KR101956589B1 - Apparatus for detecting voltage - Google Patents

Abstract

The present invention relates to a voltage detection apparatus. According to various embodiments of the present invention, the voltage detection apparatus comprises: an output unit configured to output a detection signal; a driving unit configured to drive the output unit based on an applied voltage; and a protection unit having a bidirectional flowing unit configured to allow the applied voltage to flow along a first direction extended to the driving unit, and to allow a reverse voltage generated by the driving unit to flow along a second direction extended from the driving unit.

Description

[0001] APPARATUS FOR DETECTING VOLTAGE [0002]

Various embodiments relate to a voltage detection device.

Generally, a voltage detecting device is installed in an electric equipment to detect a voltage. For example, electrical equipment may include switches and breakers. Then, the voltage detecting device notifies whether or not the voltage is detected. At this time, the voltage detecting device can generate the optical signal based on the input voltage. For example, the voltage detecting device may include a lamp for outputting an optical signal and a driver for driving the lamp using an input voltage. Thus, the administrator of the electrical equipment can determine whether or not the voltage detection device detects the voltage.

However, a noise voltage may be input to the voltage detecting device as described above. For example, a noise voltage may be input from an inverter of an electrical equipment to a voltage detection device. As a result, as the noise voltage is applied to the driving unit, at least one of a reverse voltage or an overcurrent may be generated in the driving unit. As a result, the noise voltage leads to the failure of the driving unit, so that the driving unit does not drive the lamp.

The voltage detecting device according to various embodiments can protect the driving portion. That is, in the voltage detecting apparatus, it is possible to prevent a failure in the driving unit due to the noise voltage.

A voltage detecting apparatus according to various embodiments includes an output section configured to output a detection signal, a drive section configured to drive the output section based on an applied voltage, and a drive section configured to drive the applied voltage in a first direction extending to the drive section And a protection unit having a bidirectional flow unit configured to allow a reverse voltage generated in the driving unit to flow along a second direction extending from the driving unit.

According to various embodiments, the bidirectional transfer unit includes a forward diode configured to flow the applied voltage along the first direction and a reverse diode configured to flow the reverse voltage along the second direction, The forward diode and the reverse diode may be connected in parallel with each other.

According to various embodiments, the protection unit may further include an overcurrent prevention unit connected in parallel to the bidirectional flow unit to reduce a current applied to the driving unit.

According to various embodiments, the overcurrent prevention part may include at least one resistance element connected to the gate of the driving part.

According to various embodiments, the voltage detection device may further include an application unit configured to apply an input voltage to the protection unit, and connected in series with the bidirectional flow unit and the overcurrent prevention unit.

According to various embodiments, the bidirectional transfer part may be connected to the cathode of the driving part.

According to various embodiments, the bi-directional transmission unit may further include at least one resistance element connected in series to the anode of the forward diode and the cathode of the reverse diode.

According to various embodiments, the detection signal may be an optical signal.

According to various embodiments, the applicator may comprise at least one control diode.

According to various embodiments, the voltage detection device may further include an input unit to which a voltage is input, and a conversion unit that converts the input voltage from AC to DC, and provides the converted voltage to the application unit.

In the voltage detecting device according to various embodiments, the protecting portion can protect the driving portion. That is, even if the voltage input to the voltage detecting device includes the noise voltage, it is possible to prevent the driver from being damaged by the noise voltage. Specifically, even if a reverse voltage is generated by the noise voltage in the driving unit, the protection unit can prevent the failure of the driving unit according to the reverse voltage by causing the reverse voltage to flow from the driving unit. In addition, the protection unit prevents the overcurrent from being generated by the noise voltage at the driving unit, thereby preventing the failure of the driving unit according to the overcurrent. Accordingly, reliability can be improved when the manager of the electric equipment grasps whether or not the voltage detection device detects the voltage.

1 is a perspective view showing a voltage detecting device according to various embodiments.
2 is a block diagram showing an internal configuration of a voltage detection device according to various embodiments.
3 is a circuit diagram showing an internal configuration of a voltage detecting device according to an embodiment.

Hereinafter, various embodiments of the present document will be described with reference to the accompanying drawings. However, it should be understood that the techniques described herein are not intended to limit the particular embodiments, but rather include various modifications, equivalents, and / or alternatives. In connection with the description of the drawings, like reference numerals may be used for similar components.

In this document, the expressions "have," "have," "include," or "may include" refer to the presence of such features, such as numerals, functions, And does not exclude the presence of additional features.

As used herein, the expressions " first " or " second ", and the like, may denote various components, regardless of their order and / or importance, and may be used only to distinguish one component from another But do not limit the components.

1 is a perspective view showing a voltage detection device 100 according to various embodiments.

