KR200497902Y1 - voltage detector - Google Patents

Abstract

The present invention relates to a hanger-type ultra-high pressure mold-type flash indicator.
The incoming and overhead ground lines for supplying high-voltage power of 30KV to 765KV and the distribution facility lines of the substation are hung on elastic pieces, and the support wires are installed between the supports to receive elasticity from a single coil spring, making installation simple and live wire. Make it possible to install it in the city,
A printed circuit board in which the first charging part in which the capacitance of the charging part is induced and the second charging part in which the capacitance of the ground is derived is integrated into the mold, so that it can be used indoors and outdoors,
A first cover is formed on the upper part of the light emitting part, which is located at the bottom of the mold and indicates whether electricity is supplied through the blinking state of a plurality of high-brightness light emitting diodes, to protect the light emitting part from direct sunlight, and a second cover is formed on the bottom of the outer surface. It is designed so that the light from the emitting part is clearly visible without being spread out too much.

Description

Hanger-type ultra-high pressure mold-type flash indicator {voltage detector}

The present invention relates to a hanger-type ultra-high-voltage mold-type flashing indicator, and specifically, in an energized state or when electricity is not supplied to the incoming and overhead branch lines for supplying high-voltage power of 30KV to 765KV and the distribution facility line of the substation. This relates to a hanger-type ultra-high-voltage mold-type flash indicator that displays the no-voltage state by blinking like a flash through a high-brightness LED to recognize the power supply status at once and prevent accidents due to electric shock.

In general, electric energy is the most widely used because it is pollution-free and easy to use, and it is a well-known fact that electric energy generated mainly by power plants using hydropower, thermal power, or nuclear power is supplied to various users through lines.

And since the process of supplying electricity from the power plant to each user is complex and the length of the line is very long, accidents occur frequently and construction for repair or replacement of the line is continuously carried out, so it is easy to touch the line while it is energized. It caused personal injury due to electric shock.

Therefore, there is a need for a device to visually indicate whether a device such as a circuit breaker or a distribution line is in an energized state or a no-voltage state in which electricity is not supplied.

Therefore, in the past, there is an overcharge display method that displays by directly connecting to the high-voltage charging unit, and an overcharge display method that displays by installing a high-voltage side current collector and using the capacitance between the high-voltage side current collector and the high-voltage charging section, and also displays the generated voltage. A display method in which the liquid crystal device is directly applied to the liquid crystal device and a display method in which various driving circuits are installed at the front of the liquid crystal device to display a blinking display or an alternating display were used.

Figure 1 is a schematic diagram showing the operation process of a general overcharge indicator, showing the capacitance (CS) between the high-voltage charging unit (1) and the high-voltage side current collector (2), and the electrostatic capacity between the ground (3) and the ground side current collector (4). In the case of capacitance (CO), the impedance (ZS) of the capacitance (CS), the impedance (ZL) of the overcharge indicator (5), and the impedance (ZO) of the capacitance (CO) are generated,

where impedance (ZS) = 1 / wCS,

There is a relationship of impedance (ZO) = 1 / wCO.

In this state, when the voltage (VO) is applied between the high-voltage charging unit (1) and the ground (3), the voltage (VL) is applied between the high-voltage side current collector (2) of the overcharge indicator (5) and the ground side current collector (4). This happens,

It has the value of voltage (VL) = ZL * Vo / (ZS + ZL + ZO).

Since this voltage (VL) is applied to the display unit 7 through the driving circuit 6, the display unit 7 lights up so that it can be recognized that it is in an energized state where electricity is being supplied.

However, with the conventional overcharge indicator as described above, the voltage (VL) that lights up the display unit 7 via the driving circuit 6 is about 5V, so the overcharge indicator 5 must be carefully inspected to determine the lighting state of the display unit 7. Not only can you check, but depending on the state in which the overcharge indicator is attached to the device or distribution line, the capacitance (Cs) increases and the impedance (Zs) decreases, which further deteriorates the display state of the display unit (7). There was a disadvantage in that a state occurred that could not be confirmed.

Accordingly, Registered Utility Model Publication No. 0121859 (overcurrent current indicator) was proposed by the present applicant,

As shown in Figure 2,

In the over-current indicator, which detects the voltage according to the current by placing two current collector plates (12) and (14) between the high-voltage charging unit (11) and the ground (13),

A rectifier and filter unit (17) that allows the detected AC power to pass through constant voltage diodes (ZD1) (ZD2), diode (D1), and condenser (C1),

An EL display unit (15) in which the EL lamp (16) is turned on by the above-mentioned AC power supply to enable identification at night,

A counter unit 18 of the counter 19 that receives the AC power as a clock signal and outputs it as a pulse signal with an arbitrarily set frequency;

A dividing unit 20 of the divider 21 that receives the pulse signal from the counter unit 18 as a trigger signal and receives the AC power as a driving power and outputs a divided pulse signal;

It is composed of a TN liquid crystal device (23) that blinks according to the pulse signal from the dividing unit (20) and can be identified during the day.

