KR20140063072A - Out-door type metering out-fit(mof) having electronics transformer with auxiliary power supply device and pd detection sensor - Google Patents

Abstract

The present invention is to provide an electric field relaxation type of an outdoor electronic MOF having a partial discharge (PD) detection sensor and an auxiliary power supply device which is comprised of metering outfit (MOF) body (10), a high-pressure side conductor (12) for input/output (K, L) connection, a secondary output grounding terminal box (14), an electronic current transformer (ECT) (16), an electronic voltage transformer (EVT) (17), an auxiliary power supply device (20), and a partial discharge detection sensor (21) so that it is possible to reduce field emission generated from the inside by 70% as compared with conventional field emission thereby significantly reducing leakage current.

Description

(MOF) HAVING ELECTRONICS TRANSFORMER WITH AUXILIARY POWER SUPPLY DEVICE AND PD DETECTION SENSOR WITH A PARTIAL DISCHARGE (PD) DETECTION SENSOR & AUXILIARY POWER SUPPLY DEVICE Field of the Invention < RTI ID =

The present invention relates to an electric field relaxation type electronic outdoor MOF incorporating a partial discharge (PD) detection sensor and auxiliary power supply.

The electronic transformer (ECT / EVT) implies that the transformer itself has an electronic circuit and that it is suitable for microprocessor applications.

In other words, Rogowski coils without electronic circuits do not have electronic circuits, but they are suitable for microprocessor applications, so they can be classified as electronic transformers. In short, they can be called both conventional transformers and relative transformers. Electronic voltage transformer (EVT), and electronic current transformer (ECT).

The electronic transformer is a relative concept to the conventional induction transformer. The major difference between the induction type transformer and the electron transformer is the burden and the output signal size. The output of the induction current transformer is usually 5 [A] or 1 [ A], the burden is about 15 [VA], and the output voltage of the induction type voltage transformer is generally 110 [V] and 220 [V], and the burden is about 100 [VA].

On the contrary, the output of the electronic current transformer is different from that of the inductive type. Typically, the output voltage of the current transformer is 22.5mV, 150mV, 200mV, 225mV and 4V, and the load is represented by a unit of high resistance [M? The voltage of the electronic voltage transformer is very low, but it is typically 1.32V, 1.625V, 2V, 3.25V, 4V and 6V. In the induction type, the burden is the capacity that the transformer can output. The same concept, a resistor, means the lowest impedance of the electronic device to be connected.

The output of the electronic transformer is largely analog and digital. Analog does not use a special conversion device. In this case, the output may be used as it is and some electronic circuit may be included. You can send and receive data to a remote device.

In order to use such a digital method, a communication circuit is formed on the secondary side of the electronic transformer. In particular, when three phases are constituted and power is measured, three phases are firstly formed for each of the voltage and current transformers, And a single signal source is used by using a merging unit of the IEEE or an intermediate device of the IEEE.

Electronic wattmeter used with electronic (ECT / EVT) MOF can be weighed if other power is supplied. In the electronic MOF, the output of EVT is very low and it can not be used as the power supply of the watt hour meter.

In addition, when external power is supplied, weighing of the watt hour meter can not be performed due to a short circuit.

In addition, external power must be supplied by a separate transformer or battery, but in this case installation cost, installation space and additional facilities are required.

Therefore, in order to solve this problem, it is necessary to design the electronic MOF with a built-in auxiliary power supply so as to measure the accurate amount of power by supplying the power without the power supply, and to easily reduce the installation area and to maintain it.

In addition, the electronic MOF of the present invention is required to be designed based on an eco-friendly insulation method which is excellent in partial discharge reduction technology, heat resistance, water repellency and flame retardancy.

In order to solve such a problem, Patent Application Publication No. 10-0787964 filed and filed by the applicant of the present application proposes a high-voltage side conductor for connecting the input and output (K, L) protruding from one side of the upper surface, (K, L) is connected to one side of the ECT (Electronic Current Transformer), and an ECT (Electronic Current Transformer) is installed in the inside of the electronic MOF through the center between the connecting high voltage side conductors (K, L) connection to one side of the EVT (Electronic Voltage Transformer), and a high-voltage side conductor for connecting the input and output (K, L) to the EVT A capacitor for auxiliary power supply in which a main capacitor and a capacitor for partial voltage are connected in parallel, and a power supply transformer are formed between the ground and the ground, and the ECT (Electronic Current Transformer) (PD) detection sensor in which a partial discharge detection sensor is formed in parallel with the high-voltage side conductor for connection of input / output (K, L) and the secondary output ground terminal on the opposite side of the auxiliary power supply capacitor. Although an electronic outdoor MOF incorporating a device has been proposed,

This is because there is no electric field relaxation device in the high voltage side conductor, ECT (Electronic Current Transformer), EVT (Electronic Voltage Transformer) and secondary output ground terminal for connection of input and output (K, L) And deterioration is caused in the inside.

