KR102191783B1 - Portable Current Transformer Ratio Tester - Google Patents

Abstract

The present invention relates to a portable current transformer turns ratio tester which can immediately calculate turns ratio (RATIO), turns ratio error (RATIO %ERROR), and secondary output (SEC OUTPUT) of a current transformer to be measured by configuring an operation unit with a PLC circuit. The present invention exhibits the following effects. According to the present invention, as soon as a primary winding current value (PRI.A) and a secondary winding current value (SEC.A) of the current transformer (1) are inputted, the turns ratio (RATIO), turns ratio error (RATIO %ERROR) and secondary output (SEC OUTPUT) of the current transformer (1) are calculated, thereby being easy for measurement and shortening measurement time.

Description

Portable Current Transformer Ratio Tester

The present invention relates to a portable current transformer turns ratio tester, and by configuring an operation unit with a PLC circuit, a portable current transformer that can immediately calculate the turns ratio (RATIO), turns ratio error (RATIO %ERROR), and secondary output (SEC OUTPUT) of the current transformer to be measured. It relates to a current transformer turns ratio tester.

As an index indicating the characteristics of current transformers and transformers, polarity, turns ratio, excitation current, short-circuit current, and phase difference angle or phase angle, which are parameters that have an important influence on the stability of power supply and protection control of the power system. Deviation).

KEPCO, large-capacity power receiving companies, heavy electricity manufacturers, power facility construction companies, research institutes, etc. are measuring current transformer characteristics by combining various measuring instruments when installing, repairing, inspecting and testing power facilities.

Conventional portable current transformers are operated in a microprocessor (microprocessor) method. According to this, in measuring the variables of the analysis data, the capacity or the number of combinations is enormous and must be individually measured for each variable, which takes a long time to measure.

The present invention is a portable current transformer turns ratio tester that measures all characteristics of a current transformer in a single test. Real-time measurement based on a PLC through local control, a winding ratio measurement using a fundamental wave voltage comparison method, a winding current measurement technique, an auto-ranging function, Portable current transformer winding ratio that can easily realize recording/display function of measurement result from remote location by additional connection to HMI, monitoring function that enables searching/printing/setting from external device, localization of use environment, menu room operation, etc. It is a testing machine.

In particular, PLC type includes all measurement variables (measurement variables calculated by a combination of primary current, secondary current, burden, class, etc.) that can be measured and included in the hardware to measure turns ratio (RATIO) simultaneously. , Turns ratio error (RATIO %ERROR) and secondary output (SEC OUTPUT) are calculated.

In addition, the present invention is a plug-and-socket panel, a control panel, a power application circuit, a stable power supply (SMPS), a CPU configured including a central processing unit PLC, a digital converting the switch contact status signal of the control panel into a code value. A signal input circuit, a digital signal output circuit for opening and closing the power operation circuit magnetic switch driving circuit, a current and voltage detection circuit for detecting current and voltage in the input/output circuit of the test current connected to the plug socket, the current and An analog signal input circuit that converts the output signal of the voltage detection circuit into a digital signal, a gain control circuit that controls the amplification degree setting value of the auto-ranging circuit of the current and voltage detection circuit, and a touch screen connected to the bus of the CPU , A hardware system including a communication port, a memory device capable of power failure compensation, a peripheral device driving module such as a clock alc LED, and a system scheduler that manages the processing sequence and processing time of the components of the portable current transformer tester of the present invention, main A system management module comprising a program, a digital signal acquisition module that acquires contact signals and converts them into code values, an analog signal acquisition module that samples current and voltage detection signals and converts them into code values, and processes the acquired data to measure the amount of electricity. MMI consisting of a measurement module based on a phasor measurement technique for calculation, a database for storing data in the built-in memory in the form of a file, and a database for querying stored data, a key scan module for an interface with a user, and a display module. And a software system comprising a module, a digital output signal module generating a digital signal for opening and closing the electronic switch of the power operation circuit, and a peripheral device driving module.

Registered Patent No. 10-0206655 (1999.04.09.)