However, with the conventional overcharge indicator as described above, the overcharge status is recognized and displayed through a current collector installed between the high-voltage charging unit and the ground. However, even when used for power supplied for low-voltage three-phase use, the overcharge status is displayed on each line. There was the inconvenience of having to install them one by one separately.

In general, electric energy is the most widely used because it is pollution-free and easy to use, and it is a well-known fact that electric energy generated mainly by power plants using hydropower, thermal power, or nuclear power is supplied to various users through lines.

And since the process of supplying electricity from the power plant to each user is complex and the length of the line is very long, accidents occur frequently and construction for repair or replacement of the line is continuously carried out, so it is easy to touch the line while it is energized. It caused personal injury due to electric shock.

Therefore, there is a need for a device to visually indicate whether a device such as a circuit breaker or a distribution line is in an energized state or a no-voltage state in which electricity is not supplied.

Therefore, in the past, there is an overcharge display method that displays by directly connecting to the high-voltage charging unit, and an overcharge display method that displays by installing a high-voltage side current collector and using the capacitance between the high-voltage side current collector and the high-voltage charging section, and also displays the generated voltage. A display method in which the liquid crystal device is directly applied to the liquid crystal device and a display method in which various driving circuits are installed at the front of the liquid crystal device to display a blinking display or an alternating display were used.

Figure 1 is a schematic diagram showing the operation process of a general overcharge indicator, showing the capacitance (CS) between the high-voltage charging unit (1) and the high-voltage side current collector (2), and the electrostatic capacity between the ground (3) and the ground side current collector (4). In the case of capacitance (CO), the impedance (ZS) of the capacitance (CS), the impedance (ZL) of the overcharge indicator (5), and the impedance (ZO) of the capacitance (CO) are generated,

where impedance (ZS) = 1 / wCS,

There is a relationship of impedance (ZO) = 1 / wCO.

In this state, when the voltage (VO) is applied between the high-voltage charging unit (1) and the ground (3), the voltage (VL) is applied between the high-voltage side current collector (2) of the overcharge indicator (5) and the ground side current collector (4). This happens,

It has the value of voltage (VL) = ZL * Vo / (ZS + ZL + ZO).

Since this voltage (VL) is applied to the display unit 7 through the driving circuit 6, the display unit 7 lights up so that it can be recognized that it is in an energized state where electricity is being supplied.

However, with the conventional overcharge indicator as described above, the voltage (VL) that lights up the display unit 7 via the driving circuit 6 is about 5V, so the overcharge indicator 5 must be carefully inspected to determine the lighting state of the display unit 7. Not only can you check, but depending on the state in which the overcharge indicator is attached to the device or distribution line, the capacitance (Cs) increases and the impedance (Zs) decreases, which further deteriorates the display state of the display unit (7). There was a disadvantage in that a state occurred that could not be confirmed.

Accordingly, Registered Utility Model Publication No. 0121859 (overcurrent current indicator) was proposed by the present applicant,

As shown in Figure 2,

In the over-current indicator, which detects the voltage according to the current by placing two current collector plates (12) and (14) between the high-voltage charging unit (11) and the ground (13),

A rectifier and filter unit (17) that allows the detected AC power to pass through constant voltage diodes (ZD1) (ZD2), diode (D1), and condenser (C1),

An EL display unit (15) in which the EL lamp (16) is turned on by the above-mentioned AC power supply to enable identification at night,

A counter unit 18 of the counter 19 that receives the AC power as a clock signal and outputs it as a pulse signal with an arbitrarily set frequency;

A dividing unit 20 of the divider 21 that receives the pulse signal from the counter unit 18 as a trigger signal and receives the AC power as a driving power and outputs a divided pulse signal;

It is composed of a TN liquid crystal device (23) that blinks according to the pulse signal from the dividing unit (20) and can be identified during the day.

However, with the conventional overcharge indicator as described above, the overcharge status is recognized and displayed through a current collector installed between the high-voltage charging unit and the ground. However, even when used for power supplied for low-voltage three-phase use, the overcharge status is displayed on each line. There was the inconvenience of having to install them one by one separately.

The hanger-type ultra-high pressure mold-type flash indicator of the present invention to achieve the above purpose,

It should be installed on the incoming and processing branch lines to supply high-voltage power of 30KV to 765KV and the distribution facility line of the substation.

A hanger with an elastic piece for hanging on a high-voltage wire for 30KV to 765KV and a support for installing on a support wire, which is easy to install and can be installed even when the wire is live, and is mounted on a single coil spring.