Korean Patent Registration No. 10-0787964 (issued on December 24, 2007)

In order to solve the above problems, the present invention is an improvement of Patent Registration No. 10-0787964 filed and filed by the applicant of the present invention, in which a partial discharge (PD) detection sensor and an auxiliary power supply device are installed inside an electronic outdoor MOF It is possible to apply the high voltage corona shield to the high voltage side conductor for the connection of the input and output (K, L), to alleviate the electric field, to apply the shielding case to ECT (Electronic Current Transformer) The electric field can be mitigated by shielding the main resistance and voltage resistance of EVT (Electronic Voltage Transformer) and the electric field can be mitigated by applying double shielded cable terminal to the secondary output ground terminal box. (PD) detection sensor that can reduce the leakage current remarkably, and the electric field relaxation type electronic outdoor MOF incorporating the auxiliary power supply device It is an object to the ball.

In order to achieve the above object, an electric field relaxation type electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention

(METEING-OUT-FIT) body 10 having a cylindrical upright structure with wings on both sides and supporting each device and protecting it from external pressure,

A high-voltage side conductor 12 for connecting the input and output (K, L), which is formed in an inward direction through one side of the upper surface of the MOF (Metering Out-Fit) body, Wow,

A secondary output ground terminal box 14 located at one side of the lower end of the metering out-fit (MOF) body for relaxing the electric field through the double shielded cable terminal,

(K, L) connection is provided in the inside of the electronic MOF through the center between the high-voltage side conductors 12 for connection of the input and output (K, L) An ECT (Electronic Current Transformer) 16 for detecting and measuring the amount of electric power,

Output (K, L) connection, which is located at one side of the ECT (Electronic Current Transformer) and is formed in the longitudinal direction between the high-voltage side conductor 12 for connecting the input and output (K, L) An EVT (Electronic Voltage Transformer) 17 for detecting a supply voltage supplied from the high-voltage side conductor for measuring and measuring the amount of electric power,

An auxiliary power supply 20 which is located at one side of the EVT (Electronic Voltage Transformer) 17 and is formed between the high voltage side conductor for connection of the input and output (K, L) and the ground to supply the auxiliary power,

The high voltage side conductor 12 and the secondary side output ground terminal 14 are located on the opposite side of the auxiliary power supply capacitor 18 on the basis of the ECT 16, And a partial discharge detection sensor 21 for detecting the amount of partial discharge (PD) while being connected in parallel to each other.

As described above, according to the present invention, the partial discharge (PD) detection sensor and the auxiliary power supply device can be built in the inside of the electronic outdoor MOF, so that the partial discharge detection and the auxiliary power supply can be supplied by one equipment, The field emission generated inside the MOF can be mitigated by 70% compared with the conventional one, which has a good effect of significantly reducing the leakage current.

