KR100319829B1 - Distribution automatic switch measuring with optical sensor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photometric distribution automation switch, which is integrally formed with an annular iron core for concentrating the magnetic flux density of a conductor, and flows in a distribution line according to the strength of a magnetic field formed in the conductor. Photocurrent measuring means for measuring section current; Optical voltage measuring means using a Pockels effect to measure the voltage on the distribution line according to the strength of the electric field formed in the conductor; And optical connection means for optically transmitting a signal measured from the means to an external connection device via a multi-channel, and having optical characteristics of broadband, high accuracy, explosion proof and induction. The photovoltage sensor and the photocurrent sensor that measure the voltage and current by means of measuring the distribution voltage and the section current of the distribution automation switch installed on the overhead distribution line can be measured irrespective of electromagnetic induction and switching surge. It is a very useful invention that enables high-precision measurement, maintains insulation reliability, and enables remote transmission of measurement information as optical signals.

Description

Photometric Distribution Automation Switch {Distribution automatic switch measuring with optical sensor}

The present invention relates to a photometric distribution automation switch, and more particularly, by using a photocurrent sensor and a photovoltage sensor in a distribution automation switch installed on a overhead distribution line, the distribution voltage and the section current at the installation point are fixed with high accuracy. A photometric power distribution automation switch for enabling measurement.

In general, the distribution system operates a distribution automation system to shorten the blackout period and the blackout time. In order to improve the reliability of the power supply, it is necessary to accurately measure the constant voltage, current, and fault current. Done.

First, FIG. 1 illustrates a configuration of a distribution automation switchgear for measuring a conventional distribution voltage and a sectional current, and a conventional distribution automation switch constitutes a combination of CPD (Capacitive Potential Divider) or a measuring transformer. And a current measuring means which is a current measuring current transformer using an iron core core.

Meanwhile, the upper PDs 12a and 12b are high impedance and high breakdown voltage devices used in a commercial power supply of 60 Hz, and most of the distribution voltages have voltage drops in the upper CDs 12a and 12b. The CPIs 13a and 13b are configured to select a low impedance element so as to take a low voltage that is easy to measure, for example, a low voltage of about 40 V or less. As shown in FIG. 13a and 13b may be replaced by measurement transformers 14a and 14b.

In addition, the current measuring current transformer 16 is a bushing current transformer using a silicon steel sheet, and outputs 600 mA at a rated current, and the distribution voltage and the current signal measured as described above are connected to the electrical connector 15. It is transmitted to the distribution automation switch control box (not shown) connected to the outside through the connection, it is possible to measure the distribution voltage and the section current value at the point where the distribution automation switch is installed.

However, in the conventional distribution automation switchgear configured as described above, the instrument current transformers 17a and 17b using the electromagnetic induction of the iron core core are used to measure the section current of the distribution system. Therefore, high insulation reliability under high voltage is achieved. It is difficult to maintain, and when a failure occurs, there is a problem in that the iron core is saturated by a large current and the linearity is deteriorated.

In addition, CPDs 12a, 12b, 13a, and 13b, which are used as distribution voltage measuring means, have high insulation reliability in distribution automation switchgear where accuracy of voltage measurement is lowered due to changes in characteristics with respect to temperature and the installation space is small. It is difficult to maintain and, of course, the method of directly connecting from the conductors in the distribution automation switch, which has a ripple effect on the distribution system when an accident occurs due to deterioration of characteristics due to the connection, greatly reduces the damage and reliability of the equipment. There was a problem caused.

Accordingly, the present invention has been created to solve the above problems, the optical voltage sensor and photocurrent for measuring the voltage and current using light having the characteristics of broadband, high accuracy, explosion-proof and non-inductive Provided is a photometric distribution automation switchgear which makes it possible to accurately measure distribution voltage and section current in a distribution automation switchgear provided on a overhead distribution line by a sensor. The purpose is.

Figure 1 shows a configuration for a conventional distribution automation switchgear,

Figure 2 shows the configuration for the photometric distribution automation switch according to the invention,

3 is a view illustrating a coupling state between a photocurrent sensor and a support adapter in the photometric power distribution automation switch according to the present invention;

4 is a view illustrating a coupling state between an optical voltage sensor and a support adapter in an optical measurement distribution switch according to the present invention;

FIG. 5 illustrates a configuration of a multi-channel optical connector in the photometric power distribution automation switch according to the present invention.

6 is a view illustrating a connection and installation state of the photometric power distribution automation switch and the distribution automation control box according to the present invention.

