JPH0882649A - Multiplexing system of self-emission type light sensors - Google Patents

Abstract

PURPOSE: To obtain a multiplexing system of self-emission type light sensors which makes it possible to monitor simultaneously the self-emission type light sensors provided at a plurality of places, to collect light signals through optical fibers and to detect positions of generation of the light signals. CONSTITUTION: Optical fibers 11 and 12 for signal transmission are made to branch in two at a prescribed place and laid so that they are parallel to each other at a prescribed interval between them and that the respective fore ends thereof on the branching side separate from each other, and a necessary number of self-emission type light sensors S1 to Sn emitting light on the basis of various detection outputs are connected, like steps of stairs, between the two optical fibers laid in parallel, by photocouplers a1 to an and b1 7 to bn . The connection is so made that connecting distances of the self-emission type light sensors each one end of which is connected first to these two optical fibers are made different from the branching position of the fibers. Signals generated from each of the self-emission type light sensors are transmitted as two signals through the photocouplers connected to the opposite sides thereof, a transmission time difference τ between them is detected and the position of emission of light is specified therefrom.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention collects photodetection signals from self-luminous photosensors installed at a plurality of locations through a signal transmission optical fiber to generate a light signal. The present invention relates to a multiplexing system of a self-luminous photosensor for detecting the position of a light source.

[0002]

2. Description of the Related Art There are two types of optical sensors, one of which emits light itself by a detection signal and the other of which modulates the supplied light by the detection signal. The latter type of optical sensor has one or two optical fibers. Has proposed a multi-point type optical fiber sensor system. This system will be described with reference to the system configuration diagram of FIG. 4 and the waveform diagram of FIG. As shown in FIG. 4, the laser light source 1 is controlled by the control device 2 and the laser light source 1 shown in FIG.
The transmitted light pulse sequence t _1, t ₂ shown in, ..., via the optical coupler splitter 3 t _n, (hereinafter abbreviated as optical fiber) signal transmission optical fiber the optical sensor through _{4 H 1, H 2 ... H} n Sent to. Each light sensor receives light pulses by modulating the transmitted light pulse sequence at the current / voltage waveforms as shown in FIG. _{5 (b) i 1, i} 2, ..., returned as i _n, optical coupling splitter 3
Is received by the optical receiver 5 via the reflection pulse train receiver 6
Serial-to-parallel conversion is sent to the signal processing device 7 in FIG.
Each optical sensor H reproduced from the received optical pulse train as shown in
_1, H ₂ ... H _n waveform h _1, h ₂ of, ..., in which h _n is displayed, the size and the time of transmission of each optical sensor H _1, H ₂ ... light pulses returning from H _n Depending on the elapsed time of
This is a method of detecting the quantity to be measured and specifying the location of the optical sensor.

[0003]

However, even if the latter method described above is applied to the former method using the self-emission type optical sensor, the light emission timing of the self-emission type optical sensor is unknown, so the optical sensor Therefore, the former method requires one optical fiber and one signal processing device for one optical sensor. Further, the former method using the self-luminous photosensor only needs to detect the photodetection signal transmitted when the state of the photosensor changes, so that the configuration of one system itself is simple. As described above, there is a problem in that one system cannot monitor sensors at a plurality of points, and the system cannot be applied to a system that simultaneously monitors multiple points. The present invention provides a multiplexing method capable of simultaneously monitoring optical sensors at a plurality of locations while using a self-luminous optical sensor having a simple system configuration.

[0004]

According to a first aspect of the present invention, a self-luminous optical sensor multiplexing system is provided, in which a signal transmission optical fiber is branched into two at a predetermined position, and an optical fiber on the branch side is provided. Wire the two ends so that they are parallel to each other in a direction in which they are separated in a crosswise manner, and between the two optical fibers that are wired in parallel, a required number of self-emission type optical sensors that emit light based on various detection outputs are used like ladders. Are connected by an optical coupler, and the self-luminous photosensors to which the one ends are first connected from the branch positions of the both optical fibers are connected so as to have different connection distances. The signal generated from the optical sensor is transmitted as two signals through the optical couplers connected to both sides thereof, and the optical signal detecting means provided on the other side of the signal transmitting optical fiber detects the transmission time difference between the two signals. It is obtained so as to identify the self-emission type optical sensor which emits light by.

