JP2003020891A - Detecting device of geological state - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a detecting device of a geological state which can be fixed in a shaft easily and surely and can improve the quality of a record of measurement remarkably. SOLUTION: The detecting device of the geological state investigates discontinuity in front of facing by detecting an elastic wave generated artificially by an exciting source by means of a geophone 1 which is held in a holding means buried in the shaft. The geophone 1 is provided with a fixing means 3 for fixing the geophone 1 in the holding means.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a geological condition detecting device, for example, for exploring the geological condition (discontinuous surface) in front of a cutting face in tunnel excavation work using artificially generated elastic waves or the like. It is suitable to be applied to the geological condition detection device.

[0002]

2. Description of the Related Art Conventionally, in various tunnel excavation works, as a method of investigating the geological condition in front of the face, there are a method using advanced boring and a method using underground radar. The advanced boring method is a method of boring forward from the cutting face to sample the core and analyze the drilling condition to investigate the geology.The underground radar method emits radio waves in front of the cutting face. However, it is a method of investigating the geology by receiving the reflected radio waves.

[0003]

[Problems to be Solved by the Invention] However, in recent years, as mechanization of tunnel excavation work progresses, it is becoming an increasingly important technical issue to accurately predict the geological condition in front of the cutting face. At this time, it is not possible to interrupt the excavation work for a long time for the purpose of prediction, and it is also necessary to be able to detect the location of the geological boundary, cracks, faults and shatter zones in front in a short time.

However, the method using the advanced boring is not suitable for mechanized construction because it requires a long interruption time for excavation work and requires setup change with a cutting face. Further, in the method using the underground radar, it is difficult to investigate the geological condition of a place away from the cutting face because the reach of radio waves is short in the ground.

Further, in this method using the underground radar,
Since the propagation speed is fast, only the amplitude of the detected signal has to be taken into consideration, but the amplitude is also affected by slight irregularities in the ground, making it difficult to grasp the geological condition in a comprehensive manner. there were.

As one method for solving the above problems, the HSP (horizontal seismic profile) exploration method has been implemented. This HSP exploration method uses an HSP geophone to use the already excavated section from the wellhead (tunnel opening) to the face of the face, sets the arbitrary excitation point and the receiving point, and measures the reflected wave. It is a method of extracting and visually expressing waveforms corresponding to discontinuities such as geological boundaries in front of the face and fault crush zones.

However, in this HSP exploration method, the HSP
As a method of installing the geophone in the mine (inside the tunnel), a method of fixing the HSP geophone to the tunnel wall surface with a bolt and a method of drilling a hole in the direction orthogonal to the tunnel axis of the tunnel wall surface (hereinafter referred to as a horizontal hole) Is provided, and H is provided in this lateral hole.
Although a method of fixing the SP geophone is conceivable, each has the following problems and is still insufficient.

In the former case, the sound of blasting, surface waves propagating around the pit wall (tunnel wall), and loosening of the ground near the tunnel wall are easily affected (that is, in a closed space such as a tunnel, measurement records are recorded). (Miscellaneous vibrations are likely to occur), and the quality of the measurement record may deteriorate.

The latter is less susceptible to the sound of blasting, the surface waves propagating around the tunnel wall and the loosening of the ground near the tunnel wall, and although the former problem is solved, the HSP vibration is received in the lateral hole. It is common to fix the container by gas pressure bonding using a so-called rubber packer, which consists of balloons, etc., but due to gas leakage at the valve for injecting gas into the rubber packer, rupture of rubber, etc.
As a result, the HSP geophone may not be fixed sufficiently.

Further, in this case, since the HSP geophone is installed in the lateral hole, there is a problem that even if the fixing condition changes, it is difficult to determine the change only by visual observation.

The present invention has been made in view of the above-mentioned problems, and it is an object of the present invention to realize a geological condition detecting device which can be easily and surely fixed in a minehole and which can remarkably improve the quality of measurement records. To aim.

[0012]

In order to solve the above problems, the present invention employs the following means. Claim 1
The geological condition detection device described in, by the geophone buried in the mine, by detecting the elastic wave artificially generated in the vibration source, in the geological condition detection device to explore the discontinuous surface in front of the face It is characterized in that the geophone is provided with a fixing means for fixing the geophone in the pit.

