KR200446550Y1 - Apparatus for testing characteristic of circuit breaker - Google Patents

Abstract

The present invention relates to a circuit breaker characteristic test apparatus. The present invention is a circuit breaker characteristic test device for measuring the difference between the gas insulated switchgear connected to the three-phase power line cable, the first and second signal terminals for electrical connection with the gas insulated switchgear, the high frequency to the gas insulated switchgear A high frequency voltage source providing a voltage, resistances to each phase for converting a current flowing in three phases of the gas insulated switchgear into the respective phase voltages for the three phases by a high frequency voltage, and a command signal for measuring the difference in difference; And a control unit providing the gas insulated switchgear through the signal terminal and providing each phase voltage measured from the resistors to the external device through the second signal terminal.

Description

Breaker characteristic test device {APPARATUS FOR TESTING CHARACTERISTIC OF CIRCUIT BREAKER}

The present invention relates to a circuit breaker characteristic test apparatus, and more particularly to a circuit breaker characteristic test apparatus for testing the difference between the three-phase circuit breaker.

In general, a breaker is a switch capable of breaking a load current or an abnormal state current of a power system. The breaker facilitates the load transfer operation through a close operation or a trip operation when the fault section is separated from the power system or the load is artificially transferred. 1 is a conceptual configuration diagram of a test circuit for measuring the characteristics of a conventional circuit breaker. Referring to FIG. 1, after the measurement circuit 20 and the DC voltage source 22 are connected in series to the first fixed terminal 14 and the second fixed terminal 12 of the circuit breaker 10 to form a closed circuit, the DC voltage May be applied to test the characteristics of the breaker (10).

When the circuit breaker performs the closing operation or the breaking operation for the three-phase voltages of A, B, and C, it is preferable that each phase of A, B, and C operates electrically at the same time. The closing or closing operation for does not work at the same time.

When the input or interruption operation is performed in the three-phase breaker as described above, the time difference between the first electrically operated phase and the last electrically operated phase is referred to as a time difference. Gari cars tend to increase gradually due to wear or mechanical deterioration of breaker contacts, etc. Increased Gari cars cause three-phase imbalances, causing flow in the power system, or adversely affecting the power system. Crazy to Therefore, Garicar is one of the most important check items, and it is necessary to observe whether the allowable range is defined and always operating within the specified allowable range.

2 is a conceptual configuration diagram of a test circuit for measuring the open circuit characteristics of a conventional three-phase breaker. The three-phase circuit breaker 10 shown in FIG. 2 is a switch that functions to electrically disconnect and connect three phases applied to a circuit, and includes first and second fixed terminals 12 for each phase of A, B, and C three phases. 14 and the movable terminal 16. The movable terminal 16 electrically or trips to the fixed terminal by a mechanical operation such as a spring, a gas pressure, a solenoid, or the like. The first and second fixed terminals 12 and 14 and the movable terminal 16 are structurally installed inside the main body of the three-phase circuit breaker 10 and electrically connected to the first and second fixed terminals 12 and 14. The pair of terminal blocks 17 and 18 connected to each other are insulated with an insulator (not shown) and are exposed to the outside. Each pair of terminal blocks 17 and 18 for three phases is connected to a core wire 32 of a cable 30 constituting an external circuit, respectively. Therefore, a closed circuit for testing the difference in characteristics of the three-phase circuit breaker 10 can be constructed by connecting the DC voltage source 22 and the measurement circuit 20 in series to each pair of terminal blocks 17 and 18 for three phases. have. The measuring circuit 20 includes a resistor for measuring the voltage applied by the current flowing in the closed circuit.

After applying a DC voltage on each of the terminal blocks 17 and 18 for the three phases, a closing operation or a closing operation for operating the movable terminal 16 of the circuit breaker 10 is performed, and the measuring device 20 The voltage difference of the phase can be measured and used to calculate the difference. In the closing operation, the first and second fixed terminals 12 and 14 of the three phases are electrically connected by the movable terminal 16, so that a current flows in the closed circuit for each phase and thus the voltage for each phase is measured. In the closing operation, the first and second fixed terminals 12 and 14 of the three phases are not electrically connected by the movable terminal 16, so that no current flows in the closed circuit for each phase, and thus the voltage for each phase. This is not measured. In the closing operation, the Garicha is the time difference between the first inserted phase and the last injected phase. In the blocking operation, the Garicha is the time difference between the first blocked phase and the last blocked phase.

