KR20120106467A - Light control device - Google Patents

Abstract

PURPOSE: An illumination control device is provided to effectively control each illumination installed on each area by controlling power supplied to the illuminations. CONSTITUTION: A control block(100) of an illumination control device includes a controller(102), a first communication module(104), a power connector(106), a first connecter(108), a USB connector(110) and a switch(112). The controller receives various signals from the first communication module. The first communication module includes a first PLC circuit and a first signal transceiver circuit. The power connecter supplies 5V power to the controller. The first connector is connected to the controller through an MCLR terminal, a PGC terminal, and a PGD terminal.

Description

Lighting control device {LIGHT CONTROL DEVICE}

The present invention relates to an apparatus for controlling lighting for each region in a designated space.

Initially, home networking meant a range of home automation and home control systems that automatically controlled security, lighting, and temperature in the home.

Since then, as the number of households with multiple PCs and peripherals in a home has increased, networking technologies have emerged to connect them efficiently, and the Home Networking Kit has been introduced to support them. It began to be used in earnest.

In addition, with the development of advanced transmission media technologies such as telephone lines, power lines, and wireless, and broadband network of subscriber networks such as DSL and Cable Modem, broadband internet is expanding rapidly. Intelligent communication has been enabled by providing access to external Internet networks while providing a path for the exchange of data between digital electronic devices in the home.

With the advent of home networking technology, integrated control of electronic devices is enabled, and by applying home networking technology to offices and parking lots, various electronic devices such as lighting devices and access devices can be automatically controlled.

However, in the related art, since electronic devices are controlled only according to the conditions set in the related art, there is a problem in controlling lighting according to changing conditions even when the surrounding environment (for example, illuminance or motion) changes.

An object of the present invention is to provide a lighting control device capable of adjusting a plurality of lights, respectively, according to a surrounding environment by performing bidirectional communication with a lighting device installed in a designated space.

In addition, the present invention is to provide a lighting control device that can control a plurality of lights for each area according to the illumination and the movement through the bi-directional communication by detecting the illumination and the movement in the lighting device.

The objects of the embodiments of the present invention are not limited to the above-mentioned objects, and other objects, which are not mentioned above, will be clearly understood by those skilled in the art from the following description. .

According to an embodiment of the present invention, when the illumination signal and the motion detection signal are input through the PLC communication, the illumination value for each area to have a predetermined target illumination value for each area in the designated space according to the input illumination signal and the motion detection signal The control block outputs an illumination control control signal for controlling a plurality of lights through the PLC communication, and controls the illumination signal and the motion detection signal sensed through the illumination sensor and the motion detection sensor installed for each region in the designated space. A lighting control block outputting a block and outputting a control signal for each region for adjusting power supplied to the plurality of lights by analyzing the lighting control control signal when the output lighting control signal is input; Supplying power to each of the lights, according to the output control signal for each area of the plurality of A light control device including a power supply block for controlling the respective supply voltage to be supplied to patients can be provided.

According to the present invention, an illuminance signal and a motion detection signal may be respectively input to a control block through a PLC-type bidirectional communication from an illumination control block, and a space designated to have a predetermined target illumination value by reflecting the illuminance signal and the motion detection signal By transmitting a light adjustment control signal for adjusting the light to the lighting value for each region to the lighting control block, it is possible to effectively control the lighting for each region within the designated space, thereby effectively saving energy.

In addition, in the lighting control block, after receiving and analyzing the lighting control control signal transmitted from the control block, by adjusting the power supplied to the lighting for each area, it is possible to effectively adjust the lighting installed for each area.

1 is a diagram illustrating a control block of a lighting control device according to an embodiment of the present invention;
2 is a diagram illustrating a lighting control block connected to the control block of FIG. 1 in accordance with an embodiment of the present invention;
3 illustrates a power block connected to the lighting control block of FIG. 2 in accordance with an embodiment of the invention.