According to the above-mentioned geological condition detecting device, the geophone is provided with the fixing means for fixing the geophone to the underground, so that the geophone can be carried out without complicating the structure of the geological condition detecting device. Since it can be fixed in the mine easily and reliably, the elastic wave can be detected stably, and as a result, the quality of the measurement record can be significantly improved.

Further, the invention according to claim 2 is the geological condition detecting device according to claim 1, wherein the fixing means is
A key portion slidably fitted in a groove provided on one surface of the geophone and an operation portion for sliding the key portion. The key portion slides the groove by the operation portion. It is characterized in that it is projected from the one surface by being made to move. According to this geological condition detection device, the fixing means includes a key portion slidably fitted in a groove provided on one surface of the geophone and an operation portion for sliding the key portion. The portion projects from one surface by sliding the groove by the operation portion, so that the geophone can be easily and reliably fixed in the mine without complicating the structure of the geological condition detection device.

The invention described in claim 3 is the same as that of claim 2
In the geological condition detecting device according to the present invention, the groove is provided with a guide groove for guiding the fixing means, and the key portion of the fixing means is provided with a guide portion corresponding to the guide groove. According to this geological condition detection device, the groove is provided with a guide groove for guiding the fixing means, and the key portion of the fixing means is provided with a guide portion corresponding to the guide groove, so that the key portion smoothly moves the groove. Since it can slide accurately and accurately, the geophone can be reliably fixed in the pit.

The invention according to claim 4 is the same as claim 2
Alternatively, in the geological condition detection device according to the third aspect, accommodating means for accommodating the geophone is provided in the pit, and the key portion has a contact portion corresponding to a shape of the accommodating means at a contact portion with the accommodating means. It is characterized by having. According to this geological condition detection device, the accommodating means for accommodating the geophone is provided in the mine, and the key portion has the contact portion corresponding to the shape of the accommodating means at the contact portion with the accommodating means. The geophone can be more reliably fixed in the mine.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a schematic perspective view showing an embodiment of a geophone according to the geological condition detecting apparatus of the present invention. Figure 1
In the figure, 1 indicates a geophone as a whole, which is mainly made of duralumin, resin, and the like. This is because the material of the geophone is not particularly limited because high temperature and corrosion are not considered, but it is advantageous to use a light material because it operates following the vibration of the ground.

Now, in this geophone 1, for example, a groove 2 is engraved on the left end side of the one surface 1A of the geophone 1 when viewed from the front surface 1B of the geophone 1, and the groove 2 has a fixing portion as a fixing means. The key portion 3A of No. 3 is slidably engaged, and the wire 3B, which is an operation portion attached to the key portion 3A for operating the key portion 3A, is provided on the rear surface 1C side of the geophone 1. It is exposed from an opening (not shown).

In this case, the groove 2 and the key portion 3A are provided with a guide groove 2A and a guide portion 3AG, respectively, and the guide portion 3AG of the key portion 3A is the guide groove 2 of the groove 2.
By being guided by A, the key portion 3A moves into the groove 2
When it is moved in the direction of the front surface 1B of the geophone 1 in, the head protruding from the one surface 1A of the geophone 1 of the key portion 3A is
When the key portion 3A is moved to the rear surface 1C direction of the geophone 1 in the groove 2 opposite to this, the key portion 3A can be submerged until it is below the position of the one surface 1A.
The head of A can be projected from the one surface 1A of the geophone 1. As a result, the key portion 3A
Are designed to be able to slide smoothly and accurately in the groove 2.

A wiring groove 4 is engraved from the front surface 1B side to the rear surface 1C at substantially the center of one surface 1A of the geophone 1, and a sensor hole 5A is formed in this wiring groove 4, for example, a sensor (not shown). Corresponding to, two holes are drilled. Further, the wiring groove 4 has a side groove 4A extending from the front surface 1B of the geophone 1 to the right side surface 1D (for example, two grooves in this case).