An object of the present invention is to provide a portable current transformer turns ratio tester capable of immediately calculating turns ratio (RATIO), turns ratio error (RATIO %ERROR), and secondary output (SEC OUTPUT) by configuring the operation unit as a PLC circuit.

In order to solve the above problems, in the present invention, the power supply unit 100 for supplying AC power input from the outside to the current transformer (1); An AC current converter 200 connected to the secondary winding side of the current transformer 1; A first AC voltage converter 300 connected to the primary winding side of the current transformer 1; A second AC voltage converter 400 and a third AC voltage converter 500 connected in parallel between the power supply unit 100 and the AC current converter 200; A/ which converts an analog signal into a digital signal by receiving the power converted from the AC current converter 200, the first AC voltage converter 300, the second AC voltage converter 400, and the third AC voltage converter 500. D converter 600; An operation unit 700 configured as a PLC circuit, receiving the digital signal converted by the A/D converter 600 and calculating a turns ratio (RATIO), a turns ratio error (RATIO %ERROR), and a secondary output (SEC OUTPUT); A control unit 800 for inputting a primary winding current value PRI.A and a secondary winding current value SEC.A of the current transformer 1; Including a display unit 900 for outputting the turns ratio (RATIO), turns ratio error (RATIO% ERROR), and secondary output (SEC OUTPUT) calculated by the operation unit 700 on the screen; and the power supply unit 100 is external The first and second windings input to the control unit 800 among a plurality of preset voltage values of the power output unit 110 for outputting the AC power input from the power output unit 110 and the voltage value of the AC power output from the power output unit 110 A multi-transformer 120 that transforms into a voltage value corresponding to a current value (PRI.A, SEC.A), and is connected between the power output unit 110 and the multi-transformer 120 to open or short a circuit. A circuit breaker 130 is included, and the AC current converter 200 converts AC power corresponding to the secondary winding current value (SEC.A) input to the control unit 800 into DC power, and then A/D. After applying to the converter 600, the first AC voltage converter 300 converts the AC power corresponding to the primary winding current value (PRI.A) input to the control unit 800 into DC power, and then A/D. When applied to the converter 600, the second AC voltage converter 400 is an AC power source corresponding to the first transformed value when the voltage value transformed by the multi-transformer 120 falls within the range of the first transformed value. Is converted into DC power and applied to the A/D converter 600, and the third AC voltage converter 500 is in the case where the voltage value transformed by the multi-transformer 120 falls within the range of the second transformed value. , After converting the AC power corresponding to the second transformed value to DC power and applying it to the A/D converter 600, the calculating unit 700 is the primary winding current value (PRI.A) input to the control unit 800. ) And the secondary winding current value (SEC.A) to calculate the winding ratio (RATIO), and the primary winding measurement current value measured by the first AC voltage converter 300 (RATED PRI. In the measurement winding ratio calculation unit 720 that calculates the measurement winding ratio (RATED RATIO) using the secondary winding measurement current value (RATED SEC.A) measured by A) and the AC current converter 200, and the winding ratio calculation unit 710 In the calculated turns ratio (RATIO) and the measurement winding ratio calculation unit 720 A winding ratio error calculation unit 730 that calculates a winding ratio error (RATIO% ERROR) using the calculated measurement winding ratio (RATED RATIO), a primary winding current value (PRI.A) and a winding ratio calculation unit (PRI.A) input to the control unit 800. It includes a secondary output calculation unit 740 that calculates the secondary output (SEC OUTPUT) using the turns ratio (RATIO) calculated at 710), and the turns ratio (RATIO) calculated by the turns ratio calculation unit 710 is RATIO = PRI A measurement winding ratio (RATED RATIO) calculated by .A / SEC.A and calculated by the measurement winding ratio calculation unit 720 is calculated as RATED RATIO = RATED PRI.A / RATED SEC.A, and the winding ratio error calculation unit 730 The turns ratio error (RATIO %ERROR) calculated at is calculated as RATIO %ERROR = ((RATED RATIO-RATIO)*100) / RATED RATIO, and the secondary output (SEC OUTPUT) calculated by the secondary output calculation unit 740 Presents a portable current transformer turns ratio tester characterized in that it is calculated as SEC OUTPUT = PRI.A * RATIO.