Referring to FIG. 1, the voltage detecting apparatus 100 according to various embodiments may include an input unit 110, an output unit 120, and a detection unit 130.

The input unit 110 may input a voltage to the voltage detecting device 100. [ At this time, as the voltage detecting device 100 is installed in the electric equipment (not shown), the input unit 110 can be electrically connected to the electric equipment. For example, electrical equipment may include switches and breakers. Here, the input unit 110 may be implemented corresponding to each phase of the power source connected to the electric equipment. Thus, a voltage can be input from the electrical equipment to the input unit 110. Here, due to the impedance difference between the bushing of the electric equipment and the voltage detecting device 100, the voltage of several kV flowing in the electric equipment can be lowered to a voltage of several V. [ Accordingly, a voltage of several volts can be applied to the input unit 110. [

The output unit 120 can output a detection signal. In this case, the detection signal may include at least one of an audio signal and a display signal. The display signal may include at least one of a video signal, a text signal, and an optical signal. Here, the output unit 120 may be implemented corresponding to each phase of the power source connected to the electrical equipment. Thus, the administrator of the electrical equipment can determine whether or not the voltage of each phase is detected through the output unit 120.

The detection unit 130 can detect the voltage input to the voltage detection device 100. [ The detection unit 130 may control the output unit 120 based on the voltage. At this time, the detection unit 130 can control the output unit 120 to output the detection signal using the voltage. Here, the detecting unit 130 may be implemented to operate corresponding to each phase of the power source connected to the electric equipment. That is, the detection unit 130 may connect each input unit 110 and each output unit 120.

2 is a block diagram showing an internal configuration of the voltage detecting device 200 according to various embodiments. 3 is a circuit diagram showing an internal configuration of the voltage detecting devices 200 and 300 according to one embodiment.

2, the voltage detecting apparatus 200 according to various embodiments includes an input unit 210, a converting unit 220, an applying unit 230, an output unit 240, a driving unit 250, (260). At this time, the voltage detecting apparatus 200 may be configured as at least a part of the voltage detecting apparatus 100 of FIG. The input unit 210 and the output unit 240 may be implemented as the input unit 110 and the output unit 120 of FIG. 1 and may include a conversion unit 220, an application unit 230, a driver 250, The protection unit 260 may be embedded in the detection unit 130 of FIG. According to one embodiment, the voltage detection devices 200 and 300 may be implemented in a circuit as shown in FIG.

The input unit 210 may input a voltage to the voltage detecting device 200. [ At this time, since the voltage detecting device 200 is installed in the electric equipment (not shown), the input unit 210 can be electrically connected to the electric equipment. For example, electrical equipment may include switches and breakers. In this way, a voltage can be input from the electrical equipment to the input unit 210. Here, due to the impedance difference between the bushing of the electric equipment and the voltage detecting device 200, the voltage of several kV flowing in the electric equipment can be lowered to a voltage of several V. [ Accordingly, a voltage of several volts can be applied to the input unit 210. [ According to one embodiment, the input unit 210 may input a voltage as shown in FIG.

The conversion unit 220 can convert the voltage. At this time, when a voltage is inputted from the input unit 210, the converting unit 220 can convert the voltage from AC to DC. The conversion unit 220 may provide a voltage to the application unit 230. According to one embodiment, the conversion unit 220 may include a bridge diode 320 as shown in FIG. The bridge diode 320 may include four diodes connected by a bridge circuit.

The application unit 230 may apply a voltage to the driving unit 250. [ At this time, the application unit 230 can apply a voltage to the driving unit 250 while repeating charging and discharging. Here, when a voltage is inputted from the converting unit 220, the applying unit 230 can charge the voltage. When the voltage is charged to a predetermined value, the application unit 230 can output a voltage. That is, every time the voltage is charged to a predetermined value, the applying section 230 may be discharged. For example, every time the voltage is charged to 30 V, the applying section 230 can output a voltage. According to one embodiment, the applicator 230 may include at least one zener diode 330, as shown in FIG. For example, a plurality of zener diodes 330 may be connected in series with one another. Here, a cathode of the Zener diode 330 may be connected to the conversion unit 220, and an anode of the Zener diode 330 may be connected to the driving unit 250 to be opposite to each other. That is, the cathode of the zener diode 330, may be connected against the bridge diode 320.

The output unit 240 can output a detection signal. In this case, the detection signal may include at least one of an audio signal and a display signal. The display signal may include at least one of a video signal, a text signal, and an optical signal. According to one embodiment, the output 240 may include a lamp 340, as shown in FIG. The lamp 340 can output an optical signal as a detection signal. For example, the lamp 340 may perform a flicker operation.

