KR20140006528A - Apparatus for controlling lighting device - Google Patents

Abstract

According to an embodiment of the present invention, apparatus for controlling a lighting device comprises: an illuminance detection unit for detecting illuminance around the lighting device; and a control unit which operates the lighting controlling apparatus in either a standby mode or control mode in response to a result detected by the illuminance detecting unit. The lighting controlling apparatus consumes less electrical power in the standby mode than control mode. [Reference numerals] (110) Illuminance detection unit; (120) Control unit; (130) Communication unit; (140) Solar cell; (150) Energy storage unit; (162) DC/DC conversion unit

Description

Lighting control device {Apparatus for controlling lighting device}

Embodiments relate to a lighting control device.

In general, conventional light control devices that control lighting fixtures, such as street lights, have low power efficiency because they always consume power to control the lighting fixtures.

In addition, existing lighting control devices are disposed in each of the lighting fixtures, thereby increasing the material, installation and maintenance costs of the lighting control device.

In addition, since the conventional lighting control device operates by receiving driving power from the outside, it is difficult to install the lighting control device and the lighting fixture in an environment that is not suitable for receiving the external driving power, that is, in an area where commercial power is not supplied. Constraints also follow.

An embodiment provides a power saving self-driving light control apparatus.

According to the embodiment, the lighting control device for controlling the lighting fixture, the illumination sensor for sensing the illumination around the lighting fixture; And a controller configured to operate the lighting control device in any one of a standby mode and a control mode in response to a result detected by the illuminance sensor, wherein the lighting control device is further in the standby mode than the control mode. Consumes less power.

In addition, in response to the detected result, the controller switches from the standby mode to the control mode to operate the lighting control device or from the control mode to the standby mode to operate the lighting control device.

The lighting control device may further include a communication unit controlled by the control unit and operating in the standby mode or transmitting a brightness control signal received from the control unit in the control mode to the lighting device, wherein the communication unit is further configured to control the control mode. Consuming less power in the standby mode, the luminaire is turned on, turned off or adjusts the light intensity in response to the brightness control signal.

The communication unit may transmit the brightness control signal to the lighting apparatus using near field communication. The near field communication may be, for example, RF radio communication or zigbee radio communication.

The illuminance detection unit may output a voltage having a level corresponding to illuminance around the luminaire to the controller as a detected result. For example, the illuminance sensor has a first level for a period immediately after sunrise, has a second level for a period immediately before sunset, and has a third level until a certain period immediately before sunset until after a certain period has elapsed immediately after sunrise. And a voltage having a fourth level from immediately after sunset to just before sunrise is output to the controller as the detected result, and the controller is configured to generate a voltage having the third or fourth level from the illuminance sensor. The lighting control device may be operated in the standby mode, and when the voltage having the first or second level is generated from the illuminance sensor, the lighting control device may be operated in the control mode.

The illuminance detector may output a voltage having a fifth level to the controller when the rate of change of the illuminance is relatively fast from a time after a certain period immediately after sunrise until a time point before a sunset is reached. The lighting control device may operate the lighting control device in the control mode when a voltage having the fifth level is generated from the illuminance sensor.

The lighting control device includes an energy generator for converting natural energy into electrical energy and outputting it; An energy storage unit for storing the electrical energy; And a power converter converting an output voltage of the energy storage unit into an operating voltage of each unit of the lighting control device.

The lighting control device may be allocated for each zone, and at least one lighting device may be installed in each zone, and the brightness control signal may collectively control the at least one lighting device installed in each zone.

The controller may be configured to operate the lighting control device in any one of a slave mode, a master mode, and an inoperable mode according to the amount of electrical energy stored in the energy storage unit. The other brightness control signal received from another lighting control device assigned to the other zone is transmitted to the lighting fixture installed in its own zone, and in the master mode, the controller receives the light from the illuminance sensing unit without the help of the other lighting control device. In response to the detected result, the brightness control signal is transmitted to the luminaire installed in its zone, and in the inoperative mode, the controller transmits the unique identification number of the other lighting control device selected as the master to the luminaire. Can be transmitted to the lighting fixture.

The controller may change the operation mode of the lighting control device from the master mode to the slave mode or the inoperable mode according to the amount of the electric energy stored in the energy storage unit, or from the slave mode to the master. The operation mode of the lighting control device may be switched to a mode or the inoperable mode, or the operation mode of the lighting control device may be switched from the inoperative mode to the master mode or the slave mode.

In addition, the controller may transmit its own identification number and the brightness control signal together to the other lighting control device in response to a request signal received from another lighting control device disposed in another zone.