The present invention exhibits the following effects.

That is, according to the present invention, as soon as the primary winding current value (PRI.A) and the secondary winding current value (SEC.A) of the current transformer 1 are input, the turns ratio (RATIO) of the current transformer 1, the turns ratio error ( RATIO %ERROR) and secondary output (SEC OUTPUT) are calculated, so measurement is easy and the measurement time can be shortened.

1 is a circuit diagram of a portable current transformer turns ratio tester according to the present invention.
2 is a diagram showing components of an operation unit that is a part of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described based on the accompanying drawings. However, the scope of the present invention should be grasped by the description of the claims. In addition, descriptions of known techniques that obscure the subject matter of the present invention will be omitted.

The present invention relates to a portable current transformer turns ratio tester, and by configuring an operation unit with a PLC circuit, a portable current transformer that can immediately calculate the turns ratio (RATIO), turns ratio error (RATIO %ERROR), and secondary output (SEC OUTPUT) of the current transformer to be measured. It relates to a current transformer turns ratio tester.

1 is a circuit diagram of a portable current transformer turns ratio tester according to the present invention, and FIG. 2 is a view showing components of an operation unit that is a part of the present invention.

As shown in FIG. 1, the portable current transformer turns ratio tester according to the present invention includes a power supply unit 100, an AC current converter 200, a first AC voltage converter 300, and a second AC voltage converter 400. Wow, a third AC voltage converter 500, an A/D converter 600, an operation unit 700, a control unit 800, and a display unit 900 may be included.

The power supply unit 100 will be described. The power supply unit 100 is a part that supplies AC power input from the outside to the current transformer 1, and includes a power output unit 110, a multiple transformer unit 120, and a circuit breaker 130. I can.

The power output unit 110 will be described. The power output unit 110 is a part to which AC power input from the outside is output. Preferably, it can be configured to output AC 0.8V ~ 48V power, but is not limited thereto.

The multiple transformer unit 120 will be described. The multiple transformer 120 is a part that transforms the voltage value of the AC power output from the power output unit 110 into any one of a plurality of preset voltage values.

Here, the plurality of preset voltage values may be set to specific values corresponding to the primary and secondary winding current values PRI.A and SEC.A input to the controller 800. Specifically, it is preferable to set the voltage value to 0.8V, 1.6V, 2.6V, 3.6V, 4.6V, 6.1V, 8.6V, 10V, 14V, 21V, 38V, 48V, but is not limited thereto. .

The circuit breaker 130 will be described. The circuit breaker 130 is a part that is connected between the power output unit 110 and the multiple transformer unit 120 to open or short a circuit.

A first relay 10 may be connected between the circuit breaker 130 and the multiple transformer 120. The first relay 10 serves to turn on/off the multiple transformer unit 120.

The AC current converter 200 will be described. The AC current converter 200 is a part connected to the secondary winding side of the current transformer 1, and converts AC power corresponding to the secondary winding current value SEC.A input to the control unit 800 into DC power. This is a part applied to the A/D converter 600 afterwards.

Preferably, the AC current converter 200 may be configured to convert AC 1A to DC 4-20mA, but is not limited thereto.

A sixth relay 60 may be connected between the AC current converter 200 and the current transformer 1. Here, the sixth relay 60 is a part that turns on/off the passage of any one of the three-phase secondary winding current values SEC.A, and preferably, the sixth relay 60 connected in parallel with each other. It may be configured to include a 1 relay 61, a 6-2 relay 62, and a 6-3 relay 63.

The first AC voltage converter 300 will be described. The first AC voltage converter 300 is a part connected to the primary winding side of the current transformer 1, and uses AC power corresponding to the primary winding current value PRI.A input to the control unit 800 as a DC power source. It is a part that is applied to the A/D converter 600 after conversion.

Preferably, the first AC voltage converter 300 may be configured to convert AC 10V into DC 4-20mA, but is not limited thereto.

