KR101108499B1 - Leakage Current Remote Monitoring System for Streetlight - Google Patents

Abstract

Disclosed is a leakage current remote detection system for a street lamp. The remote leakage detection system of the present invention detects a resistive leakage current generated in a street light and displays the monitor so that an administrator can monitor it. The detection system of the present invention includes a controller installed for each street light, a server for managing the information provided by each controller and displaying it for the administrator to monitor, and a relay device for relaying the information provided by the plurality of controllers to the server. do. The controller measures the resistive leakage current by reading the value of Zero-phase Current Transformer (ZCT) when the instantaneous voltage of AC power is 0V.

Description

Leakage Current Remote Monitoring System for Street Light

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a street light leakage current remote detection system capable of detecting a resistance leakage current (Igr) that causes a human electric shock accident or the like in a street light or security, and monitoring the detection result.

Externally installed lighting devices such as street lighting or security lamps that illuminate the street are designed and maintained to be turned on and off at a set time by receiving AC power.

As lighting devices installed outside are exposed to the outside, or AC wires for power supply, leakage current may occur as the earth insulation deteriorates due to various factors, and such leakage current may cause not only malfunction of the device but also human body. Cause an accident such as electric shock.

On the other hand, the leakage current Ig is represented by a vector sum of the resistive leakage current Igr, the capacitive leakage current Igc, and the inductive leakage current Igl. The element that causes fire or electric shock by electric leakage is resistive leakage current (Igr). Inductive leakage current (Igl) is a negligible value in the line, and capacitive leakage current (Igc) may be a factor that causes device malfunction or inevitably occurs in the device.

Therefore, a situation where a safety problem actually arises and an administrator needs repair is when a resistive leakage current (Igr) is detected. However, the existing streetlight controller or the ground fault breaker operates by detecting the entire leakage current (Ig) using a zero-phase current transformer (ZCT) installed on the line, so that the resistive leakage current (Igr) and the capacitive The leakage current Igc could not be classified and processed. Accordingly, the method of collectively shutting off the power supply of the lighting device causes a problem that the lighting device is unnecessarily turned off, and requires unnecessary management by the manager.

Therefore, it is necessary to isolate and detect only the resistive leakage current Igr from the leakage current detected through the image current transformer, so that the breaker or the manager can cope only when the resistive leakage current Igr occurs.

In addition, when such a resistive leakage current (Igr) is detected, it is necessary not only to cut off the AC current but also to notify the manager so that immediate response is possible.

SUMMARY OF THE INVENTION An object of the present invention is to provide a street light leakage current remote detection system capable of detecting a resistance leakage current (Igr), which causes a human electric shock accident in a street light or security, and monitoring the detection result.

The leakage current remote detection system for achieving the above object, the resistance generated in the lighting device by using the image current transformer provided in the AC power supply line to control the blinking of the lighting device installed externally, and supply the AC power to the lighting device A controller for measuring the leakage current value, a server, and a repeater. Here, the relay device relays data communication between the plurality of controllers and the server.

The controller generates an alarm and provides the server to the server when the leakage current value exceeds a reference value, and the server stores the history of resistance leakage current provided by a plurality of controllers and receives the alarm while managing the history. Display the alert to the administrator.

According to an embodiment, the controller includes a zero voltage detector, a leakage current measurer, a communication interface, and a controller to measure the resistive leakage current.

The zero voltage detector generates a pulse having a rising edge when the instantaneous voltage of the AC power is 0 V, and the leakage current measurer generates an instantaneous value of the AC power according to a pulse generated by the zero voltage detector. The current value of the current transformer when the voltage is 0V is measured as the resistive leakage current value.

The communication interface unit provides the relay apparatus with the leakage current value measured by the leakage current measuring unit, and the controller controls the overall operation of the controller.

According to another embodiment, the zero voltage detector may include a step-down transistor for stepping down the AC power to a predetermined level, a full-wave rectifier for full-wave rectifying the step-down AC power including a bridge diode, and the output of the full-wave rectifier. A pulse generation unit for outputting a logic high pulse below a turn-on base voltage, including at least one transistor to be switched, and correcting a phase error included in an output of the pulse generation unit to correct the instantaneous voltage of the AC power supply. Compensation circuit for outputting a pulse having a rising edge (Edge) when the time is 0V.

The remote leakage current detecting system according to the present invention can substantially monitor and monitor whether a short circuit has occurred in an externally installed lighting device such as a street lamp, based on the result of detecting only a resistive leakage current without a capacitive leakage current. .