1 is a front view showing an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention,
FIG. 2 is a front view showing a high-voltage three-phase outdoor electronic MOF incorporating an auxiliary power supply unit and a partial discharge detection sensor in an electronic transformer (ECT / EVT)
FIG. 3 is a plan view showing a high-voltage three-phase outdoor electronic MOF incorporating an auxiliary power supply device and a partial discharge detection sensor in an electronic transformer (ECT / EVT)
4 is a front sectional view showing an internal configuration of an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention,
5 is a side cross-sectional view showing an internal configuration of an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention.
FIG. 6 is a diagram illustrating a process of configuring an ECT among the components of an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to an embodiment of the present invention.
FIG. 7 is an integrator circuit diagram added to the ECT among the components of the electronic outdoor MOF incorporating the partial discharge (PD) detection sensor auxiliary power supply device according to the present invention,
8 is a diagram showing an embodiment of the partial pressure of EVT among the components of the electronic outdoor MOF incorporating the partial discharge (PD) detection sensor auxiliary power supply device according to the present invention,
9 is a view showing a half screen mesh screen metal screen shield attached to the upper and lower ends of the EVT among the components of the outdoor outdoor MOF incorporating the PD detection sensor and the auxiliary power supply according to the present invention Perspective,
10 is a perspective view illustrating a semicircular shield formed of a semiconductive functional synthetic resin attached to the upper and lower ends of an EVT among the components of an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention A perspective view of the city.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a front view showing components of an electronic outdoor MOF 1 incorporating a partial discharge (PD) detection sensor auxiliary power supply device according to the present invention. This is a front view of a MOF (metering out-fit) A secondary output ground terminal box 14, an ECT (Electronic Current Transformer) 16, an EVT (Electronic Voltage Transformer) 17, an A / A supply device 20, and a partial discharge detection sensor 21.

First, the MOF (Metering Out-Fit) body 10 according to the present invention will be described.

The MOF (Metering Out-Fit) body 10 has a cylindrical upright structure having wings on both sides thereof to support each device and to protect it from external pressure.

It is molded with outdoor epoxy resin that has improved insulation and mechanical properties and is designed to be small and lightweight, so as to minimize installation area and environmental friendliness.

Further, it has excellent heat resistance, water repellency and flame retardancy.

The MOF (Metering Out-Fit) body 10 has improved insulation characteristics and environmental friendliness,

100 parts by weight of a bisphenol-A type epoxy resin which is liquid at room temperature,

100 parts by weight of an acid anhydride-based curing agent of MeTHPA (Methyl Tetra Hydro Phthalic Anhydride)

50 to 60 parts by weight of an amine-terminated poly (butadiene-co-acrylonitrile) (ATBN)

50 to 60 parts by weight of silica (SiO ₂ ) treated with silica (SiO ₂ ) at 500 ° C. for 5 hours to remove impurities and surface-treated with an organosilane coupling agent,

5 to 20 parts by weight of the plasticizer is mixed at 80 ° C. for 20 to 30 minutes, then primary cured at 100 ° C. for 3 to 4 hours, and then secondary cured at 140 ° C. for 8 to 10 hours.

The above-mentioned amine-terminated poly (butadiene-co-acrylonitrile) (ATBN) is a liquid rubber having an amine group at the terminal and a backbone chain of which is a copolymer of butadiene and acrylonitrile. The amine rubber has properties of increasing physical properties at low temperature, .

When the amount of the amine-terminated butadiene-co-acrylonitrile (AMI) is less than 50 parts by weight, it is difficult to expect improvement in physical properties at low temperatures, insulation and toughness, The use amount of the amine-terminated polyol (butadiene-co-acrylonitrile) is 50 to 60 wt% based on the total weight of the entire MOF (Body Outfit) body 10, since the increase in the effect is insignificant, It is preferable to limit it to the negative range.

The reason why the silica (SiO ₂ ) is subjected to the silane treatment is to chemically bond the organic material epoxy resin and the inorganic material silica with the organic silane coupling agent to strengthen the mechanical properties.

At this time, (γ-mercaptopropyl) trimethoxysilane is used as a specific example of the organosilane coupling agent.

When the amount of the silica to be used is less than 50 parts by weight, it is difficult to expect improvement in mechanical and thermal properties. When the amount of the silica to be used exceeds 60 parts by weight, the mechanical and thermal properties of the silica may be improved. The amount of the silane-treated silica is preferably limited within a range of 50 to 60 parts by weight with respect to the total weight of the whole body 10 of the MOF (Metering Out-Fit), since the improvement of the thermal properties is insignificant.

The plasticizer is used to improve the impact strength and tensile strength of a cured product. Examples of the plasticizer include dioctyl adipate, dioctyl phthalate, diethyl phthalate or dioctyl sebacate dioctyl sebacate) is used.

When the amount of the plasticizer is less than 5 parts by weight, the effect of improving the impact strength and the tensile strength is insignificant. When the plasticizer exceeds 20 parts by weight, the plasticizer does not significantly improve the effect, (METERING OUT-FIT) It is preferable to limit the range to 5 to 20 parts by weight with respect to the total weight of the body 10.

