JPH11230840A - Landslide detecting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a landslide detecting system which can detect the occurring position of a landslide over the full length of an optical fiber regardless of the scale of the landslide. SOLUTION: A land slide detecting system is provided with a plurality of pipes 1 which are laid in objecting earth and sand, and connected to each other so that an optical fiber 2 can pass through the hollow sections of the pipes 1; bellows members 12 provided to the pipes 1, so that the corresponding pipe 1 may expand or shrink when the objective earth and sand slide; and a measuring means 4 which detects the slide of the objective earth and sand, by measuring the strain distribution in the fiber 2 associated with the extension and shrinkage of the pipe 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a landslide detection system for detecting landslide using an optical fiber.

[0002]

2. Description of the Related Art FIGS. 4A and 4B are diagrams showing an example of laying optical fibers in a conventional earth and sand collapse detection system, where FIG. 4A is a perspective view and FIG. 4B is a side view. . Conventionally, as shown in (a) and (b) of FIG.
A plurality of troughs 22 are arranged in a groove (not shown) provided on the top or the ground 21. At this time, a gap 23 is provided in each of one or a plurality of troughs 22 (every two in FIG. 2) and arranged in the longitudinal direction, and a bar 24 is erected on the ground of each gap 23.

[0003] After one optical fiber 25 is wired so as to form a loop crossing the rod-shaped body 24 along the groove of each trough 22 and at each gap 23, a lid 26 is put on each trough 22. In addition, it is desirable to pack a filler (pebble or the like) so that small animals do not enter each trough 22.

FIGS. 4 (c) and 4 (d) show the above ground 21
It is a figure which shows the case where the earth and sand collapsed. When a part of the soil on the ground 21 collapses, the trough installed on the soil collapses as shown in FIG. 4C. Then, the rod 24 adjacent to the trough also collapses, and the rod 24
The loop of the optical fiber crossing in FIG.
It is deformed as shown in FIG. Therefore, by flowing the sensing light from the predetermined detecting device to the optical fiber 25, the position where the loop is deformed, that is, the position where the earth and sand collapses and the trough collapses can be detected.

On the other hand, the following method has been developed for measuring the amount of strain applied to an optical fiber by analyzing the scattered light of the optical fiber. In this method, the frequency shift of the backward Brillouin scattered light, that is, the value obtained by subtracting the center frequency of the Brillouin scattered light spectrum from the optical frequency of the incident light is the tensile stress applied to the optical fiber, that is, the relative elongation due to the equivalent tensile stress. Focusing on the fact that it increases with the elongational strain of the optical fiber, an abnormal point of the optical fiber (or optical cable) is searched for from the increase of the Brillouin frequency shift.

In this method, pulse light is incident from one end of an optical fiber, and backscattered light of Brillouin scattered light generated in the optical fiber is detected with high sensitivity by a coherent detection method. At this time, the strain distribution of the optical fiber is measured from the frequency shift distribution of the Brillouin scattered light by utilizing the fact that the Brillouin scattered light is induced by the interaction between the light wave and the sound wave in the optical fiber to shift the optical frequency.

The relationship between the frequency shift of Brillouin scattered light and the amount of distortion is given by the following equation (1). fb (ε) = fb (0) (1 + Cε) (1) where fb (0) is the Brillouin frequency shift when the strain amount ε (%) is zero (the center of the Brillouin scattering spectrum from the frequency of the incident light). The value when the wavelength of incident light is 1500 nm is 11 GHz. C is a proportional coefficient, which is about 4.5. When the above equation (1) is solved for ε, ε = {fb (ε) −fb (0)} / {Cfb (0)} (2) Therefore, by measuring the Brillouin frequency shift, the distortion of the optical fiber can be obtained.

In order to measure the Brillouin frequency shift, it is necessary to efficiently receive weak Brillouin scattered light. As this method, BOTDA (Brillouin Op
tical Fiber Domain Analysis) and BOTDR (Brilloui
n Optical Time Domain Reflectometry).

BOTDA is an application of Brillouin gain spectroscopy, and the optical power of backward Brillouin scattered light generated by pump pulse light can be increased by probe light. On the other hand, BOTDR receives weak Brillouin scattered light by high-sensitivity reception using means such as coherent reception. Thus, BO
TDA and BOTDR can measure with high sensitivity,
Since the relative optical frequency can be measured with high accuracy, the distribution of the Brillouin frequency shift of the optical fiber can be measured by either method. These methods are described in the literature (IEEJ, BI Vol. J73-BI, No. 2, pp. 144-152, 1990; Technical
Digest of International Quantum Electronics Confe
rence (IQEC'92), paper no. MoL. 4, pp. 42-43, 1992).

