KR101093171B1 - Device and method for measuring the leakage current - Google Patents

Abstract

PURPOSE: A leakage current measurement apparatus and a leakage current measurement method thereof are provided to eliminate an induction current included in leakage current measurement, thereby precisely measuring a leakage current. CONSTITUTION: A first Rogowski coil sensor(111) is equipped in a connection metal of an insulator. The first Rogowski coil sensor detects first detection voltage corresponding to a leakage current of the insulator. A second Rogowski coil sensor(112) is located by being separated from the first Rogowski coil sensor with a predetermined distance. The second Rogowski coil sensor detects second detection voltage which is noise voltage included in the first detection voltage. A leakage voltage calculation part(113) calculates leakage voltage of the insulator by subtracting the second detection voltage from the first detection voltage. A leakage current transformation part(114) transforms the calculated leakage voltage to the leakage current.

Description

Leakage current measuring device and leakage current measuring method {DEVICE AND METHOD FOR MEASURING THE LEAKAGE CURRENT}

The present invention relates to a leak current measuring device and a leak current measuring method for measuring a leak current flowing on the insulator surface.

The development of the industry is increasing the demand for power and the power system is becoming very complicated. Accordingly, when a failure such as a power failure occurs, the influence on society is increasing. Therefore, it is very important to secure the reliability of the power system. Among the breakdowns of the power system, breakdowns caused by insulator breakdown are also frequently occurring. However, dielectric breakdown is very difficult to find visually. As a method for diagnosing the dielectric breakdown of such insulator, the dielectric breakdown can be determined by measuring the leakage current flowing through the insulator surface. At this time, the leakage current flowing to the surface of the insulator is measured using a current transformer or Rogowski Coil. However, the measurement method using such a sensor is measured not only the leakage current of the insulator, but also the induced current by the electric field generated in the power facilities around the insulator. Therefore, the insulation breakdown diagnosis of the insulator is also inaccurate due to the incorrect leakage current measurement value. LPF (Low Pass Filter) is used to remove the induced current, but LPF is expensive.

The present invention is to provide a leakage current measuring device and a leakage current measuring method for measuring the leakage current of the insulator.

The present invention is to provide a leakage current measuring apparatus and a leakage current measuring method by using the Rogoowski coil sensor to remove the noise voltage, the production cost is reduced.

According to one aspect of the invention there is provided a leakage current measuring device.

Leakage current measuring device according to an embodiment of the present invention is mounted on the insulator connecting bracket, the first Rogowski coil sensor, the first Rogowski coil sensor for detecting the first detection voltage corresponding to the leakage current of the insulator A second Rogosky coil sensor which is spaced apart by a predetermined distance from the first detection voltage and detects a second detection voltage which is a noise voltage included in the first detection voltage, and subtracts the second detection voltage from the first detection voltage to leak the insulator. A leakage voltage calculator for calculating a voltage and a leakage current converter for converting the calculated leakage voltage into a leakage current are included.

According to another aspect of the present invention, a leakage current measuring method is provided.

The leakage current measuring method according to another embodiment of the present invention includes detecting a first detection voltage corresponding to the leakage current flowing through the insulator from the first Rogowski coil sensor mounted on the insulator connecting bracket, and the first Rogowski Detecting a second detection voltage, which is a noise voltage included in the first detection voltage, from a second Rogowski coil sensor spaced apart from the coil sensor by a predetermined distance, by subtracting the second detection voltage from the first detection voltage, Calculating a leakage voltage and converting the calculated leakage voltage into a leakage current value.

The leakage current measuring apparatus according to the embodiment of the present invention can measure the accurate leakage current by removing the induced current included in the leakage current measurement.

Leakage current measuring apparatus according to an embodiment of the present invention can reduce the cost by using a Rogousuki coil sensor in place of the LPF to remove the induced current included in the leakage current.

1 is an exemplary view showing a leakage current measuring apparatus according to an embodiment of the present invention.
Figure 2 is an exemplary view showing a leakage current measuring device according to another embodiment of the present invention.
Figure 3 is an exemplary view showing a leakage current measuring method according to an embodiment of the present invention.
Figure 4 is an exemplary view showing a leakage current measuring method using a leak current measuring apparatus according to an embodiment of the present invention.

The present invention may be variously modified and have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail with reference to the accompanying drawings. However, this is not intended to limit the present invention to the specific embodiments, it should be understood to include all modifications, equivalent to substitute moisture included in the spirit and scope of the present invention.

In describing the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, numerals (eg, first, second, etc.) used in the description process of the present specification are merely identification symbols for distinguishing one component from another component.

In addition, in the present specification, when one component is referred to as "connected" or "connected" with another component, the one component may be directly connected or directly connected to the other component, but in particular It is to be understood that, unless there is an opposite substrate, it may be connected or connected via another component in the middle.

