KR101232304B1 - power supply control apparatus for lighting - Google Patents

Abstract

The present invention provides a power supply control device for lighting having a main light control unit for controlling the main light emitting diode module, and a network function having a sub light control unit for controlling the sub light emitting diode module according to a control signal received from the main light control unit. The main lighting control unit includes a power supply unit for converting commercial AC power into a DC power source, a main control unit driven by electric power supplied from the power supply unit, an input unit capable of inputting input signals to the main control unit, and a main control unit. A sub-communication unit controlled by the main communication unit for transmitting a control signal to the sub-illumination control unit, the sub-illumination control unit processing a signal received through the main communication unit, a sub-drive unit driving the sub-light emitting diode module; Sub according to the control signal received through the sub communication unit Presented photodiode module is driven and a sub-controller for controlling the sub-drive. According to the lighting power supply control device having the network function, by transmitting the optical signal control information through the flashing pattern of the light emitting diode module applied for lighting, it is possible to reduce the control signal transmission error environment, and to provide a plurality of different transmission methods. It offers the advantage of reducing the required components.

Description

Power supply control apparatus for lighting with network function

The present invention relates to a lighting power supply control device having a network function, and more particularly to a lighting power supply control device having a network function to be able to control the sub-light control unit from the main lighting control unit.

Recently, with the development of communication technology and sensor technology, various technologies for controlling lighting devices have been developed.

On the other hand, the control unit for controlling the lighting device and the power supply unit for supplying power to the lighting device is mostly provided separately, there is a disadvantage that the workability during the installation is not good.

In addition, a method of partitioning a lighting area and controlling the lighting through the communication of the sub control area in the main control area with respect to the partitioned lighting area is also known. It has a structure that transmits a control signal by using a separate communication channel, and there is a problem in that resource utilization is low. When only a single communication channel is applied, normal control of the sub control area is performed when an error occurs in the communication channel. There is a problem.

On the other hand, when a wireless communication such as wired communication and RF (Rf) signal to be built in parallel to perform the communication there is a problem that the configuration is complicated and the economic burden increases.

The present invention has been made to solve the above problems, and while driving the LED module for lighting independently from each other, the control signal can be transmitted in a plurality of different transmission methods from the main lighting control unit to the sub-light control unit. It is an object of the present invention to provide a lighting power supply control device having a network function that can be simplified.

Still another object of the present invention is to provide a lighting power supply control device having a network function in which a control unit for controlling a light emitting diode module for lighting and a power supply unit for supplying power to the light emitting diode module are integrally formed.

In order to achieve the above object, a lighting power supply control apparatus having a network function according to the present invention includes a main lighting control unit for controlling a main light emitting diode module and a sub light emitting diode module according to a control signal received from the main lighting control unit. A lighting power supply control device having a network function having a sub-light control unit for controlling the power supply, the main lighting control unit comprising: a power supply unit for converting commercial AC power into DC power; A main control unit driven by electric power supplied from the power supply unit; An input unit for inputting an input signal to the main control unit; A main communication unit controlled by the main control unit to transmit a control signal to the sub illumination control unit, wherein the sub illumination control unit includes a sub communication unit processing a signal received through the main communication unit; A sub driver for driving the sub light emitting diode module; And a sub controller configured to control the sub driver to drive the sub light emitting diode module according to a control signal received through the sub communication unit.

Preferably, the main controller processes the drive control information of the sub light emitting diode module determined according to the control condition information input through the input unit to be transmitted as an electrical signal through the main communication unit, and the drive transmitted through the main communication unit. A light receiver configured to control the main driver to generate optical signal information corresponding to control information by a blinking pattern of the main LED module, and the sub illumination control unit to detect the blinking pattern information of the main LED module; And the western control unit reads the optical signal information of the main control unit from the blinking pattern information received from the light receiving unit, and the sub communication unit in a state in which control information contained in the blinking pattern information received from the light receiving unit is received. If control information is not received through And it controls the driving of the sub-light-emitting diode module according to the cylinder control information in the flashing pattern information received through the light receiving portion.

In addition, the main light emitting diode module includes a first light emitting diode for outputting a wavelength of the visible light band; And a second light emitting diode for outputting infrared light, and the light receiving unit may be an infrared light receiving sensor for receiving infrared light output from the second light emitting diode.