In these methods, the peak frequency of the Brillouin scattered light is obtained by scanning the input light or the frequency of the light receiving unit in order to obtain the Brillouin frequency shift. Also, by measuring the time required for the scattered light to return to the incident end by making the incident light into a pulse shape, the distribution of strain in each part of the optical fiber can be obtained. , and performing averaging operations of about 2 ²⁰ times the measurement of one frequency.

[0011]

In the above-mentioned conventional earth and sand collapse detection system, only the collapse of a portion where a loop is formed by an optical fiber can be detected, and the collapsed position is determined over the entire length of the optical fiber. It cannot be detected. Further, there is a problem that only a collapse of a scale such that the loop of the optical fiber is deformed can be detected, and a collapse of a small scale such that the optical fiber is slightly deformed cannot be detected. The purpose of the present invention is to determine the position of the collapsed earth and sand,
It is an object of the present invention to provide an earth and sand collapse detection system capable of detecting the entire length of an optical fiber regardless of the magnitude of the collapse.

[0012]

Means for Solving the Problems In order to solve the above problems and achieve the object, the earth and sand collapse detection system of the present invention is configured as follows. (1) The earth and sand collapse detection system of the present invention is provided on a target earth and sand, and a plurality of pipes connected so that an optical fiber is inserted into each hollow portion. A bellows member provided on each of the tubes so that the tubes expand and contract, and a measuring means for detecting a collapse position of the object by measuring a strain distribution of the optical fiber accompanying expansion and contraction of the tubes. I have. (2) The earth and sand collapse detection system of the present invention is the system according to the above (1), and has brim members provided at both ends of each pipe.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a diagram showing a configuration of a landslide detection system according to an embodiment of the present invention. In FIG. 1, a plurality of stainless steel tubes 1 are connected, and one optical fiber 2 is inserted into a hollow portion of each stainless steel tube 1. At both ends of each stainless steel tube 1, a resistance collar 11 having a circular hollow portion at the center is provided, and a bellows 12 is provided at the center. The plurality of stainless steel pipes 1 are connected by fixing the resistance collars 11 of the adjacent stainless steel pipes 1 to each other.

The optical fiber 2 is fixed by the fiber fixing adhesive 3 in the hollow portion of each resistance collar 11. As a result, the optical fiber 2 has a unit length (approximately 2
m) each end of which has a stainless steel protective tube 1 resistance flange 1
Fixed to 1.

Such a series of stainless steel pipes 1 is buried and laid in, for example, earth and sand along a railway track.
The end of the optical fiber 2 is connected to a strain measuring device 4 using the BOTDR method for measuring the amount of distortion of the optical fiber by the frequency shift of the backward Brillouin scattered light.

FIG. 2 is a block diagram showing the configuration of the strain measuring device 4. In the strain measuring device 4, the measuring light output from the light transmitting and receiving device 41 enters the optical fiber 2, and the returned light is received by the light transmitting and receiving device 41 via the filter 42. Averaging unit 43
Then, the intensity distribution of the light returned for each frequency is added and averaged, and when the addition and averaging is completed, the frequency control unit 44 changes the transmission frequency of the filter 42.

When the averaging process for all the frequencies is completed, the relationship between the frequency, the distance between the optical fibers, and the back Brillouin scattered light intensity is obtained as shown in FIG. The peak detector 45 detects the frequency 31 at which the scattered light intensity has a peak from the intensity frequency distribution of the backward Brillouin scattered light for each distance of the optical fiber 2 as shown in FIG. Then, the distortion is calculated by the distortion calculator 46.

In the earth and sand collapse detection system having the above-described configuration, the optical fiber 2 is protected by the stainless steel tube 1,
We are trying to improve the environment. When a part of the earth and sand in which the optical fiber 2 is buried collapses, the belly 12 of the stainless steel tube 1 extends even if it is a small-scale collapse or a medium-scale or large-scale collapse. (Or shrink), the flanges 1 at both ends of the stainless steel pipe 1
The optical fibers 2 fixed in the hollow portions 1 and 11 move, and the optical fibers 2 are distorted.

Therefore, by measuring the amount of the strain with the strain measuring device 4, the strain (deformation) over the entire length of the optical fiber 2 can be detected. That is, since the position of the distortion can be detected at any point in the optical fiber 2 where the distortion occurs, the position of the collapsed earth and sand can be accurately detected. Note that, in the strain measuring device 4, the optical fiber having a length of about 2 m is used as a light emitting element.
Since distortion of about 2 mm or more can be detected, minute distortion can be detected, and advance prediction of earth and sand collapse becomes possible.

