KR200414256Y1 - voltage detector - Google Patents

Abstract

The present invention visually displays the energized state supplied through a line through a plurality of light emitting diodes and blinks at a cycle determined by the gun diode and the variable capacitor, so as to recognize the energized state simply and quickly to prevent electric shock. It is about one live indicator.

The above invention is

A reverse diode is connected to the ground side of the current collector plate provided between the line and the ground through a capacitor.

On the line side of the high voltage charging section of the current collector, a cathode of the reverse diode is connected to the forward diode connected to the anode,

The anode of the reverse diode is connected to the cathode of the forward diode through the gun diode,

A capacitor and a plurality of light emitting diodes are connected in parallel between the cathode of the forward diode and the anode of the forward diode,

The variable capacitor is connected to the cathode of the forward diode so that the ground side and the distribution line side are connected to each other so that the light emitting diodes blink on a periodic basis by the gun diode and the variable capacitor so that the distribution line is energized. It is characterized by the configuration to prevent accidents.

Current board, support, spring, coupling piece, gun diode

Description

Live indicator

1 is a circuit diagram showing a configuration according to an embodiment of the present invention.

Figure 2 is a perspective view showing the appearance of the present invention.

Figure 3 is a side view showing the appearance of the subject innovation.

Explanation of symbols on the main parts of the drawings

1: track 2: earth

3: current collector 4: light emitting diode

11: support 12: spring

13 shaft 14 coupling piece

D1: reverse diode C1, C2: capacitor

C3: variable capacitor D2, D3: forward diode

GD: Gun Diode

The present invention relates to a live line indicator, and more specifically, to prevent an electric shock by visually displaying the energized state through which a plurality of light emitting diodes are supplied to a line such as a transformer room or a power receiving room where a high voltage of 3300V to 154000V flows. It is about one live indicator.

In general, electric energy is most widely used because it is pollution-free and easy to use, and it is well known that electric power generated by hydroelectric power, thermal power, or nuclear power is mainly supplied to various uses through a track.

In addition, since the process of supplying electricity from the power plant to each site is complicated and the length of the track is very long, accidents occur frequently and construction for repair or replacement of the track is carried out. Was the cause of personal injury from electric shock.

Therefore, there is a need for a device for visually indicating whether an electricity supply state such as a circuit breaker or a distribution line is supplied with electricity or a non-voltage state without electricity.

Therefore, conventionally, there is an overvoltage display method for directly connecting and displaying a high voltage charging part, and an overvoltage display method for installing the high voltage side current collector plate and displaying the capacitance using the capacitance between the high voltage side current collector plate and the high voltage charge part. The display method of directly applying to the liquid crystal device and the display method of providing various flashing circuits and alternating display by providing various driving circuits in front of the liquid crystal device.

Conventional general electrical indicator,

The capacitance (ZS) of the capacitance (CS) and the impedance (ZL) of the overvoltage indicator by the capacitance (CS) between the high-voltage charging section and the high-side current collector plate, and the capacitance (CO) between the earth and the earth-side current collector plate. ), The impedance ZO of the capacitance CO is generated.

Here, there is a relationship of impedance (ZS) = 1 / wCS and impedance (ZO) = 1 / wCO.

In this state, when the voltage (VO) is applied between the high voltage charging section and the ground, the voltage (VL) is generated between the high-voltage current collector and the earth-side current collector of the overload indicator, and the voltage (VL) = ZL · Vo / (ZS + ZL + ZO).

Since the voltage VL is applied to the display unit through the driving circuit, the display unit is turned on to recognize that electricity is being supplied.

However, in the conventional over-current indicator as described above, the voltage VL for turning on the display unit through the driving circuit is about 5 V, so that the over-display should be carefully checked to confirm the lighting state of the display unit. According to the state in which it is attached to the power distribution line, the capacitance (Cs) increases, the impedance (Zs) is reduced, the display state of the display is further reduced, there is a disadvantage that can not be confirmed.

Accordingly, Utility Model Registration Publication No. 0121859 (overcurrent energization indicator) has been proposed, which allows the high voltage side current collector plate to be positioned at the high voltage charging unit and the earth side current collector plate at the earth to detect whether the power is supplied by a capacitance. Collector,

An EL lamp that is turned on with low power consumption by a low voltage induced by the current collector;

A rectifier and filter unit configured to allow the induced voltage of the alternating current detected by the current collector to pass a minimum induced voltage through two constant voltage diodes connected in series and to remove noise while being half-wave rectified by the diode and the capacitor;

A counter for receiving an AC voltage induced by the current collector as a clock signal and outputting a pulse signal having a frequency of 24 to 25 Hz;

A divider which receives the pulse signal input from the counter unit as a trigger signal and receives the DC power from the rectifier and filter unit as a driving power source and divides it into 1/24 to 1/25 and outputs it;

The display unit was configured to receive a DC power supplied from the division unit at 1/24 to 1/25, and flicker the letters " currently energized ".

In the conventional over-current indicator as described above, the voltage is generated in the form of alternating current between the two current collector plates while the electricity is flowing. Only when the noise is removed and the half-wave rectified DC power is applied as the driving power to the divider, the AC power is input to the counter as a clock signal and output as a pulse signal.

Therefore, by dividing the DC power divided by the divider that receives the pulse signal of the counter as the trigger signal, the TN liquid crystal device in which the power is supplied is blinked only at the portion of the “is energized”.

However, according to the conventional over-power indicator as described above, the EL lamp is always on, so that the visual effect is reduced, and there is a problem that an approaching person may not recognize the fast and accurately, causing an electric shock or the like.

The present invention has been devised in order to solve the above-mentioned problems, and visually shows the energized state in which electricity is supplied to a line such as a substation room or a power receiving room where a high pressure of 3300V to 154000V flows through a plurality of light emitting diodes. It is an object of the present invention to provide a live indicator that is displayed to prevent an electric shock.

