JPH11132732A - Hollow cross section measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hollow cross section measuring device which can calculate the deformation amount of a tunnel cross section in real time and in a short time. SOLUTION: This hollow cross section measuring device is provided with an optical fiber distortion sensor 1, one optical fiber 2 provided in a tunnel, and rods for fixing rock bed 3 (3A to 3E). The optical fiber 2 consists of a part connected with the optical fiber distortion sensor 1, a part affixed to the tunnel wall in the peripheral direction, and a part to be inserted inside the rod for fixing rock bed 3. The rod for fixing rock bed 3 is provided in the vertical direction of the tunnel wall, one end 6 of the rod for fixing rock bed is fixed on a tunnel wall surface 4, and the other end 7 thereof is fixed on a rock bed 8. A flat plate or a round bar 9 and the optical fiber are attached inside the rod for fixing rock bed 3 so as to follow the deformation of the rod for fixing rock bed 3, and a deformation amount of the tunnel wall in the peripheral direction and vertical direction is measured by one optical fiber to monitor a deformation amount of the tunnel at all times.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring an inner space section of a railway or road tunnel.

[0002]

2. Description of the Related Art FIG. 7 shows a conventional method for measuring the inner space cross section of a tunnel (survey method). As shown in FIG. 7, two digital transit units 2 are placed at an arbitrary position on the central passage with a measuring point therebetween.
1 and 22 are installed horizontally at a distance of 7 to 8 m.

The collimation targets 23 attached to the front surfaces of the digital transits 21 and 22 are collimated with each other so that the collimation lines coincide with each other. After collimating the collimation targets 23 affixed to both ends of the reference scale 24 with the telescope at the correct and opposite positions, the collimators collimate each other.

[0004] In this way, the position coordinates of the two digital transit arbitrarily set are determined. By collimating the measuring points 25, the coordinates of the measuring points 25 are determined. When the collimation of all the measuring points 25 is completed, the personal computer 26 or the like calculates the coordinates and calculates the interval between the measuring points.

[0005] This operation is periodically measured at each section, and a change in the inner section of the tunnel is examined. There is also a method of directly examining the cross-sectional change of a tunnel due to an Invar rule or the like.

[0006]

However, the prior art has the following problems. (1) The conventional method requires the use of train time intervals or stops vehicles, and is not efficient. (2) The conventional method requires considerable time and cost. An object of the present invention is to provide a device that can solve these problems.

[0007]

[Means for Solving the Problems]

(First Means) An inner space section measuring apparatus according to the present invention
(A) An optical fiber strain sensor 1, an optical fiber 2 laid in a tunnel, and a rock fixing rod 3 are provided.
(B) The optical fiber 2 has a portion connected to the optical fiber strain sensor 1 and a portion attached in the circumferential direction of the tunnel wall.
It consists of a part to be inserted inside the rod 3 for rock fixing,
(C) The rock fixing rod 3 is installed in the vertical direction of the tunnel wall, one end 6 of the rock fixing rod is fixed to the tunnel wall surface 4 and the other end 7 is fixed to the rock 8, (D) A flat plate or a round bar 9 is mounted inside the rock fixing rod 3 so as to follow the deformation of the rock fixing rod 3. (E) An optical fiber inserted into the rock fixing rod 3 The part is inserted from one end 6 of the rock fixing rod and fixed to a flat plate or a round bar 9,
It is folded back from the other end 7, taken out from one end 6, connected to the optical fiber portion attached in the circumferential direction of the tunnel wall, and (F) measuring the amount of deformation in the circumferential direction and vertical direction of the tunnel wall with one optical fiber, The feature is that the amount of deformation of the tunnel can be constantly monitored. (Second Means) The inner space section measuring apparatus according to the present invention
(A) laying an optical fiber 2 fixed to the tunnel wall for measuring the amount of deformation in the circumferential direction and vertical direction of each section of the tunnel wall for each section, and (B) connecting the optical fibers continuously (C) The optical fibers 11 are also connected in the longitudinal direction of the tunnel.
(D) An optical fiber sensor 10 for temperature measurement is connected to the optical fiber 11 laid in the longitudinal direction of the tunnel, and data of the optical fiber strain sensor 1 and the optical fiber 10 for temperature measurement are By connecting the computer 12 to be organized and (E) using the optical fiber 2 fixed to the tunnel wall and the optical fiber 11 laid in the longitudinal direction of the tunnel, abnormal deformation of each section of the tunnel wall and temperature It is characterized by being able to regularly check and detect abnormalities (fire) and to monitor the danger of tunnels.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION

(First Embodiment) FIG. 1 shows a first embodiment of the present invention.
2 to FIG. FIG. 1 is an installation diagram of an optical fiber for measuring a cross section in a tunnel of the apparatus according to the first embodiment, FIG. 2 is a conceptual diagram of a rock fixing rod 3, and FIG. 3 is a view along an optical fiber. FIG. 4 is a diagram showing the distribution of strain, FIG. 4 is a diagram showing a method of laying an optical fiber inside a tunnel wall, a rock fixing rod for measuring strain along the longitudinal direction of an optical fiber, and FIG. FIG. 4 is a diagram showing a method of fixing a flat or round bar 9 and an optical fiber.