A seventh relay 70 may be connected between the first AC voltage converter 300 and the current transformer 1. Here, the seventh relay 70 is a part that turns on/off the passage of any one of the three-phase primary winding current values PRI.A, and preferably, the seventh relay 70 connected in parallel with each other. It may be configured to include a first relay 71, a 7-2 relay 72, and a 7-3 relay 73.

The second AC voltage converter 400 will be described. The second AC voltage converter 400 is a part connected between the power supply unit 100 and the AC current converter 200, and the voltage value transformed by the multiple transformer unit 120 falls within the range of the first transformer value. , It is a part that converts the AC power corresponding to the first transformed value into DC power and applies it to the A/D converter 600.

Here, the range of the first transformed value is preferably set to 14 to 48V, and in this case, the second AC voltage converter 400 may convert AC 50V to DC 4 to 20mA. However, it is not necessarily limited thereto.

The second and fourth relays 20 and 40 may be connected in series between the second AC voltage converter 400 and the multi-transformer 120.

Here, the second relay 20 is a part for passing a voltage value corresponding to the voltage value transformed by the multiple transformer 120 among a plurality of preset voltage values.

The second relay 20 includes relays 2-1 (21), relays 2-2 (22), relays 2-3 (23), and relays 2-4 (24) connected in parallel. Can be configured.

The 2-1 relay 21 is a part that turns on/off the passage of the 2-1 transformation value, and the 2-2 relay 22 is a part that turns on/off the passage of the 2-2 transformation value. , The 2-3rd relay 23 is a part that turns on/off the passage of the 2-3rd transformation value, and the 2-4 relay 24 is a part that turns on/off the passage of the 2nd-4th transformation value. .

Here, it is preferable to set the 2-1 transformation value to 48V, the 2-2 transformation value to 38V, the 2-3rd transformation value to 21V, and the 2-4 transformation value to 14V. However, the present invention is not necessarily limited thereto, and the number of the second relays 20 may be increased or decreased, and may be set to other specific transformation values.

The fourth relay 40 is a part that turns on/off the voltage value that has passed through the second relay 20 to be input to the second AC voltage converter 400.

The third AC voltage converter 500 will be described. The third AC voltage converter 500 is a part connected between the power supply unit 100 and the AC current converter 200, and the voltage value transformed by the multiple transformer unit 120 falls within the range of the second transformer value. , It is a part that converts the AC power corresponding to the second transformed value into DC power and then applies it to the A/D converter 600.

Here, the range of the second transformed value is preferably set to 0.8 to 10V, and in this case, the third AC voltage converter 500 may convert AC 10V to DC 4 to 20mA. However, it is not necessarily limited thereto.

The third and fifth relays 30 and 50 may be connected in series between the third AC voltage converter 500 and the multi-transformer 120.

Here, the third relay 30 is a part for passing a voltage value corresponding to the voltage value transformed by the multiple transformer 120 among a plurality of preset voltage values.

The third relay 30 includes the 3-1 relay 31, the 3-2 relay 32, the 3-3 relay 33, the 3-4 relay 34, and the third relay 31 connected in parallel. It may include a 3-5 relay 35, a 3-6 relay 36, a 3-7 relay 37, and a 3-8 relay 38.

The 3-1 relay 31 is a part that turns on/off the passage of the 3-1 transformation value, and the 3-2 relay 32 is a part that turns on/off the passage of the 3-2 transformation value. , The 3-3 relay 33 is a part that turns on/off the passage of the 3-3 transformation value, and the 3-4 relay 34 is a part that turns on/off the passage of the 3-4 transformation value. , The 3-5 relay 35 is a part that turns on/off the passage of the 3-5 transformation value, and the 3-6 relay 36 is a part that turns on/off the passage of the 3-6 transformation value. , The 3-7 relay 37 is a part that turns on/off the passage of the 3-7 transformation value, and the 3-8 relay 38 is a part that turns on/off the passage of the 3-8 transformation value. .