According to another embodiment, a lighting control method of a lighting control device for controlling a lighting device, the method comprising: sensing the illumination around the lighting device; When the rate of change of illuminance around the luminaire is relatively slow, entering the lighting control device into a standby mode; And entering the lighting control device into a control mode that turns on, turns off, or adjusts the intensity of light when the rate of change of illuminance around the lighting fixture is relatively fast. The lighting control device may consume less power in the standby mode than in the control mode.

The step of entering the lighting control device into the control mode includes turning on or dim up the luminaire when the amount of change in voltage corresponding to the sensed illuminance is greater than a positive first threshold value. ; And turning off or dim down the luminaire when the amount of change is less than a second negative threshold.

The lighting control method includes converting natural energy into electrical energy; Storing the converted electrical energy; And converting a voltage corresponding to the stored electrical energy into an operating voltage having at least one different level for operating each unit of the lighting control device.

In the lighting control method, when the amount of the stored electrical energy is less than the minimum value, the lighting control device in a slave mode for transmitting another brightness control signal received from another lighting control device disposed in the other zone to the lighting equipment installed in its own zone. Entering; And when the amount of stored electrical energy is greater than or equal to the minimum value, entering the lighting control device into a master mode.

The step of entering the lighting control device into the slave mode may include generating and transmitting an interrupt signal to at least one other lighting control device; Requesting and receiving a unique identification number and another brightness control signal of the at least one other lighting control device that received the interrupt signal; Selecting another lighting control device that has transmitted another brightness control signal having the largest level as a master; And transmitting the other brightness control signal transmitted by the other lighting control device selected as the master to the lighting device installed in its own area.

The lighting control method may further include transmitting a unique identification number and the brightness control signal of the lighting control device itself to the other lighting control device when an interrupt signal comes from the other lighting control device disposed in the other zone and requests a request. It may further include.

The lighting control device of the embodiment consumes less power because it enters the standby state at a time other than a certain period immediately after sunrise and a certain period immediately before sunset, compared to a conventional lighting control device which always consumes a constant power, thereby saving energy. You can control the luminaire with less power,

As it stores and drives natural energy such as the sun and wind, it does not need to receive power from the outside, which saves electricity costs, and it can be installed in any space to control lighting fixtures if natural energy can be obtained. Since no separate power line is required, construction cost is reduced and installation is easier, which reduces the cost for lighting fixture control.

Since a plurality of lighting fixtures can be controlled collectively, the material, installation and maintenance costs of the lighting control apparatus can be reduced as compared with the case where the lighting control apparatus is arranged for each lighting fixture,

Since the lighting apparatus can be controlled wirelessly, a separate communication line is not required, thereby reducing the construction cost and easier installation, thereby reducing the cost for controlling the lighting apparatus.

1 shows a layout view of a lighting control device and a lighting apparatus according to an embodiment.
FIG. 2 is a block diagram according to an embodiment of the n-th light control apparatus illustrated in FIG. 1.
3 is a graph illustrating a change in brightness for each time zone.
FIG. 4A shows the appearance of the embodiment of the luminaire shown in FIG. 1, and FIG. 4B schematically shows a block diagram according to the embodiment of the control box shown in FIG. 4A.
5 is a flowchart illustrating a lighting control method according to an embodiment.
6 is a flowchart for describing a method according to an embodiment of operating an n-th lighting control device in a slave mode and a master mode.
FIG. 7 is a flowchart for describing an exemplary embodiment of the step 530 illustrated in FIG. 6.
8 is a graph illustrating energy saved in the lighting control device according to the embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate understanding of the present invention. However, the embodiments according to the present invention can be modified into various other forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. Embodiments of the invention are provided to more fully describe the present invention to those skilled in the art.

1 shows a layout view of a lighting control device and a lighting apparatus according to an embodiment.

Referring to FIG. 1, the first to Nth lighting control devices 100 ₁ to 100 _N are allocated to the first to Nth zones 200 ₁ to 200 _N , respectively. Here, N is a positive integer of 1 or more. At least one lighting device 200 is installed in each zone 200 ₁ to 200 _N , and at least one installed in each zone by the brightness control signal D1 generated from the corresponding lighting control device 100 ₁ to 100 _N. Lighting fixtures 200 are collectively controlled.

In other words, the first lighting control device (100 ₁₎ is a batch by the first region (200 ₁₎ and assigned to a first zone (200 ₁₎ at least one luminaire brightness control 200 signal (D1) provided in To control. Similarly, the n controls the at least one luminaire (200) installed in the lighting control device (100 _n) are assigned to the n-th zone (200 _n), the n-th zone (200 _n) at the same time. Here, 1? N? N.

