JPH05173024A - Method and device for laying distribution type optical fiber sensor and method for measuring distribution of physical quantity - Google Patents

Abstract

PURPOSE:To precisely attain correspondence of a position by specifying a distance from each measuring part based upon the delivering length of an optical fiber to be measured when a specific part of the fiber passes the measuring part. CONSTITUTION:A delivering device utilizing a rotary drum or the like to deliver an optical fiber 9 (or a capillary when the fiber is stored in the capillary) delivers the fiber 9 along respective measuring parts. While delivering the fiber 9, the distance of a distribution type optical fiber sensor 6 from a reference point set up near a measuring device is determined by measuring the delivering length of the fiber 9. The delivering length of the fiber 9 is measured by counting up marks 8 formed on the fiber 9 itself in each unit length by an optical means 7 or the like or measuring the length by a delivering length measuring means or the like included in the delivering device itself.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention uses an OTDR (Optical Time Domain Reflectometry) method to measure physical quantity distributions such as temperature distributions, break point detections and pressure distributions along an optical fiber to be measured. The present invention relates to a method for laying a distributed optical fiber sensor and a method for measuring a physical quantity distribution.

[0002]

2. Description of the Related Art A block diagram of a conventional distributed optical fiber temperature sensor is shown in FIG. The laser pulse oscillated from the laser pulser 40 (semiconductor laser or the like) of the light source unit is incident on the optical fiber 42 to be measured, and the backward Raman scattered light generated in the optical fiber 42 to be measured returns to the incident end. The rearward Raman scattered light is guided to the measuring device by an optical directional coupler 11 (optical fiber star coupler or acousto-optical switch).

First, the Stokes light and the anti-Stokes light in the backward Raman scattered light are separated by the filter 43 (optical filter or the like), and the photoelectric conversion units 44A and 44B are respectively separated.
(Photodiode, avalanche photodiode, etc.) is converted into an electric signal proportional to its intensity. The electric signals are amplified by preamplifiers 45A and 45B, respectively,
It is converted into a digital signal by the D converters 46A and 46B. After that, the signal processing unit 47 performs addition and averaging processing a predetermined number of times, and performs processing such as conversion to temperature distribution by obtaining the ratio of Stokes light and anti-Stokes light. The obtained temperature distribution data is displayed on a computer display or the like.

Conventionally, when an optical fiber to be measured is laid on a measuring object such as a building, a factory, a chemical or heavy electric plant, it is equivalent to a reference position of the measuring object after the optical fiber to be measured is installed on the measuring object. The physical quantity (temperature, etc.) of the reference point of the optical fiber to be measured is intentionally changed, measured with a distributed optical fiber sensor, and each position of the measurement target is associated with the distance from the reference point of the optical fiber to be measured. Was there.

[0005]

The problems of the prior art are as follows. (1) When the shape of the measurement target becomes complicated, the measurement accuracy deteriorates. That is, a structure that can be simply one-dimensionalized with an almost linear shape such as a power transmission cable may be used. However, it is extremely worse than the distance accuracy of the distributed optical fiber sensor.

Therefore, as shown in FIG. 5, the distance between the optical fiber and the position of the measurement target is associated with each measurement target. In the figure, 1 is a measurement object such as a pipe, 2 is a reference position, 3 is a physical quantity change such as temperature, 4 is a physical quantity distribution obtained from measurement, and 5 is an optical fiber to be measured. At the reference position 2, the optical fiber 5 to be measured is pulled out extra,
The temperature of this part is changed. The position can be associated by reading this with a distributed optical fiber sensor. As a result, accurate measurement can be performed in the vicinity of the reference point, but as the distance from the reference point increases, the positioning error increases, and as a result, the measurement accuracy deteriorates.

(2) After laying the optical fiber to be measured on the object to be measured, it may be difficult to intentionally change the physical quantity such as the temperature of a part of the optical fiber to be measured. For example, it is difficult in the case where the optical fiber to be measured is laid in a complicated intricate pipe or along the pipe, in a facility for storing explosive chemical substances and radioactive substances, in a nuclear fuel reactor, or the like.

(3) Conventionally, after the optical fiber to be measured has been laid once, the above-mentioned work process for position matching is further required, so that the laying work takes time or a new device is used. There is a problem in that the need arises and the installation cost is increased.

It is an object of the present invention to solve the above-mentioned problems and to accurately associate positions while laying an optical fiber to be measured on an object to be measured.