In the multiplexing system of the self-luminous photosensor of the second invention, one of the signal transmission optical fibers is folded back at an arbitrary position and wired in parallel at a predetermined interval, and the wires are wired in parallel. The required number of self-emission type optical sensors that emit light based on various detection outputs are connected between both optical fibers by an optical coupler like a ladder cross, and the signal generated from this self-emission type optical sensor is connected to both sides of the optical fiber. A self-luminous optical sensor that emits light is specified by transmitting two signals via a coupler, and detecting a transmission time difference between the two signals by an optical signal detecting means provided on the other side of the signal transmitting optical fiber. It was done like this.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail based on the embodiments shown in the drawings. FIG. 1 shows a system configuration diagram of the first embodiment of the present invention, in which S ₁ , S ₂ , ..., S _n-1 , S _n are self-luminous photosensors, which are used for optical fibers 11 and 12. Coupler a
₁ , a ₂ , ..., A _n-1 , a _n and the optical coupler b ₁ ,
b _2, ..., are connected in a ladder rungs by b _n-1, b n. And between each optical coupler a ₁ a ₂ (b
₁ b ₂ ), a ₂ a ₃ (b ₂ b ₃ ), ..., a _n-1 a _n (b
The optical fiber length of _{( n-1} b _n ) is l ₁ , l ₂ , ..., L _n-1 . One of the optical fibers 11 and 12 is combined by the optical coupler c and connected to the optical fiber 13, and is connected to the optical signal detector 14. Also, the optical fibers 11 and 12
The other of the two is wired in parallel at a predetermined interval in a direction in which both tips are crossed and separated. That is, the self-luminous optical sensor S ₁ is connected so that it is closest to the optical fiber 11 and farthest from the optical fiber 12 from the optical signal detector 14, and the self-luminous optical sensor S ₁ is also connected. S _n is farthest from the optical signal detector 14 to the optical fiber 11,
It is wired so as to be connected to the optical fiber 12 so as to be closest to it.

The lengths of the optical fibers 11 and 12 are set to different lengths. That is, the length L _A from the optical signal detector 14 to the optical coupler a ₁ of the fiber 11 and the length L _A from the optical signal detector 14 to the optical coupler b _n of the fiber 12.
The length is different from that of _B. In addition, 15
Is a display device that displays the optical signal detected by the optical signal detector 14, and is a display unit of an oscilloscope, or a display device such as an LED or LCD. Reference numeral 16 denotes an excitation light source, the operation of which will be described later.

In the system configuration diagram shown in FIG. 1, when an abnormal state change for various detection purposes is detected and one of the self-luminous photosensors S _i emits light,
Optical signals are transmitted in two directions of the optical couplers a _i and b _i , detected by the optical signal detector 14 and displayed on the display device 15. The optical signals are transmitted to the optical fiber 11 and the optical fiber 12 having different lengths. Optical signal detector 1 with a time difference for transmitting
4 and the display device 15 displays τ
Two pulse signals with a time difference of _i are displayed. Therefore, by observing this time difference τ, it is possible to specify the installation location of the self-luminous photosensor S _{i that} emitted light.
That is, for example, when the self-luminous photosensor S _i emits light,
The time difference τ _i between the two optical signals is the speed of light in the optical fiber u
(= C ₀ / n; c ₀ : speed of light in vacuum, n: refractive index of optical fiber), the time difference τ _i in the case of FIG.
It is expressed by the following equation (1).

[0009]

[Equation 1]

However, it is assumed that L _A ≠ L _B. When L _A = L _B , the signals from the first and nth sensors cannot be distinguished, so that L _A ≠ L _B is necessary. In the present invention, when the optical signal from the optical sensor passes through an optical fiber having a large number of branch points, the optical signal is branched at the branch points, the optical signal intensity detected at the receiving end becomes weak, and the number of sensors that can be installed is reduced. Since there is a problem that it cannot be increased, the self-luminous photosensor S can be solved by using, for example, the self-luminous amplified photosensor shown in FIG.

The self-luminous amplified optical sensor shown in FIG. 3 (a) is a corona for detecting light generated by ultraviolet rays hitting a fluorescent substance by corona discharge for detecting deterioration of a gas insulated switchgear (GIS). A fluorescent sensor 21 is provided as a discharge sensor or a radiation photosensor (scintillator) that detects the light generated when the radiation hits a fluorescent substance (such as sodium iodide), and an amplification optical fiber 22 is connected to both ends thereof. It was done. Then, the pumping light 23 is supplied from the pumping light source 16 of FIG. 1 to the amplifying optical fiber 22 by using the optical fibers 11 and 12, and the detected optical signal is amplified, and the amplified optical signal 24 is transmitted. Therefore, the number of installed sensors can be increased.
In addition, the self-emission type amplified optical sensor S shown in FIG.
Light emitting element 25 such as light emitting diode due to surge current
The amplification optical fiber 22 is connected to the surge current detection sensor 26 that emits light, and the detection light signal 24 is amplified by supplying the excitation light 23 from the excitation light source 16 as in FIG. 3A. is there.