Advantages and features of the embodiments of the present invention, and methods of achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions in the embodiments of the present invention, which may vary depending on the intention of the user, the intention or the custom of the operator. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a control block of a lighting control device according to an embodiment of the present invention.

Referring to FIG. 1, the control block 100 of the lighting control device includes a control unit 102, a first communication module unit 104, a power connection unit 106, a first connection unit 108, a USB connection unit 110, and a switch. The unit 112 may be included.

When the illuminance signal and the motion detection signal are input from the illumination control block to be described later through PLC communication, the control block 100 may have a predetermined target illumination value for each area in the designated space according to the input illuminance signal and the motion detection signal. An illumination control signal for controlling a plurality of lights by a star illumination value may be output through a PLC communication to an illumination control block to be described later.

Referring to the above-described control block 100 in detail, the control unit 102 is connected to the SDO terminal of the first communication module unit 104 through the SDO (data output) terminal, the control unit 102 is SDI (data input) By connecting to the SDI terminal of the first communication module unit 104 via the terminal, various signals (eg, illuminance signal, motion detection signal, etc.) from the first communication module unit 104 are input through the SDO terminal. In addition, various signals (eg, lighting control signals) of the controller 102 may be output to the first communication module unit 104 through the SDI terminal.

In addition, DC power of the power connection unit 106 may be supplied through the VDD (drain power supply) terminal of the control unit 102, and the first connection unit 108 may be provided through the MCLR terminal, the PGC terminal, and the PGD terminal of the control unit 102. And may be connected to another device in an ICD manner.

In addition, the controller 110 may be connected to the USB connection unit 110 through the USB_D + terminal and the USB_D- terminal of the controller 102 to be connected to a communication terminal (for example, a computer, etc.) in a USB manner.

Meanwhile, the switch on / off signal may be input by being connected to the switch 112 through the SW1 terminal, the SW2 terminal, and the SW3 terminal of the controller 102, respectively.

When the illumination signal and the motion detection signal are input from the first communication module unit 104, the controller 102 having the above-described configuration adjusts the illumination to have a predetermined target illumination value according to the illumination signal and the motion detection signal. It is possible to output a control signal for controlling illumination. Here, the preset target illumination value means a value obtained by adding the illumination value of the illumination signal and the illumination value for controlling the illumination, and may be set to different values for each region.

In addition, the illumination signal and the motion detection signal are sensed for each area through an illumination sensor and a motion detection sensor respectively installed in a plurality of lights (LED lights) installed inside a designated space, thereby detecting a plurality of illumination signals and a plurality of motions for each area. Signals may be input, respectively, and thus the illumination adjustment control signal may be output to have a plurality of illumination values for each region. The lighting value for each region may have a different value for each region because the preset target lighting value may have a different value.

The first communication module unit 104 may include a first PLC circuit 104a, a first signal transmission / reception circuit 104b, and the like.

Here, the first PLC circuit 104a is a communication module for general PLC communication, and can perform bidirectional communication, and the first signal transmission / reception circuit 104b includes an insulated transformer for signal transmission. The power signal including the data signal may be transmitted or may be separated from the power signal input through the INLET1 terminal and transmitted to the first PLC circuit 104a.

The first communication module unit 104 may be connected to the L1 terminal and the L2 terminal of the lighting control block to be described later through the INLET1 terminal, thereby performing a two-way communication using a PLC method. That is, various signals (for example, illuminance signals, motion detection signals, etc.) from the lighting control block can be transmitted to the control unit 102, and various signals (for example, lighting control signals, etc.) from the control unit 102 are transmitted. Can be passed to the lighting control block.

The power connection unit 106 may be connected to the DC power supply through the connector CN7 terminal to input the DC power supply to supply the power supply such as 5V to the control unit 102. In this case, the LED1 illumination may be emitted according to the connection of the DC power supply.

