portion 4 at both ends 2 of the unit boring rod 1.
The mark 5 is a circular or polygonal hole provided on the circumference of the unit boring rod 1 and is provided adjacent to the connecting portions 4 of both end portions 2 and 3 of the unit boring rod 1. The size does not affect the strength.
The connecting portion 4 is constituted by a screw 6, and when the unit boring rod 1 is screwed, the screw 6 has a circumference of the mark 5 of the two screwed unit boring rods 1 as shown in FIG. The direction position is the same.

The screw 6 that connects the boring rod 1 includes a screw that changes the screwing position by adjusting the screwing force (tapered screw), and a screw that does not change its position when the screwing is finished, no matter how much force is applied thereafter.
The boring lot 1 of the present invention can be neglected even if the boring lot 1 is connected by any number of straight screws using the straight screw, and the boring with the sign 5 connected as shown in FIG. 5 (B). Come to the same position in lot 1.
The marking 5 of the boring rod 1 is a circular or polygonal hole provided on the circumference of the unit boring rod 1 and is provided adjacent to the connecting portions 4 of both end portions 2 and 3 of the unit boring rod 1. The size does not affect the strength of the boring rod 1.

Boring is performed by mounting the boring rod 1 on a boring machine.
There are rotary boring machines and rotary percussion boring machines that are usually used for drainage boring. When drilling without disturbing the hole as much as possible, the rotary boring machine is used when crushing and digging rocks. , Rotary percussion type boring machine is used.
As shown in FIG. 3, the rotary percussion type boring machine has a structure in which a drill head is integrated with a striking portion and a rotating portion. The hammer spool inside the drill head is hydraulically vibrated back and forth to generate a striking force. The rotational force is given by an oil motor mounted on the drill head, and the rotational force is transmitted to the hammer sub to be driven. The drill head moves forward and backward on the guide cell by hydraulic pressure to obtain a feeding force.

In the embodiment of the present invention, the drainage boring had an installation length of 80 m, the diameter of the boring rod was 100 mm, and the length was 15 m. One end of the boring rod is cut with a 100 mm male straight screw in the length direction from the end of the boring rod, and the other end is cut with a 100 mm female straight screw in the length direction. A hole having a diameter of 10 mm was drilled as a mark at a position of 50 mm in each direction. The screw formed at both ends is the position in the length direction of all the boring rods where the circumferential positions of the two screwed unit boring rods are connected when the unit boring rods are screwed together. In the same position.
In the embodiment, the marker is a 10 mm diameter circular hole provided on the circumference of the unit boring rod, but the size and shape may be any as long as they do not affect the strength of the unit boring rod. Good.

Hereinafter, the boring hole locus correcting method using the boring rod 1 of the present invention will be described.
First, when the provided sign 5 connects the unit boring rod 1, they are connected so as to be in the same position on the circumference.
At both ends 2 and 3 of the unit boring rod 1, the unit boring is such that when the unit boring rod 1 is connected, the marker 5 provided on the circumference is at the same position on the circumference of each unit boring rod 1. A connecting portion 4 for connecting the rods is provided.
A trajectory correction bit is attached to the most distal end of one end of the connected boring rod 1, and the other end of the connected boring rod 1 is adjusted so that the trajectory correction bits are arranged in the trajectory correction direction.
That is, the excavation is performed by aligning the correction bit at the bottom of the hole in the correction direction while observing the position of the mark 5 on the mouth ground portion that can be visually confirmed.
As shown in FIG. 6, the tip of the bit is uniformly arranged on the circumference so that the normal boring bit can be dug straight while rotating. In the modified bit, if a bit is arranged on a part of the circumference of the tip of the bit so that excavation can be performed on a part of the circumference, a borehole is dug in that direction.

Generally, a drainage pipe with a diameter of 90 to 115 mm is used for drainage boring.
In the embodiment of the present invention, a 100 mmφ drain pipe was used.
The drilling length of the drainage boring is 80 m or less, and in this example it was 60 m. As the drilling length becomes longer, a larger rotational torque and a feeding force are required, and further, a longer time is required for slime discharge, so the length is limited.
According to the present invention, when the unit boring rods 1 are connected, the punch marks on the outer circumferences of the unit boring rods, that is, the markers 5 are located at the same position on the outer circumference of the boring rod, and the hole locus correction bit is attached to the tip of the boring rod. The sign 5 can be confirmed at the boring mouth, and the borehole locus can be corrected in the drainage boring by directing the bit in the direction to be corrected.

1 Boring rods 2 and 3 Both ends 4 Connection 5 Mark 6 Screw

Claims (8)

A boring rod for hole trajectory control,
A unit boring rod connectable in the longitudinal direction;
A connecting portion provided at both ends of the unit boring rod and configured by screws ;
Connecting portions provided at both ends of the unit boring rod;
A marker provided on the circumference of the unit boring rod adjacent to the connecting portion at both ends of the unit boring rod ;
Including
The mark is a circular or polygonal hole provided on the circumference of the unit boring rod;
A marked boring rod characterized by. By the screw, when the boring rod of two unit was screwed, the circumferential position of the label provided at both ends of the boring rod screwed the two units are in the same position in the circumferential direction The marked boring rod according to claim 1 . The marker is a circular or polygonal outer circle with a diameter of 10 mm provided on the circumference of the unit boring rod, and a hole with a diameter of 10 mm, and is provided adjacent to a connecting portion between two unit boring rod ends. The marked boring rod according to claim 1, wherein: If the provided label are linked to two unit boring rod, aligned such that the circumferential position of the label provided on the tube ends of the two unit boring rod connected is in the same position on the circumference Connecting, and
Attaching a trajectory correction bit to the leading edge of one end of the coupled unit boring rods ;
The trajectory correction bit is attached to the most distal end of one end of the connected unit boring rods, and the bit having a tooth shape is a free end of the trajectory correction bit. Adjusting at the other end of the boring rod provided in part and connected so that a hole is dug in the direction in which the bit is provided ;
Adjusting at the other end of the connected boring rods so that a trajectory correcting bit at the extreme end of one end of the boring rod is arranged in the trajectory correcting direction;
A step of correcting the hole trajectory in the direction in which the trajectory correction bits are arranged; and
Consists of
The mark is a circular or polygonal hole provided on the circumference adjacent to the connecting portion at both ends of the unit boring rod. When the two unit boring rods are connected, the two unit borings connected to each other The circumferential position of the rod sign is the same in the circumferential direction, and when correcting the hole trajectory, based on the circumferential deviation of the circumferential position of the two connected unit boring rod signs borehole trajectory modification method characterized by correcting the borehole trajectory. At both ends of the unit boring rod, there are connecting units for connecting the unit boring rods so that when the unit boring rod is connected, the markings provided on the circumference are at the same position on the circumference of each unit boring rod. 5. The marked boring hole trajectory correcting method according to claim 4, wherein the method is provided. The label is labeled borehole trajectory correcting method according to claim 4, wherein the circular or polygonal holes provided on the circumference of the unit boring rod. The trajectory correction bits are attached to the leading edge portion of one end of the unit boring rod linked, the bit is a tooth of the circular ring portion of the tube cross-section of the trajectory correction bit tip is a free end of the trajectory correction bits 5. A marked borehole trajectory correcting method according to claim 4 , wherein a hole is dug in a direction provided in a part and in a direction in which the bit is provided. The marker is provided adjacent to a connecting portion at both ends of the unit boring rod, and a circular or polygonal circumscribed circle having a diameter of 10 mm provided on the circumference of the unit boring rod is a hole having a diameter of 10 mm. The marked boring hole locus correcting method according to claim 4 . .

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