Hereinafter, a leak current measuring apparatus and a leak current measuring method according to embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary view showing a leakage current measuring apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the leakage current measuring apparatus 100 is a device for measuring leakage current flowing on the insulator surface, and may include a leakage current measuring unit 110 and a leakage current output unit 120.

The leakage current measuring unit 110 includes a first Rogowski coil sensor 111, a second Rogowski coil sensor 112, a leakage voltage calculator 113, a leakage current converter 114, and a signal processor 115. ), A first communication unit 116, and a power supply unit 117.

The first Rogowski coil sensor 111 detects the first detection voltage. The first Rogowski coil sensor 111 is installed in such a manner as to surround the connecting brackets at a predetermined interval so as not to contact the insulator connecting brackets. The first detection voltage includes a leakage voltage induced in the first Rogowski coil sensor 111 in proportion to the leakage current flowing on the surface of the insulator. Here, the leakage voltage is a derivative of the leakage current flowing on the surface of the insulator. In addition, the first detection voltage may include a noise voltage induced by an electric field generated in a power facility such as a power line around the insulator.

The second Rogoowski coil sensor 112 detects a second detection voltage which is a noise voltage included in the first detection voltage. The second Rogoowski coil sensor 112 is positioned to be spaced apart from the first Rogoowski coil sensor 111 by a predetermined distance. In addition, the second Rogowski coil sensor 112 has a central axis parallel to the central axis of the first Rogowski coil sensor 111. A noise voltage corresponding to a noise current that changes with time is derived from the current flowing through the first Rogoowski coil sensor 111 in the second Rogowski coil sensor 112. That is, the second Rogowski coil sensor 112 may detect a noise voltage among voltages induced in the first Rogowski coil sensor 111 by mutual induction. The second Rogoowski coil sensor 112 may further include a power coil 118. The power supply coil 118 is a coil additionally installed in the second Rogoowski coil sensor 112 to use the second detection voltage induced in the second Rogoowski coil sensor 112 as a power source for other components. The second Rogowski coil sensor 112 may transmit the second detection voltage to the power supply unit 117 by the power coil 118.

The first Rogoowski coil sensor 111 and the second Rogoowski coil sensor 112 have the same shape. The first Rogo whiskey coil sensor 111 and the second Rogo whiskey coil sensor 112 have a form in which a coil wound uniformly has one end penetrated into the coil.

In addition, the first Rogowski coil sensor 111 and the second Rogowski coil sensor 112 have the same shape, the number of coil windings, and the kind of constituent materials.

The first Rogowski coil sensor 111 and the second Rogowski coil sensor 112 may be connected in parallel by being commonly grounded.

The leakage voltage calculator 113 calculates a leakage voltage that is a voltage corresponding to the leakage current flowing on the insulator surface. The leakage voltage calculator 113 subtracts the first and second detection voltages. That is, the leakage voltage calculator 113 may calculate the leakage voltage induced by the leakage current flowing on the insulator surface by subtracting the noise voltage included in the first detection voltage.

The leakage voltage calculator 113 may include a subtraction circuit. For example, the leakage voltage calculator may include a differential amplifier.

The leakage current converter 114 converts the leakage voltage into a leakage current. The leakage current converter 114 can convert the leakage current to the leakage current by integrating the leakage voltage calculated by the leakage voltage calculator 113. Thus, the leakage current converter 114 may include an integrator. For example, the leakage current converter 114 may include a passive integrator composed of a resistor and a capacitor. Alternatively, the leakage current converter 114 may include an active integrator configured as an operational amplifier.

The signal processor 115 converts the leakage current converted by the leakage current converter 114 into a digital signal. For example, the signal processor 115 may include an analog-to-digital converter. The signal processor 115 transmits the leakage current value converted into the digital signal to the first communication unit 116.

The first communication unit 116 communicates with the second communication unit 121. The first communication unit 116 transmits the leakage current value converted into the digital signal to the second communication unit 121. The first communication unit 116 may communicate with the second communication unit 121 through wireless communication. The first communication unit 116 may be a module capable of performing wireless communication such as WiFi, Wibro, RFID, Zigbee, and the like.

The power supply unit 117 supplies power to at least one component of the leakage voltage calculator 113, the leakage current converter 114, the signal processor 115, and the first communication unit 116. The power supply unit 117 receives the second detection voltage from the power supply coil 118 of the second Rogowski coil sensor 112. The power supply unit 117 controls the received second detection voltage to change the power to a power having a constant voltage supplied to the component. For example, the power supply unit 117 may be configured as a voltage regulator that maintains a constant output voltage at all times even if the second detection voltage changes.

The leakage current output unit 120 outputs the leakage current value received from the leakage current measuring unit 110.