Hereinafter, the configuration and operation of the n-th light control device 100 _n shown in FIG. 1 will be described as follows. However, the other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N are respectively described. Since has the same configuration and operation as the n-th lighting control device 100n, description thereof will be omitted.

FIG. 2 shows a block diagram according to an embodiment 100A of the n-th light control device 100 _n shown in FIG. 1. Here, the solid line represents the power line, and the dotted line means the line through which control signals are transmitted or the line through which data is transmitted.

Embodiment 100A of the nth light control device 100 _n illustrated in FIG. 2 includes an illuminance sensor 110 and a controller 120. The illuminance detector 110 detects illuminance around at least one lighting device 200 installed in the n-th region 200 _n . Here, since the n-th lighting control apparatus 100A is located close to the lighting apparatus 200, the illuminance of the illuminance detecting unit 110 included in the n-th lighting control apparatus 100A and the illuminance around the lighting apparatus 200 are It is considered to be substantially the same.

The control unit 120 operates the n-th lighting control device 100A in any one of a standby mode and a control mode in response to the result detected by the illuminance sensor 110. The n-th light control device 100A consumes less power in the standby mode than in the control mode. The control mode refers to a mode in which the n-th light control device 100A controls the brightness of the lighting fixture 200 and consumes more power than the standby mode. In addition, the standby mode refers to a mode in which the n-th light control device 100A consumes less power than the control mode without controlling the brightness of the lighting fixture 200.

3 is a graph showing a change in brightness for each time zone, where the horizontal axis represents time t and the vertical axis represents brightness. Here, 320 denotes a change in brightness of the luminaire 200 and reference numeral 330 denotes a change in illuminance according to an external environment.

Based on the result detected by the illuminance detecting unit 110, when it is determined that the rate of change of the illuminance around the luminaire 200 is relatively fast, the controller 120 enters the n-th lighting control apparatus 100A into the control mode. Let's do it. At this time, the controller 120 itself also enters the control mode. Referring to FIG. 3, the rate of change of the illuminance 330 for a period 304 immediately after sunrise 303 and for a period 308 immediately before sunset 309 is relative when compared to other intervals 302, 306, 310. As fast as Therefore, the controller 120 enters the n-th light control device 100A into the control mode in the sections 304 and 308.

Alternatively, when it is determined based on the result detected by the illuminance detecting unit 110 that the change rate of illuminance around the luminaire 200 is not relatively fast but slow, the controller 120 controls the n-th illumination control apparatus 100A. Enter standby mode. Referring to FIG. 3, the rate of change of the illuminance 330 during the sections 302, 306, 310 is relatively slow compared to the other sections 304, 308. Therefore, in this section 302, 306, 310, the control unit 120 causes the n-th lighting control device 100A to enter the standby mode.

After the n-th illumination control device 100A enters any one of the standby mode and the control mode, the control unit 120 controls or moves from the standby mode to the control mode in response to the result detected by the illuminance sensor 110. The n-th illumination control device 100A may switch the operation mode from the mode to the standby mode.

According to the embodiment, the illuminance detector 110 may output a voltage having a level corresponding to the illuminance around the lighting apparatus 200 to the controller 120 as a detected result. That is, the result detected by the illuminance detector 110 may take the form of voltage SV. However, embodiments are not limited to this and the sensed results may take various forms.

For example, the voltage SV which is a detected result output from the illuminance sensor 110 may have the first level V1 for a period 304 immediately after the sunrise 303. Alternatively, the detected voltage SV may have the second level V2 during the predetermined period 308 immediately before sunset 309. Alternatively, the voltage SV may be a period 306 until the time t3 of the predetermined period 308 immediately before the sunset 309 is reached after the predetermined period 304 elapses immediately after the sunrise 303. May have a third level V3. Alternatively, the voltage SV may have a fourth level V4 from just after sunset 309 to just before sunrise 320, that is, in sections 302 and 310.

In this case, when the voltage SV having the third level V3 or the fourth level V4 is generated from the illuminance sensor 110, the controller 120 sets the n-th illumination control device 100A to the standby mode. Operate. Alternatively, the controller 120 operates the n-th illumination control device 100A in the control mode when the voltage SV having the first level V1 or the second level V2 is generated from the illuminance sensor 110. Let's do it.

