JPH0726774U - Current detector - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a current detection device capable of accurately detecting a current flowing through a conductor without being affected by stress (vibration) applied to a transmission line portion to cause birefringence. To do. [Structure] An optical fiber 2 for a sensor head made of a single mode fiber is wound around a conductor 1, and one end face and the other end face of the optical fiber 2 for a sensor head are composed of a polarizer 3 and a polarization beam splitter made of laminated thin film polarizers. The respective analyzers 4 are arranged so that one end face of the transmission outward optical fiber 5 made of a single mode fiber is opposed to one end face of the sensor head optical fiber 2 through the polarizer 3,
One end face of a transmission return optical fiber 6 made of a multimode fiber is opposed to the other end face of the sensor head optical fiber 2 via an analyzer 4, and a light emitting element made of a light emitting diode is made at the other end face of the transmission outward optical fiber 5. 7 are opposed to each other, and the light receiving element 8 formed of a photodiode is opposed to the other end surface of the transmission return optical fiber 6.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a current detection device for detecting a current flowing through a conductor in an electric power system by using an optical fiber current sensor.

[0002]

[Prior art]

 FIG. 3 shows a schematic view of a conventional current detection device. In FIG. 3, 21 is a conductor for current detection. Reference numeral 22 is an optical fiber for a sensor head and a transmission / return path, which consists of a single-mode fiber, a multimode fiber, a polarization-maintaining fiber, etc. wound around the conductor 21, and has a sensor head portion, a transmission forward path portion, and a transmission return path portion. It is composed of. Reference numeral 23 denotes a light emitting element such as a laser diode which is opposed to one end surface (transmission path) of the optical fiber 22 and generates linearly polarized light. Reference numeral 24 denotes a light receiving element such as a photodiode which is opposed to the other end surface (transmission return path) of the optical fiber 22, and an input portion thereof is provided with an analyzer such as a polarization beam splitter although not shown. .

In such a current detecting device, light is incident on one end surface of the optical fiber 22 from the light emitting element 23, and light emitted from the other end surface of the optical fiber 22 is detected by the light receiving element 24. It is designed to detect the current that flows through. The principle of current detection is as follows. Here, the principle of current detection will be briefly described. When the optical fiber 22 is placed in a magnetic field parallel to the magnetic field, the polarization plane of the linearly polarized light propagating inside rotates. When the strength of the magnetic field increases, the rotation angle of the plane of polarization increases. Since the optical fiber 22 is wound around the conductor 21 so as to interlink with the conductor 21, the magnetic field generated by the current flowing through the conductor 21 is generated between the winding portion (sensor head portion) of the optical fiber 22 around the conductor 21. Become parallel. As a result, the plane of polarization of the linearly polarized light propagating in the optical fiber 22 rotates. Therefore, as the current flowing through the conductor 21 increases, the rotation angle of the plane of polarization of linearly polarized light increases. The light receiving element 24 detects this change in the rotation angle as a change in the amount of light.

For example, when a current I flows through the conductor 21, the rotation angle (sensitivity) θ of the polarization plane of the light passing through the optical fiber 22 is V when the Verdet constant and N is the number of turns of the optical fiber 22. Is represented by θ = V · N · I.

[0005]

[Problems to be solved by the device]

 In the current detection device shown in FIG. 3, the distance between the installation location of the light emitting element 23 and the light receiving element 24 and the sensor head portion in which the optical fiber 22 is wound around the conductor 21 is relatively large, and therefore the distance between them is large. The transmission line becomes longer, and stress (vibration) tends to be applied to this transmission line. When stress (vibration) is applied to the transmission line portion, double bending occurs and the plane of polarization is not preserved. Therefore, the light receiving output of the light receiving element 24 changes, and the current flowing through the conductor 21 cannot be accurately measured. There was a problem.

Therefore, an object of the present invention is to detect a current flowing in a conductor with high accuracy without being affected by stress (vibration) applied to a transmission line portion and causing birefringence. It is to provide a device.

[0007]

[Means for Solving the Problems]

 In the current detection device of the present invention, an optical fiber for a sensor head is wound around a conductor, and a polarizer and an analyzer are arranged on one end surface and the other end surface of the optical fiber for the sensor head, respectively. One end surface of the optical fiber for transmission forward path is opposed to one end surface of the sensor via the polarizer, and one end surface of the optical fiber for return path is opposed to the other end surface of the sensor head optical fiber via the analyzer. The light emitting element is made to face the other end surface of the optical fiber for use in transmission, and the light receiving element is made to face the other end surface of the optical fiber for transmission return path.

[0008]

[Action]

 According to the configuration of the present invention, the light emitted from the light emitting element propagates through the optical fiber for the outward transmission path and passes through the polarizer to become linearly polarized light. The linearly polarized light that has passed through the polarizer propagates through the optical fiber for the sensor head wound around the conductor, and the plane of polarization rotates by an angle proportional to the magnitude of the current flowing through the conductor during propagation. Then, the light whose polarization plane is rotated in proportion to the magnitude of the current is detected by passing through the analyzer, and the amount of light is proportional to the magnitude of the current flowing in the conductor and propagated through the transmission return optical fiber. Then, it is incident on the light receiving element.