The driving unit 250 may drive the output unit 240 based on the voltage. At this time, when a voltage is applied from the application unit 230, the driving unit 250 can control the output unit 240 to output the detection signal. Here, every time a voltage is applied from the applying unit 230, the driving unit 250 is triggered and the output unit 240 can be driven. According to one embodiment, the driver 250 may include a silicon controlled rectifier (SCR) 350 as shown in FIG. Here, a cathode and a gate of the silicon controlled rectifier device 350 are connected opposite to the application portion 230, and an anode of the silicon controlled rectifier device 350 may be connected to the output portion 240 to be opposed to each other. That is, the cathode and gate of the silicon controlled rectifier element 350 are connected opposite to the zener diode 330, and the anode of the silicon controlled rectifier element 350 is connected to the lamp 340.

The protection unit 260 can protect the driving unit 250. For this, the protection unit 260 may be disposed between the application unit 230 and the driving unit 250. At this time, the protection unit 260 may transfer the voltage from the application unit 230 to the driving unit 250. The protection unit 260 may process a reverse voltage generated in the driving unit 250. Also, the protection unit 260 may reduce the current applied to the driving unit 250, thereby preventing the driving unit 250 from overcurrent. According to various embodiments, the protection portion 260 may include a bidirectional flow portion 270 and an overcurrent prevention portion 280.

The bidirectional flow unit 270 may be connected between the application unit 230 and the driving unit 250. The bidirectional flow unit 270 may cause a voltage to flow from the applying unit 230 to the driving unit 250 along the first direction. Here, the first direction may extend from the applying part 230 to the driving part 250. At this time, when a voltage is output from the application unit 230, the bidirectional flow unit 270 can transfer the voltage to the driving unit 250. The bidirectional flow unit 270 may flow a reverse voltage generated in the driving unit 250 along the second direction. Here, the second direction is opposite to the first direction, and may extend from the driving unit 250 to the application unit 230. At this time, when a reverse voltage is generated in the driving unit 250, the bidirectional flow unit 270 can flow a reverse voltage along the second direction.

According to one embodiment, bi-directional flow portion 270 may include bi-directional diode 371 as shown in FIG. The bidirectional diode 371 may include a forward diode 372 and a reverse diode 374. The forward diode 372 may cause a voltage to flow from the application unit 230 to the driver 250 along the first direction. The reverse diode 374 may cause a reverse voltage generated in the driver 250 to flow along the second direction. Here, the forward diode 372 and the reverse diode 374 may be connected in parallel with each other. The forward diode 372 and the reverse diode 374 may be connected in series to the application unit 230 and the driver unit 250. For example, the anode of the forward diode 372 and the cathode of the reverse diode 374 may be connected opposite the applicator 230. The anode of the forward diode 372 and the cathode of the reverse diode 374 may be connected opposite the anode of the Zener diode 330. [ Also, the cathode of the forward diode 372 and the anode of the reverse diode 374 may be connected opposite to the driver 250. The cathode of the forward diode 372 and the anode of the reverse diode 374 may be coupled to the cathode of the silicon controlled rectification element 350. [

According to one embodiment, bidirectional flow portion 270 may further include at least one resistive element 377 as shown in FIG. Here, the resistive element 377 of the bidirectional flow portion 270 can be mixed with the term resistive element 377. The first resistive element 377 may be connected between the application part 230 and the bidirectional diode 371. Here, the first resistive element 377 may be connected in series to the application unit 230 and the bidirectional diode 371. For example, a first resistive element 377 may be connected opposite the anode of zener diode 330. [ And a first resistive element 377 may be coupled to the anode of the forward diode 372 and the cathode of the reverse diode 374.

The overcurrent prevention unit 280 may be connected between the application unit 230 and the driving unit 250. At this time, the overcurrent prevention unit 280 may be branched between the application unit 230 and the bidirectional flow unit 270, and may be connected to the driving unit 250. Here, the overcurrent prevention unit 280 may be connected to the bidirectional flow unit 270 in parallel. The overcurrent prevention unit 280 can reduce the current applied to the driving unit 250 and prevent the overcurrent of the driving unit 250. [ Here, the second direction of the bidirectional flow unit 270 may be connected to the overcurrent prevention unit 280.