More specifically,

First, the silica is treated at 500 ° C for 5 hours at high temperature to remove various impurities, treated with an organosilane coupling agent, and dried at 80 ° C for 4 hours to prepare silane-treated silica.

Next, 100 parts by weight of a liquid bisphenol-A type epoxy resin, 100 parts by weight of an acid anhydride-based curing agent of MeTHPA (Methyl Tetra Hydro Phthalic Anhydride), 100 parts by weight of an amine-terminated butadiene acrylic 50 parts by weight of the silane-treated silica and 5 parts by weight of the plasticizer were placed in a stirrer, and the mixture was stirred at 80 DEG C at a rate of 10 < ^-1 > Torr The components are stirred uniformly in a vacuum of 30 [min].

The liquid epoxy mixture thus prepared was poured into a preformed Teflon molder, followed by primary curing at 100 ° C for 4 hours and secondary curing at 140 ° C for 10 hours.

The MOF (Metering Out-Fit) body 10 according to the present invention is characterized in that a high-voltage side conductor 12 for connecting the input and output (K, L) protrudes from one side of the top face of the hat shape, And an ECT (Electronic Current Transformer) 16, which is formed by connecting a detection sensor 21 and is annularly installed in the inside of the electronic MOF through the center between the high voltage side conductors 12 for connection to the input and output (K, L) Connected to the high voltage side conductor 12 for connecting the input and output (K, L) and the secondary output ground terminal 14-1 to one side of the ECT (Electronic Current Transformer) 16, Voltage side conductor 12 for connecting the input and output (K, L) to the EVT (Electronic Voltage Transformer) 17, and a main capacitor 18 1), a capacitor 18 for supplying an auxiliary power supply connected in parallel to the capacitor 18-2 for partial pressure, and a power supply transformer 19, Voltage side conductor 12 for connection of input and output (K, L) is connected to the opposite side of the auxiliary power supply capacitor 18 on the basis of the ECT (Electronic Current Transformer) A secondary output ground terminal box 14 which is located at the lower one side surface and which alleviates the electric field through the double shielded cable terminal is formed in the partial discharge detection sensor 21 provided in parallel connection between the ground terminals 14-2, A high voltage side conductor 12 for connection of input and output (K, L), an ECT (Electronic Current Transformer) 16, an EVT (Electronic Voltage Transformer) 17, an auxiliary power supply 20, An outdoor epoxy resin and an environmentally friendly insulating material are molded in the discharge detection sensor 21.

Next, the high voltage side conductor 12 for connection of the input and output (K, L) according to the present invention will be described.

The high-voltage side conductor 12 for connecting the input and output (K, L) is formed in an inward direction through one side of the upper surface of the MOF (Metering Out-Fit) body, It is a role to mitigate.

It consists of a high-voltage side conductor for input (K) connection and a high-voltage side conductor for output (L) connection.

Then, a high-pressure corona shield is formed which relaxes the electric field around the periphery.

Here, the high-voltage corona shield is a conductive layer provided around the high-voltage side conductor for connection of the input and output (K, L) in order to prevent corona generation due to concentration of an electric field (electric field) .

Next, the secondary output ground terminal box 14 according to the present invention will be described.

The secondary output ground terminal box 14 is located on one side of the lower end of the METF (Metering Out-Fit) body, and serves to alleviate the electric field through the double shielded cable terminal.

This is applied to a double shielded cable terminal at a conventional insert terminal to relax the electric field.

Here, the double shielded cable terminal is formed in a hexagonal shape or a tightening manner.

Next, an ECT (Electronic Current Transformer) 16 according to the present invention will be described.

The electronic current transformer (ECT) 16 is annularly installed inside the electromagnetic MOF through the center between the high-voltage side conductors 12 for connecting the input and output (K, L) ) It detects the supply current supplied from the connection high-voltage side conductor and measures and quantifies the amount of power.

This is a Rogowski type current transformer installed in the electronic MOF to detect the supply current of the customer so as to precisely measure and meter the amount of electric power. This is a non-magnetic core (μ = μ0) (RC) is wound and formed, and when the integrator is added thereto, it has a function as an ECT (Electronic Current Transformer).