The first connection unit 108 may be connected to the control unit 102 through an MCLR terminal, a PGC terminal, and a PGD terminal, and may be connected to another device through an IDC connector.

The USB connection unit 110 may be connected to the control unit 102 through the USB_D + terminal and the USB_D- terminal, and may be connected to the communication terminal through the USB1 terminal in a USB manner, and various signals transmitted from the communication terminal (for example, lighting control settings). Signal) can be transmitted to the control unit 102, and the illuminance signal and the motion detection signal from the control unit 102 can be transmitted to the communication terminal through the USB1 terminal.

The switch unit 112 may include a first switch unit 112a, a second switch unit 112b, a third switch unit 112c, and the like. The switch unit 112 may be connected to the control unit 102 through the SW1 terminal, the SW2 terminal, and the SW3 terminal, respectively, and each switch on / off signal may be selectively input to the control unit 102.

Therefore, in the control block of the lighting control device, the illumination signal and the motion detection signal may be input through the PLC-type bidirectional communication, respectively, and the area in the space designated to have a predetermined target illumination value by reflecting the illumination signal and the motion detection signal. By transmitting a light adjustment control signal for adjusting the light to a star light value, it is possible to effectively control the light for each area within a specified space, thereby saving energy effectively.

Next, a lighting control block connected to the control block having the circuit configuration as described above and connected to the illumination sensor and the motion detection sensor, respectively, to adjust the illumination will be described.

2 is a diagram illustrating a lighting control block connected to the control block of FIG. 1 according to an embodiment of the present invention.

1 and 2, the lighting control block 200 connected to the control block 100 of the lighting control device includes an lighting control unit 202, a signal amplifier 204, and a second communication module unit 206. The voltage generator 208, the current amplifier 210, the digital variable resistor 212, and the second connector 214 may be included.

The illumination control block 200 outputs the illumination signal and the motion detection signal sensed through the illumination sensor and the motion detection sensor installed for each area in the designated space to the control block 100, and the output light adjustment control signal is a control block. When input from the 100, the control signal may be interpreted to output a control signal for each region for controlling power supplied to the plurality of lights to a power block to be described later.

In detail with respect to the above-described light control block 200, the light control unit 202 is connected to the illumination sensor through the CDS_IN terminal, the sensed illumination signal can be input to the RA2 line, from the signal amplifier 206 The transferred motion detection signal may be input to the RA5 line. The illuminance signal and the motion detection signal may have an address (ie, an address number) corresponding to a location of each installation area in a designated space.

In addition, the lighting control unit 202 is connected to the second communication module unit 204 through the RC7 line to output the illuminance signal and the motion detection signal sensed for each region to the second communication module unit 204 along with the address. It may be connected via the second communication module unit 204 through the RB4 line to input a light control control signal for adjusting the illumination for each area from the second communication module unit 204.

The lighting controller 202 analyzes the input lighting control signal and then generates a pulse width modulation (PWM) signal (control signal for each region) for adjusting the lighting value for each region through the RC4 line. ) May be connected to the digital variable resistor unit 212 through the RC4 line and the RC3 line to output a data signal (eg, a 16 byte signal) for generating a digital variable resistor.

Meanwhile, the lighting controller 202 may be connected to the second connector 214 through the CHK_VIN terminal to output a region-specific control signal for adjusting the supply power. In addition, the lighting control unit 202 is connected to the power block to be described later through the CN1: 6 connector and is supplied with power, so that the lighting may be continuously driven even if the lighting is turned off.

The signal amplifier 204 may be connected to a motion sensor (motion sensor) through the CN2 terminal, and the motion detection signal input from the motion sensor may be amplified and input to the lighting controller 202 through the RA5 line. Here, a plurality of motion detection sensors may be additionally installed to correspond to illumination (LED lighting) installed for each region within a designated space.

The second communication module unit 206 may include a second PLC circuit 206a, a second signal transmission / reception circuit 206b, and the like.