The front surface 1B of the geophone 1 is provided with a sensor hole 5B at substantially the center thereof, and a sensor 6 is embedded in the sensor hole 5B. In addition, on the right side surface 1D of the geophone 1, a portion corresponding to that in FIG.
As shown in FIG. 5, a sensor hole 5C is provided, and a sensor 6 is embedded in the sensor hole 5C. The sensor hole 5C is communicated with the side groove 4A and the sensor vertical groove 4B.

These sensors 6 (partly not shown) are connected to the rear surface 1C of the geophone 1 by bolts 7A by wirings (not shown) passing through the wiring groove 4, the side groove 4A, the sensor vertical groove 4B and the like. It is configured to be electrically connected to a control device (not shown) via a fixed cord 7.

In the geological condition detecting method using the geological condition detecting device having the geophone 1 having such a structure, for example, as shown in FIG. 3, a plurality of geophones 1 are predetermined in a tunnel K which is a pit. By detecting the reflected waves P1 and P2 reflected by the faults F1 and F2, which are elastic surfaces generated by the blasting in the vibration source T at intervals, from the facet J, It is for exploring discontinuities (geological conditions) such as geological boundaries in front and fault crush zones.

In practice, such a geological condition detection method is shown in FIG.
As shown in, the tunnel wall KA, which is the tunnel wall at the face J in the tunnel K, has a vibration source T of, for example, 50 [g].
A dynamite (No. 3 paulownia or No. 2 Enoki, etc.) of about -100 [g] and a flash detonator are buried in the blast hole S1 having a depth X ₁ (for example, 2 [m]).

Further, from the face J toward the tunnel opening, at a distance X ₂ (for example, 10 [m]), to the left and right of the tunnel wall KA, a length X ₃ (for example, 5) is sequentially applied.
For example, eight installation holes S are provided at intervals of [m]).
The protection pipe 10 as a housing means is embedded in the protection pipe 2, and the geophone 1 is installed in the protection pipe 10.

More specifically, the installation condition of the geophone 1 will be described with reference to FIG.
As shown in (a) and (b), the installation hole S2 and the protective tube 10
A filler M made of mortar, resin, or the like is filled in between. After filling the installation hole S2, the filling material M is filled with air or the like to be discharged to sufficiently remove excavation debris in the installation hole S2. At this time, the filler M
Are sequentially filled from the hole bottom of the installation hole S2 toward the hole mouth, and in the case of spilling out from the hole mouth, the hole mouth is covered with a cloth or the like and filled.

Further, since the protective tube 10 is vertically and horizontally aligned with its corner sides vertically and the axis of the protective tube 10 is buried horizontally and at right angles to the axis of the tunnel K, the excavation of the installation hole S2 is also horizontal and tunnel. It must be done at right angles to the K axis.

The geophone 1 is inserted into the protective tube 10 with the key portion 3A lowered, and the wire 3B is pulled to protect the key portion 3A from the one surface 1A of the geophone 1. Since it comes into contact with the tube 10, it is fixed inside the protective tube 10.

In this way, in this geological condition detecting device, the fixed portion 3 is provided in the geophone 1, and the geophone 1 is installed in the protective tube 10 embedded in the installation hole S2 in the tunnel K. At this time, by pulling the wire 3B of the fixed portion 3 of the geophone 1, the key portion 3A of the fixed portion 3 is attached to the one surface 1A of the geophone 1.
By raising it further, the geophone 1 can be easily and surely fixed in the protection tube 10.

Further, by securely fixing the geophone 1 in the protective tube 10 as described above, it is possible to prevent the measurement record detected by the geophone 1 from including miscellaneous vibrations. As a result, the quality of the measurement record of the geological condition detection device can be significantly improved.