According to one embodiment, the overcurrent protection unit 280 may include at least one resistance element 380 as shown in FIG. The resistance element 380 can reduce the current applied from the applying part 230 and transmit the reduced current to the driving part 250. Here, the resistance element 380 of the overcurrent prevention unit 280 may be used in combination with the second resistance element 380. The second resistor element 380 may be connected in parallel to the bidirectional diode 371. Here, when the bidirectional flow unit 270 further includes the first resistive element 377, the second resistive element 380 may be connected in parallel to the bidirectional diode 371 and the first resistive element 377. For example, a second resistive element 380 may be connected opposite the anode of the forward diode 372 and the cathode of the reverse diode 374. The second resistive element 380 may be connected in series to the application unit 230 and the driving unit 250. For example, a second resistive element 380 may be connected opposite the anode of zener diode 330. [ And a second resistive element 380 may be connected to the gate of the silicon controlled rectification element 350. [

According to one embodiment, the voltage detection devices 200 and 300 may be implemented and operated as shown in FIG. That is, when a voltage is input to the voltage detecting devices 200 and 300, the bridge diode 320 can convert the voltage from AC to DC and provide the voltage to the zener diode 330. When a voltage is input from the bridge diode 320, the zener diode 330 can charge the voltage. When the voltage is charged to a predetermined value, the zener diode 330 can output a voltage. When a voltage is inputted from the Zener diode 330, the forward diode 372 can pass the voltage along one direction and can be transmitted to the cathode of the silicon controlled rectifier device 350. Further, when a voltage is inputted from the Zener diode 330, the second resistive element 380 can reduce the current applied to the silicon controlled rectifier element 350 and transmit it to the gate of the silicon controlled rectifier element 350. Thereby, the silicon controlled rectifying element 350 can drive the lamp 340. Namely, the lamp 340 can output an optical signal as a detection signal. For example, the lamp 340 may perform a flicker operation. On the other hand, when a reverse voltage is generated in the silicon controlled rectifier device 350, the reverse diode 374 can cause a reverse voltage to flow from the cathode of the silicon controlled rectifier device 350 along the second direction.

According to various embodiments, in the voltage detecting device 200, the protecting portion 260 can protect the driving portion 250. [ That is, even if the voltage input to the voltage detecting device 200 includes the noise voltage, the protecting part 260 can prevent the driving part 250 from being damaged by the noise voltage. More specifically, even if a reverse voltage is generated by the noise voltage in the driving unit 250, the protective unit 260 can prevent the failure of the driving unit 250 according to the reverse voltage by flowing a reverse voltage from the driving unit 250 . In addition, the protection unit 260 prevents an overcurrent from being generated due to the noise voltage in the driving unit 250, thereby preventing a failure of the driving unit 250 according to the overcurrent. Accordingly, in the case where the administrator of the electrical equipment grasps whether or not the voltage detection device 200 detects the voltage through the output unit 240, the reliability can be improved.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the other embodiments. The singular expressions may include plural expressions unless the context clearly dictates otherwise. Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by one of ordinary skill in the art. The general predefined terms used in this document may be interpreted in the same or similar sense as the contextual meanings of the related art and, unless expressly defined in this document, include ideally or excessively formal meanings . In some cases, even the terms defined in this document can not be construed as excluding the embodiments of this document.

100, 200, 300 voltage detecting device 110 input unit
120 output unit 130 detection unit
210 Input unit 220 Conversion unit
230 application unit 240 output unit
250 driving unit 260 protection unit
270 Bidirectional flow unit 280 Overcurrent prevention unit
320 bridge diode 330 zener diode
340 Light emitting device 350 Silicon controlled rectifier
371 Bidirectional Diode 372 Forward Diode
374 reverse diode 377 first resistor element
380 second resistive element

Claims (10)

An output configured to output a detection signal;
A driving unit configured to drive the output unit based on an applied voltage; And
And a reverse diode connected in parallel to the forward diode for applying a reverse voltage generated by the driving unit to a second direction extending from the driving unit, Directional flow portion configured to flow along the flow path;
And a protection unit connected in parallel to the bidirectional flow unit and having an overcurrent prevention unit for reducing a current applied to the driving unit,
Wherein the bidirectional flow portion includes a first resistive element serially connected to an anode of the forward diode and a cathode of the reverse diode,
Wherein the overcurrent prevention unit includes a second resistance element connected to a gate of the driving unit,
Wherein the first resistance element and the second resistance element are connected in parallel so as to allow a reverse voltage generated in the driving unit to flow and to prevent an overcurrent of the driving unit. delete delete delete The method according to claim 1,
Further comprising an application unit configured to apply an input voltage to the protection unit and connected in series with the bidirectional flow unit and the overcurrent prevention unit, respectively. The apparatus of claim 1, wherein the bidirectional flow unit comprises:
And a cathode of the driving unit. delete The method according to claim 1,
Wherein the detection signal is an optical signal. 6. The apparatus of claim 5,
And at least one control diode. 10. The method of claim 9,
An input unit to which a voltage is input; And
Further comprising a converting unit for converting the input voltage into an AC to DC voltage and providing the converted voltage to the applying unit.

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