JP2017025618A - Advanced boring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an advanced boring method capable of providing a high accuracy investigation result and an effective drainage result by executing a boring hole locus almost along a tunnel route by bending a boring hole, by using a boring rod.SOLUTION: An advanced boring method comprises a stage of digging a boring hole at an inclined angle in the tunnel excavation direction in the direction dislocated from a tunnel cross section in the tunnel excavation direction, a stage of changing the digging direction in the parallel direction to the tunnel excavation direction after digging at the inclined angle by a predetermined distance and a stage of continuing excavation in the parallel direction to the tunnel excavation direction, and a change in the hole digging direction is executed by a track correction bit provided in the forefront part on one end of a connected rod.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an advanced boring method, and more specifically, by using a boring rod, bending a boring hole and performing a boring hole locus substantially along the tunnel route, a highly accurate investigation result and an effective draining result can be obtained. It relates to the obtained advanced boring method.

Boring is 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.

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 inner diameter of the boring iron pipe, measurement cannot be performed.

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, the drain boring is easy to bend the hole, and it has been conventionally assumed that it is due to the skill of the operator to bring it close to the planned position.

In addition to landslide drainage boring, in tunnel construction, surveys on the geology ahead of the tunnel that has not yet been constructed, that is, advanced survey boring are performed.
Usually, boring is performed about 100 m per time, but at this level, the hole trajectory does not deviate significantly from the tunnel route, and the hole trajectory control is not performed because it is not a problem.
However, in some cases, it is better to perform hole trajectory control in 100m class tunnel advanced boring.
If tunnel boring is performed along the tunnel route from the face of the tunnel and within the tunnel plan section, if groundwater springs out, the tunnel construction will always be flooded, making the tunnel construction difficult.
If such is expected, advanced boring is performed to remove it from the tunnel cross section.

Japanese Patent Laid-Open No. 09-032449

  An object of the present invention is to obtain a highly accurate investigation result and an effective draining result by using a boring rod, bending a boring hole and performing a boring hole locus substantially along the tunnel route.

The present invention includes a step of digging a borehole at an angle inclined from the tunnel excavation direction in a direction deviating from the tunnel cross section in the tunnel excavation direction;
After digging a predetermined distance at the inclined angle, changing the direction to dig a hole to a direction parallel to the tunnel excavation direction;
Continuing drilling in a direction parallel to the tunnel excavation direction;
It is characterized by comprising.

    The change in the direction in which the hole is dug is caused by a trajectory correction bit provided at the most distal end of one end of the connected rod.

According to the present invention, a highly accurate investigation result and an effective draining result can be obtained by bending a boring hole and performing a boring hole locus substantially along the tunnel route.
In addition, if a borehole is installed under the invert, the invert work will be facilitated by pumping up and collecting groundwater in the catchment pit.

FIG. 3 is a diagram of advanced boring using the boring rod of the present invention. It is a figure of the boring rod of this invention. It is a figure of a boring machine.

Advanced boring is intended to make it possible to perform tunnel excavation work safely by checking the geology ahead of the tunnel in tunnel construction.
If flammable gas is assumed to exist in front of the tunnel, degassing is performed in advance to ensure the safety of tunnel construction.
In addition, when performing advanced boring, if tunnel boring is carried out from the tunnel face along the tunnel route within the cross section of the tunnel plan, if groundwater comes out, the tunnel construction is always covered with water, making the tunnel construction difficult.
If groundwater is expected to flow out, advanced drilling will be performed at a location outside the tunnel cross section.

However, in this method, as the boring progresses, the advanced boring gradually moves away from the cross section of the tunnel, resulting in problems such as a decrease in survey accuracy and a weak water draining effect.
FIG. 1 shows the relationship between the planned tunnel cross section and advanced boring.
In advanced drilling that deviates from the planned cross section of the tunnel, the distance from the planned cross section of the tunnel increases as shown in (3) as it proceeds as shown in (2). It becomes difficult.

The present invention bends the borehole as in (4) and performs a borehole locus substantially along the tunnel route, thereby obtaining a highly accurate survey result and obtaining an effective drainage result. In the tunnel excavation direction, the step of digging a borehole at an angle inclined with respect to the tunnel excavation direction in a direction deviating from the tunnel cross section, and the direction in which the hole is excavated after digging a predetermined distance at the inclined angle The step of changing to a direction parallel to the excavation direction and the step of continuing excavation in a direction parallel to the tunnel excavation direction are characterized in that:
And the change of the direction which advances the said hole is performed with the track | orbit correction bit provided in the most distal end part of the end of the connected rod.

As shown in FIG. 2, the boring rod 1 used in the present invention is provided with connecting portions 4 at both end portions 2 and 3 of the boring rod 1, and a mark 5 adjacent to the connecting portions 4 at both end portions 2 and 3 of the boring rod. Is provided.
And the connection part 4 is comprised with the screw 6, and when the screw 6 screws the boring rod 1 for connection, as shown in FIG. 2, the circumferential direction of the mark 5 of the screwed boring rod is shown. The positions are the same.
This mark 5 is a circular or polygonal hole provided on the circumference of the boring rod 1 and is provided adjacent to the connecting portion 4 of the both ends 2 and 3 of the boring rod 1 and affects the strength of the boring rod 1. The size is not.

Advanced boring is performed by mounting the boring rod 1 on a boring machine as shown in FIG.
100m class advanced boring is mainly rotary percussion type, and 1000m class is controlled boring machine.
The rotary percussion boring machine has a structure in which a drill head is integrated with a striking part and a rotating part. 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.

  Advanced boring excavation involves digging a borehole at an angle inclined with respect to the tunnel excavation direction in a direction away from the tunnel cross section in the tunnel excavation direction, and excavating the hole after excavating a predetermined distance at the inclined angle. Changing the direction to a direction parallel to the tunnel excavation direction and continuing the excavation in a direction parallel to the tunnel excavation direction. By a trajectory correction bit provided at the end of the edge.

Hereinafter, a method for changing the direction of digging a hole 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.

In the embodiment of the present invention, a 115 mmφ tube was used.
The drilling length of the advanced boring according to this example was 100 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 boring rods 1 are connected, the punch mark on the outer periphery of each boring rod, that is, the mark 5 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 boring rod, The sign 5 can be confirmed at the boring mouth, and the borehole locus can be corrected in the drainage boring by turning the bit in the direction to be corrected.

According to the present invention, as shown in FIG. 1 (4), it is possible to make the borehole locus substantially along the bending tunnel route, thereby obtaining a highly accurate investigation result and effect. A typical draining result is obtained.
Furthermore, if a boring hole (7) is installed under the invert shown in (6) of FIG. 1, the invert work will be facilitated by collecting the groundwater in the pump-up and collecting pit.
Here, invert means to excavate the bottom from the roadbed after excavation of the upper tunnel and make the tunnel quasi-circular structure to be strong,

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

Claims (2)

A step of digging a borehole at an angle inclined with respect to the tunnel excavation direction in a direction away from the tunnel cross section in the tunnel excavation direction;
After digging a predetermined distance at the inclined angle, changing the direction to dig a hole to a direction parallel to the tunnel excavation direction;
Continuing drilling in a direction parallel to the tunnel excavation direction;
An advanced boring method characterized by comprising     The advanced boring method according to claim 1, wherein the change of the direction in which the hole is dug is made by a trajectory correcting bit provided at one end of the connected rod.

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