That is, as shown in FIG. 6, the ECT (Electronic Current Transformer) 16 according to the present invention has an annular band shape such that the high-voltage side conductor 12 for connecting the input and output (K, L) The non-magnetic core 23 is formed by winding the non-magnetic core 23 in the 90 占 direction along the outer periphery of the insulating layer 22 and is formed in the 90 占 direction along the outer periphery of the non- The Rogowski coil (RC) is formed by winding a coil insulated with enamel, then placing the coil in an annular band-shaped shield case, molding it inside the epoxy and shielding it. By applying the shielded case to the ECT, it is possible to obtain a CT field relaxation effect which is 70% higher than that of the conventional epoxy mold.

The ECT (Electronic Current Transformer) 16 is constructed by adding an integrator circuit as shown in Fig.

As shown in FIGS. 4 and 5, the ECT (Electronic Current Transformer) 16 according to the present invention constructed as described above includes a high-voltage side conductor 12 for connecting the input and output (K, L) And is connected to the secondary output ground terminal box 14 through an electrical wiring to the lower end side of the electromagnetic MOF.

Next, an EVT (Electronic Voltage Transformer) 17 according to the present invention will be described.

The electronic voltage transformer 17 is disposed at one side of the ECT and is formed in the longitudinal direction between the high voltage side conductor 12 for connection of the input and output (K, L) and the secondary output ground terminal. And detects the supply voltage supplied from the high-voltage side conductor for connecting the input and output (K, L) to measure and measure the amount of power.

The EVT (Electronic Voltage Transformer) 17 is an electronic VT (voltage transformer) of an electric resistance partial pressure type and is installed in an electronic MOF to detect a supply voltage of a customer so as to precisely measure and measure the amount of electric power. As shown in the figure, it is configured to have a function as an EVT by using a resistor-dividing method of the main resistor 17-2 and the voltage dividing resistor 17-3 connected in series. The main resistor and the voltage divider resistor have a function of electric field relaxation by using a shielding shield.

Here, the shielding shield refers to coating the exterior with a coating of a conductive material in order to block the influence from the electric field induced in the electric field.

The resistive voltage dividing method of the main resistor 17-2 and the voltage dividing resistor 17-3 can be expressed by Equation (1).

[Equation 1 ]

As shown in FIG. 5, an electronic voltage transformer (EVT) 17 according to the present invention constructed as described above includes an ECT (Electronic Current Transformer) 16 having a high voltage side conductor (12) and the secondary output ground terminal box (14-1).

Here, the secondary output ground terminal box 14 is composed of an output ground terminal 14-1 and an output terminal 14-2.

The electronic voltage transformer (EVT) 17 thus installed is formed with a semicircular mesh screen metal shield or semicircular shield 17-1 made of semiconductive functional synthetic resin at the upper and lower ends thereof A main resistor 17-2 is formed between the upper end portion and the lower end portion shield and a voltage dividing resistor 17-3 is formed on one side of the shield at the lower end portion in series with the main resistor 17-2.

Here, the shield (17-1) has a problem that the electric field is concentrated on the main resistance and the insulation is broken by the electric stress. Therefore, the shield (17-1) is provided at both ends of the dummy port so as to prevent electric field smoothing Structure.

As shown in FIG. 9, the shield 17-1 according to the present invention having such a configuration may be formed of a semicircular shield made of a semiconductive functional synthetic resin, or, as shown in FIG. 10, And is formed of a mesh-type metal screen shield in which a plurality of holes are formed along the semicircular perimeter.

Next, the auxiliary power supply device 20 according to the present invention will be described.

The auxiliary power supply unit 20 is disposed at one side of an EVT (Electronic Voltage Transformer) 17 and is provided between the high voltage side conductor for connection of the input and output (K, L) and the ground to supply the auxiliary power .

The main capacitor 18-1 and the voltage dividing capacitor 18-2 are connected in parallel between the high voltage side conductor 12 for connecting the input and output (K, L) and the ground to one side of the EVT (Electronic Voltage Transformer) A capacitor 18 connected to the auxiliary power supply, and a power supply transformer 19.

Particularly, the auxiliary power supply capacitor 18 according to the present invention is constituted by a main capacitor 18-1 and a partial voltage capacitor 18-2 using a capacitor partial pressure method and is connected in parallel to the partial capacitor 18-2 4, a partial discharge (PD) detection sensor 21 is provided on the basis of the ECT 16, and the partial discharge (PD) Pressure side conductor 12 for connection of the input and output (K, L) and the power supply transformer 19 on the opposite side of the power supply transformer 19.