※ Explanation of code for main part of drawing

10: voltage sensor 16: current sensor

22: photo voltage sensor 23: photo current sensor

24: multi-channel optical connector 31,34,41: polarizer

32, 42 polarizer 33: paradata element

35: pure iron core 43: Pockels element

46: auxiliary electrode 52: ring

62: distribution line 63: distribution automation switchgear control box

64: optical cable 65: communication line

Photometric distribution automation switchgear according to the present invention for achieving the above object, in the distribution automation switchgear, is integrally formed with an annular iron core for the magnetic flux density focusing of the conductor, the strength of the magnetic field formed in the conductor Accordingly, photocurrent measuring means for measuring the section current flowing in the distribution line; Optical voltage measuring means using a Pockels effect to measure the voltage on the distribution line according to the strength of the electric field formed in the conductor; And optical connection means for optically transmitting a signal measured from the means to an external connection device through a multi-channel,

Hereinafter, preferred embodiments of the photometric power distribution automation switch according to the present invention will be described in detail with reference to the accompanying drawings.

First, FIG. 2 illustrates the configuration of the photometric power distribution automation switch according to the present invention, and the magnetic field formed in the three-phase conductors 21a, 21b, and 21c inside the photometric power distribution automation switch 20 is shown. The photocurrent sensors 23a, 23b and 23c for measuring the section current flowing through the power distribution line according to the intensity, and the photovoltage sensors 22a, 22b and 22c for measuring the distribution voltage according to the intensity of the electric field. In addition, a multi-channel optical connector 24 for connecting and connecting the wire automation switch control box (not shown) and the transmission of the light measurement signal to the outside is provided.

On the other hand, Figure 3 shows a coupling state between the photocurrent sensor in the photometric distribution automation switch according to the present invention, and the support adapter for fixed support, as shown in Figure 3, the U-shaped magnetic core 35 ) Is a pure iron core heat-treated to measure the induction phenomenon and low current of another phase, and is integrated with the photocurrent sensor 30, wherein the integrated photocurrent sensor 30 and the U-shaped magnetic core 35 are It is easy to install around the bushing inside the distribution automation switch 20 and is fixed with an adhesive to the support adapter 36 for maintaining high insulation.

Referring to the current measurement process of the photocurrent sensor 30, first, as shown in FIG. 3, the optical signal 37 emitted from a light emitting element such as an LED, the polarizer (included in the photocurrent sensor 30 ( 31) and a half wave plate 32, that is, a polarizer 31 which linearly polarizes the light emitted from the LED and reflects and rotates the traveling direction of the light by 90 degrees, and rotates the linearly polarized light by 45 degrees. Pass through the half wave plate 32 for applying the optical bias, and then enters the magneto-optical element 33, which is a paradata element that is a YIG crystal containing a bi element, at which time the current flowing through the conductor When the intensity (H) 39 of the magnetic field formed by the same as the traveling direction of the optical signal, the polarization plane of the optical signal passing through the magneto-optical element 33 is rotated by a predetermined angle (Θ), the polarization plane The rotation angle of Θ is detected as light intensity by the analyzer 34, and the optical fiber It is transmitted to the signal processing device provided in the distribution automation switchgear control unit connected to the multi-channel optical connector 24 through, and measured as the section current value at the point where the photometric distribution automation switch is installed.

As a result, since the photocurrent measurement signal 38 is proportional to the intensity of the magnetic field, by measuring optically the magnetic field formed around the conductor, it is possible to measure the amount of current flowing through the distribution line.

4 is a view illustrating a coupling state between an optical voltage sensor in a photometric power distribution automation switch according to the present invention and a support adapter for fixing and supporting the same. As shown in FIG. 4, non-contact having high insulation reliability. In order to supply an equal magnetic field to the Pockels element 43 by the spatial partial pressure method, auxiliary electrodes 46a and 46b are provided on both end faces of the case of the optical voltage sensor 40, and both sides of the Pockels element in the light traveling direction are provided. It is connected to the indium tin oxide (ITO) electrode coated on the.

The adapter 47 for supporting the optical voltage sensor is composed of one assembly such that the optical voltage sensor 40 of each phase is positioned at the center of the conductor so as to be installed on the photometric distribution automation switch 20. When the voltage measurement process of the optical voltage sensor 40 will be described.

First, as shown in FIG. 4, the optical signal 48 emitted from a light emitting element such as an LED is a polarizer 41 and a quarter wave plate 42 included in the optical voltage sensor 40. The polarizer 41 for linearly polarizing the light emitted from the LED and the quarter wave plate 42 for converting the linearly polarized light into circularly polarized light are passed through, and the optical signal converted into the circularly polarized light is Incident on the Pockels element 43 of BSO (Bi ₁₂ SiO ₂₀ ) and BGO (Bi ₁₂ GeO ₂₀ ), wherein the Pockels element 43 is caused by a voltage supplied through the auxiliary electrodes 46a and 46b. It has a birefringence phenomenon, the phase difference is generated by the birefringence phenomenon is an elliptical polarization.

