JPH0814984A - Water level sensor - Google Patents

Abstract

PURPOSE:To provide a water level sensor which is the optimum for monitoring water levels at a plurality of locations from a remote area and can monitor the water levels at a low cost. CONSTITUTION:The temperature of an optical fiber 7 for detecting temperature in a spirally wound stainless tube 5 is raised by causing the tube 5 to generate heat by making an electric current to flow through the tube 5. When the chamber 9 of a sensor main body 1 is dipped in water under such a condition, the temperature of the part of the optical fiber 7 dipped in the water drops. By generating Raman scattered light by making optical signals to incident to the optical. fiber 7, the scattered light is sampled and analyzed. The level and frequency of the scattered light fluctuate in accordance with the temperature and length of the optical fiber 7. Therefore, a water sensor is constituted so that the water level at a location can be obtained by finding the length of the temperature-dropped part of the optical fiber 7, namely, the water level can be found by analyzing the Raman scattered light generated in the optical, fiber 7.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water level sensor for detecting the water level of rivers, lakes, ponds and the like.

[0002]

2. Description of the Related Art Various devices and methods have been proposed and implemented for detecting the water level in a river. The simplest device is to set up a scaled column on the bottom of the water and read the scale of the column at the position of the water surface to know the water level. There is also a sensor that supports a float so that it can float and sink, and detects the position of this float to detect the water level.

On the other hand, in order to monitor the water levels at a plurality of locations, a plurality of graduated columns are set up at their respective positions, and the telescope is used to read the graduated scales of these columns, or a plurality of sensors are used respectively. , And the detection outputs of these sensors are collected by a telemeter system or an appropriate communication system.

[0004]

However, when the scale of each column is read using the telescope, the water level cannot be monitored in such a wide range. Moreover, when using a telemeter system or a communication system, the cost for these systems was high.

Therefore, an object of the present invention is to provide a water level sensor which is optimal for remotely monitoring water levels at a plurality of locations and which can be implemented at a low cost.

[0006]

In order to solve the above-mentioned problems, the water level sensor of the present invention is a spiral body formed by spirally winding a conductor tube through which an optical fiber is passed, and protruding at a position where the water level should be detected. And heating means for heating the conductor tube of the spiral body to raise the temperature of the optical fiber inside the conductor tube, and for making light incident on the optical fiber, detecting scattered light from the optical fiber, and analyzing the scattered light. By doing so, an optical analysis unit for detecting the water level is provided.

Further, a plurality of spirals are projected at respective positions, and the optical fibers of these spirals are connected in series, and the optical analysis means measures the time from the time when light is incident on the optical fibers. By detecting the scattered light at each predetermined time and analyzing the scattered light, the water level at the position of each spiral is detected.

The scattered light detected and analyzed by the light analysis means is Raman scattered light.

[0009]

In the water level sensor of the present invention, the spiral conductor tube is heated to raise the temperature of the optical fiber inside the conductor tube. Since the spiral body is projectingly provided at the position where the water level should be detected, as the water level rises, the portion of the conductor pipe that is immersed in water becomes longer, and the temperature of the optical fiber at that portion decreases. On the other hand, when light is incident on the optical fiber, scattered light is generated, and the scattered light changes depending on the temperature and the length of the optical fiber. Therefore, the optical analysis means can detect the scattered light from the optical fiber and analyze the scattered light to detect the length of the portion of the optical fiber where the temperature has dropped, that is, the water level.

When a plurality of spiral optical fibers are connected in series, when light is incident on the end of this optical fiber, the scattered light generated in each spiral can be detected from this end. Each time from the incidence of this light to the detection of the scattered light of each spiral is proportional to the length of each optical fiber from the end of the optical fiber to each spiral.
Therefore, the optical analysis means measures the time from the time when the light is incident on the optical fiber, and for each predetermined time,
By detecting each scattered light and analyzing these scattered lights, each water level at the position of each spiral can be detected.

When the scattered light detected and analyzed by the light analyzing means is Raman scattered light, changes in the level and frequency of this Raman scattered light are analyzed.

[0012]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 schematically shows an embodiment of the water level sensor of the present invention. The water level sensor of this embodiment is composed of a plurality of sensor bodies 1 _-1 , 1 _-2 , which are provided at the respective locations of the river.
.., 1- _n and the measuring device 2.