As described above, the auxiliary power supply capacitor 18 according to the present invention is constituted by a capacitor partial pressure method composed of the main capacitor 18-1 and the partial pressure capacitor 18-2, Voltage side conductor 12 for connection of input and output (K, L), one side of the upper end of the voltage dividing capacitor 18-2 is connected to an input terminal of a power supply transformer 19, And the ground terminal of the power supply transformer 19 is connected to the lower side.

The power supply transformer (19) is molded with an outdoor epoxy resin to enhance the insulation performance.

With this configuration, the auxiliary power supply unit 20 and the partial discharge (PD) detection sensor 21 are built in the electronic transformer (ECT / EVT) 16, 17 and molded with an epoxy resin thereon, It is possible to provide an outdoor high voltage electronic (ECT / EVT) MOF having a single-phase structure and a three-phase structure as shown in Fig. Reference numeral 11 in Fig. 2 is a support frame.

Next, the partial discharge detection sensor 21 according to the present invention will be described.

The partial discharge detection sensor 21 is located on the opposite side of the auxiliary power supply capacitor 18 based on the ECT 16 and is connected to the high voltage side conductor 12 for input / output (K, L) And the secondary output ground terminal 14-2 in parallel to detect a partial discharge (PD) amount.

The partial discharge detection sensor 21 is deteriorated by voids remaining in the epoxy resin mold of the outdoor high voltage electronic MOF and partial discharge PD generated at the interface of the charger conductor, (PD) detection sensor is built in to solve this problem. Therefore, it can detect the partial discharge (PD) amount to predict the failure in advance, and to secure reliability and stability by performing preventive diagnosis monitoring .

As shown in FIG. 4, the partial discharge detection sensor 21 is provided on the opposite side of the auxiliary power supply capacitor 18 with respect to the ECT (Electronic Current Transformer) 16 on the high voltage side Is connected in parallel between the conductor (12) and the secondary output terminal (14-2), and is molded with an epoxy resin.

Hereinafter, an electronic outdoor MOF incorporating a partial discharge (PD) detection sensor / auxiliary power supply device according to the present invention will be described.

<Design and manufacture of ECT>

The electronic current transformer (ECT) 16 has a function as an ECT when a non-magnetic core (μ = μ0) is wound with a Rogowski coil (RC) and an integrator is added thereto. Of course, although the secondary characteristics of RC itself can be defined as ECT, it is generally impossible to think of the two devices separately because the use of the integrator is essential.

The output voltage of the Rogowski coil can be obtained by the following equations (2) and (3).

& Quot; (2 ) & quot ;

& Quot; (3 ) & quot ;

These Rogowski coils are characterized by high measurement accuracy (1 to 3%), wide current measurement range, frequency range (typically 0.4Hz to 1MHz, possible up to 200MHz) and short circuit currents, Since the output is in the form of voltage and is not electrically connected to the primary conductor, it provides an output signal that can drive various measurement devices, digital watt-hour meters and protective relays, and has the advantage of low production cost.

The design specifications of the ECT to be proposed in the present invention are that the maximum application rating is 25.8 kV 1500 A 50/60 Hz 150 kV BIL, the rated primary current is 5 A to 2000 A (continuous), the rated secondary voltage is 10 V to 4 V, The output characteristics are produced by selecting the voltage that meets the domestic conditions at the rated output voltage specified by the IEC standard.

<EVT design and production>

In the present invention, the EVT 17 is designed using a resistance partial pressure method, and the principle of its design is as shown in FIG.

Since the resistive voltage divider for using the resistive voltage division method should have resistance to the juxtaposition, be highly accurate, and have excellent characteristics for the partial discharge (PD) characteristic and the withstand voltage characteristic (commercial frequency withstand voltage and impulse withstand voltage) Smooth structure was designed and fabricated. High-voltage resistors were fabricated in thin film form rather than general resistors, and are configured to improve precision using non-inductive resistors.

The design specifications are 25.8kV 50 / 60Hz, 150kV BIL, the rated primary voltage is 22900V / v3, and the rated secondary voltage is 1.32V to 6V.

<Design and manufacture of auxiliary power supply unit>

In the present invention, the auxiliary power supply unit 20 is composed of a main capacitor 18-1 and a voltage-dividing capacitor 18-2 in a capacitor partial pressure manner. The auxiliary power supply unit 20 is connected to the power- The principle of supplying the auxiliary power required by the transformer 19 is as follows.

