KR20120091778A - Monitering apparatus and monitering method for street furnitures - Google Patents

Abstract

PURPOSE: An apparatus and a method for monitoring street equipment are provided to measure an induced electromotive force using electric current supplied to a street light lamp regardless of peripheral circumstances. CONSTITUTION: An apparatus for monitoring a street light comprises a street light lamp(1) which emits lights with the power supplied from a street light, a monitoring unit(10) including a cable(101) for supplying power to the street light lamp and a coil crossing the cable, a measuring unit(20) which measures the intensity of an induced electromotive force transmitted from the monitoring unit, and a determining unit(30) which determines the lighting condition of the street light lamp by comparing the intensity of the induced electromotive force, delivered from the measuring unit, with a reference induced electromotive force.

Description

Street facility monitoring device and street facility monitoring method {MONITERING APPARATUS AND MONITERING METHOD FOR STREET FURNITURES}

The present invention relates to a street facility monitoring device and a street facility monitoring method, and more particularly, a street lamp monitoring device and street lamp for monitoring whether the street lamp lamp is actually lit by measuring the induced electromotive force generated from the current supplied to the street lamp lamp It relates to a lamp monitoring method.

In the residential area of humans, a number of street lamps are installed to facilitate night activities, and these street lamps are managed to maintain good operating conditions.

In order to solve the problem that the conventional maintenance personnel manually supply the street lamps and visually judge the illuminance of the street lamps, the maintenance personnel can not only supply the street lamps from a remote place but also determine the operation status of the street lamps. Patent Application No. 1998-8880, Patent Application No. 2006-62976 and the like have been proposed.

The conventional street lamp monitoring method is configured to detect a state physical quantity indicating the operation state of the street lamp through a sensor installed in the street lamp, and transmit the detected state physical quantity to a street lamp lamp monitoring system installed remotely through a predetermined data communication network. It is.

However, the conventional optical sensor was used as a means for monitoring the lighting of the street lamp. In this case, even when the street lamp is turned off, when the environment around the street lamp is bright, the sensor may determine that the light is received by the light sensor and the lamp is turned on. If there is foreign matter such as dust or frost on the light receiving part of the optical sensor, the sensor judges that the lamp is turned off because the light does not enter the light receiving part of the sensor even though the lamp is turned on.

In addition, a thermal sensor was used as a means for monitoring the lighting of a conventional street lamp. In this case, when the temperature around the sensor is high due to the weather, even if the lamp is turned off, the sensor judges that the lamp is on, or the temperature of the environment around the lamp is low even though the lamp is on. There was a problem such that the sensor determines that the lamp lamp is off.

The present invention is to solve the above problems, an object of the present invention is to measure the induced electromotive force by the current supplied to the street lamp lamp irrespective of the environment surrounding the street lamp to monitor whether the street lamp lamp is actually turned on or off For sake.

In order to achieve the above object, the horizontal facility monitoring apparatus according to the present invention, the induction is connected to the coil and the coil generating the induced electromotive force by the current flowing in the conductive wire, and intersects the conductive wire flowing the current supplied to the street lamp A monitoring unit including an electromotive force terminal; And a measurement unit connected to the induction electromotive force terminal to measure a magnitude of the induction electromotive force provided from the induction electromotive force terminal.

In addition, the horizontal facility monitoring apparatus according to the present invention includes a determination unit for determining whether the street lamp lamp is turned on by comparing the magnitude of the induced electromotive force measured by the measurement unit with the size of the predetermined reference induced electromotive force.

 In addition, the street facility monitoring apparatus according to the present invention includes at least two street lamps, one monitoring unit monitors the induced electromotive force generated by the current flowing in the conductive wires supplied to each street lamp.

In addition, the horizontal facility monitoring method according to the present invention comprises the steps of monitoring the generation of induced electromotive force by the current flowing in the conductive wire to the coil crossing the conductive wire flowing current supplied to the street lamp; Measuring the magnitude of the induced electromotive force; And comparing the measured induced electromotive force with a preset reference induced electromotive force to determine whether the street lamp is turned on or off.