Further, a part of each stainless steel tube 1 has a shroud structure, and the amount of elongation of the shroud 12 can be changed according to the required specification of the strain detection sensitivity of the optical fiber 2.
Specifically, for example, it can be changed within a range of 0.2 mm to 6 cm of elongation per 2 m of the length of the stainless steel tube 1 as a standard. Further, since the resistance collars 11 are provided at both ends of each stainless steel pipe 1, the stainless steel pipe 1 and the optical fiber 2 do not move and only the earth and sand do not move when buried in the soil.

Although the optical fiber 2 has both ends fixed to the flange 11 of the stainless steel protection tube 1 for each unit length (about 2 m), since the inside of the stainless steel protection tube 1 is in a free state, the earth and sand may be removed. Even when the optical fiber 2 moves slightly, distortion occurs, and accurate distortion detection of the optical fiber 2 becomes possible.

It should be noted that the present invention is not limited to the above-described embodiment, and can be implemented with appropriate modifications without departing from the scope of the invention. (Summary of Embodiment) The configuration, operation and effect shown in the embodiment are summarized as follows. [1] The landslide detection system described in the embodiment
A plurality of pipes (1) provided in the target earth and sand and connected so that the optical fiber 2 is inserted into each hollow portion, such that when the target collapses, the corresponding pipe (1) expands and contracts. Measuring means for detecting a collapse position of the object by measuring a belly member (12) provided in each of the tubes (1) and a strain distribution of the optical fiber 2 accompanying expansion and contraction of the tubes (1) ( 4).

Therefore, according to the above-mentioned earth and sand collapse detection system, the strain over the entire length of the optical fiber 2 can be detected, and the position of the collapsed earth and sand can be accurately determined over the entire length of the optical fiber 2 regardless of the scale of the collapse. Can be detected. [2] The earth and sand collapse detection system shown in the embodiment is the system according to the above [1], and each of the pipes (1)
Are provided with brim members (11) at both ends.

Therefore, according to the above-mentioned sediment collapse detection system, when each pipe (1) and the optical fiber 2 are buried in the earth and sand, each of the pipes (1) and the optical fiber 2 move without moving. This can prevent the occurrence of the collapse of the earth and sand, and can surely detect the collapse.

[0025]

According to the landslide detection system of the present invention, the strain over the entire length of the optical fiber can be detected, and the position of the landslide where the collapse has occurred can be accurately determined over the entire length of the optical fiber regardless of the scale of the collapse. Can be detected.

According to the earth and sand collapse detection system of the present invention,
When each tube and optical fiber are buried in earth and sand, each tube and optical fiber can be prevented from moving without moving and only earth and sand can be reliably detected when collapse of earth and sand occurs. Can be.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a sediment collapse detection system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a strain measuring device according to the embodiment of the present invention.

3A and 3B are diagrams according to the embodiment of the present invention, wherein FIG. 3A is a diagram illustrating a relationship between a frequency, an optical fiber distance, and a backward Brillouin scattered light intensity, and FIG. 3B is a diagram illustrating a frequency shift and a backward Brillouin scattered light intensity; FIG.

FIG. 4 is a diagram showing an example of laying optical fibers in a conventional earth and sand collapse detection system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Stainless steel tube 11 ... Resistance brim 12 ... Belt 2 ... Optical fiber 3 ... Fiber fixing adhesive 4 ... Strain measuring device 41 ... Transmitter / receiver 42 ... Filter 43 ... Addition average part 44 ... Frequency control part 45 ... Peak Detector 46: Strain calculator

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tadashi Sugimura 5-717-1 Fukabori-cho, Nagasaki-shi, Nagasaki Sanishi Heavy Industries Co., Ltd. Nagasaki Research Institute (72) Inventor Masazumi Tsukano 1-1-1, Akunoura-cho, Nagasaki-shi, Nagasaki No.Mitsubishi Heavy Industries, Ltd.Nagasaki Shipyard

Claims (2)

[Claims] 1. A plurality of pipes provided on a target earth and sand and connected so that an optical fiber is inserted into each hollow portion, and each of said pipes expands and contracts when said target collapses. A shrinkage member provided on the pipe, and measuring means for detecting a dislocation position of the target by measuring a strain distribution of the optical fiber due to expansion and contraction of the pipe; system. 2. The earth and sand collapse detection system according to claim 1, wherein collar members are provided at both ends of each pipe.