Therefore, the reliability of the electric leakage detection is secured, thereby solving the problem that the power supply of the street light is cut off or an administrator is dispatched due to a false alarm.

In addition, the controller of the detection system of the present invention minimizes the risk of malfunction by providing a relatively simple and accurate resistive leakage current detection method.

1 is a block diagram of a leakage current remote detection system for a street lamp according to an embodiment of the present invention;
2 is a block diagram of a controller included in the detection system of FIG.
3 is a detailed block diagram of the zero voltage detector of FIG. 2.

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in more detail with reference to the drawings.

Referring to FIG. 1, the leakage current remote detection system 100 for a street lamp of the present invention is connected to a controller 110 installed for each street lamp, security lamp, and other external lighting devices, and a plurality of controllers 110, 111, and 113. Including the relay device 130 and the server 150, and controls and monitors the street lighting, security and other external installation lighting devices. The relay device 130 and the server 150 may be connected through a wired or wireless Internet or other commercial network 170. Hereinafter, the street lamp 10 will be described as a representative of the external installation lighting device.

The controller 110 is installed in the street lamp 10, and basically controls the street lamp 10 to blink at a preset time. In addition, the controller 110 controls the operation of the street lamp 10 according to a control command of the server 150 received through the relay device 130.

The controller 110 measures the resistive leakage current Igr using the image current transformer ZCT installed in the AC power line 20 for supplying AC power to the street lamp 10, and measures the measured leakage current value of the relay device. 130 to the server 150 through. In addition, when the measured leakage current value exceeds a predetermined reference value, the controller 110 provides a corresponding alarm to the server 150 and at the same time blocks supply of AC power to prevent an accident. The resistive leakage current Igr measurement of the controller 110 will be described again below.

The relay device 130 is provided between the plurality of controllers 110 and the server 150 to relay the information provided by the plurality of controllers 110 to the server 150, and the server 150 provides the specific controller. The control command is relayed to the controller.

The server 150 is connected to the plurality of controllers 110 through the relay device 130 and controls and monitors the overall operation of the remote detection system 100. In detail, the server 150 receives the control command of the administrator and provides the controller 110 with the control command. The server 150 receives the information provided from the controller 110 and displays the information for the administrator to monitor. The information provided by the controller 110 to the server 150 may vary, but the present invention will be described based on the resistive leakage current value.

When the server 150 receives the resistive leakage current value from the specific controller 110 and manages the history, the server 150 may display the corresponding alarm to the manager when receiving the alarm from the controller 110.

According to an embodiment, when the controller 110 provides only a leakage current value without providing an alarm, the server 150 determines whether the leakage current value received from the controller 110 exceeds a predetermined criterion to the administrator. By displaying alarms, it is possible for the administrator to respond immediately.

Hereinafter, a method of measuring a leakage current value of the controller 110 will be described with reference to FIGS. 2 and 3.

Referring to FIG. 2, the controller 110 includes a zero voltage detector 210, a leakage current measurer 230, a communication interface 250, and a controller 270 to resistive resistance using an image current transformer (ZCT). The leakage current Igr value is measured and the result is provided to the server 150. The controller 110 may be connected to the server 150 to perform various operations, and of course may further include other additional components for such operations. However, hereinafter, the controller 110 will be described based on the configuration and operation of the leakage current measurement and monitoring.

In order to measure the resistive leakage current (Igr) value not including the capacitive leakage current (Igc), the controller 110 determines that the instantaneous value of the AC voltage provided to the street lamp 10 is 0 V. Measure the leakage current value as the resistance leakage current value. This is because the current measured at the instantaneous value of the voltage applied to the load includes only the resistive current from which the capacitive current is removed. Therefore, the controller 110 detects a point where the instantaneous value of the AC voltage input to the street light 10 is 0V and measures the leakage current at the corresponding point of time using the image current transformer ZCT.

The zero voltage detector 210 detects a time point when the instantaneous value of the AC voltage applied to the street light 10 is 0V by receiving AC power, generates a pulse synchronized with the corresponding time point, and provides the same to the leakage current measurement unit 230. .

The zero voltage detector 210 may detect a time point when the instantaneous value of the AC voltage is 0 V in various ways. For example, as illustrated in FIG. 3, the zero voltage detector 210 includes a transformer 301 for stepping down an input AC voltage to a predetermined level and an AC stepped down by a transformer 301 including a bridge diode. It may include a full-wave rectifier 303 for full-wave rectifying the voltage, and a pulse generator 305 for outputting a pulse having a rising edge at zero voltage by using the output of the full-wave rectifier 303.