Alternatively, the illuminance detecting unit 110 may be, for example, until the time t3 of the predetermined period 308 immediately before the sunset 309 until the predetermined time 304 elapses immediately after the sunrise 303 (t2). In operation 306, the voltage SV having the fifth level V5 may be output to the controller 120 when the change rate of illuminance is relatively fast. The voltage having the fifth level V5 in the illuminance sensing unit 110 may be generated by various causes. For example, the rate of change in illuminance may be relatively very large due to a sudden natural disaster during day time 306. At this time, when the voltage having the fifth level V5 is generated from the illuminance detecting unit 110, the controller 120 switches the n-th lighting control device 100A in the standby mode to the control mode to operate the lighting device ( 200).

Meanwhile, the n-th lighting control device 100A may further include a communication unit 130 and an antenna 132, but is not limited thereto. That is, instead of including the communication unit 130 and the antenna 132, the n-th lighting control apparatus 100A may be connected to the lighting apparatus 200 installed in the _n- th region 200 _{n by} wire.

The communication unit 130 is controlled by the control unit 120 to operate in the standby mode or to operate in the control mode. In the control mode, the communication unit 130 transmits the brightness control signal D1 received from the control unit 120 to the at least one lighting device 200 installed in the _n- th zone 200 _n through the antenna 132. Like the controller 120, the communicator 130 consumes less power in the standby mode than in the control mode. For example, the communicator 130 may transmit a brightness control signal to the lighting apparatus 200 using short-range wireless communication. The near field communication may be, for example, RF radio communication or zigbee radio communication.

The at least one lighting device 200 installed in the n-th zone 200 _n receives the brightness control signal transmitted from the n-th light control device 100A and is turned on in response to the received brightness control signal. ), Turn off, or adjust the intensity of light. To this end, the lighting device 200 may be implemented in various ways.

The n-th light control apparatus 100A according to the embodiment may enter the standby mode from the time point t2 after diming down the luminaire 200 in the section 304 of the control mode. After the dim up of the lighting device 200 in the section 308 of the can be entered into the standby mode from the time point (t4). Thus, as shown in FIG. 3, the brightness of the light around the luminaire 200 can be kept constant at the level L1.

Hereinafter, with reference to the accompanying drawings, the appearance, configuration and operation of the embodiment (200A) of the lighting device 200 shown in Figure 1 by way of example, but is not limited thereto, the lighting device 200 is Of course, it can be implemented in various forms.

4A shows an appearance of an embodiment 200A of the lighting fixture 200 shown in FIG. 1, and FIG. 4B schematically shows a block diagram of an embodiment 210A of the control box 210 shown in FIG. 4A. Indicates.

As illustrated in FIG. 4A, the lighting fixture 200A may be a street light. The luminaire 200A illustrated in FIG. 4A is a strut 226, a plurality of solar cell modules 224 installed on the upper surface at the upper end of the strut 226, and the radio emitted from the n-th light control apparatus 100A. It may include a control box 210 for receiving a signal and controlling the lighting fixture 200A and a street light head 220 fitted and fixed to face the ground. A separate LED module (not shown) may be inserted into and coupled to the bottom surface of the street lamp head 220.

Referring to FIG. 4B, the control box 210A of the lighting apparatus 200A includes an antenna 212, a control signal receiver 214, and a brightness controller 216. The brightness control signal transmitted from the nth illumination control device 100A is received by the control signal receiver 214 through the antenna 212. The control signal receiver 214 removes noise that may be included in the received brightness control signal or amplifies the signal level and outputs the signal to the brightness controller 216. The brightness controller 216 converts the output of the control signal receiver 214 into a signal suitable for driving the LED module and outputs the signal to the LED module through the output terminal OUT.

Meanwhile, the n-th light control apparatus 100A illustrated in FIG. 2 may further include an energy generator 140, an energy storage unit 150, and a power converter 160, but are not limited thereto. That is, instead of including the energy generator 140, the energy storage unit 150, and the power converter 160, the n-th light control apparatus 100A may provide an external source having a form other than natural energy. For example, it may be supplied from alternative energy or fuel cells or from a commercial power source.

According to the embodiment, the energy generation unit 140 illustrated in FIG. 2 converts natural energy into electrical energy and outputs the converted result to the energy storage unit 150. For example, the natural energy may be made of any one or combination of hydro energy, solar energy, wind energy, wave energy, tidal energy, marine thermoelectric energy. For example, when natural energy is solar energy, the energy generator 140 may be a solar cell 142 that is a solar cell as illustrated in FIG. 2. Since the solar cell 142 is a general matter, a detailed description thereof will be omitted.