As described above, the street lamp monitoring apparatus according to the present invention measures the induced electromotive force generated by the current flowing in the street lamp in the measuring unit and transmits the measured magnitude of induced electromotive force to the determination unit, and the determination unit turns on the street lamp. By comparing the reference induced electromotive force, which is an induced electromotive force when it is measured, with the measured induced electromotive force, it is possible to determine whether the lamp lamp is turned on or off regardless of the environment change around the street lamp.

In addition, even when there are a plurality of street lamps, the measurement unit measures the sum of induced electromotive force generated by the plurality of lamps and transmits the measured magnitude of induced electromotive force to the determination unit, and the determination unit is the induced electromotive force when the street lamp is turned on. By comparing the reference induced electromotive force with the measured induced electromotive force, it may be determined whether the street lamp is turned on or off regardless of the change in the environment around the street lamp.

In addition, in the case where there are a plurality of street lamps and a monitoring unit, since the monitoring unit is provided for each street lamp, it is possible to determine which street lamp among the plurality of street lamps is turned on or off regardless of the change in the environment around the street lamp.

1 is a view schematically showing the shape of a general street lamp in which the lamp lamp monitoring apparatus according to an embodiment of the present invention is installed.
2 is a block diagram of a street lamp in which a street lamp monitoring apparatus according to an embodiment of the present invention is installed.
3 is a diagram illustrating a monitoring unit of a street lamp monitoring device.
4 is a block diagram of a street lamp in which a street lamp monitoring apparatus including a plurality of street lamps is installed according to an embodiment of the present invention.
FIG. 5 is a block diagram of a street lamp provided with a plurality of street lamps and a street lamp monitoring apparatus including a plurality of monitors according to an exemplary embodiment.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter will be described in detail to enable those skilled in the art to easily understand and reproduce through this embodiment of the present invention.

1 is a view schematically showing the shape of a general street lamp in which the lamp lamp monitoring apparatus according to an embodiment of the present invention is installed. Hereinafter, a street lamp monitoring apparatus according to an embodiment of the present invention will be described with reference to FIG. 1.

Street light lamp monitoring device of the present invention includes a street lamp (1), the monitoring unit 10, the measuring unit 20, the determination unit 30.

According to Figure 1, the street lamp (1) is installed in the street lamp is a lamp that emits light by receiving power may be used a variety of lamps such as halogen, sodium, neon, LED.

The monitoring unit 10 includes a conductive wire 101 for supplying power to the street lamp 1, and a coil 201 intersecting the conductive wire 101, wherein the coil includes a current flowing through the street lamp 1. Induced electromotive force occurs.

The induced electromotive force generated by the monitoring unit 10 is transmitted to the measuring unit 20.

The measuring unit 20 measures the magnitude of induced electromotive force generated by the monitoring unit 10.

The magnitude of the induced electromotive force measured by the measuring unit 20 is transmitted to the determining unit 30.

The determination unit 30 compares the measured value of the induced electromotive force measured by the measurement unit 20 with the reference induced electromotive force to determine whether the street light lamp 1 is turned on.

1 illustrates the measurement unit and the determination unit in separate configurations, but may be designed in one configuration as necessary.

A process of determining whether the streetlight lamp 1 is turned on by the determination unit 30 will be described later.

2 is a block diagram of a street lamp in which a street lamp monitoring apparatus according to an embodiment of the present invention is installed. Hereinafter, an operation performed in a street lamp monitoring apparatus according to an embodiment of the present invention will be described in detail with reference to FIG. 2.

According to Figure 2, the street lamp (1) is installed in the street lamp is a lamp that is supplied with power to emit light may be used a variety of lamps such as halogen, sodium, neon, LED.

The monitoring unit 10 includes a conductive wire 101 for supplying power to the street lamp 1, and a coil 201 intersecting the conductive wire 101, wherein the coil includes a current flowing through the street lamp 1. Induced electromotive force occurs.

A coil 201 intersecting the conductive wire 101 for supplying power to the street lamp 1 is included therein. When AC power flows through the street lamp 1, induced electromotive force is generated in the coil 201 intersected with the conductive wire 101 by an electromagnetic induction phenomenon as the current flowing in the conductive wire 101 changes.

The measurement unit 20 measures the magnitude of induced electromotive force generated by the monitoring unit 10 and transmits the measured value to the determination unit 30.