For example, the pulse generator 305 is switched according to the full-wave rectified voltage in the full-wave rectifier 303 to generate a pulse that is logic high at a turn-on base voltage (about 0.7 V) or more. And a first npn transistor and a second npn transistor for inverting the output of the first npn transistor. In this case, the zero voltage detector 210 outputs a logic high pulse when the full-wave rectified voltage is equal to or lower than the turn-on base voltage of the transistor.

Therefore, since the pulse signal generated by the pulse generator 305 of FIG. 3 is not a pulse having a rising edge when the instantaneous voltage of the AC power supply is 0V, the signal is advanced in phase by 0.7V, which is the turn-on base voltage of the transistor. The zero voltage detector 210 may further include a compensation circuit 211 that compensates for the phase error by delaying the phase of the pulse signal by a corresponding portion. The compensation circuit 211 compensates the phase error by delaying the phase of the pulse signal by simply adjusting the time constant by using a resistor-capacitor integrating circuit, where the instantaneous value of the power supply voltage is 0V. Can generate a rising pulse signal at. The value of the capacitor is fixed and the resistance is adjusted using a variable resistor.

The leakage current measuring unit 230 reads the measured value of the image current transformer ZCT at the rising edge of the pulse provided by the zero voltage detector 210 and measures the resistance leakage current Igr value, and a measuring device ( An analog-to-digital converter (233) for converting the value measured at 231 to a digital value, and a comparator (235) for comparing the output of the AD converter 233 with a predetermined reference value. Here, the reference value may correspond to a leakage current value that is the target of the alarm.

The communication interface 250 is connected to the relay device 130 to transmit data to the relay device 130 or to provide the controller 270 with data transmitted by the relay device 130. Accordingly, the communication interface 250 transmits the leakage current value measured by the leakage current measuring unit 230 to the relay device 130 under the control of the controller 270.

The controller 270 controls the overall operation of the controller 110 and is connected to the relay device 130 through the communication interface 250 to transfer various information of the controller 110 to the server 150, and the server ( The component inside the controller 110 is controlled to perform an operation according to a control command provided from 150. In particular, by providing the resistance leakage current value measured by the leakage current measuring unit 230 to the relay device 130 to enable the monitoring of the server 150.

The controller 270 determines whether the leakage current value is an alarm issuing object based on the output of the comparator 235, and when the alarm is an alarm issuing object, the controller 150 transmits a predetermined alarm to the server 150 through the communication interface 250. Can be provided to

According to an exemplary embodiment, the controller 110 may further include a circuit breaker 290 that blocks supply of AC power to the street lamp 10 when the resistance leakage current value exceeds the reference value in association with the comparison result of the comparator 235. It may include.

The controller 110 measures the resistive leakage current value that does not include the capacitive leakage current, thereby allowing the server 150 or the administrator to accurately monitor whether a short circuit has actually occurred, and furthermore, in the case of an actual short circuit. By shutting off the power supply, the oboe streetlight can be powered off or prevented from running by the manager.

Although the above has been illustrated and described with respect to preferred embodiments of the present invention, the present invention is not limited to the above-described specific embodiments, it is usually in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (3)

Controlling the flashing of the lighting device installed outside, measuring the resistance leakage current generated in the lighting device by using an image current transformer provided on the AC power line for supplying AC power to the lighting device, the leakage current value is a reference value A controller for generating an alarm if exceeded;
A server displaying the alarm to an administrator when receiving the alarm from the controller while storing and managing the resistance leakage current values provided by the plurality of controllers; And
A relay device for relaying data communication between the plurality of controllers and the server,
The controller,
A zero voltage detector configured to generate a pulse having a rising edge when the instantaneous voltage of the AC power is 0V;
A leakage current measuring unit measuring a current value of the current transformer when the instantaneous voltage of the AC power is 0 V according to the pulse generated by the zero voltage detector;
A communication interface unit providing the relay device with a leakage current value measured by the leakage current measuring unit; And
And a control unit for controlling the overall operation of the controller.
delete The method of claim 1,
The zero voltage detection unit,
A step-down transistor for stepping down the AC power supply to a predetermined level;
A full-wave rectifier including a bridge diode for full-wave rectifying the stepped AC power;
A pulse generation unit including at least one transistor switched according to an output of the full-wave rectifying unit, and outputting a pulse having a logic high below a turn-on base voltage; And
And a compensation circuit for correcting a phase error included in the output of the pulse generator to output a pulse having a rising edge when the instantaneous voltage of the AC power supply is 0V.

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