The energy storage unit 150 is a type of storage battery that stores electrical energy received from the energy generation unit 140. The energy storage unit 150 may include a charge protection circuit such as a fuse (not shown) that protects the energy storage unit 150 so as not to overcharge the electric energy.

The power conversion unit 160 converts the output voltage from the energy storage unit 150 into an operating voltage (OV) for operating each unit of the nth lighting control device 100A, and converts the converted operating voltage into the control unit 120. Under the control of)) and output to each part. For example, the power converter 160 converts the voltage output from the energy storage unit 150 into the first, second and third operating voltages OV1, OV2, and OV3, and converts the converted first and second voltages. And output the third operating voltages OV1, OV2, and OV3 to the illuminance sensing unit 110, the control unit 120, and the communication unit 130, respectively.

For example, the power conversion unit 160 converts the voltage stored in the energy storage unit 150 into a rated voltage, for example, a voltage of 7.3 volts or a voltage of 5 volts and supplies a DC / DC converter 162. ) May be included. Alternatively, the power conversion unit 160 may include a regulator (not shown) instead of the DC / DC converter 162 for this operation.

On the other hand, the control unit 120 according to the amount of the electrical energy stored in the energy storage unit 150, the n-th lighting control device 100A in any one of the slave mode, the master mode and the inoperable mode. ) Can be operated.

Here, the slave mode means that the n-th light control device 100A is disposed in the _n- th zone 200 _n with the help of other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N. Means a mode for controlling the lighting fixture 200.

In the master mode, the n-th light control device 100A is disposed in the _n- th zone 200 _n by its own force without the help of other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N. Means a mode for controlling the lighting device 200.

The inoperable mode means a mode in which the n-th illumination control device 100A cannot control the lighting fixture 200 disposed in the _n- th region 200 _n .

After the n-th lighting control device 100A enters the slave mode from the master mode or the inoperable mode, the controller 120 operates in the master mode or the operation from the slave mode according to the amount of electrical energy stored in the energy storage unit 150. The operation mode of the nth lighting control device 100A may be switched to the disabled mode.

Alternatively, after the n-th lighting control device 100A enters the master mode from the slave mode or the inoperable mode, the controller 120 according to the amount of electric energy stored in the energy storage unit 150, from the master mode to the slave mode. Alternatively, the operation mode of the n-th light control device 100A may be switched to an inoperable mode.

For example, the controller 120 may detect a storage amount of the electric energy stored in the energy storage unit 150 through the level of the second operating voltage OV2 provided from the power converter 160.

In the master mode, the control unit 120 of the n-th light control device 100 _n is controlled from the illuminance detection unit 110 without the help of other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N. In response to the received sensed result, generates a brightness control signal (D1), and transmits the generated brightness control signal (D1) to the luminaire 200 installed in its zone (200 _n ).

In the slave mode, the control unit 120 of the n-th lighting control device 100 _n is allocated to the other zones 200 ₁ to 200 _n-1 and 200 _{n + 1} to 200 _N except for its own zone 200 _n . The other brightness control signal (D2) received from the other lighting control device (100 ₁ ~ 100 _n-1 , 100 _{n + 1} ~ 100 _N ) is transmitted to the luminaire 200 installed in its area (200 _n ). That is, in the slave mode, since the amount of energy stored in the energy storage unit 150 is not sufficient to generate the brightness control signal D1 by itself, the nth lighting control device 100 _n is configured to be used by other lighting control devices 100 ₁ to 100. The brightness control signal D2 obtained in dependence on 100 _n-1 , 100 _{n + 1} to 100 _N ) is transmitted to the luminaire 200 of the _n- th zone 200 _n that it controls. Various embodiments of the slave mode will be described in detail in the lighting control method described below.

In the non-operational mode, the control unit 120 of the n-th lighting control device 100 _n assigns a unique identification number (ID) of another lighting control device selected as a master to its n-th zone 200 _n . Send to 200. That is, in the inoperable mode, since the amount of electric energy stored in the energy storage unit 150 is insufficient to perform even the slave mode, the n-th zone 200n receiving the unique identification number (ID) of the other lighting control device. The luminaire 200 arranged in FIG. 1 operates according to the brightness control signal D1 transmitted by another lighting control device selected as a master.

Further, the control unit 120 is the other area _{(200 1 ~ 200 n-1} , 200 n + 1 ~ 200 N) of the other light control device disposed in the _{(100 1 ~ 100 n-1} , 100 n + 1 ~ 100 N) In response to the request signal received from, the unique identification number (ID) and the brightness control signal (D1) may be transmitted to the other lighting control device (100 ₁ ~ 100 _n-1 , 100 _{n + 1} ~ 100 _N ). . In this case, the n-th light control device 100A may serve as a master of other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N that request the brightness control signal.