The determination unit 30 compares the measured value of the induced electromotive force measured by the measurement unit 20 with the reference induced electromotive force to determine whether the street light lamp 1 is turned on.

The determination unit 30 uses the magnitude of the induced electromotive force generated corresponding to the current required to turn on the street light lamp 1 as the reference induced electromotive force, so that the measured value transmitted from the measurement unit 20 is within an error range of the reference induced electromotive force. In this case, it is determined that the lamp lamp 1 is turned on.

The user may determine whether the street light lamp 1 is turned on or off by looking at the determiner 30, and the measuring unit 20 and the determiner 30 may be connected by wire or wireless to monitor the street light at a long distance. have.

Hereinafter, the determination unit 30 will be described by taking an example where the street lamp 1, the monitoring unit 10, and the measuring unit 20 are each one of the reference values.

When the street lamp 1 is turned off, the induced electromotive force generated in the coil 201 by the current for driving the monitoring unit 10 is referred to as 0.1 mA, and the induced electromotive force when the street lamp 1 is turned on. Assume that the size of 1mA. When the measured value is less than 0.05mA, the determination unit 30 determines that the street light lamp 1 is turned off. If the measured value is within an error range of 0.95 mA to 1.05 mA, the determination unit 30 determines the street light lamp ( It is judged that 1) is lit.

3 is a schematic diagram of a monitoring unit 10 according to an embodiment of the present invention.

Hereinafter, a street lamp monitoring apparatus according to an embodiment of the present invention will be described with reference to FIG. 3.

According to Figure 3, the street lamp (1) is installed in the street lamp is a lamp that is supplied with power to emit light may be used a variety of lamps such as halogen, sodium, neon, LED.

The monitoring unit 10 is a coil 201 and the induced electromotive force generated by the electric current flowing through the conductive wires 101 and crossing the conductive wires 101 in a case made of a material in which no electricity such as plastic or rubber flows. It consists of an induction electromotive force terminal 202 connected with the generated coil 201.

Of course, the monitoring unit 10 may include a conductive wire 101 through which a current supplied to the street lamp 1 flows.

When AC power flows into the street lamp 1 through the monitoring unit 10, induced electromotive force is generated in the coil 201 and the induced electromotive force flows to the determination unit 30 through the induced electromotive force terminal 202. .

In one embodiment of the present invention, since the induced electromotive force by AC power is not necessarily generated when the conductive wire 101 and the coil 201 are orthogonal to each other, a person having ordinary knowledge in the art to which the present invention pertains to the conductive wire ( The monitoring unit 10 having various shapes by varying the crossing angle of the 101 and the coil 201, changing the position by making the conductor 101 and the coil 201 parallel, or varying the number of times the coil is wound. The present invention will be able to be implemented.

4 is a block diagram of a street lamp system in which a plurality of street lamps 1, one monitoring unit 10, and a measuring unit 20 are installed according to an embodiment of the present invention.

Hereinafter, an operation of performing the apparatus for monitoring a street lamp 1 according to an embodiment of the present invention will be described in detail with reference to FIG. 4.

According to Figure 4, the street lamp (1) is installed in the street lamp is a lamp that is supplied with power to emit light may be used a variety of lamps such as halogen, sodium, neon, LED.

The monitoring unit 10 includes a conductive wire 101 for supplying power to the street lamp 1, and a coil 201 intersecting the conductive wire 101, wherein the coil includes a current flowing through the street lamp 1. Induced electromotive force occurs.

The measuring unit 20 measures the magnitude of induced electromotive force generated by the monitoring unit 10.

The determination unit 30 compares the measured value of the induced electromotive force measured by the measurement unit 20 with the reference induced electromotive force to determine whether the street light lamp 1 is turned on.

As described above, when there are a plurality of street lamps 1, the monitoring unit 10 intersects the conductive wire 101 through which current supplied to the street lamps 1-1 to 1-n flows to the lamps 1-1. And induction electromotive force terminals 202 connected to the coil 201 generating the induced electromotive force due to the current flowing through the conductive wire 101 of FIGS.