FIG. 2 shows a system configuration diagram of the second embodiment of the present invention. The difference from the first embodiment shown in FIG. 1 is that one of the optical fibers 17 is optional. It is folded back at a place and wired in parallel at a predetermined interval, and between the optical fibers wired in parallel, the required number of self-emission type optical sensors that emit light based on various detection outputs are used like a ladder cross. It has just been connected to the optical coupler. Therefore, the optical couplers a _n and b for connecting the self-luminous photosensor S _n are connected.
between _n has a structure that is connected by an optical fiber having a length l _n. Other configurations are the same as those in the system configuration diagram of FIG. 1, and thus description thereof will be omitted. Next, the operation of this embodiment will be described. As in the case of the first embodiment, when one of the self-emission type optical sensors S _i emits light, the optical couplers a _i and b are used.
_The optical signal is transmitted in two directions, _i.e. , _i, and is detected by the optical signal detector 14 and displayed on the display device 15.
In 4, the signal on the optical coupler b side is detected after the signal on the optical coupler a side, but the delay time difference τ differs depending on the installation location of the self-emission type optical sensor S. Therefore, by observing this time difference τ, it is possible to specify the installation location of the self-luminous photosensor S _{i that} emitted light.

[0013] That is, for example, the time difference tau _i of the two light signals when the self-emission type optical sensor S _i is emitted, if the velocity of light in the optical fiber and u, the time difference in the case of FIG. 2 tau _i
Is expressed by the following equation (2).

[Equation 2] Also in the second embodiment, the self-luminous amplified optical sensor is used as the self-luminous optical sensor S, and the excitation light source 16 is used.
First, it is possible to increase the number of sensors to be installed by supplying the excitation light 23 from the amplifier and amplifying the detection light signal.
This is the same as the embodiment.

[0014]

As is apparent from the above description, according to the present invention, it is possible to multiplex the self-emission type optical sensor by one or two optical fibers for signal transmission. The system can be simplified and the detection position can be known with certainty. Furthermore, by using the self-emission type amplified optical sensor for the self-emission type optical sensor, it is possible to install a large number of self-emission type optical sensors, and it is possible to expand the optical sensor system. It plays.

[Brief description of drawings]

FIG. 1 is a system configuration diagram of an embodiment of the present invention.

FIG. 2 is a system configuration diagram of another embodiment of the present invention.

FIG. 3 is a configuration diagram of an embodiment of a self-emission type amplified optical sensor used in the present invention.

FIG. 4 is a configuration diagram of a conventional optical sensor system that modulates supplied light with a detection signal.

FIG. 5 is a waveform diagram of a transmission signal in the conventional optical sensor system.

[Explanation of symbols]

1 Laser Light Source 2 Control Device 3 Optical Coupling Brancher 4, 11, 12, 13, 17 Signal Transmission Optical Fiber 5 Optical Receiver 6 Reflection Pulse Train Receiver 7 Signal Processing Device 14 Optical Signal Detector 15 Display Device 16 Excitation Light Source 21 fluorogenic 22 amplification optical fiber 23 the pumping light 24 optical signal 25 light emitting element 26 surge current detection sensor H ₁ to H _n optical sensors S ₁ to S _n self-emission type light sensor a ₁ ~a _n, b ₁ ~b _n , c Optical coupler

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G01R 29/00 FG 01T 1/00 A 9216-2G H04J 14/00 14/04 14/06

Claims (5)

[Claims] 1. An optical fiber for signal transmission is branched into two at a predetermined position, and both ends of the optical fiber on the branch side are wired so as to be parallel to each other in a direction in which they are separated in a crosswise manner. A number of self-luminous photosensors that emit light based on various detection outputs are connected between both optical fibers with an optical coupler like a ladder cross. The self-luminous photosensors to which one end thereof is connected are connected so as to have different connection distances, and signals generated from the self-luminous photosensors are transmitted as two signals through the optical couplers connected to both sides thereof. A self-emission type optical sensor for identifying a self-emission type optical sensor that emits light by detecting a transmission time difference between the two signals by an optical signal detection means provided on the other side of the signal transmission optical fiber Optical sensor multiplexing method. 2. One of the optical fibers for signal transmission is folded back at an arbitrary position and wired so as to be parallel to each other at a predetermined interval, and the two optical fibers wired in parallel are automatically controlled so as to emit light based on various detection outputs. The light emitting type optical sensor is connected by an optical coupler like a ladder cross, and the signal generated from this self-luminous type optical sensor is transmitted as two signals through the optical couplers connected on both sides of the light emitting type optical sensor. A method of multiplexing a self-luminous photosensor, wherein a self-luminous photosensor that emits light is specified by detecting a transmission time difference between the two signals by an optical signal detector provided on the other side of the fiber. 3. An amplification optical fiber is provided in the self-emission type optical sensor portion, and an excitation light source is provided between the optical signal detecting means of the signal transmission optical fiber and the self-emission type optical sensor. The multiplexing system of a self-luminous photosensor according to claim 1 or 2, wherein a detection optical signal of the self-luminous photosensor is amplified. 4. The multiplexing system for a self-luminous photosensor according to claim 1, 2 or 3, wherein the self-luminous photosensor is a light emitting element that emits light by a surge current or the like. 5. The method of multiplexing a self-luminous photosensor according to claim 1, 2 or 3, wherein the self-luminous photosensor is a fluorescence generating part which emits light when irradiated with ultraviolet rays or radiation.