[0010]

The present invention has been made to solve the above-mentioned problems, and as a first invention,
In a method of laying a distributed optical fiber sensor that measures the physical quantity distribution along the optical fiber to be measured, the optical fiber to be measured is sent out along the measuring object while measuring the sending length through a reference point, and there is an identification of the optical fiber to be measured. The method for laying a distributed optical fiber sensor is characterized in that, when the part (1) passes through each part of the object to be measured, the distance from the reference point of each part of the object to be measured is specified from the delivery length at that time.

As a second invention, a feeding device for feeding the optical fiber to be measured along a measuring object through a reference point, a measuring device for measuring the feeding length of the optical fiber to be measured, and each part of the measuring object corresponding to the feeding length. And a storage device for storing the position of the distribution type optical fiber sensor.

As a third invention, based on the distance data from the reference point of each part of the measurement object and the design data of the measurement object, the position and structure of each part of the measurement object and the physical quantity distribution along each part of the measurement object are displayed. The present invention provides a method for measuring the physical quantity distribution of a characteristic distributed optical fiber sensor.

[0013]

In the present invention, the optical fiber to be measured is laid on the object to be measured as follows. (1) The optical fiber to be measured is sent along the object to be measured by a sending device for the optical fiber to be measured (the thin tube if it is housed in a thin tube) using a rotating drum or the like. At this time, the distance from the reference point provided near the measuring device of the distributed optical fiber sensor is determined by sending out the optical fiber to be measured and measuring its sending length. The sending-out length of the optical fiber to be measured is marked on the unit itself per unit length (for example, every 1 m), and the marking is counted using an optical means or the sending-out length to the sending-out device itself. Can be measured by providing a means for measuring

(2) When the tip of the optical fiber to be measured reaches the measurement starting point of the object to be measured, the feed length at that time is measured (marking is counted) to determine the distance from the reference point to the measurement starting point. .. Similarly, the distance between each part of the measurement target and the measurement end point can be determined.

(3) While sending out the optical fiber to be measured, install it on the object to be measured. In this case, it should be noted that the optical fiber for measurement and the position of the measurement target are installed so as not to be misaligned.

(4) When the installation of the optical fiber for measurement is completed, which part of the optical fiber for measurement corresponds to which part of the object to be measured is stored in a storage device such as a computer. For example, if 1000 pieces (1 piece / m) of markings are provided on the optical fiber for measurement of 1 km, the measurement starting point is the 20th piece (20 pieces from the reference point).
m) corresponding to each part of the measurement object p ₁ , p ₂ , p ₃ , ...
., _Pn are k ₁ , k ₂ , k ₃ , ..., K _n from the reference point
Which corresponds to the first (k ₁ , k ₂ , k ₃ , ..., K _n m),
Positioning data such that the measurement end point corresponds to the 960th point (960 m) from the reference point is stored. After that,
At the time of measuring the physical quantity, the distribution can be accurately measured based on the position data.

The physical quantity referred to in the present invention is temperature, pressure, breaking point, connection failure point, broken point and the like. In the present invention, the physical quantity distribution along the optical fiber to be measured can be measured.

[0018]

Embodiments of the present invention will be described with reference to FIGS. FIG. 1 shows a delivery length measuring device for an optical fiber to be measured. In the figure, 6 is an optical sensor including a light emitting element such as an LED that projects light on the marking of the optical fiber to be measured and a light receiving element such as a photodiode that detects a change in light reflectance due to the marking, and 7 is an optical sensor. It is a counter that measures the sending length by the data from 6.
Is a marking, and 9 is an optical fiber for measurement.

FIG. 2 shows a feed length measuring device of a type different from that shown in FIG. 1, in which the feed device itself utilizing a rotating drum is provided with means for measuring the feed length. In the figure, 10 is a feeding device, 11 is a microswitch for detecting the number of revolutions and rotational speed by a protrusion provided on the rotary shaft of the rotary drum 12, and 13 is an ON / OFF signal from the microswitch. Reference numeral 14 is a counter for counting the number of rotations and the rotation speed of the rotary drum 12, and 14 is an optical fiber for measurement.

FIG. 4 shows a block diagram of the storage device. In the figure, 15 is a memory in the microcomputer or a memory such as an external storage device using a magnetic disk or an optical disk, 16 is a microcomputer for processing and displaying data, 17 is a signal from the counter 18 to the microcomputer 16. An I / F (interface) unit 18 for introduction is a counter of the sending device in FIGS. 1 and 2.