 When AC power flows through each of the street lamps 1-1 to 1-n, the coil 201 intersects with each of the conductive wires 101 by an electromagnetic induction phenomenon as the current flowing through the conductive wires 101 changes. ), Induced electromotive force is generated.

The measurement unit 20 measures each induced electromotive force and transmits the measured value to the determination unit 30.

The determination unit 30 measures each induced electromotive force by using the sum of the magnitudes of each induced electromotive force generated corresponding to the current required to light up the plurality of street lamps 1-1 to 1-n as the reference induced electromotive force. When the total measured value is within the error range of the reference induced electromotive force, it is determined that all the street lamps 1 are turned on.

The user may determine whether the street light lamp 1 is turned on or off by looking at the determiner 30, and the measuring unit 20 and the determiner 30 may be connected by wire or wireless to monitor the street light at a long distance. have.

Hereinafter, the determination unit 30 will be described taking an example in which the street lamp 1 and the monitoring unit 10 are three at the reference value. When all the lamp lamps 1 are turned off, it is assumed that the magnitude of induced electromotive force generated in the coil 201 by the current for driving the monitoring unit 10 is 0.1 mA. The sum of the induced electromotive force when one street lamp (1-1) is lit is 1 mA and the sum of two street lamps (any one of 1-1, 1-2, 1-3) is lit. It is assumed that the magnitude of the induced induced electromotive force is 2 mA, and the sum of the induced induced electromotive force when all three street lamps 1-1, 1-2, 1-3 are turned on is 3 mA. The determination unit 30 determines that all the lamp lamps 1 are turned off when the total measured value is 0.05 mA or less, and the determination unit 30 when the total measured value is within an error range of 0.95 mA to 1.05 mA. ) Determines that only one of the three street lamps (1-1, 1-2, 1-3) is turned on, and judges if the summed measurement value is within an error range of 0.90 mA to 2.10 mA. The unit 30 determines that only two street lamps among the three street lamps 1-1, 1-2, 1-3 are turned on, and the summed measurement value is within an error range of 2.75 mA to 3.15 mA. The determination unit 30 determines that all the street lamps 1-1, 1-2, 1-3 are turned on.

5 is a block diagram of a street lamp system in which a plurality of street lamps 1 and the monitoring unit 10 are installed in accordance with an embodiment of the present invention.

Hereinafter, an operation of performing the apparatus for monitoring a street lamp 1 according to an embodiment of the present invention will be described in detail with reference to FIG. 5.

According to Figure 5, the street lamp (1) is installed in the street lamp is a lamp that is supplied with power to emit light may be used a variety of lamps such as halogen, sodium, neon, LED.

The monitoring unit 10 includes a conductive wire 101 for supplying power to the street lamp 1, and a coil 201 intersecting the conductive wire 101, wherein the coil includes a current flowing through the street lamp 1. Induced electromotive force occurs.

The measuring unit 20 measures the magnitude of induced electromotive force generated by the monitoring unit 10.

The determination unit 30 compares the measured value of the induced electromotive force measured by the measurement unit 20 with the reference induced electromotive force to determine whether the street light lamp 1 is turned on.

As described above, when there are a plurality of street lamps 1 and the monitoring unit 10, the outer skin of the monitoring units 10-1 to 10-n is a material that surrounds the conductive wire 101 and does not pass current. The monitoring units 10-1 to 10-n include a conductive wire 101 through which a current supplied to the street lamps 1-1 to 1-n flows. In addition, the monitoring unit 10-1 to 10-n crosses the conductive wire 101 and generates induced electromotive force due to a current flowing in the conductive wire 101 of the street light lamps 1-1 to 1-n. And an induction electromotive force terminal 202 connected to the coil 201 and the coil 201 where the induction electromotive force is generated.

 When AC power flows to the monitoring units 10-1 to 10-n of the street lamps 1-1 to 1-n, the current flowing through the conductive wire 101 in the monitoring units 10-1 to 10-n. As is changed, induced electromotive force is generated in the coils 201 intersected with the respective conductive wires 101 by the electromagnetic induction phenomenon.

The measurement unit 20 measures the induced electromotive force and transmits the measured value to the determination unit 30.