In addition, according to the embodiment, when the foreign matter is attached to the illumination sensing unit 110, the illumination control unit 110 can not faithfully perform the role of detecting the illumination, other lighting control device 100 ₁ ~ 100 _n-1 , 100 _{n + 1} ~ 100 _N ) to correct the result of sensing the illumination, it is also possible to control the lighting fixture 200 without abnormality using the corrected value.

As described above, the n-th illumination control device 100A operates in the control mode during the sections 304 and 308 where the change in the illuminance 330 is relatively large, and the section 302 in which the change in the illuminance 330 is relatively weak. , 306, 310, since the n-th lighting control device 100A operates in a standby mode, power consumed by the n-th lighting control device 100A may be reduced.

Hereinafter, a lighting control method of the above-described n-th light control apparatus will be described with reference to the accompanying drawings.

5 is a flowchart illustrating a lighting control method according to an embodiment.

First, the illuminance detecting unit 110 detects illuminance around the lighting apparatus 200 (operation 410).

After operation 410, the controller 120 obtains an amount of change in illuminance using the result detected by the illumination sensor 110 (operation 420). For example, the controller 120 may obtain a change amount of illuminance by subtracting a current level from a previous level of a voltage corresponding to illuminance around the luminaire 200.

After operation 420, when the change rate of illuminance around the lighting apparatus 200 is relatively slow, the controller 120 enters the n-th lighting control apparatus 100 _n to the standby mode (430, 450, and _th ). Step 470). As described above in FIG. 3, the rate of change (or the amount of change or the slope) of the illuminance 330 in the sections 302, 306, 310 is the rate of change of the illuminance 330 in the sections 304, 308 (or, Relative slower than amount of change or slope).

That is, after operation 420, the controller 120 determines whether the amount of change in illuminance is greater than the positive first threshold value TH1 (operation 430). If the amount of change in illuminance is not greater than the positive first threshold value TH1, the controller 120 determines whether the amount of change in illuminance is smaller than the negative second threshold value -TH2 (S450). If it is determined that the amount of change in illuminance is not greater than the negative second threshold value -TH2, the controller 120 enters the illuminance control device 100A, including itself, into the standby mode (step 470). The first threshold value TH1 and the second threshold value TH2 described above may be the same as or different from each other.

For example, the first threshold value TH1 may be an absolute value of the minimum slope of illuminance in the interval 308, and the second threshold value TH2 may be a minimum slope of the illuminance in the interval 304. .

On the other hand, the control unit 120 enters the n-th lighting control device (100 _n ) into the control mode when the change rate of the illumination around the lighting fixture 200 is relatively fast (steps 430 to 460). As described above in FIG. 3, the rate of change (or the amount of change or the slope) of the illuminance 330 in the sections 304 and 308 is the rate of change of the illuminance 330 in the sections 302, 306 and 310 (or, Relatively faster than the amount of change or slope).

That is, after operation 420, the controller 120 determines whether the amount of change in illuminance is greater than the positive first threshold value TH1 (operation 430). If it is determined that the amount of change in voltage corresponding to the sensed illuminance is greater than the positive first threshold value TH1, the controller 120 generates a brightness control signal D1 to turn on the lighting device 200. Dim up (step 440). However, when the amount of change in illuminance is not greater than the positive first threshold value TH1, it is determined whether the amount of change in illuminance is smaller than the negative second threshold value -TH2 (step 450). If it is determined that the amount of change in illuminance is smaller than the negative second threshold value -TH2, the controller 120 generates a brightness control signal D1 to turn off or dim down the lighting fixture 200. (Step 460).

According to an embodiment, when the control unit 120 enters the n-th lighting control device into the standby mode, power consumed by the communication unit 130 may be reduced in various ways as follows.

First, the controller 120 may generate the first control signal C1 to block the supply of the third operating voltage OV3 provided by the power converter 160 to the communication unit 130.

Alternatively, the power converter 160 may provide both the first standby power and the first control power to the communication unit 130. In this case, when the first control power is supplied from the power conversion unit 160, the communication unit 130 may transmit the brightness control signal to the lighting device 200 through the antenna 132 under the control of the control unit 120. have. Alternatively, when the first standby power lower than the first control power is supplied from the power converter 160, the communicator 130 stays in a standby state which can be operated immediately instead of transmitting a signal. To this end, the controller 120 generates a first control signal C1 in response to the result detected by the illuminance sensor 110, and the power converter 160 responds to the first control signal C1. The first standby power or the first control power is provided to the communication unit 130.