Live line indicator of the present invention for achieving the above object,

The current collector board installed between the track and the ground to recognize the overcurrent state,

A reverse diode is connected to the ground side of the current collector plate via a capacitor,

On the distribution line side of the current collecting plate, a cathode of the reverse diode is connected to the forward diode connected to the anode,

The anode of the reverse diode is connected to the cathode of the forward diode through the gun diode,

A capacitor and a plurality of light emitting diodes are connected in parallel between the cathode of the forward diode and the anode of the forward diode,

By connecting a variable capacitor to the cathode of the forward diode so that the ground-side current collector plate and the distribution line-side current collector plate are connected, the light emitting diodes blink in cycles changed by the variable capacitor to clearly recognize that the power distribution line is energized. It is characterized in that it is configured to prevent an electric shock accident.

Hereinafter, with reference to the accompanying drawings illustrating a preferred embodiment of the present invention.

1 to 3 illustrate a configuration according to an embodiment of the present invention,

Live indicator according to the present invention,

The current collector plate (3) installed between the line (1) and the ground (2) to recognize the over-current state,

The ground side of the current collector plate 3 is connected to the anode of the reverse diode D1 via a capacitor C1,

On the line side of the current collector plate 3, a cathode of the reverse diode D1 is connected to the first forward diode D2 connected to the anode,

The anode of the reverse diode D1 is connected to the cathode of the second forward diode D3 via a first gun diode GD,

A capacitor C2 and a light emitting diode LED1 (LED2) ... (LEDn) 4 are connected in parallel between the cathode of the first forward diode D2 and the anode of the second forward diode D3,

The variable capacitor C3 is connected to the cathode of the first forward diode D2 so that the earth 2 side and the line 1 side of the current collector plate 3 are connected to each other.

The light emitting diodes (LED1) (LED2) ... (LEDn) (4) of the spring (12) at the end of the support (11) on the rear of the main body 10 is exposed through the front display (5) Receiving elasticity through the two coupling pieces 14, one side is coupled to the shaft 13 is formed to facilitate attachment and separation on the line (1).

Since the light emitting diodes 4 are attached to the lower side of the line 1, at least one or more sides of the light emitting diodes 4 are installed on the top, bottom, left and right sides of the main body 10 so that the approaching person can be quickly recognized in any direction.

The live indicator of the present invention configured as described above is coupled to the shaft 13 when the coupling piece 14 is placed in a state in which the spring 12 is compressed to open the two coupling pieces 14 to surround the line 1. The spring 13 is held by the two coupling pieces 14 stably surrounding the track 1 by the elastic force of the spring 13 so as to recognize the state of overload between the track 1 and the earth 2. do.

The impedance ZO is generated on the earth 2 side of the current collector plate 3 by the capacitance CO.

The impedance ZS due to the capacitance CS also occurs on the line 1 side of the current collector plate 3.

While power is applied to the line 1, voltage is generated at both ends of the current collector plate 3.

The 5V power generated by the line (1) side impedance (ZS) and the earth (2) side impedance (ZO) of the current collector plate 3 passes through the first forward diode (D2) or the capacitor (C1) and A plurality of light emitting diodes LED1 (LED2) ... (LEDn) 4 connected in parallel with the capacitor C2 via the reverse diode D1 are made to blink.

The light emitting diodes (LED1) (LED2) ... (LEDn) (4) are gun diodes which are oscillation elements connected between the ground-side current collector plate (1) and the distribution line-side current collector plate (2). The blinking period is determined according to the oscillation period of GD) and the charging period of the variable capacitor C3.

Therefore, a plurality of light emission formed to be exposed through the front and four sides of the main body 10 which is stably attached to the track 1 by the two coupling pieces 14 which are subjected to the elastic force of the spring 13 in the rear of the main body 10 Diodes (LED1) (LED2) ... (LEDn) (4) in a flashing state to inform the energized state of the high-voltage power supply flowing to prevent accidents such as electric shock.

As described in detail above, the live line indicator according to the present invention visually displays the energized state of supplying electricity to the single-phase distribution line through a plurality of light emitting diodes, and blinks at a cycle determined by the gun diode and the variable capacitor. By recognizing the state of electricity simply and quickly there is an effect that can prevent the electric shock accident in advance.

Claims (3)

In the live line indicator for recognizing the overcurrent state in the collector plate (3) provided between the line (1) and the ground (2), The reverse diode D1 is connected to the ground 2 side of the current collector plate 3 via a capacitor C1, On the line 1 side of the current collecting plate 3, a cathode of the reverse diode D1 is connected to a first forward diode D2 connected to the anode, The anode of the reverse diode D1 is connected to the cathode of the second forward diode D3 through the gun diode GD, A capacitor C2 and a plurality of light emitting diodes LED1 (LED2) ... (LEDn) are connected in parallel between the cathode of the first forward diode D2 and the anode of the second forward diode D3, A live line indicator characterized in that the variable capacitor C3 is connected to the cathode of the first forward diode D2 such that the ground-side current collector plate 1 and the distribution line-side current collector plate 2 are connected to each other. . The method of claim 1, The light emitting diodes (LED1) (LED2) ... (LEDn) (4) of the spring (12) at the end of the support (11) on the rear of the main body 10 is exposed through the front display (5) The live line indicator, characterized in that formed by forming two engaging pieces (14), one side of which is coupled to the shaft (13) while receiving elasticity. The method of claim 1, The light-emitting indicator, characterized in that the light emitting diode (4) is installed on the display unit (5) formed on the front of the main body (10), at least one of the light emission on the side of the top, bottom, left and right.

Images