Recently, due to the rapid increase in power demand due to the development of the industry, the electric power system is large-capacity, ultra-high pressure gas insulation switchgear to ensure high reliability has been used a lot. Gas Insulated Switchgear (GIS) is a bulk insulated switchgear, breaker, disconnector, transformer, lightning arrester, main circuit busbar, etc. Opening and closing equipment system filled and sealed with sulfur hexafluoride (SF6) gas with excellent ability as an insulating medium. The gas insulated switchgear is advantageous for reducing the installation area, securing high safety, and high reliability.However, unlike the conventional three-phase breaker, the terminal block for each phase is connected to the power cable and is covered by the cable head so that it is not exposed to the outside. Because of the true structure, the circuit breaker characteristic test apparatus described above cannot be used. When the power cable is disconnected from the gas insulated switchgear and the circuit breaker characteristic test device is electrically connected to the terminal block for each phase, the characteristic test of the gas insulated switchgear, such as a gas difference switch, can be performed. Disconnecting from cables is a problem because it can increase the probability of insulation accidents and failures.

That is, the conventional circuit breaker characteristic test apparatus can perform a circuit breaker characteristic test by applying DC voltage to both ends of the power line cable core wire. In the gas insulated switchgear, the both ends of the power line cable core wire are coupled to the gas insulated switchgear device so that they are not exposed to the outside. There is a problem that cannot be used to perform breaker characteristic tests.

Also, in the gas insulated switchgear (for example, 25.8 kV gas insulated switchgear) in which the first stator side terminal is connected to the power line in a plug-in type, and the second stator side terminal is connected to ground, the first plug in type Although the stator side terminal can be connected to the circuit breaker characteristic test apparatus, there is a problem that the second stator side terminal associated with the ground is still unable to be connected to the circuit breaker characteristic test apparatus.

Therefore, the present invention has been devised to solve the problem of the characteristic test apparatus of the conventional gas insulated switchgear, and the circuit breaker characteristics by applying high frequency power to the first stator side terminal of the cable plug-in type and the second stator side terminal connected to the ground. The technical problem is to provide a circuit breaker characteristic test apparatus capable of carrying out the test.

The circuit breaker characteristic test apparatus according to the present invention includes a circuit breaker characteristic test apparatus for measuring an opening difference of a gas insulated switchgear connected to a three-phase power line cable, the first and second signal terminals for electrical connection with the gas insulated switchgear; A high frequency voltage source for providing a high frequency voltage to the gas insulated switchgear; Through the first signal terminal, a command signal for measuring resistances and gaps for each phase which converts a current flowing in three phases of the gas insulated switchgear into the respective phase voltages for the three phases by the high frequency voltage is measured. And a controller for providing a gas insulated switchgear and providing each phase voltage measured from the resistors to an external device through the second signal terminal.

The circuit breaker characteristic test apparatus of the present invention has a technical configuration capable of performing a circuit breaker characteristic test by applying a high frequency power to the first stator side terminal of the cable plug-in type and the second stator side terminal connected to the ground, so that the gas insulation It provides the effect of testing the characteristics of the breaker, such as the breaker gasket, without disconnecting the power line cable connected to the switchgear.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. 3 is a diagram illustrating a circuit breaker characteristic test apparatus connected to a gas insulated switchgear for measuring Gari vehicle according to an embodiment of the present invention. Referring to FIG. 3, the circuit breaker characteristic test apparatus is electrically connected to the gas insulated switchgear and the notebook computer. More specifically, the gas insulated switchgear 100 includes a movable terminal, a fixed terminal pair, and a movable terminal controller corresponding to each of A, B, and C three phases. The first terminal and the second terminal are connected to each of the fixed terminal pairs. Here, the first terminal is a plug-in type terminal to which the power supply side power line cable (primary power line cable) is connected, and includes a phase A terminal 102, a phase B terminal 104, and a phase C terminal 106. The second terminal is a terminal to which a load side power line cable (secondary power line cable) is connected. The power line cable includes a core wire and a sheath. Each of the power line cable 400 sheaths connected to the second terminal of each phase is electrically connected to the ground bar 410 and grounded.