In the above-mentioned embodiment,
The case where a square bar is used for the protective tube 10 which is the accommodating means has been described, but the present invention is not limited to this, and the point is that
When installing the geophone 1 in the installation hole S2, the geophone 1
As long as it stabilizes the installation condition (that is, the fixed state), various accommodating means having various shapes can be widely applied. For example, the same reference numeral is given to a portion corresponding to FIG. As shown in FIG. 6 (a), the protective tube 1
As 0, a cylindrical shape corresponding to the shape of the installation hole S2 may be used. In that case, there is an advantage that the clearance between the protection tube 10 and the installation hole S2 becomes constant. Also, the geophone 1
If the contact portion 20 corresponding to the shape of the protective tube 10 is provided in the contact portion of the key portion 3A with the protective tube 10, the fixed state of the geophone 1 can be further stabilized.

Further, when the tunnel wall KA for forming the installation hole S2 is hard and hard to collapse, the geophone 1 may be installed directly in the installation hole S2 without providing the protection tube 10. . In this case, although the protection pipe 10 is not provided, there is an advantage that the structure of the geological condition detection device can be simplified. However, for example, FIG. 6B in which the same reference numerals are given to the corresponding portions with FIG. As shown in FIG. 3, when the size of the installation hole S2 is larger than that of the geophone 1, the back plate 30 or the like may be installed between the geophone 1 and the installation hole S2. The fixed state of the container 1 can be stabilized.

[0034]

As described above, according to the present invention, in the geological condition detecting device, the geophone is provided with the fixing means for fixing the geophone in the mine, thereby constructing the geological condition detecting device. The geophone can be stably and reliably fixed in the mine without making it complicated, so that the elastic wave can be stably detected, and thus the quality of the measurement record can be significantly improved. Can be realized.

Moreover, according to this geological condition detection device,
The fixing means includes a key portion slidably fitted in a groove provided on one surface of the geophone and an operating portion for sliding the key portion, and the key portion slides the groove by the operating portion. By being protruded from one surface by being caused, the geophone can be easily and reliably fixed in the mine without complicating the structure of the geological condition detection device.

Further, according to this geological condition detecting device, the key portion is provided with the guide groove for guiding the fixing means, and the key portion of the fixing means is provided with the guide portion corresponding to the guide groove. Since the groove can slide smoothly and accurately, the geophone can be securely fixed in the pit.

Further, according to this geological condition detecting device,
By providing the receiving means for accommodating the geophone in the mine, and the key portion having the contact portion corresponding to the shape of the accommodating means at the contact portion with the accommodating means, the geophone is more surely installed in the mine. Can be fixed to.

[Brief description of drawings]

FIG. 1 is a schematic perspective view showing an embodiment of a geophone according to a geological condition detecting apparatus of the present invention.

FIG. 2 is a side view of the geophone according to the geological condition detection apparatus of the present invention.

FIG. 3 is a schematic diagram for explaining a geological condition detection method using the geological condition detection device of the present invention.

FIG. 4 is a schematic sectional view for explaining the installation of a geophone in a tunnel.

FIG. 5 is an enlarged view of the essential parts showing the installed state of the geophone.

FIG. 6 is a partial cross-sectional view showing another embodiment.

[Explanation of symbols]

1 geophone 1A side 2 grooves 2A guide groove 3 Fixed part (fixing means) 3A key part 3B wire (operation part) 3AG guide section 10 Protection tube (accommodation means) 20 Contact part 30 Back plate (auxiliary member) F1 and F2 faults J Face K tunnel (pit) KA tunnel wall surface (pit wall) M filler P1, P2 reflected wave S2 side hole T source

Claims (4)

[Claims] 1. A geological condition detector for detecting a discontinuous surface in front of a face by detecting an elastic wave artificially generated by a vibration source by a geophone embedded in a mine, wherein the geophone is provided. In addition, the geological condition detection device is provided with a fixing means for fixing the geophone to the mine. 2. The key means includes a key portion slidably fitted in a groove provided on one surface of the geophone and an operation portion for sliding the key portion. The geological condition detection device according to claim 1, wherein the projecting part projects from the one surface when the groove is slid by the operating part. 3. A guide groove for guiding the fixing means is provided in the groove, and a guide portion corresponding to the guide groove is provided in the key portion of the fixing means. Geological condition detection device described. 4. A housing means for housing the geophone is provided in the pit, and the key portion has a contact portion corresponding to a shape of the housing means at a contact portion with the housing means. The geological condition detection device according to claim 2 or 3.