As described above, the control unit 120 may control the communication unit 130 and / or the power conversion unit 160 in the standby mode to reduce the power consumption, but also reduce the power consumed in the following manner. can do.

The power converter 160 may provide both the second standby power and the second control power to the controller 120. In this case, when the second control power is supplied from the power converter 160, the controller 120 generates a brightness control signal D1 corresponding to the illuminance detected by the illuminance sensor 110 to communicate with the communicator 130. Will output When the second standby power lower than the second control power is supplied from the power converter 160, the controller 120 may be configured to have the above-described first or second level of the voltage SV output from the illuminance sensor 110. It consumes only enough power to wake up immediately, and does not generate a brightness control signal during this time. To this end, the controller 120 generates a first control signal C1 in response to the result detected by the illuminance sensor 110, and the power converter 160 generates a first control signal in response to the first control signal C1. 2 standby power or the second control power to the control unit 120.

6 is a flowchart for explaining a method according to an embodiment of operating the n-th light control device 100A in a slave mode and a master mode.

First, the controller 120 determines whether the amount of electrical energy stored in the energy storage unit 150 is smaller than the minimum value (operation 510). To this end, the controller 120 measures the level of the second supply voltage OV2 supplied from the power converter 160, and stores the amount of electrical energy above the minimum value through the measured level of the second supply voltage OV2. Can be judged. Here, the minimum value means a voltage level value sufficient to generate the first to third supply voltages OV1, OV2, and OV3 for operating the illuminance sensing unit 110, the control unit 120, and the communication unit 130. . That is, when the amount of energy stored in the energy storage unit 150 is less than the minimum value, the n-th light control apparatus 100A generates the brightness control signal D1 and thus cannot control the lighting apparatus 200. This minimum value varies depending on the circuit configuration of the illumination sensor 110, the controller 120, and the communicator 130 that require an operation power source.

If the amount of electrical energy stored in the energy storage unit 150 is not less than the minimum value, the controller 120 enters the n-th lighting control device 100A into the master mode (operation 520). In the master mode, the n th lighting control apparatus 100 _n may perform steps 410 to 470 illustrated in FIG. 5.

However, when the amount of electric energy stored in the energy storage unit 150 is less than the minimum value, the controller 120 enters the n-th lighting control device 100A into the slave mode (operation 530). In the slave mode, the n-th light control device 100 _n receives another brightness control signal D2 received from another light control device 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N arranged in another zone. It transmits to the luminaire 200 installed in its own area 200 _n .

FIG. 7 is a flowchart for describing an exemplary embodiment 530A of the step 530 illustrated in FIG. 6.

Referring to FIG. 7, in order to enter the slave mode, the n-th lighting control device 100 _n generates an interrupt signal to generate at least one other lighting control device 100 ₁ to 100 _n-1 , 100 _{n + 1} to 100. _N ) (step 532).

After the step 532, the unique identification number (ID) and the other brightness control signal (D2) of the at least one other lighting control device (100 ₁ ~ 100 _n-1 , 100 _{n + 1} ~ 100 _N ) received the interrupt signal (Step 534).

After operation 534, the other illumination that transmits the other brightness control signal D2 having the largest level among other brightness control signals received from the other light control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100 _N. The control device is selected as the master of the n-th light control device 100 _n (step 536). Here, one of the reasons for selecting the other lighting control device that transmits the other brightness control signal D2 having the largest level as a master is the other lighting control devices 100 ₁ to 100 _n-1 and 100 _{n + 1} to 100. This is because the probability that the brightness control signal transmitted from another lighting control device disposed closest to the nth lighting control device 100 _n among _N ) may have the highest level is high.

After operation 536, the other brightness control signal D2 transmitted by the other lighting control device selected as the master is transmitted to the lighting device 200 installed in the own area 200 _n to control the brightness of the lighting device 200. (Step 538).

If the energy storage unit 150 stores energy again during the period 306, the n th lighting control device 100 _n operating in the slave mode may return to the master mode to operate.

On the other hand, the interrupt signal is input from the other lighting control device (100 ₁ ~ 100 _n-1 , 100 _{n + 1} ~ 100 _N ), the brightness control signal and the unique identification number (ID) to the n-th lighting control device (100 _n ) When requesting the transmission of, the n-th light control device 100 _n is interrupted with its unique identification number (ID) and brightness control signal (D1) other lighting control device (100 ₁ ~ 100 _n-1 , 100) and it transmits the _{n + 1} ~ 100 _n) (the 538 step).