The determination unit 30 uses the sum of the magnitudes of each induced electromotive force generated corresponding to the current required for one street lamp (1 to 1-n) to be turned on as the reference induced electromotive force. When the measured value of 20) is within the error range of the reference induced electromotive force, it is determined that the street lamps 1-1 to 1-n are turned on.

The user may determine whether each of the plurality of street lamps 1-1 to 1-n is turned on or off by looking at the determination unit 30, and the measurement unit 20 and the determination unit 30 may be wired or wireless. It can be connected to remotely monitor street lights.

Hereinafter, the determination unit 30 will be described taking an example in which the street lamp 1 and the monitoring unit 10 are three at the reference value. When the lamp lamp 1-1 is turned off, the magnitude of the induced electromotive force generated in the coil 201 by the current for driving the monitoring unit 10-1 is referred to as 0.1 mA, and the lamp lamp 1-1 is applied. Assume that the magnitude of the induced electromotive force when is lit is 1 mA.

If the measured value transmitted from the monitoring unit 10-1 is 0.05 mA or less, the determination unit 30 determines that the lamp lamp 1-1 is turned off, and the measured value is 0.95 mA to 1.05 mA. If it is in the range, the determination unit 30 determines that the street light lamp 1-1 is lit.

If the measured value transmitted from the monitoring unit 10-2 is 0.05 mA or less, the determination unit 30 determines that the lamp lamp 1-2 is turned off, and the measured value is between 0.95 mA and 1.05 mA. If it is within the range, the determination unit 30 determines that the lamp lamp 1-2 is turned on.

If the measured value transmitted from the monitoring unit 10-3 is 0.05 mA or less, the determination unit 30 determines that the street lamp lamp 1-3 is turned off, and the measured value is 0.95 mA to 1.05 mA. If it is within the range, the determination unit 30 determines that the street lamps 1-3 are turned on.

Therefore, the determination unit 30 may determine which streetlight lamps 1-1 to 1-n are turned on or off specifically based on the measured values transmitted from the monitoring units 10-1 to 10-n. .

The measured value and the error range in the embodiment of the present invention are merely exemplary, and those skilled in the art may determine the actual measured value and the error range.

In addition, the present invention has been described with reference to one embodiment shown in the drawings, but this is only exemplary and those skilled in the art that various modifications and equivalent other embodiments are possible from this. It is.

1: street lamp 101: lead wire
10: monitoring unit 201: coil
20: measuring unit 202: induction electromotive force terminal
30: judgment unit

Claims (7)

A monitoring unit intersecting a conducting wire flowing through the current supplied to the street lamp, the coil generating an induced electromotive force by the current flowing through the conducting wire, and an inductive electromotive force terminal connected to the coil; And
And a measuring unit connected to the induction electromotive force terminal and measuring a magnitude of the induction electromotive force provided from the induction electromotive force terminal. The method according to claim 1,
And a judging unit comparing the magnitude of the induced electromotive force measured by the measurement unit with a preset reference induced electromotive force to determine whether the street lamp is lit. The method according to claim 1 or 2,
The street lamp includes at least two, and the monitoring device for the street facility, characterized in that for monitoring the induced electromotive force generated by the current flowing in the conductor supplied to each street lamp in one monitoring unit. The method according to claim 1 or 2,
The street lamp includes at least two, and the number of the monitoring unit is adjusted to correspond to the number of the street lamp to distinguish the induced electromotive force generated by the current flowing through the conductive wires supplied to each street lamp. Street facility monitoring device. Monitoring the generation of induced electromotive force due to the current flowing in the conductive wire in a coil intersecting the conductive wire in which the current supplied to the street lamp is flowing;
Measuring the magnitude of the induced electromotive force; And
And comparing the measured induced electromotive force with a preset reference induced electromotive force to determine whether the street lamp is turned on or off. The method of claim 5, wherein
The at least one street lamp is a street facility monitoring method, characterized in that the size of each predetermined reference induced electromotive force is changed according to the number of the street lamp. The method of claim 5, wherein
The at least two street lamps, and the number of coils intersecting with the conductive wires through which the current supplied to each street lamp flows is composed of a plurality of pieces to correspond to each conductive wire, or one regardless of the number of the conductive wires. .

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