The capacitor voltage divider for using the capacitor partial pressure method should have a sufficient capacity to secure a desired final output capacity and should have a dielectric constant of 2,000 to 9,000 and a dielectric loss of 2.5 because of the excellent electrical characteristics (commercial frequency withstand voltage, impulse withstand voltage) % Or less) is formed at a high temperature and baked at a high temperature (1,300 to 1,500) to improve the electrical and mechanical properties.

In addition, transformers connected in parallel to the capacitors have electric characteristics (commercial frequency withstand voltage, impulse withstand voltage), low loss, high efficiency, partial discharge (PD) and stable temperature characteristics.

And the rated secondary voltage is set to AC 40 / v 3 to 110 V / v 3 and the divided voltage V 2 for the primary voltage V 1 and the divided voltage V 2 for the primary voltage V 1, (C2) is expressed by the following equation (4).

& Quot; (4 ) & quot ;

&Lt; Design and manufacture of partial discharge (PD) detection sensor >

In the present invention, the partial discharge (PD) detection sensor 21 is designed using the partial discharge generation waveform detectable frequency band characteristic, and the principle of the design is as follows.

In order to use the waveform detection method of the capacitor partial discharge (PD), the capacitor sensor is required to have a capacitance of 100 pF or more so as to satisfy the characteristics from the appropriate frequency band 10 MHz (3 dB cutoff standard) to 50 MHz to secure the output waveform of the desired frequency range (Q) is at least 1000 or more and has a partial discharge (PD) characteristic that can withstand the withstand voltage characteristics (commercial frequency withstand voltage, impulse withstand voltage) and can be generated by itself for partial discharge detection Ceramic dielectrics with dielectric constant (500) and dielectric loss (less than 2.5%) were formed at high pressure and then fired at high temperature (1,300 ~ 1,500) to have stable electrical and mechanical properties.

The design specifications are 25.8kV 50 / 60Hz, 150kV BIL, and the rated partial discharge (PD) detection frequency range is 10MHz ~ 100MHz.

1: Electronic outdoor MOF 10: MOF (METERING OUT-FIT) body
12: High voltage side conductor for connection of input, output (K, L) 14: Secondary output ground terminal box
16: ECT 17: EVT
20: auxiliary power supply unit 21: partial discharge detection sensor

Claims (6)