8 is a graph for explaining energy saving in the lighting control apparatus according to the embodiment, the horizontal axis represents time, and the vertical axis represents power consumption, respectively. Here, t1, t2, t3, and t4 have the same meanings as t1, t2, t3, and t4 shown in FIG.

3 and 8, the conventional lighting control device always consumes a constant first power P1. However, each lighting control device 100 ₁ to 100 _N according to the embodiment enters the standby mode in the sections 302, 306, and 310, and consumes only the second power P2 less than the first power P1. . In addition, the lighting control device enters the control mode in the sections 304 and 308 and consumes the first power P1. Therefore, compared with the conventional, the lighting control device according to the embodiment can save energy by the hatched portion.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

1001 to 100N: lighting control device 110: illuminance control unit
120: control unit 130:
132, 212: antenna 140: energy generating unit
150: energy storage unit 160: power conversion unit
200: lighting fixtures 2001 to 200N: zone
210: control box 214: control signal receiving unit
216: brightness control unit 220: street light head
224: solar cell module 226: prop

Claims (12)

An illuminance detecting unit detecting an illuminance around the lighting fixture; And
A control unit for operating the lighting control device in any one of a standby mode and a control mode in response to the result detected by the illuminance sensor;
The lighting control device consumes less power in the standby mode than the control mode. The lighting control apparatus of claim 1, wherein, in response to the detected result, the controller switches the standby mode from the standby mode to operate the lighting control device, or switches from the control mode to the standby mode. Lighting control device for operating the. The apparatus of claim 1, further comprising a communication unit controlled by the control unit to transmit a brightness control signal to the lighting apparatus operating in the standby mode or received from the control unit in the control mode.
The communication unit consumes less power in the standby mode than the control mode,
And the lighting apparatus is turned on, turned off, or adjusts the intensity of light in response to the brightness control signal. The lighting control device of claim 3, wherein the communication unit transmits the brightness control signal to the lighting apparatus using near field communication. The lighting control device of claim 1, wherein the illuminance sensor outputs a voltage having a level corresponding to illuminance around the lighting fixture to the controller as a result of the sensing. The method of claim 5, wherein the illuminance sensor has a first level for a predetermined period immediately after sunrise, has a second level for a predetermined period immediately before sunset, and reaches a point in time just before sunset from a certain period immediately after sunrise. Outputting a voltage having a third level until and having a fourth level from immediately after sunset to just before sunrise, as the detected result, to the controller;
The control unit operates the lighting control device in the standby mode when the voltage having the third or fourth level is generated from the illuminance sensing unit, and the voltage having the first or second level is generated from the illuminance sensing unit. A lighting control device operating the lighting control device in the control mode when generated. The method of claim 5, wherein the illuminance detector outputs a voltage having a fifth level to the controller when the rate of change of illuminance is relatively fast from a time after a certain period immediately after sunrise until a time point before a sunset is reached. and,
And the control unit operates the lighting control device in the control mode when a voltage having the fifth level is generated from the illuminance sensing unit. The method of claim 1, wherein the light control device
An energy generator for converting natural energy into electrical energy and outputting the electrical energy;
An energy storage unit for storing the electrical energy; And
And a power converter converting an output voltage of the energy storage unit into an operating voltage of each unit of the lighting control device. The apparatus of claim 1, wherein the lighting control device is allocated for each zone, at least one lighting device is installed in each zone, and the brightness control signal is at least one installed in each zone. Lighting control device for controlling the lighting fixtures in a batch. The method of claim 9, wherein the control unit
Operating the lighting control device in any one of a slave mode, a master mode and an inoperable mode according to the amount of electrical energy stored in the energy storage unit,
In the slave mode, the control unit transmits another brightness control signal received from another lighting control device assigned to another zone to the lighting fixture installed in its own zone,
In the master mode, the controller transmits the brightness control signal to the luminaire installed in its zone in response to the detected result received from the illuminance sensor without the help of the other lighting control device.
In the inoperable mode, the control unit transmits a unique identification number of the other lighting control device selected as a master to the lighting fixture installed in its zone. The method of claim 10, wherein the controller switches an operation mode of the lighting control device from the master mode to the slave mode or the inoperable mode according to the amount of the electric energy stored in the energy storage unit, or the slave device. Switching the operation mode of the lighting control device from the mode to the master mode or the inoperative mode, or switching the operation mode of the lighting control device from the inoperative mode to the master mode or slave mode. The method of claim 9, wherein the control unit
And an own identification number and the brightness control signal together with the other light control device in response to a request signal received from another light control device disposed in another area.

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