Here, the 3-1 transformation value is 10V, the 3-2 transformation value is 8.6V, the 3-3 transformation value is 6.1V, the 3-4 transformation value is 4.6V, and the 3-5 transformation value is 3.6V. , It is preferable to set the 3-6 transformation value to 2.6V, the 3-7 transformation value to 1.6V, and the 3-8 transformation value to 0.8V. However, the present invention is not limited thereto, and the number of the third relays 30 may be increased or decreased, and may be set to other specific transformation values.

The fifth relay 50 is a part that turns on/off the voltage value that has passed through the third relay 30 to be input to the third AC voltage converter 500.

The A/D converter 600 will be described. The A/D converter 600 receives power converted from the AC current converter 200, the first AC voltage converter 300, the second AC voltage converter 400, and the third AC voltage converter 500, and receives an analog signal. This is the part that converts the digital signal.

The calculation unit 700 will be described. The operation unit 700 is made of a PLC circuit, but receives the digital signal converted by the A/D converter 600 and calculates the turns ratio (RATIO), turns ratio error (RATIO %ERROR), and the secondary output (SEC OUTPUT). Part.

As shown in FIG. 2, the calculation unit 700 includes a winding ratio calculation unit 710, a measurement winding ratio calculation unit 720, a winding ratio error calculation unit 730, and a secondary output calculation unit 740. I can.

The winding ratio calculation unit 710 is a part that calculates the turns ratio RATIO using the primary winding current value PRI.A and the secondary winding current value SEC.A input to the control unit 800.

Specifically, it is calculated as RATIO = PRI.A / SEC.A.

The measurement winding ratio calculating unit 720 includes a primary winding measurement current value measured by the first AC voltage converter 300 (RATED PRI.A) and a secondary winding measurement current value measured by the AC current converter 200 (RATED SEC) It is a part that calculates the measurement winding ratio (RATED RATIO) using .A).

Specifically, it is calculated as RATED RATIO = RATED PRI.A / RATED SEC.A.

The turns ratio error calculation unit 730 is a part that calculates a turns ratio error (RATIO %ERROR) using the turns ratio (RATIO) calculated by the turns ratio calculation unit 710 and the measurement turns ratio (RATED RATIO) calculated by the measurement winding ratio calculation unit 720 to be.

Specifically, it is calculated as RATIO %ERROR = ((RATED RATIO-RATIO)*100) / RATED RATIO.

The secondary output calculation unit 740 uses the primary winding current value (PRI.A) input to the control unit 800 and the turns ratio (RATIO) calculated by the winding ratio calculation unit 710 to calculate the secondary output (SEC OUTPUT). This is the part to calculate.

Specifically, it is calculated as SEC OUTPUT = PRI.A * RATIO.

The controller 800 will be described. The control unit 800 is a part to which the primary winding current value PRI.A and the secondary winding current value SEC.A of the current transformer 1 are input.

The display unit 900 will be described. The display unit 900 provides a user interface to input the primary winding current value (PRI.A) and the secondary winding current value (SEC.A) of the current transformer 1, or the turns ratio calculated by the calculation unit 700. (RATIO), turns ratio error (RATIO %ERROR), and secondary output (SEC OUTPUT) are displayed on the screen.

The control unit 800 and the display unit 900 may be implemented using an HMI touch screen method or a PC CIMON method.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have knowledge.

100: power supply
110: power input unit
120: multiple transformer
130: circuit breaker
200: AC current converter
300: first AC voltage converter
400: second AC voltage converter
500: 3rd AC voltage converter
600: A/D converter
700: operation unit
710: winding ratio calculation unit
720: Measurement winding ratio calculation unit
730: turns ratio error calculation unit
740: secondary output calculation unit
800: control unit
900: display
10: first relay
20: second relay
21: relay 2-1
22: relay 2-2
23: relay 2-3
24: relay 2-4
30: 3rd relay
31: 3-1 relay
32: 3-2 relay
33: 3-3 relay
34: relay 3-4
35: relay 3-5
36: relay 3-6
37: relay 3-7
38: relay 3-8
40: 4th relay
50: 5th relay
60: 6th relay
61: relay 6-1
62: relay 6-2
63: relay 6-3
70: 7th relay
71: relay 7-1
72: relay 7-2
73: relay 7-3
1: current transformer