Here, the second PLC circuit 206a is a communication module for general PLC communication, and can perform bidirectional communication, and the second signal transmission / reception circuit 206b includes an insulation transformer for signal transmission, and includes an L1 terminal and The power signal including the data signal may be transmitted through the L2 terminal, or the data signal may be separated from the power signals input through the L1 terminal and the L2 terminal and transmitted to the second PLC circuit 206a.

The second communication module unit 206 may be connected to the INLET1 terminal of the control block through the L1 terminal and the L2 terminal, thereby performing PLC-type bidirectional communication. That is, various signals (eg, illuminance signals, motion detection signals, etc.) from the lighting controller 202 may be transmitted to the control block 100, and various signals (eg, lighting) from the control block 100 may be transmitted. Control signal, etc.) may be transmitted to the lighting controller 202.

The voltage generator 208 may generate a PWM signal output through the RC5 line of the lighting controller 202 as a voltage value, thereby outputting a PWM signal as a digital signal as a voltage value as an analog signal. This voltage generation may be generated according to Equation 1 below using the ratio value (duty value,%) of the high signal to the low signal of the PWM signal and the resistance relationship of R27 and R28.

Here, V _out refers to a voltage generated by the voltage generator 208 and output from 208a, and V _cc refers to a collector power supply (eg, + 5V) of the transistor MMBT2907.

The current amplifier 210 may amplify the current value with respect to the voltage value output from the voltage generator 208 and transmit the current value to the power block to be described later through the CN1: 5 terminal.

The digital variable resistor unit 212 is connected to the lighting controller 202 through the U / D line and the CS line to generate a digital resistance value so that the variable resistor can be applied to the power block to be described later. And a resistance value signal may be transmitted to the second connector 214 through the VR_A terminal.

The second connector 214 includes a regulator, a plurality of connectors CN1: 1, CN1: 2, CN1: 3, CN1: 4, and the like, and is connected to the lighting control unit 202 through the CHK_VIN terminal. The control signal may be transmitted to a power block to be described later through the connector.

In addition, the second connection unit 214 is connected to the digital variable resistor unit 212 through the VR_W terminal and the VR_A terminal to transmit a resistance value signal transmitted from the digital variable resistor unit 212 through the CN1: 2 and CN1: 3 connectors. It can be transmitted to a power block described later.

Therefore, in the lighting control block of the lighting control device, the illumination intensity signal and the motion detection signal sensed for each area in the space designated by the PLC method can be transmitted to the control block, and after receiving and analyzing the lighting control control signal transmitted from the control block, By adjusting the supply power supplied to the lights for each area, it is possible to effectively control the lights installed for each area.

Next, a power block connected to the lighting control block having the above-described circuit configuration and supplying power to the lighting according to the adjustment of the lighting control block will be described.

3 is a diagram illustrating a power block connected to the lighting control block of FIG. 2 according to an embodiment of the present invention.

2 and 3, the power block 300 of the lighting control device may include a power supply unit 302, a third connection unit 304, a supply power control unit 306, and the like. The power block 300 may be installed in each of the lights installed for each area so that each of the power blocks 300 may be operated. Hereinafter, the power block 300 will be described as supplying power to one light.

The power block 300 supplies power to the plurality of lights, respectively, and may adjust the supply power supplied to the plurality of lights according to control signals for each region output from the light control block 200.

Referring to the above-described power block 300 in detail, the power supply unit 302 may be supplied with AC power through the CN1 connector to supply power to the light (LED) connected through the CN2 connector. Since this configuration is a general configuration implemented in the prior art, the detailed description thereof will be omitted.