In this case, since the polarizer is provided on the one end surface of the sensor head optical fiber, the light propagating in the transmission optical path may be random light. Since the analyzer is provided on the other end surface, the light propagated in the transmission return optical fiber may be random light, and stress (vibration) is applied to the transmission forward optical fiber and the transmission return optical fiber. Even if birefringence occurs, the amount of light propagating inside them is not affected by birefringence and does not change at all.

Therefore, the current flowing through the conductor can be accurately detected without being affected by the stress (vibration) applied to the transmission forward optical fiber and the transmission backward optical fiber.

[0011]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic diagram of a current detecting device according to an embodiment of the present invention. In FIG. 1, reference numeral 1 is a conductor whose current is to be detected. Reference numeral 2 denotes an optical fiber for a sensor head, which is wound around the conductor 1 and is composed of, for example, a single mode fiber. Reference numeral 3 denotes a polarizer composed of a laminated thin film polarizer (laminipole) arranged on one end surface of the sensor head optical fiber 2. Reference numeral 4 denotes an analyzer composed of a polarization beam splitter arranged on the other end surface of the sensor head optical fiber 2. Reference numeral 5 denotes an optical fiber for forward transmission, which is composed of, for example, a single mode fiber with one end surface facing the one end surface of the sensor head optical fiber 2 via the polarizer 3. Reference numeral 6 denotes a transmission return optical fiber, which is made of, for example, a multimode fiber and has one end face opposed to the other end face of the sensor head optical fiber 2 through the analyzer 4. Reference numeral 7 denotes a light emitting element which is opposed to the other end surface of the transmission outward optical fiber 5 and is composed of, for example, a light emitting diode. Reference numeral 8 denotes a light receiving element, which is made of, for example, a photodiode and is opposed to the other end surface of the optical path 6 for transmission return path. Reference numeral 9 denotes a lens that collects the light of the light emitting element 7 and makes it enter the optical fiber 5 for the forward transmission path.

The operation of this current detecting device will be described below. The light emitted from the light emitting element 7 is condensed by the lens 9 and then enters the forward transmission optical fiber 5, propagates through the forward transmission optical fiber 5 and passes through the polarizer 3 to become linearly polarized light. The linearly polarized light that has passed through the polarizer 3 propagates through the sensor head optical fiber 2 wound around the conductor 1, and the plane of polarization is rotated by an angle proportional to the magnitude of the current flowing through the conductor 1 during propagation. become. Then, the light whose polarization plane is rotated in proportion to the magnitude of the current is detected by passing through the analyzer 4, and becomes a light amount proportional to the magnitude of the current flowing in the conductor 1 and the light for the transmission return path. It propagates through the fiber 6 and enters the light receiving element 8.

In this case, since the polarizer 3 is provided on one end surface of the sensor head optical fiber 2, the light propagating in the transmission outward optical fiber 5 may be random light, and similarly, the sensor head optical fiber 2 Since the analyzer 4 is provided on the other end surface of 2, the light propagating in the transmission return optical fiber 6 may be random light, and stress is applied to the transmission forward optical fiber 5 and the transmission backward optical fiber 6. Even if birefringence occurs due to the addition of vibration, the amount of light propagating inside these is not affected by birefringence and does not change at all.

Therefore, the current flowing through the conductor 1 can be accurately detected without being affected by the stress (vibration) applied to the transmission forward optical fiber 5 and the transmission backward optical fiber 6. Further, it is not affected by the temperature change. According to the current detection device of this embodiment, the optical fiber 2 for the sensor head is wound around the conductor 1, and the polarizer 3 and the analyzer 4 are respectively provided on one end surface and the other end surface of the optical fiber 2 for the sensor head. The optical fiber 5 for the sensor head is arranged so that one end surface of the optical fiber 5 for the outgoing path is opposed to the one end surface of the optical fiber 2 for the sensor head, and the other end surface of the optical fiber 2 for the sensor head is transmitted through the analyzer 4. Since one end face of the return optical fiber 6 faces, the light emitting element 7 faces the other end of the transmission outgoing optical fiber 5, and the light receiving device 8 faces the other end of the transmission backward optical fiber 6. The light propagating in the transmission forward optical fiber 5 and the transmission return optical fiber 6 may be random light, and stress (vibration) is applied to the transmission forward optical fiber 5 and the transmission return optical fiber 6, Even if birefringence occurs The amount of light propagating inside them is not affected by birefringence and does not change at all, and the current flowing in the conductor 1 is stressed (vibrated by vibration) to the transmission forward optical fiber 5 and the transmission backward optical fiber 6. It is possible to detect with high accuracy without being affected by).