In FIG. 1, reference numeral 1 denotes an optical fiber strain sensor;
2 is an optical fiber laid on a tunnel wall, 3 is a rock fixing rod, 4 is a tunnel wall, and 5 is a coordinate measurement point.

The principle of the optical fiber strain sensor is that pulse light is incident from one end of an optical fiber to be measured, Brillouin scattered light generated in the optical fiber is detected with high sensitivity by a coherent detection method, and the frequency shift distribution of the Brillouin scattered light is obtained. Therefore, the strain distribution of the optical fiber is detected.

An optical fiber strain sensor 1 that can perform multipoint measurement with one optical fiber is used. What is multipoint measurement?
This means that the distribution of strain can be measured along the optical fiber.

In FIG. 3, the x-axis indicates the direction along the optical fiber, and the y-axis indicates the magnitude of the distortion. The strain at one measurement point can be measured with one optical fiber strain sensor (strain gauge).

The rock fixing rod 3 has a rod length and a distance between the rods (along the tunnel wall 4) satisfying the required length (gauge length) of the strain sensor. Since the apparatus of the present invention measures the strain in the longitudinal direction of the optical fiber, the optical fiber is laid inside the tunnel wall and the rock fixing rod as shown in FIG. Therefore, the strain of the tunnel wall and the rock fixing rod can be measured simultaneously with one optical fiber strain sensor.

The displacement of the coordinate measurement point can be calculated from the distortion in the circumferential direction of the tunnel and the distortion in the vertical direction. The rock fixing rod 3 has a cylindrical shape as shown in FIG.
7 is fixed to the tunnel wall 4 and the bedrock 8, respectively.

A flat plate or a round bar 9 is mounted inside the rock fixing rod 3 so as to follow the deformation of the rock fixing rod 3. The fixing of the flat plate or the round bar 9 and the optical fiber is performed by adhesion or a method as shown in FIG.

The connection between the portion of the optical fiber attached in the circumferential direction of the tunnel wall and the portion inserted into the rock fixing rod 3 is performed as follows. One end of the optical fiber attached in the circumferential direction of the tunnel wall is inserted from the wall fixed end 6 of the rock fixing rod, and is fixed to a flat plate or a round bar 9 in the rock fixing rod. It is folded back from the rock fixed end 7 and comes out from the wall fixed end 6 and is attached in the circumferential direction of the tunnel wall.

In this way, the coordinate measurement points 5A of FIG.
5B, 5C, 5D, 5E, rock rod fixing rod 3
A, 3B, 3C, 3D, and 3E connect the optical fiber portion inserted inside and the optical fiber portion attached in the circumferential direction of the tunnel wall.

Therefore, the operation is as follows. When the laid optical fiber expands and receives strain, its position and the amount of strain can be measured. Therefore, as shown in FIG. 1, when an optical fiber having a rock fixing rod is laid,
And the strain (vertical deformation) of the rock fixing rod 3 can be measured.

By calculating the coordinates of the coordinate measurement point 5 from the data of these strains (deformation amounts) with a personal computer or the like, the deformation amount of the tunnel cross section can be known in real time and in a short time. (Second Embodiment) FIG. 6 shows a second embodiment of the present invention.
Shown in

FIG. 6 is a diagram showing an example of a tunnel danger prediction system of a device according to the second embodiment. In addition to the example of the installation of the device according to the first embodiment, as shown in FIG. 6, one optical fiber is continuously connected and the other cross sections are similarly connected and installed.

Further, an optical fiber 11 is also laid in the longitudinal direction of the tunnel. An optical fiber sensor 10 for temperature measurement is connected to the optical fiber 11 laid in the longitudinal direction of the tunnel.

Then, a computer 12 for organizing data of the optical fiber strain sensor 1 and the temperature measuring optical fiber 10 is connected. Therefore, it operates as follows.

By using the optical fiber 11 of FIG. 6 and the device according to the first embodiment, abnormal displacement and abnormal temperature (fire) can be detected by regular inspection at a level of several minutes to several hours. I can do it.