According to the lighting power supply control apparatus having a network function according to the present invention, by transmitting the optical signal control information through the flashing pattern of the light emitting diode module applied for lighting, it is possible to reduce the control signal transmission error environment, a plurality of different transmission methods It offers the advantage of reducing the components required to achieve this.

1 is a block diagram showing a lighting power supply control device having a network function according to the present invention,
FIG. 2 is a detailed block diagram of the main lighting control unit of FIG. 1 and the sub lighting control unit. FIG.
FIG. 3 is a diagram illustrating a driving waveform for explaining an example of a blinking pattern generated by the main lighting control unit of FIG. 1.

Hereinafter, a lighting power supply control apparatus having a network function according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in more detail.

1 is a block diagram illustrating a lighting power supply control apparatus having a network function according to the present invention, Figure 2 is a detailed block diagram of the main lighting control unit and the sub-light control unit of FIG.

1 and 2, the lighting power supply control apparatus 100 having a network function includes a main lighting control unit 110, a main light emitting diode module 150, a plurality of sub lighting control units 210, and a sub light emitting unit. The diode module 250 is provided.

The main lighting control unit 110 controls the main light emitting diode module 150 and the sub lighting control unit 210 through a communication network.

The sub lighting control unit 210 controls the sub light emitting diode module 250 according to the control signal received from the main lighting control unit 110.

Here, the main lighting control unit 110 includes an input unit 111, a main control unit 113, a main communication unit 115, a main driver 117, a main memory 119, and a power supply unit 130.

The input unit 111 may input a control input signal corresponding to a driving condition of the main light emitting diode module 150 or the sub light emitting diode module 250 through the main control unit 113.

The input unit 111 may set a driving condition through an operation key to input the main control unit 113 in a wired or wireless manner, or when the illumination level is higher than the set illumination level, the main LED module 150 or the sub LED module 250 is turned off. And a human body detecting sensor that emits light when the human body is detected when the detected illuminance is less than the set illuminance or a human body sensor that turns off when the human body is detected.

The main communication unit 115 is controlled by the main control unit 113 and transmits a control signal to the sub-light control unit 210.

The main communication unit 115 may be configured to transmit an electrical control signal to the sub communication unit of the sub illumination control unit 210 through a wire.

Alternatively, the main communication unit 115 may be configured to transmit the wireless RF control signal to the sub communication unit 215 of the sub illumination control unit 210.

The main driver 117 is controlled by the main controller 113 to switch on / off power supply from the power supply unit 130 to the main light emitting diode module 150 to drive the main light emitting diode module 150.

The main memory 119 includes a main communication unit 115 when processing driving control information of the sub light emitting diode module 250 determined according to control condition information input through the input unit 111 to be transmitted through the main communication unit 115. Blinking pattern information of the main LED module 150 for generating optical signal information set corresponding to the driving control information transmitted through the driving control information is stored.

The power supply unit 130 converts commercial AC power into DC power, and is integrally formed with the main lighting control unit.

The power supply unit 130 may be constructed as a conventional switching mode power supply (SMPS).

The power supply unit 130 includes a noise filter for removing noise included in the AC power supply, a primary rectifying unit for rectifying AC passing through the noise filter, and a power source smoothed through the primary rectifying unit to the primary coil of the high frequency transformer. The switching unit for switching the current conduction by the pulse width modulation method and the rectified power to the secondary coil of the high frequency transformer to generate a drive DC power source for the main lighting control unit 110 and the main light emitting diode module 150 It is a feedback detector which detects the output voltage of the secondary rectifier and the secondary rectifier, and provides it to a power supply control unit that controls the switching unit.

The power supply unit 130 may be configured to supply driving DC power for the sub illumination control unit 210 and the sub light emitting diode module 250. Alternatively, the sub illumination control unit 210 and the sub light emitting diode module 250 may be provided. Of course, it can be built as a separate power supply.

The main controller 113 is driven by the power supplied from the power supply unit 130 and controls the driving of the main light emitting diode module 150 and the sub illumination control unit 210 according to the information input through the input unit 111.