The leakage current output unit 120 may include a second communication unit 121 and a display unit 122.

The second communication unit 121 performs communication with the first communication unit 116. The second communication unit 121 receives a leakage current value converted into a digital signal from the first communication unit 116. The second communication unit 121 may be a module capable of performing wireless communication such as WiFi, Wibro, RFID, Zigbee, and the like.

The second communication unit 121 transmits the leakage current value converted into the received digital signal to the display unit 122.

The display unit 122 visually or acoustically outputs the leakage current value converted into the received digital signal. For example, the display unit 122 may output the leakage current value to the video through the display. In addition, the display unit 122 may output guide information as audio through the guide voice.

Figure 2 is an exemplary view showing a leakage current measuring device according to another embodiment of the present invention.

In describing FIG. 2, components having the same function as those of FIG. 1 are denoted by the same reference numerals, and redundant descriptions thereof will be omitted.

Referring to FIG. 2, the leakage current measuring unit 110 includes a leakage current measuring unit 110 and a leakage current output unit 120 measuring leakage current flowing on the insulator surface.

The leakage current measuring unit 110 includes a first Rogowski coil sensor 111, a second Rogowski coil sensor 112, a leakage voltage calculator 113, a leakage current converter 114, and a signal processor 115. ), A first communication unit 116 and a power supply unit 117.

The first Rogowski coil sensor 111 detects a first detection voltage including a voltage induced by a leakage current flowing on the insulator surface.

The second Rogowski coil sensor 112 detects a second detection voltage, which is a noise voltage induced by the first Rogowski coil sensor 111 by the surrounding power facility.

The leakage voltage calculator 113 calculates a leakage voltage which is a voltage induced by the leakage current of the insulator by subtracting the second detection voltage from the first detection voltage.

The leakage current converter 114 converts the calculated leakage voltage into a leakage current.

The signal processor 115 converts the converted leakage current into a digital signal.

The first communication unit 116 transmits the leakage current value converted into the digital signal to the leakage current output unit 120.

The power supply unit 117 generates a power source having a constant voltage by using the second detection voltage of the second Rogowski coil sensor 112. The power supply unit 117 supplies power to components that require power among the components included in the leakage current measuring unit 110.

The leakage current output unit 120 includes a second communication unit 121, an insulator state diagnosis unit 123, and a display unit 122.

The second communication unit 121 receives the leakage current value converted into a digital signal from the leakage current measuring unit 110.

The insulator state diagnosis unit 123 may perform diagnosis on the insulation performance of the insulator by using the leakage current value. The leakage current value converted into a digital signal is compared with a preset reference value. The insulator state diagnosis unit 123 may diagnose the insulator as a failure state when the leakage current value exceeds a preset reference value. Alternatively, the insulator state diagnosis unit 123 may diagnose the insulator as a normal state when the leakage current value is less than or equal to a preset reference value. The insulator state diagnosis unit 123 may output the diagnosis result to the display unit 122.

The display unit 122 visually or audibly outputs the insulator state diagnosis result. The display unit 122 may display the diagnosis result of the insulator through the screen. Alternatively, the display unit 122 may output a diagnosis state of the insulator by voice or alarm sound.

Figure 3 is an exemplary view showing a leakage current measuring method according to an embodiment of the present invention.

Referring to FIG. 3, the leakage current measuring device detects the first detection voltage in step S300. The leakage current measuring device detects a first detection voltage, which is a voltage induced by a leakage current flowing on the surface of the insulator with a first Rogowski coil sensor.

In operation S310, the leakage current measuring apparatus detects the second detection voltage. The leakage current measuring device detects the second detection voltage with a second Rogowski coil sensor positioned apart from the first Rogowski coil by a predetermined distance. The second detection voltage is a noise voltage which is a voltage induced by an electric field of a power facility around the insulator among the first detection voltages.

In operation S320, the leakage current measuring apparatus calculates a leakage voltage. The leakage current device may calculate the leakage voltage by subtracting the second detection voltage from the first detection voltage.

In operation S330, the leakage current measuring apparatus converts the calculated leakage voltage into a leakage current. The leakage current measuring device can convert the leakage current into an leakage current by integrating the calculated leakage voltage.

In operation S340, the leakage current measuring apparatus compares the leakage current value with a preset reference value. The preset reference value is a leakage current value that is a reference for determining the insulation state of the insulator.

As a result of the comparison, if the leakage current value exceeds the preset reference value, the leakage current measuring device diagnoses the insulator as a failure state in step S350.

As a result of the comparison, if the leakage current value is equal to or less than the preset reference value, the leakage current measuring device diagnoses the insulator as a normal state in step S360.

Figure 4 is an exemplary view showing a leakage current measuring method using a leak current measuring apparatus according to an embodiment of the present invention.