A first charging part in which the capacitance of the charging part is induced and a second charging part in which the electrostatic capacitance of the ground is induced are integrated, and the generation of induced voltage due to the accumulation of the electrostatic capacitance of the charging part and the ground is detected by the state of the current collector to determine whether the current is energized. A mold on which a printed circuit board is mounted at the bottom of the hanger,

A light emitting unit located at the bottom of the mold that indicates whether or not electricity is energized through the blinking state of a plurality of high-brightness light emitting diodes;

A first cover made of silicone that is positioned on the top of the outer surface of the light emitting unit and protects the light emitting unit from direct sunlight;

It is composed of a second cover that extends upward and downward from the bottom of the outer surface of the light emitting unit so that the light of the light emitting unit is clearly visible without being spread too far.

According to the hanger-type ultra-high-voltage mold-type flashing indicator according to the present invention, the incoming and overhead branch lines for supplying high-voltage power of 30KV to 765KV and the distribution facility lines of the substation are hung on elastic pieces and the support wires are installed between the supports. By receiving elasticity from a single coil spring, installation is easy and installation is possible even when the wire is live.

A printed circuit board in which the first charging part in which the capacitance of the charging part is induced and the second charging part in which the capacitance of the ground is derived is integrally formed in a mold, so that it can be used indoors and outdoors,

A first cover is formed on the upper part of the light emitting part, which is located at the bottom of the mold and indicates whether electricity is supplied through the blinking state of a plurality of high-brightness light emitting diodes, to protect the light emitting part from direct sunlight, and a second cover is formed on the bottom of the outer surface. It has the effect of allowing the light from the emitting part to be seen clearly without spreading too much.

Figure 1 is a schematic diagram showing the operation process of a typical conventional overcharge indicator.
Figure 2 is a circuit diagram showing the configuration of a conventional over-current indicator.
Figure 3 is a front view showing the overall configuration of the present invention.
Figure 4 is a perspective view showing the configuration of the hanger of the present invention.
Figure 5 is a bottom view of the present invention.
Figure 6 is a circuit diagram showing the internal configuration of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings.

Figures 3 to 5 show the external configuration of the hanger-type ultra-high pressure mold-type flashing indicator according to the present invention,

It should be installed on incoming and overhead ground lines to supply high-voltage power of 30KV to 765KV and high-voltage lines that are distribution facility lines of substations.

The elastic piece (41) for hanging the energization indicator body (30) on the high-voltage wire (31) for 30KV to 765KV and the support span (42) for installing it on the support wire (32) are mounted on one coil spring (43). A hanger (40) that is easy to install and can be installed even when the wire is live,

A mold 50 located at the bottom of the hanger 40 and detecting whether electricity is supplied by the generation of induced voltage due to the accumulation of the capacitance of the charging part and the capacitance of the ground as the capacitance of the charging part is induced and the capacitance of the ground is induced;

A light emitting unit (60) located at the bottom of the mold (50) that indicates whether or not electricity is supplied by flashing a plurality of high-brightness light emitting diodes (61);

A first cover 70 made of silicone located on the top of the outer surface of the light emitting unit 60 and protecting the light emitting unit 60 from direct sunlight;

It is composed of a second cover 80 that extends upward and downward from the bottom of the outer surface of the light emitting unit 60 so that the light of the high-brightness light emitting diode 61 is clearly visible without being spread too far.

Figure 6 shows the configuration of the printed circuit board and light emitting unit built into the mold of the present invention,

A first charging unit 91 where the capacitance of the charging unit is induced from the high-voltage wire 31 for 30KV to 765KV on which the hanger 40 is hung through the elastic piece 41, and a second charging unit 92 where the capacitance of the ground is induced. It is provided integrally to detect the generation of induced voltage due to accumulation of electrostatic capacitance of the charging part and the ground by the state of the current collector 90, and whether or not electricity is supplied,

In the rectifier and filter unit 93, which receives the alternating current induced voltage detected by the current collector 90, the rated voltage is supplied to the next divider 95 as operating power through the constant voltage diode (ZD1). do,

The neutral wire, which is connected to the first charging unit 91 through the constant voltage diode (ZD2) and to the second charging unit 92 via the constant voltage diode (ZD3), is connected to the condenser C1 and the two diodes D1 and D2. The direct current power rectified by full wave is supplied in a stable state to the next divider (95) through the condenser (C11),

The counter 94, which receives the above AC voltage as a clock signal, outputs it as a randomly determined input pulse,

The divider 95, which receives the half-wave direct current power from the rectifier and filter unit 93 as the driving power and receives the input pulse from the counter 94 unit as a trigger signal, converts it to 1/24 to 1/25. Make it busy and print it out.