Here, the conditions for controlling the driving of the main light emitting diode module 150 and the sub light control unit 210 according to the information input through the input unit 111 is the main light emitting diode module 150 and the sub light emitting diode module 250. It can be applied in various ways depending on the installation environment.

As an example, an illuminance sensor is applied as the input unit 111, and the main control unit 113 turns off the sub light emitting diode module 250 when the illuminance input from the input unit 111 is equal to or greater than the set reference illuminance, and the main light emitting diode module. If only 150 is turned on and the illuminance is less than the set reference illuminance, the sub light emitting diode module 250 is turned on and the main light emitting diode module 150 is continuously turned on. The control information corresponding to the on / off of the light emitting diode module 250 is transmitted to the sub illumination control unit 210.

Preferably, the main controller 113 processes the driving control information of the sub light emitting diode module 250 determined according to the control condition information input through the input unit 111 to be transmitted as an electrical signal through the main communication unit 115, The main driver 117 is controlled such that the optical signal information set to correspond to the driving control information transmitted through the main communication unit 115 is generated by a blinking pattern by driving on / off of the main light emitting diode module 150.

Here, the blinking pattern information may be used to indirectly transmit control information when an error occurs in a signal transmitted through the main communication unit 115 or a problem occurs in a wired communication channel between the main communication unit 115 and the sub communication unit 215. The detailed description will be described later.

In the main LED module 150, a plurality of LEDs 151 are arrayed and turned on / off by the main driver 117.

Preferably, the main light emitting diode module 150 is connected to the first light emitting diode 151 for outputting the wavelength of the visible light band and the second light emitting diode 151a for outputting infrared light by the main driver 117. It is constructed to emit light on / off.

Here, the second light emitting diode 151a for outputting infrared light is for transmitting an optical signal through the light receiving unit 211 described later.

The sub illumination control unit 210 includes a sub controller 213, a sub communication unit 215, a sub driver 217, a sub memory 219, and a light receiver 211.

 The sub communication unit 215 processes the signal received through the main communication unit 115 and outputs the signal to the sub control unit 213.

The sub communication unit 215 may be configured to receive a signal through the wired communication channel with the main communication unit 115 or may be configured to receive a wireless RF signal.

The sub driver 217 is controlled by the sub controller 213 to drive the sub light emitting diode module 250 on / off.

The light receiving unit 211 detects the blinking pattern information of the main LED module 150 and provides it to the sub controller 213.

The light receiving unit 211 may be configured to receive a blinking pattern of the first light emitting diode 151 that outputs visible light.

Preferably, the light receiving unit 211 is an infrared light receiving sensor for receiving the infrared light output from the second light emitting diode 151a.

In the sub memory 219, control signal information corresponding to the flashing pattern information generated from the main LED module 150 is recorded so that the sub controller 213 can use the optical signal to be read.

The sub controller 213 controls the sub driver 217 to drive the sub light emitting diode module 250 according to a control signal received through the sub communication unit 215.

In addition, the sub controller 213 reads the optical signal information of the main controller from the blinking pattern information received from the light receiving unit 211, and the sub communication unit in the state in which the control information contained in the blinking pattern information received from the light receiving unit 211 is received. If the control information is not received through 215, the control information is determined to be an error of the signal transmission system through the sub communication unit 215, and the control information contained in the flashing pattern information received through the light receiving unit 211 is recorded in the sub memory 219. Information is read using information, and the driving of the sub light emitting diode module 250 is controlled according to the read control information.

The sub light emitting diode module 250 includes a plurality of second light emitting diodes 151 that emit light of visible light.

An example of control signal generation by a blinking pattern in the lighting power supply control device 100 will be described with reference to FIG. 3.

First, it is possible to generate a plurality of bit information for the unit information generation section (a) set for the main light emitting diode module 150, wherein the plurality of bit information of the main light emitting diode module 150 in the unit information generation section (a) In order to make it difficult for the human body to visually recognize the off state of light emission by using the afterimage effect of the human body on / off, a frequency corresponding to the period of the unit information fish section (a) applies several KHz to several hundred KHz. Here, the driving waveform refers to a waveform for switching on / off power supply to the main light emitting diode module 150 by the main driver 117.