According to the exemplary embodiment of the present invention, the leakage current measuring device 100 may include a leakage current measuring unit 110 and a leakage current output unit 120.

The leakage current measuring unit 110 is installed in the connection bracket of the insulator leakage current measuring unit 110. The leakage current measuring unit 110 detects the first detection voltage generated by the leakage current flowing on the insulator surface. At this time, the first detection voltage includes a noise voltage generated by an electric field generated by the peripheral power line or the like. Therefore, the leakage current measuring unit 110 separately detects the second detection voltage which is the noise voltage. The leakage current measuring unit 110 may calculate only the leakage voltage due to the leakage current flowing on the insulator surface by subtracting the second detection voltage which is the noise voltage from the detected first detection voltage. The leakage current measuring unit 110 converts the calculated leakage voltage into a leakage current value and transmits the leakage current to the leakage current output unit 120.

The leakage current output unit 120 may be mounted on a moving means such as an automobile. The leakage current measuring unit 110 may be moved by the moving unit, and receive a leakage current value from the leakage current measuring unit 110 included in a preset range.

The leakage current output unit 120 may display the leakage current value on the screen so that a user who uses the leakage current measuring device may check.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be appreciated that modifications and variations can be made.

100: leakage current measuring device
110: leakage current measuring unit
111: first Rogowski coil sensor
112: second Rogowski coil sensor
113: leakage voltage calculation unit
114: leakage current converter
115: signal processing unit
116: first communication unit
117: power supply
120: leakage current output unit
121: second communication unit
122: display unit
123: insulator diagnosis unit

Claims (15)

In the leakage current measuring device for measuring the leakage current flowing on the surface of the insulator,
A first Rogoowski coil sensor mounted to the insulator connecting bracket and detecting a first detection voltage corresponding to the leakage current of the insulator;
A second Rogowski coil sensor positioned apart from the first Rogowski coil sensor by a predetermined distance and detecting a second detection voltage which is a noise voltage included in the first detection voltage;
A leakage voltage calculator configured to calculate a leakage voltage of the insulator by subtracting the second detection voltage from the first detection voltage; And
Leakage current measuring device including a leakage current converter for converting the calculated leakage voltage into a leakage current.
The method of claim 1,
The first Rogo whiskey coil sensor and the second Rogo whiskey coil sensor are each leakage current measuring device, characterized in that the central axis is located in parallel.
The method of claim 1,
The first Rogoowski coil sensor and the second Rogoowski coil sensor are the same, characterized in that the leakage current measuring device.
The method of claim 1,
The first Rogo whiskey coil sensor and the second Rogo whiskey coil sensor are connected to each other in parallel with a common ground.
The method of claim 1,
The leakage current converter
The leakage current measuring device converts the leakage voltage into the leakage current by integrating the leakage voltage.
The method of claim 1,
Leakage current measuring device further comprises a power supply for supplying power to the leakage voltage calculator and the leakage current converter.
The method of claim 6,
And the power supply unit adjusts the magnitude of the second detection voltage to supply the power supply to the power supply.
The method of claim 7, wherein
The power supply unit is a leakage current measuring device, characterized in that for receiving the second detection voltage by winding an additional coil to the second Rogoowski coil sensor.
The method of claim 1,
And a insulator state diagnosis unit configured to determine whether the insulator is in a state by comparing the leakage current with a preset reference value that is a criterion for diagnosing insulation of the insulator.
10. The method of claim 9,
And if the leakage current exceeds the predetermined reference value, the insulator state diagnosis unit diagnoses the insulator as a fault state.
10. The method of claim 9,
And the insulator state diagnosis unit diagnoses the insulator to a normal state if the leakage current is less than or equal to the preset reference value.
In the leakage current measuring method for measuring the leakage current flowing on the surface of the insulator,
Detecting a first detection voltage corresponding to a leakage current flowing through the insulator from a first Rogowski coil sensor mounted on the insulator connecting bracket;
Detecting a second detection voltage, which is a noise voltage included in the first detection voltage, from a second Rogoowski coil sensor spaced apart from the first Rogoowski coil sensor by a predetermined distance;
Calculating a leakage voltage by subtracting the second detection voltage from the first detection voltage; And
Integrating the calculated leakage voltage and converting the leakage voltage into a leakage current value.
The method of claim 12,
After converting the leakage voltage to the leakage current value,
And comparing the leakage current value with the preset reference value to diagnose a state of the insulator.
The method of claim 13,
Diagnosing the insulator state,
And diagnosing the insulator as a fault condition if the leakage current exceeds the preset reference value.
The method of claim 13,
And if the leakage current value is less than or equal to the preset reference value, diagnosing the insulator in a steady state.

Images