The storage device has at least three types of functions, that is, a function of reading the sending length, a function of labeling each part of the object to be measured, and a function of storing the label and the sending length in association with each other. In this case, the relationship between the measurement target and the label needs to be specifically stored by another method. For example, at the time of laying the optical fiber for measurement, when the tip of the optical fiber for measurement reaches the measurement start point of the measurement target, the label command is executed in the microcomputer 16 to perform I / O
Input the measurement start point name from F section 17. Thereby, the distance (feeding length) from the reference point of the measurement start point is specified.

By adding an NC data reading function of an object to be measured, a graphic function, and a pointing function of each part of the object to be measured to which the function is applied to the storage device,
The above work can be simplified. Further, the laying operator can read the distance from the reference point (feeding length) and record it in association with each part to be measured, so that the storage device itself can be omitted.

The laying data (distance data from the reference point) of the present invention can be incorporated into the NC data as the attribute data of the measurement target using CAD. CAD is often used for the design of measurement objects such as buildings such as buildings and various plants, and in this case, design data is stored in a database. Therefore, if the optical fiber laying data for temperature distribution measurement is incorporated as attribute data in the database, it becomes easy to create application software when it becomes necessary to measure temperature distribution.

A display screen as shown in FIG. 4 was created based on the above. Displayed by CR such as microcomputer
T, liquid crystal display screen, etc. are used. This is a display of a partial temperature distribution measurement result in a plant piping. Reference numeral 19 is a pipe, and 20 is a temperature distribution. The horizontal axis corresponds to the pipe distance and the vertical axis corresponds to the temperature. In this way, by incorporating the distance data of the optical fiber into the design data incorporated in the CAD, it is possible to extract each part of the measurement target and display the temperature distribution, and easily install various application software therefor. be able to.

[0025]

According to the method of the present invention, it is possible to lay an optical fiber with high precision and with a simple operation even for an object to be measured having a complicated shape. Therefore, accurate measurement corresponding to the structure and position of each part to be measured can be performed. It will be possible. Further, if the installation data is incorporated into the CAD design data as the attribute data of the measurement target, the temperature distribution data together with the structure of each part of the measurement target can be displayed on the CRT of the microcomputer based on the design data. Is also very easy to create. In addition, it is also very effective for maintenance management of measurement targets such as buildings and plants.

[Brief description of drawings]

FIG. 1 is a basic configuration diagram of a delivery length measuring device for an optical fiber to be measured according to the present invention.

FIG. 2 is a basic configuration diagram of another delivery length measuring device for an optical fiber for measurement according to the present invention.

FIG. 3 is a block diagram of a storage device of the present invention.

FIG. 4 is a front view showing a display screen of temperature distribution measurement results according to the present invention.

FIG. 5 is a basic configuration diagram showing a laid state of a conventional optical fiber for measurement.

FIG. 6 is a block diagram of a conventional distributed optical fiber temperature sensor.

[Explanation of symbols]

 6 Optical Sensor 7 Counter 8 Marking 9 Optical Fiber for Measurement 10 Sending Device 11 Micro Switch 12 Rotating Drum 13 Counter 14 Optical Fiber for Measurement 15 Memory 16 Microcomputer 17 I / F Section 18 Counter

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical display location G01M 11/00 U 8204-2G G02B 6/00 H02G 1/06 Q 7373-5G

Claims (4)

[Claims] 1. A method of laying a distributed optical fiber sensor for measuring a physical quantity distribution along an optical fiber to be measured, wherein the optical fiber to be measured is sent along an object to be measured while measuring its sending length through a reference point, and the object to be measured is measured. A method for laying a distributed optical fiber sensor, characterized in that, when a specific part of the optical fiber for use passes through each part of the object to be measured, the distance from the reference point of each part of the object to be measured is specified from the delivery length at that time. 2. When the distance from each reference point of each part to be measured is specified, the delivery length of the optical fiber to be measured at that time and the position of each part to be measured corresponding to the delivery length are stored in a storage device. The method for laying a distributed optical fiber sensor according to claim 1, wherein 3. A delivery device for delivering an optical fiber to be measured along a measurement target through a reference point, a measuring device for measuring the delivery length of the optical fiber to be measured, and a position of each part of the measurement target corresponding to the delivery length is stored. A distribution type optical fiber sensor laying device, comprising: 4. A distribution characterized by displaying the position and structure of each part of the measurement object and the physical quantity distribution along each part of the measurement object based on the distance data from the reference point of each part of the measurement object and the design data of the measurement object. Method of measuring physical quantity distribution of optical fiber sensor.