In the illustrated example, a 4-bit signal is generated during the unit information generation section (a), and a driving waveform is generated with a duty of 50% for each bit generation section. That is, in FIG. 3, T is a bit generation period, and in order to reduce signal detection error of the light receiving unit 211, when generating information of '1' corresponding to a binary signal in the bit generation period, the signal is generated at a duty of 50%. Was applied.

Here, when the flashing pattern information is to be generated while adjusting the luminance of the main LED module 150, the duty ratio for the bit generation period may be adjusted.

In this case, information generated in the first unit information generation section is '1110', information generated in the second unit information generation section is '1110', information generated in the third unit information generation section is '1111', and fourth unit information. The information generated in the generation section is '1010'.

Therefore, various bits of control information may be transmitted to the sub controller 213 through the light receiver 211 through the bit information.

In addition, the blinking pattern generated through the main light emitting diode module 150 may be constructed to occur while having a certain rest period.

As an example, an illuminance sensor is applied as the input unit 111, and the main control unit 113 turns off the sub light emitting diode module 250 when the illuminance input from the input unit 111 is equal to or greater than the set reference illuminance, and the main light emitting diode module. If only 150 is turned on and the illuminance is less than the set reference illuminance, the sub light emitting diode module 250 is turned on and the main light emitting diode module 150 is continuously turned on. When the control command to turn on the light emitting diode module 250 is the main control unit 113, if the illuminance signal of the input unit 111 is less than the set reference illuminance, the main control unit 113 through the main communication unit 115 through the sub communication unit ( 215 transmits a control command to turn on the sub LED module 250 according to a set communication system, and generates a '1110' blinking pattern signal through the main driver 117 through the main driver 117. Drive.

On the other hand, when the second light emitting diode 151a for emitting infrared light to the main light emitting diode module 150 is applied and the infrared light receiving sensor for receiving the infrared light by the light receiving unit 211 is applied, the human body visually receives infrared light. Since the second light emitting diode 151a may be installed at a position outside the illumination area of the main light emitting diode module 150 since it is not recognized, the second light emitting diode 151a may be constructed to reduce an infrared signal detection error of the light receiving unit 211 by external light. There is an advantage.

The flashing pattern generated through the main light emitting diode module 150 in the power supply control device 100 recognizes the human body as visually on by the afterimage effect, and thus bypasses the control information while maintaining the normal lighting effect. It offers the advantage of being able to transmit to the network.

110: main light control unit 150: main light emitting diode module
210: sub light control unit 250: sub light emitting diode module

Claims (3)

In the lighting power supply control device having a network function comprising a main lighting control unit for controlling the main light emitting diode module, and a sub-lighting control unit for controlling the sub light emitting diode module according to the control signal received from the main lighting control unit. ,
The main lighting control unit
A power supply unit converting commercial AC power into DC power;
A main control unit driven by electric power supplied from the power supply unit;
An input unit configured to input an input signal to the main control unit;
And a main communication unit controlled by the main control unit to transmit a control signal to the sub illumination control unit.
The sub light control unit
A sub communication unit processing a signal received through the main communication unit;
A sub driver for driving the sub light emitting diode module;
And a sub controller configured to control the sub driver to drive the sub LED module according to a control signal received through the sub communication unit.
The main controller processes the drive control information of the sub light emitting diode module determined according to the control condition information input through the input unit to be transmitted as an electrical signal through the main communication unit, and to the drive control information transmitted through the main communication unit. The main driver is controlled to generate the corresponding optical signal information by the blinking pattern of the main LED module.
The sub light control unit
And a light receiving unit detecting the blinking pattern information of the main light emitting diode module.
The sub control unit reads the optical signal information of the main control unit from the blinking pattern information received from the light receiving unit, and control information is stored through the sub communication unit in a state in which control information contained in the blinking pattern information received from the light receiving unit is received. If not received, controls the driving of the sub light emitting diode module according to the control information contained in the flashing pattern information received through the light receiving unit.
The main light emitting diode module includes a first light emitting diode for outputting a wavelength in a visible light band;
And a second light emitting diode connected in series with the first light emitting diode and turned on / off with the first light emitting diode by the main driver to output infrared light.
The light receiving unit is a power supply control device for lighting having a network function, characterized in that the infrared light receiving sensor for receiving the infrared light output from the second light emitting diode.
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