The circuit breaker characteristic test apparatus 200 includes a signal terminal and a gas insulated switchgear for electrical connection with the gas insulated switchgear 100 and the notebook computer 300 to measure the difference between the gas insulated switchgear 100. A high frequency voltage source that provides a high frequency voltage to 100), resistors that convert current flowing in each phase into voltage for each phase, and generates a command signal in response to an open circuit measurement command provided by the notebook computer 300 and And a controller for providing information related to the current and voltage of each phase measured by the notebook computer 300.

Signal terminals for electrical connection with the gas insulated switchgear 100 include a command terminal 210, a power supply terminal 220, a ground terminal 230, an A phase terminal 240, a B phase terminal 242, and a C phase terminal. (244). The command terminal 210 provides a command signal to the gas insulated switchgear. The command signal includes a signal for a trip operation or a close operation. The power supply terminal 220 is connected to a high frequency voltage source to provide high frequency power to the gas insulated switchgear 100. The ground terminal 230 is electrically connected to the ground bar 410. The A-phase terminal 240, the B-phase terminal 242, and the C-phase terminal 244 are the A-phase terminal 102, the B-phase terminal 104, and the C-phase terminal 106 of the gas insulated switchgear 100, respectively. And electrically internally to the resistor for each phase.

The signal terminal 250 for the electrical connection with the notebook computer serves as an interface for carry difference measurement command or carry difference transmission between the circuit breaker characteristic test apparatus 200 and the notebook computer 300. A high frequency voltage source (not shown) provides an alternating voltage having a frequency of 9 kHz to 22 kHz. The frequency may be selected optimally by experimental values, taking into account the capacitor induced between the core and the sheath of the power line cable.

The notebook computer 300 includes a Garicar measurement application running on a general purpose operating environment. The Gari vehicle application measuring program may automatically provide the Gari vehicle measurement command to the breaker characteristic test apparatus 200 by a user or programming. The notebook computer 300 also displays information or stores the measured current or voltage provided from the breaker characteristic test apparatus 200 in units of days and hours. In addition, the notebook computer 300 calculates and displays or stores the difference in real time using the measured current or voltage provided from the circuit breaker characteristic test apparatus 200.

4 is a circuit diagram illustrating a closed circuit for measuring an open difference of a gas insulated switchgear using a circuit breaker characteristic test apparatus according to an embodiment of the present invention. Referring to FIG. 4, a closed circuit for measuring an open difference of a gas insulated switchgear includes a high frequency voltage source 250, a measuring circuit 260, a sheath 412 of a secondary power line cable 410, a capacitor, and a primary power line cable. And a core wire 422 of 420. Here, the capacitor refers to a capacitor component formed between the sheath 412 of the secondary power line cable 410 and the core line 422 of the primary power line cable 420.

FIG. 5 is a cross-sectional view of a power line cable for explaining a principle of measuring an open difference of a gas insulated switchgear using the capacitor described in FIG. 4. Referring to FIG. 5, an insulating layer 520 is present between the core wire 510 and the sheath 530 of the power line cable 500, and thus, between the core wire 510 and the sheath 530 of the power line cable 500. The capacitor C is formed. In addition, the core wire 510 and the sheath 530 of the power line cable 500 are connected to the high frequency voltage source 250. Therefore, when a DC voltage is applied to the power line cable 500 core line 510 and the sheath 530 as in the conventional three-phase breaker characteristic test, the capacitor C formed between the power line cable 500 core line 510 and the sheath 530. Since it operates as an open circuit, current by DC voltage does not flow, so the open difference cannot be measured normally.

However, according to an embodiment of the present invention when the high-frequency voltage is applied to the power line cable 500 core line 510 and the sheath 530 is formed between the core line 510 and the sheath 530 of the power line cable 500 The impedance of the capacitor C is reduced to allow a constant current to flow. Therefore, the difference in opening and closing of the gas insulated switchgear 100 can be calculated using the current flowing in each phase. Since the method for calculating the difference difference using the current flowing in each phase can be easily implemented by those skilled in the art, a detailed description thereof will be omitted.