(METEING-OUT-FIT) body 10 having a cylindrical upright structure with wings on both sides and supporting each device and protecting it from external pressure,
A high-voltage side conductor 12 for connecting the input and output (K, L), which is formed in an inward direction through one side of the upper surface of the MOF (Metering Out-Fit) body, Wow,
A secondary output ground terminal box 14 located at one side of the lower end of the metering out-fit (MOF) body for relaxing the electric field through the double shielded cable terminal,
(K, L) connection is provided in the inside of the electronic MOF through the center between the high-voltage side conductors 12 for connection of the input and output (K, L) An ECT (Electronic Current Transformer) 16 for detecting and measuring the amount of electric power,
Output (K, L) connection, which is located at one side of the ECT (Electronic Current Transformer) and is formed in the longitudinal direction between the high-voltage side conductor 12 for connecting the input and output (K, L) An EVT (Electronic Voltage Transformer) 17 for detecting a supply voltage supplied from the high-voltage side conductor for measuring and measuring the amount of electric power,
An auxiliary power supply 20 which is located at one side of the EVT (Electronic Voltage Transformer) 17 and is formed between the high voltage side conductor for connection of the input and output (K, L) and the ground to supply the auxiliary power,
The high voltage side conductor 12 and the secondary side output ground terminal 14 are located on the opposite side of the auxiliary power supply capacitor 18 on the basis of the ECT 16, 2) and a partial discharge detection sensor (21) for detecting the amount of partial discharge (PD) while being connected in parallel between the partial discharge (PD) detection sensor and the auxiliary power supply device. The electric field relaxation type electronic outdoor MOF .
[3] The apparatus of claim 1, wherein the MOF (Metering Out-Fit)
A high voltage side conductor 12 for connecting the input and output (K, L) protrudes to one side of the top face of the hat shape, and EVT and the partial discharge detection sensor 21 are connected in the inward direction, (ECT) 16, which is annularly installed in the inside of the electronic MOF through the center between the high voltage side conductors 12 for connection to the high voltage side And an EVT (Electronic Voltage Transformer) 17 connected to the high-voltage side conductor 12 and the secondary output ground terminal 14-1 for connection of the input and output (K, L) (18-1) and a voltage-dividing capacitor (18-2) are connected in parallel between the ground and the high-voltage side conductor (12) for connecting the input and output (K, L) to one side of the electronic voltage transformer An auxiliary power supply unit 20 including a power supply capacitor 18 and a power supply transformer 19 is formed and the ECT voltage side conductor 12 and the secondary output ground terminal 14-2 for input / output (K, L) connection on the opposite side of the auxiliary power supply capacitor 18 based on the ransformer 16, A secondary output ground terminal box 14 is formed which is located at one side of the lower end to mitigate the electric field through the double shielded cable terminal and is connected to the input / output (K, L) connection (ECT) 16, an EVT (Electronic Voltage Transformer) 17, an auxiliary power supply 20, and a partial discharge detection sensor 21 are arranged in a liquid state at room temperature, for example, a bisphenol- 100 parts by weight of an A-type (bisphenol-A type) epoxy resin,
100 parts by weight of an acid anhydride-based curing agent of MeTHPA (Methyl Tetra Hydro Phthalic Anhydride)
50 to 60 parts by weight of an amine-terminated poly (butadiene-co-acrylonitrile) (ATBN)
50 to 60 parts by weight of silica (SiO ₂ ) treated with silica (SiO ₂ ) at 500 ° C. for 5 hours to remove impurities and surface-treated with an organosilane coupling agent,
5 to 20 parts by weight of the plasticizer is mixed at 80 DEG C for 20 to 30 minutes and then primary cured at 100 DEG C for 3 to 4 hours and then cured at 140 DEG C for 8 to 10 hours to prepare an outdoor epoxy resin (PD) detection sensor and an auxiliary power supply device.
2. The device of claim 1, wherein the high voltage side conductor for connecting the input and output (K, L)
(PD) detecting sensor and an auxiliary power supply device, characterized in that a high-voltage corona shield for reducing an electric field along the periphery is formed.
An electronic current transformer (ECT) 16 according to claim 1,
An insulation layer 22 having an annular strip shape is formed so that the high voltage side conductor 12 for connection of the input and output (K, L) passes through the central axis. The non-magnetic core 23 is formed by winding a coil wound with enamel in the direction of 90 degrees along the outer periphery of the non-magnetic core 23 and then putting the coil into an annular band- (PD) detection sensor and an auxiliary power supply device, characterized in that the electromagnetic induction mold is formed by an inner mold of epoxy and a shield process.
The electronic device according to claim 1, wherein the EVT (Electronic Voltage Transformer)
A semicircular shield 17-1 made of a semi-circular mesh screen metal shield or semiconductive functional synthetic resin is formed on the upper and lower ends, and a main resistor (not shown) is formed between the upper and lower shields. A voltage dividing resistor 17-3 is formed in series with the main resistor 17-2 and a main resistor 17-2 and a voltage dividing resistor 17-2 which are connected in series are formed on one side of the shield at the lower end thereof, 3) are shielded and shielded, respectively. The electric field relaxation type electronic outdoor MOF incorporating a partial discharge (PD) detection sensor auxiliary power supply device.
[2] The apparatus of claim 1, wherein the MOF (Metering Out-Fit)
100 parts by weight of a bisphenol-A type epoxy resin,
100 parts by weight of a curing agent of MeTHPA (Methyl Tetra Hydro Phthalic Anhydride)
50 to 60 parts by weight of ATBN (Amine-terminated Poly (butadiene-co-acrylonitrile)),
50 to 60 parts by weight of silica (SiO ₂ ) treated with silica (SiO ₂ ) at 500 ° C. for 5 hours to remove impurities and surface-treated with an organosilane coupling agent,
And 5 to 20 parts by weight of a plasticizer are mixed at 80 캜 for 20 to 30 minutes and then primary cured at 100 캜 for 3 to 4 hours and then secondary cured at 140 캜 for 8 to 10 hours. Electric field relaxation type electronic outdoor MOF incorporating discharge (PD) detection sensor and auxiliary power supply.

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