The elliptical polarization signal is detected by the analyzer 44 at a light intensity and transmitted to the signal processing device provided in the distribution automation switch controller connected to the multi-channel optical connector 24 through the optical fiber as described above. Thus, it is measured by the distribution voltage value at the point where the photometric distribution automation switch is installed.

On the other hand, Figure 5 shows a multi-channel optical connector in the photometric distribution automation switch according to the present invention, the multi-channel optical connector 50 is connected to the voltage and current measurement signals for the three-phase voltage and current at the same time or Separately, it is possible to transmit to the wiring automation switch control box (not shown) installed on the outside, at this time is made of a structure 51 as shown in Figure 5 so that the transmission loss is minimized.

In addition, the photometric power distribution automation switch 20 is operated in a state in which SF ₆ gas is charged at about 1.2 atm to maintain insulation reliability even at a high impulse voltage, for example, about 70 kV. The multi-channel optical connector 50 In installation, in order to prevent gas leakage, by inserting the 'O' shaped ring inside the enclosure 53 of the photometric distribution automation switch, and fixing it using the fixing bolt 54, Do not leak.

Accordingly, it is possible to prevent the gas from leaking due to the impact caused by the opening and closing operation of the photometric power distribution automation switch.

6 is a view illustrating a state in which the photometric power distribution automation switch according to the present invention is installed on a process distribution line, and the light transmitted from the distribution automation switch control box 63 separately installed from the photometric power distribution automation switch 20. The signals 37 and 48 are transmitted to the photocurrent sensor 30 and the photovoltage sensor 40 through the multi-core optical cable 64 and the multi-channel optical connector 61, and measured by the photocurrent sensor and the photovoltage sensor. The photocurrent measurement signal and the photovoltage measurement signal, that is, the photocurrent measurement signal measured according to the intensity of the magnetic field formed in the three-phase conductors 21a, 21b, and 21c as described above with reference to FIGS. 3 and 4, and the intensity of the electric field. The optical voltage measurement signal measured according to the present invention is transmitted to the distribution automation switchgear control box 63 through the multi-channel optical connector 61 and the multi-core optical cable 64, converted into an electrical signal, and then signal processed. Photometric distribution automation instrument (2 It is measured by the value of distribution voltage and section current at the installation point where 0) is installed.

Accordingly, the accident current, the constant voltage and the current occurring in the distribution lines 62a and 62b are transmitted to a central control room (not shown) remotely located through a communication line 65 installed to operate the distribution automation system. The optimal distribution system operation and accident handling tasks can be efficiently handled.

As mentioned above, preferred embodiments of the present invention are disclosed for the purpose of illustration, and those skilled in the art can improve and change various other embodiments within the spirit and technical scope of the present invention disclosed in the appended claims below. , Replacement or addition would be possible.

The photometric power distribution automation switch according to the present invention made as described above includes an optical voltage sensor and a photocurrent sensor for measuring voltage and current using light having characteristics of broadband, high accuracy, explosion proof and induction. Thus, by measuring the distribution voltage and the sectional current in the distribution automation switchgear installed on the overhead distribution line, it is possible to measure the high accuracy irrespective of electromagnetic induction and switching surge, and to maintain insulation reliability. It is also a very useful invention that enables remote transmission of measurement information as optical signals.

Claims (6)

In the distribution automation switchgear, Photocurrent measuring means integrally formed with an annular iron core for concentrating magnetic flux density, for measuring section current flowing in a distribution line in accordance with the strength of a magnetic field formed in the conductor; Optical voltage measuring means using a Pockels effect to measure the voltage on the distribution line according to the strength of the electric field formed in the conductor; And And optical connection means for optically transmitting signals measured from said means to an external connection device through a multi-channel. The method of claim 1, The external connection device controls a distribution automation switch that transmits and applies an optical signal through the optical connecting means and calculates the section current value and the distribution voltage value from the measurement signals transmitted through the optical connecting means. Photometric distribution automation switch, characterized in that. The method of claim 1, The photocurrent current measuring means is configured integrally with a heat-treated U-shaped magnetic pure iron core in order to suppress the magnetic flux density focusing and induction of the wound between the conductors. Photometric distribution automation switch characterized in that the support is fixed to the enclosure of the switch. The method of claim 1, The photovoltaic measuring means includes a Pockels element utilizing the Pockels effect and is fixedly supported by the high insulation support adapter in the enclosure of the photometric power distribution automation switch. Automation switchgear. The method of claim 4, wherein And a plurality of auxiliary electrodes connected to the Pockels element in order to apply an electric field uniformly in a non-contact manner. The method of claim 1, And the optical connecting means is a multi-channel optical connector having a sealing structure for preventing leakage of a filling gas due to an impact generated by an opening and closing operation of the photometric distribution automation switch.