1 is a conceptual configuration diagram of a test circuit for measuring the characteristics of a conventional circuit breaker.

2 is a conceptual configuration diagram of a test circuit for measuring the open circuit characteristics of a conventional three-phase breaker.

3 is a diagram illustrating a circuit breaker characteristic test apparatus connected to a gas insulated switchgear for measuring Gari vehicle according to an embodiment of the present invention.

4 is a circuit diagram illustrating a closed circuit for measuring an open difference of a gas insulated switchgear using a circuit breaker characteristic test apparatus according to an embodiment of the present invention.

FIG. 5 is a cross-sectional view of a power line cable for explaining a principle of measuring an open difference of a gas insulated switchgear using the capacitor described in FIG. 4.

Claims (15)

A circuit breaker characteristic test apparatus for measuring the open difference of a gas insulated switchgear connected to a three-phase power line cable, First and second signal terminals for electrical connection with the gas insulated switchgear; A high frequency voltage source for providing a high frequency voltage to the gas insulated switchgear; Resistors for each phase for converting a current flowing in three phases of the gas insulated switchgear into the respective phase voltages for the three phases by the high frequency voltage, and A circuit breaker including a control unit for providing a command signal for measuring an opening difference to the gas insulated switchgear through the first signal terminal and providing each phase voltage measured from the resistors to an external device through the second signal terminal. Characteristic testing device. 2. The apparatus of claim 1, wherein the power line cable comprises a cable core and a cable sheath, wherein a capacitor is induced between the cable core and the cable sheath by an insulating layer interposed between the cable core and the cable sheath. The gas insulated switchgear of claim 2, further comprising: a plug-in type first terminal to which a power supply side power line cable is connected; And a second terminal to which the load side power line cable is connected. The circuit breaker characteristic test apparatus according to claim 3, wherein the high frequency voltage source, the resistor, the core of the power supply side power line cable, the capacitor and the sheath of the load side power line cable are electrically connected to form a closed circuit for the high frequency voltage. . The circuit breaker characteristic of claim 4, wherein the external device is a computer that provides a command signal for measuring the difference difference to the circuit breaker characteristic test apparatus and calculates the gap difference of the gas insulated switchgear using the respective phase voltages. tester. 6. The apparatus of claim 5, wherein the high frequency voltage is an alternating voltage having a frequency of 9 kHz to 22 kHz. 7. The apparatus of claim 6, wherein the command signal comprises a closing operation signal or a breaking operation signal. 8. The apparatus of claim 7, wherein the sheath of the load side power line cable is connected to ground. A circuit breaker characteristic test apparatus for measuring the difference in opening and closing of a gas insulated switchgear performing a closing or closing operation with respect to a three-phase power line cable including a core wire, a sheath, and an insulation layer interposed between the core wire and the sheath, Circuit breaker characteristic test device for measuring the current flowing in the closed circuit by applying a high frequency voltage to a closed circuit comprising a core wire, a capacitor and a sheath formed between the core wire and the sheath. The apparatus of claim 9, wherein the high frequency voltage is an alternating voltage having a frequency of 9 kHz to 22 kHz. The gas insulated switchgear of claim 10, further comprising: a plug-in type first terminal to which a power supply side power line cable is connected; And a second terminal to which the load side power line cable is connected. 12. The apparatus of claim 11, wherein the sheath of the load side power line cable is connected to ground. Circuit breaker for measuring the difference in opening and closing of the gas insulated switchgear which performs the input or interruption operation of the power supply-side three-phase power line cable and the load-side three-phase power line cable including the core wire, the sheath, and the insulation layer interposed between the core wire and the sheath. As a characteristic test device, A high frequency voltage source providing a high frequency voltage to the core of the power supply-side three-phase power line cable and the sheath of the load side three-phase power line cable; And a measuring unit for converting a current flowing in a capacitor formed between the core of the power supply-side three-phase power line cable and the sheath of the load-side three-phase power line cable to the voltage by the high frequency voltage. The apparatus of claim 13, wherein the high frequency voltage is an alternating voltage having a frequency of 9 kHz to 22 kHz. 15. The apparatus of claim 14, wherein the sheath of the load side power line cable is connected to ground.

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