Each of the sensor bodies 1 _-1 to 1 _-n is the same and is constructed as shown in FIG. As is apparent from FIG. 2, the sensor body 1 has the hollow pipe 3 inside.
And the outer sheath pipe 4 on the outside, and the stainless pipe 5 is spirally wound around the outer periphery of the hollow pipe 3.

The stainless steel pipe 5 is one and is folded in two as shown in FIG. This stainless tube 5
Fix the bent part of the to the lower end of the hollow pipe 3 and
A folded stainless steel tube 5 is spirally wound around the outer circumference of the hollow pipe 3.

FIG. 4 shows a cross section of a stainless steel tube 5 folded in two. As is clear from FIG. 4, the stainless steel pipe 5 is covered with an anticorrosion layer 6 (for example, synthetic resin paint). An optical fiber 7 for temperature detection is passed through the stainless steel tube 5.

A plurality of through holes 8 are provided on the outer circumference of the exterior pipe 4.
Is provided. These through holes 8 are formed in the hollow pipe 3
This is for introducing water into the chamber 9 between the exterior pipe 4 and the exterior pipe 4 and for draining the water in the chamber 9 to the outside.

At the upper ends of the hollow pipe 3 and the exterior pipe 4,
A waterproof box 13 is provided. In the waterproof box 13, the temperature detecting optical fiber 7 is led out from the stainless tube 5, and the temperature detecting optical fiber 7 is connected to the transmission optical fiber 15 via the optical connecting portion 14. Also,
A pair of power lines 16 are connected to both ends of the stainless steel pipe 5. Transmission optical fiber 15 and each power line 16
Are bundled as one cable 17, and this cable 17 is led out from the waterproof box 13.

As shown in FIG. 1, a cable 17 connects the respective sensor bodies 1 _-1 to 1 _-n and the measuring device 2 to each other.
The transmission optical fiber 15 of the cable 17 is interposed between the temperature detection optical fibers 7 of the respective sensor bodies 1 _-1 to 1 _-n ,
The temperature detecting optical fibers 7 are connected in series. Therefore, these optical fibers can be regarded as one, one end of which is connected to the measuring device 2 and the other end of which is open at the last sensor body 1 _-n .

Each power line 16 of the cable 17 is connected to the measuring device 2 and the stainless steel pipe 5 of each sensor body 1 _-1 to 1 _-n .

On the other hand, the measuring device 2 includes an optical pulse generator 2
1, timer 22, Raman scattered light analysis unit 23, control unit 2
4, a power supply 25 and the like.

The optical pulse generator 21 generates a monochromatic optical signal in a pulse form and transmits the optical signal to the transmission optical fiber 15
Is incident on one end of. The Raman scattered light analysis unit 23 detects light from one end of the transmission optical fiber 15, analyzes the Raman scattered light contained in this light, and detects the level and frequency displacement of this Raman scattered light. The power supply 25 supplies power to each power line 16 of the cable 17.

In this water level sensor, by supplying power from the power supply 25 of the measuring device 2 to each power line 16 of the cable 17, a current is supplied to the stainless steel pipe 5 of each sensor body 1 _-1 to 1 _-n. Sink, these stainless tubes 5
Heat up. As a result, the temperature of each temperature detecting optical fiber 7 inside each stainless steel tube 5 is kept sufficiently higher than the air temperature or the water temperature.

In this state, the respective sensor bodies 1 _-1 to 1 _-n are submerged in water, and the chambers 9 of these sensor bodies 1 _-1 to 1 _-n are submerged. For example, the chamber 9 of the sensor body _1-1 has a water level H
When it is flooded until, stainless tube 5 of the sensor body 1 _-1 soak in water until the water level H, the temperature of the portion of the temperature sensing optical fiber 7 below the water level H is lowered. Similarly,
Also in each of the other sensor body 1 _-2 to 1 _-n, and the chamber 9 is submerged, the temperature of the portion of the temperature sensing optical fiber 7 of the water level below is reduced.