Further, by using a laminated thin film polarizer (Lamipol) as the polarizer 3, it is possible to easily connect optical fibers to each other by using a normal FC / FC adapter (adapter for coupling FC / FC connectors). Since it can be connected to the PC and an FC / FC adapter can be used, miniaturization can be achieved. FIG. 2 shows an enlarged schematic view of the sensor head portion of the current detection device of this embodiment. In FIG. 2, reference numeral 10 denotes a bobbin having a through hole 10a penetrating the conductor 1 and having a hollow structure. The optical fiber 2 for a sensor head wound so as to surround the through hole is built in the gel and the gel is formed inside. It is filled. An example of this gel is silicone gel (organosilicon compound: organosiloxane (R ₂ SiO) _n ; where R is an organic group).

Reference numeral 11 denotes an analyzer block having a built-in analyzer 4 which is a polarization beam splitter, and is rotatably attached to a notched portion of a corner of the bobbin 10. Reference numerals 12 and 13 denote connectors connected to both ends of the sensor head optical fiber 2. One connector 12 is fixed to a portion other than the notch at the corner of the bobbin 10, and the other connector 13 is notched at the corner of the bobbin 10. It is fixed to the part and is connected to the analyzer block 11. Reference numeral 14 is a connector to which the transmission / reception optical fiber 5 is connected, and is connected to the connector 12 via the polarizer 3. Reference numeral 15 is a connector to which the transmission return optical fiber 6 is connected, and is connected to the analyzer block 11. Reference numeral 16 is a connector to which an optical fiber 6'for transmission return path is connected, which is connected to the analyzer block 11. The analyzer block 11 is configured to be rotatable about an axis passing through the connectors 13 and 15, and is rotated to match the angle of the analyzer 4.

Two connectors 15, 16 are provided from the analyzer block 11 in order to extract both P-polarized light and S-polarized light. In the sensor head portion configured as described above, the light propagating through the transmission outward optical fiber 5 passes through the connector 14 and the polarizer 3, and then enters the sensor head optical fiber 2 through the connector 12. The light propagating through the sensor head optical fiber 2 enters the transmission return optical fiber 6 through the connector 13, the analyzer 4 and the connector 15, or the transmission return optical fiber passes through the connector 13, the analyzer 4 and the connector 16. It is incident on the bar 6 '. In this case, the P-polarized component is transmitted to the optical fiber 6 for transmission return path, and the S-polarized component is transmitted to the optical fiber 6'for transmission return path.

As described above, by making the bobbin 10 hollow and filling the inside thereof with gel, vibration of the optical fiber 2 for sensor head due to thermal expansion and vibration can also be suppressed, and the conductor 1 can be made with higher accuracy. The current flowing through can be measured. In the above embodiment, the sensor head optical fiber 2 is a single mode fiber, but it is also possible to use a multimode fiber or a polarization plane preserving fiber instead. Further, as the polarizer 3, a laminated thin film polarizer (lamipole) is used, but a polarizing beam splitter may be used instead. Further, although the polarization beam splitter is used as the analyzer 4, it is also possible to use a laminated thin film polarizer (laminipole). Further, although the single-mode fiber is used as the optical fiber 5 for the outgoing path, it is also possible to use a multi-mode fiber or a polarization-maintaining fiber instead of this. Further, although the multimode fiber is used as the optical fiber 6 for the transmission return path, it is also possible to use a single mode fiber.

[0019]

[Effect of device]

 According to the current detecting device of the present invention, the optical fiber for the sensor head is wound around the conductor, and the polarizer and the analyzer are arranged on one end surface and the other end surface of the optical fiber for the sensor head, respectively. One end face of the optical fiber for the forward transmission path is opposed to one end surface of the sensor via the polarizer, and the other end surface of the optical fiber for the sensor head is opposed to the other end surface of the optical fiber for the transmission head via the analyzer. Since the light emitting element is opposed to the other end surface of the optical fiber and the light receiving element is opposed to the other end surface of the transmission return optical fiber, the light propagating in the transmission forward optical fiber and the transmission return optical fiber is random. Light is sufficient, and even if stress (vibration) is applied to the transmission optical fiber and the transmission optical fiber to cause birefringence, the amount of light propagating inside them is Without being influence, without any change can be detected accurately without being affected by stress applied to the transmission forward optical fiber and transmission return optical fiber the current flowing through the conductor (vibration).

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a configuration of a current detection device according to an embodiment of the present invention.

FIG. 2 is an enlarged schematic view of a sensor head portion of a current detection device.

FIG. 3 is a schematic diagram showing a configuration of a conventional current detection device.

[Explanation of symbols]

 1 conductor 2 optical fiber for sensor head 3 polarizer 4 analyzer 5 optical fiber for transmission forward path 6 optical fiber for transmission return path 7 light emitting element 8 light receiving element

Claims (1)

[Scope of utility model registration request] 1. An optical fiber for a sensor head wound around a conductor, a polarizer and an analyzer respectively disposed on one end surface and the other end surface of the optical fiber for the sensor head, and for the sensor head through the polarizer. An optical fiber for transmission forward path, one end surface of which is opposed to one end surface of the optical fiber; a transmission return optical fiber whose one end surface is opposed to the other end surface of the sensor head optical fiber through the analyzer; A current detection device comprising a light emitting element facing the other end surface of the outward optical fiber and a light receiving element facing the other end surface of the transmission backward optical fiber.