The DC power divided from the divider 35 is configured to cause a plurality of high-brightness light-emitting diodes 61 of the light emitting unit 60 to blink to indicate whether electricity is supplied.

Here, the blinking cycle of the high-brightness light-emitting diode 61 is determined by the charging capacity of the condenser C11.

The hanger-type ultra-high-voltage mold-type flashing indicator of the present invention, constructed as described above, is intended to be installed on incoming and overhead wires for supplying high-voltage power of 30KV to 765KV and high-voltage wires that are distribution equipment lines of substations,

The elastic piece (41) for hanging the energization indicator body (30) on the high-voltage wire (31) for 30KV to 765KV and the support span (42) for installing it on the support wire (32) are one coil spring of the hanger (40). It is mounted on (43) so that installation is easy and installation is possible even when the wire is live.

As the capacitance of the charging part is induced in the lower mold 50 of the hanger 40, the capacitance of the ground is induced, and the presence of electricity is detected by generating an induced voltage due to the accumulation of the capacitance of the charging part and the ground capacitance.

The printed circuit board embedded in the mold 50 includes a first charging unit 91 through which the charging unit capacitance is induced from the high-voltage wire 31 for 30KV to 765KV on which the hanger 40 is hung, through the elastic piece 41, and The second charging unit 92, in which the electrostatic capacitance of the ground is induced, is provided integrally, so that the generation of induced voltage due to the accumulation of the electrostatic capacitance of the charging unit and the ground is detected by the state of the current collector 90 to determine whether or not the current is energized.

In the rectifier and filter unit 93, which receives the alternating current induced voltage detected by the current collector 90, the rated voltage is supplied to the next divider 95 as operating power through the constant voltage diode (ZD1). do.

The neutral wire, which is connected to the first charging unit 91 through the constant voltage diode (ZD2) and to the second charging unit 92 via the constant voltage diode (ZD3), is connected to the condenser C1 and the two diodes D1 and D2. The full-wave rectified direct current power is supplied in a stable state to the next divider (95) through the condenser (C11).

The counter 94, which receives the above AC voltage as a clock signal, outputs it as a randomly determined input pulse.

The divider 95, which receives the half-wave direct current power from the rectifier and filter unit 93 as the driving power and receives the input pulse from the counter 94 unit as a trigger signal, converts it to 1/24 to 1/25. Divide and print.

The DC power divided from the divider 35 causes the plurality of high-brightness light-emitting diodes 61 of the light emitting unit 60 to blink to indicate whether or not electricity is running.

Here, the blinking cycle of the high-brightness light-emitting diode 61 is determined by the charging capacity of the condenser C11.

The light emitting unit 60 is located at the bottom of the mold 50 and indicates whether or not electricity is supplied by blinking a plurality of high-brightness light emitting diodes 61.

The first cover 70 made of silicone and positioned on the top of the outer surface of the light emitting unit 60 in an upward and downward light pattern protects the light emitting unit 60 from direct sunlight.

The second cover 80, which extends upward and downward from the bottom of the outer surface of the light emitting unit 60, allows the light of the high-brightness light emitting diode 61 to be clearly visible without being spread too far.

In the above, preferred embodiments of the present invention have been shown and described, but the present invention is not limited to the above-described embodiments, and can be used in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Anyone with knowledge can make various modifications, and such modifications are within the scope of the claimed claims.

30: Energization indicator body 31: High-voltage wire
32: support wire 40: hanger
41: elastic piece 42: support section
43: coil spring 50: mold
60: light emitting unit 61: high brightness light emitting diode
70: first cover 80: second cover

Claims (1)

It should be installed on incoming and overhead ground lines to supply high-voltage power of 30KV to 765KV and high-voltage lines that are distribution facility lines of substations.
The elastic piece (41) for hanging the energization indicator body (30) on the high-voltage wire (31) for 30KV to 765KV and the support span (42) for installing it on the support wire (32) are mounted on one coil spring (43). A hanger (40) that is easy to install and can be installed even when the wire is live,
A mold 50 located at the bottom of the hanger 40 and detecting whether electricity is supplied by the generation of induced voltage due to the accumulation of the capacitance of the charging part and the capacitance of the ground as the capacitance of the charging part is induced and the capacitance of the ground is induced;
A light emitting unit (60) located at the bottom of the mold (50) that indicates whether or not electricity is supplied by flashing a plurality of high-brightness light emitting diodes (61);
A first cover 70 made of silicone located on the top of the outer surface of the light emitting unit 60 and protecting the light emitting unit 60 from direct sunlight,
A hanger-type ultra-high pressure mold, characterized in that it is composed of a second cover 80 that extends upward and downward from the bottom of the outer surface of the light emitting unit 60 so that the light of the high-brightness light emitting diode 61 is clearly visible without being spread too far. Expression flash indicator.