The control unit 24 of the measuring apparatus 2 activates the optical pulse generation unit 21 and causes the optical pulse generation unit 21 to output an optical signal. This optical signal is transmitted by the optical fiber 15 for transmission.
Is incident on one end of the sensor body 1 and is sequentially transmitted to the temperature detecting optical fibers 7 of the respective sensor bodies 1 _-1 to 1 _-n .

With the transmission of this optical signal, Raman scattered light is generated in the optical fiber. The level and frequency of this Raman scattered light change according to the temperature and length of the optical fiber. Therefore, the level and frequency of the Raman scattered light generated in the temperature detecting optical fiber 7 changes according to the length of the temperature detecting optical fiber 7 where the temperature has dropped, that is, the water level.

Further, from the measuring device 2, each sensor body 1 _-1 to
Since the length of each of the optical cables of up to 1 _-n is different, the light signal reaches the respective sensor body 1 _-1 to 1 _-n, Raman scattered light measurement of each sensor body 1 _-1 to 1 _-n Each time it takes to return to the device 2 is different.

The control unit 24 of the measuring device 2 activates the timer 22 at the time when the optical signal is output, and each sensor body 1 _-1
Each time until Raman scattered light of 1- _n is returned to the measuring device 2 is measured. These times are sequentially notified from the timer 22 to the Raman scattered light analysis unit 23.

The Raman scattered light analyzing section 23 is arranged so that the optical fiber 1 for transmission is sent every time the timer 22 notifies each time.
Raman scattered light is sampled from one end of 5. Then, the Raman scattered light analysis unit 23 analyzes each scattered light sampled at each time, and based on the change in the level and frequency of these scattered light, each sensor main body 1 _-1 to 1 _-n.
Find each water level at the position. And the measuring device 2
Displays these water levels on a display device (not shown) or records them by a recording device (not shown).

In such a water level sensor, a telemeter system and a communication system are not required, and since the water level is detected and data is transmitted by the optical fiber connected in one, the cost can be kept low. Also,
There is little concern about breakdown, and maintenance is easy.

Although the detection of the water level is illustrated here, the present invention is not limited to this, and this water level sensor may be used for detecting water leakage.

[0032]

As described above, in the water level sensor of the present invention, the spiral conductor pipe is provided at the position where the water level should be detected,
The conductor tube is heated to raise the temperature of the optical fiber inside the conductor tube. The part of the conductor tube is soaked in water, and the temperature of the optical fiber in this part decreases. The water level is detected by injecting light into this optical fiber and analyzing the scattered light from this optical fiber.

This water level sensor can monitor the water level from a remote place without installing a communication device. Further, by disposing a plurality of spiral bodies in a wide range and connecting the optical fibers of these spiral bodies in series, it is possible to detect each water level at the position of these spiral bodies.

[Brief description of drawings]

FIG. 1 is a schematic view showing an embodiment of a water level sensor of the present invention.

FIG. 2 is a cross-sectional view showing a sensor body in the water level sensor shown in FIG.

3 is a partially enlarged view showing a stainless steel tube in the sensor body of FIG.

4 is a sectional view showing a stainless steel tube in the sensor body of FIG.

[Explanation of symbols]

1,1 _-1 to 1 _-n Sensor body 2 Measuring device 3 Hollow pipe 4 Exterior pipe 7 Temperature detection optical fiber 13 Waterproof box 15 Transmission optical fiber 16 Power line 17 Cable 21 Optical pulse generator 22 Timer 23 Raman scattered light analyzer 24 control unit 25 power supply

Claims (3)

[Claims] 1. A spiral body formed by spirally winding a conductor tube through which an optical fiber is passed, and a spiral conductor projecting at a position where a water level should be detected; By injecting light into the heating means for raising the temperature and this optical fiber, detecting scattered light from this optical fiber, and analyzing this scattered light,
A water level sensor comprising an optical analysis means for detecting the water level. 2. A plurality of spirals are projected at respective positions, and the optical fibers of these spirals are connected in series, and the optical analysis means measures the time from the time when light is incident on the optical fibers. The water level sensor according to claim 1, wherein the scattered light is detected every predetermined time, and the scattered light is analyzed to detect each water level at the position of each spiral. 3. The water level sensor according to claim 1, wherein the scattered light detected and analyzed by the light analyzing means is Raman scattered light.