Claims (4)

delete delete delete A power supply unit 100 for supplying AC power input from the outside to the current transformer 1;
An AC current converter 200 connected to the secondary winding side of the current transformer 1;
A first AC voltage converter 300 connected to the primary winding side of the current transformer 1;
A second AC voltage converter 400 and a third AC voltage converter 500 connected in parallel between the power supply unit 100 and the AC current converter 200;
A/D that receives power converted from the AC current converter 200, the first AC voltage converter 300, the second AC voltage converter 400, and the third AC voltage converter 500 to convert an analog signal into a digital signal. Converter 600;
An operation unit 700 configured as a PLC circuit, receiving the digital signal converted by the A/D converter 600 and calculating a turns ratio (RATIO), a turns ratio error (RATIO %ERROR), and a secondary output (SEC OUTPUT);
A control unit 800 for inputting a primary winding current value PRI.A and a secondary winding current value SEC.A of the current transformer 1;
Including; a display unit 900 for outputting a turns ratio (RATIO), a turns ratio error (RATIO% ERROR), and a secondary output (SEC OUTPUT) calculated by the calculation unit 700 on the screen; and

The power supply unit 100 is
A power output unit 110 for outputting an AC power input from the outside;
A multi-transformer 120 transforming the voltage value of the AC power output from the power output unit 110 into any one of a plurality of preset voltage values,
A circuit breaker 130 connected between the power output unit 110 and the multi-transformer unit 120 to open or short a circuit,

The AC current converter 200 is
After converting the AC power corresponding to the secondary winding current value (SEC.A) input to the control unit 800 to DC power, and applying it to the A/D converter 600,

The first AC voltage converter 300 is
After converting the AC power corresponding to the primary winding current value (PRI.A) input to the control unit 800 to DC power, and applying it to the A/D converter 600,

The second AC voltage converter 400 is
When the voltage value transformed by the multi-transformer 120 falls within the range of the first transformed value, the AC power corresponding to the first transformed value is converted into DC power and then applied to the A/D converter 600,

The third AC voltage converter 500 is
When the voltage value transformed by the multi-transformer 120 falls within the range of the second transformed value, the AC power corresponding to the second transformed value is converted into DC power and then applied to the A/D converter 600,

The operation unit 700 is
A winding ratio calculating unit 710 that calculates a turns ratio RATIO using a primary winding current value (PRI.A) and a secondary winding current value (SEC.A) input to the control unit 800;
The measurement winding ratio using the primary winding measurement current value (RATED PRI.A) measured by the first AC voltage converter 300 and the secondary winding measurement current value (RATED SEC.A) measured by the AC current converter 200 A measurement winding ratio calculating unit 720 that calculates (RATED RATIO),
A turns ratio error calculation unit 730 that calculates a turns ratio error (RATIO% ERROR) using the turns ratio (RATIO) calculated by the winding ratio calculation unit 710 and the measurement winding ratio (RATED RATIO) calculated by the measurement winding ratio calculation unit 720,
A secondary output calculation unit 740 that calculates a secondary output (SEC OUTPUT) using the primary winding current value (PRI.A) input to the control unit 800 and the turns ratio (RATIO) calculated by the winding ratio calculation unit 710 Including,

The turns ratio (RATIO) calculated by the turns ratio calculation unit 710 is
RATIO = PRI.A / SEC.A calculated,

The measurement winding ratio (RATED RATIO) calculated by the measurement winding ratio calculation unit 720 is
RATED RATIO = RATED PRI.A / RATED SEC.A is calculated,

The turns ratio error (RATIO %ERROR) calculated by the turns ratio error calculation unit 730 is
RATIO %ERROR = ((RATED RATIO-RATIO)*100) / Calculated as RATED RATIO,

The secondary output (SEC OUTPUT) calculated by the secondary output calculation unit 740 is
SEC OUTPUT = PRI.A * RATIO
Portable current transformer turns ratio tester.

Images