[0024]

Since the present invention is configured as described above, it has the following effects. (1) Effect of the Invention of Claim 1 The advantage of the invention of claim 1 is that the sensor section of the optical fiber is always installed in the tunnel, and the measurement can be performed even when the train and the vehicle are passing.

Once installed, the operation can be done away from the tunnel,
In addition, the amount of deformation of the tunnel cross section can be known in a short time. Therefore, the measurement cost can be reduced. (2) Effect of the invention of claim 2 It is dangerous to confirm an abnormality in a tunnel, such as after an earthquake, but according to the invention of claim 2, the abnormality can be constantly monitored, and if there is an abnormality in the displacement / temperature. By issuing an alarm and stopping the tunnel, disasters can be prevented.

[Brief description of the drawings]

FIG. 1 is an installation diagram of an optical fiber sensor for measuring a cross section in a tunnel of an apparatus according to a first embodiment of the present invention.

FIG. 2 is a conceptual diagram of a rock fixing rod 3 of the device according to the first embodiment of the present invention.

FIG. 3 is a diagram showing a distribution of strain along an optical fiber.

FIG. 4 is a diagram showing a method of laying an optical fiber inside a tunnel wall and a rock fixing rod for measuring a strain along a longitudinal direction of an optical fiber.

FIG. 5 is a diagram showing a method of fixing a flat or round bar 9 and an optical fiber.

FIG. 6 is a diagram showing a tunnel danger prediction system of a device according to a second embodiment of the present invention.

FIG. 7 is a diagram showing a conventional method for measuring the inner space section (survey method) of a tunnel.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical fiber strain sensor 2 ... Optical fiber (optical fiber fixed to tunnel wall) 3 ... Rod for rock fixing 3A, 3B, 3C, 3D, 3E ... Rod for rock fixing 4 ... Tunnel wall surface 5 ... Coordinate measurement point 5A 5B, 5C, 5D, 5E: Coordinate measurement point 6: End of rod for fixing rock 7: End of rod for fixing rock 8: Rock 9: Flat plate or round bar 10: Optical fiber for temperature measurement 11: Optical fiber (for tunnel Optical fiber laid in the longitudinal direction) 12 ... Computer 21 ... Digital transit 22 ... Digital transit 23 ... Collimation target 24 ... Standard scale 25 ... Measurement point 26 ... PC etc.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Taketoshi Yamaura 5-717-1, Fukahori-cho, Nagasaki-city, Nagasaki Prefecture Inside Nagasaki Research Laboratory, Mitsubishi Heavy Industries, Ltd. No. 1 Inside Nagasaki Shipyard, Mitsubishi Heavy Industries, Ltd.

Claims (2)

[Claims] 1. An optical fiber strain sensor comprising: an optical fiber strain sensor, one optical fiber laid in a tunnel, and a rock fixing rod; and (B) a portion connected to the optical fiber strain sensor. , A part to be attached in the circumferential direction of the tunnel wall,
It consists of a part that is inserted inside the rock fixing rod,
(C) The rock fixing rod is installed in the vertical direction of the tunnel wall, and one end of the rock fixing rod is fixed to the tunnel wall surface, and the other end is fixed to the rock, (D) the rock fixing rod Inside the rod, a flat plate or a round bar is attached so as to follow the deformation of the rock fixing rod, and (E)
The portion of the optical fiber inserted into the rock fixing rod is inserted from the wall fixing end of the rock fixing rod and fixed to a flat plate or a round bar, and is folded back from the rock fixing end and out from the wall fixing end, (F) Measure the amount of deformation in the circumferential direction and vertical direction of the tunnel wall with one optical fiber,
An inner space section measuring device characterized by constantly monitoring the amount of deformation of a tunnel. (A) laying an optical fiber fixed to the tunnel wall for measuring the amount of deformation in the circumferential direction and vertical direction of each section of the tunnel wall for each cross section, and (B) connecting the optical fibers continuously. (C) an optical fiber is laid in the longitudinal direction of the tunnel, and (D) an optical fiber laid in the longitudinal direction of the tunnel has a temperature measuring light. (E) connecting a fiber sensor and connecting a computer for organizing data of these optical fiber strain sensors and optical fibers for temperature measurement;
By using the optical fiber fixed to the tunnel wall and the optical fiber laid in the longitudinal direction of the tunnel, the abnormal deformation of each section of the tunnel wall and the abnormal temperature can be regularly inspected and detected, and the danger of the tunnel. The apparatus according to claim 1, wherein monitoring is possible.