The third connection unit 304 is connected to the lighting control block 200 including a plurality of connectors CN3: 1, CN3: 2, CN3: 3, CN3: 4, CN3: 5, CN3: 6, and CN3 The: 1 connector is connected to the CN1: 1 connector of the second connector 214, the CN3: 2 connector is connected to the CN1: 2 connector of the second connector 214, and the CN3: 3 connector is connected to the second connector 214. CN3: 4 connector is connected to the CN1: 3 connector of the second connector 214, CN3: 4 connector is connected to the CN1: 5 connector of the current amplifier 210, Various signals for adjusting the supply power from the adjustment block 200 may be input to the power supply unit 302 and the supply power control unit 306.

For example, the CN3: 1 connector and the CN3: 2 connector may be connected to the VCC terminal of the power supply unit 302 by connecting the VCC terminal, and the CN3: 3 connector may be connected to the CTRL1 terminal of the supply power control unit 306. The terminal may be connected to the CTRL1 terminal, and the CN3: 5 connector may be connected to the VREF terminal of the power supply unit 302 by connecting the VREF terminal.

Meanwhile, the CN3: 6 connector of the third connector 304 may be connected to the CN1: 6 connector of the lighting controller 202, thereby supplying power from the power supply controller 306 to the lighting controller 202. .

The supply power control unit 306 includes a comparator, which may be connected to the power supply unit 302 through the VCC terminal and the VOUT terminal, and adjusts the current of the voltage value input through the VREF terminal of the power supply unit 302. The CN2 connector can be used to power the light.

Here, the power supply adjusting unit 306 may generate a variable resistance between 306a and 306b through a digital resistance value input through the CTRL1 terminal, thereby more accurately adjusting the current value of the power supplied to the lighting.

On the other hand, when the power supply is not input to the predetermined voltage value (LED light) is turned off, the power supply control unit 306 is connected to the third connection unit 304 through the CTRL terminal and the third connection unit By being connected to the lighting control unit 202 through the 304, it is possible to stably supply driving power for the operation of the lighting control unit 202.

Here, the predetermined voltage value is that the LED light is composed of 10 LEDs, if a voltage drop of 3V occurs when 5V is supplied from one LED, the LED light is turned off when the power supply is less than 30V, Power may be supplied to the lighting controller 202 as a driving power.

Therefore, in the power block of the lighting control device, it is possible to stably supply power to the lighting by using a voltage value, a current value, a resistance value, etc. for supply power adjustment transmitted from the lighting control block.

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 embodiments, but, on the contrary, It will be readily apparent that such substitutions, modifications, and alterations are possible.

100: control block 102: control unit
104: first communication module unit 106: power connection unit
108: first connection unit 110: USB connection unit
112: switch 200: light control block
202: lighting control unit 204: signal amplification unit
206: second communication module unit 208: voltage generator
210: current amplifier 212: digital variable resistor
214: second connection portion 300: power block
302: power supply unit 304: third connection unit
306: power supply control unit

Claims (10)

When the illuminance signal and the motion detection signal are input through the PLC communication, the illumination for adjusting a plurality of lights with the illumination value for each area to have a predetermined target illumination value for each area in the designated space according to the input illumination signal and the motion detection signal. A control block for outputting an adjustment control signal through the PLC communication;
The illuminance signal and the motion detection signal sensed by the illuminance sensor and the motion detection sensor installed for each region in the designated space are output to the control block, and when the output illumination control signal is input, the illumination control signal is analyzed. And lighting control block for outputting a control signal for each area for adjusting the power supplied to the plurality of lights;
A power block for supplying power to the plurality of lights, respectively, and controlling supply power supplied to the plurality of lights according to the control signals for each region outputted thereto;
Lighting control device comprising a. The method of claim 1,
The control block,
A first communication module unit performing bidirectional PLC communication through a first PLC circuit, and separately transmitting and transmitting a first data signal from a first power signal through a first signal transmission / reception circuit including a first insulation transformer;
After comparing the illuminance signal and the motion detection signal input through the first communication module unit with the preset target illumination value, the illumination value for each area is determined, and the determined illumination value for each area is determined by the first communication module unit. A control unit for outputting to the lighting control block through;
Power connection unit for supplying DC power to the control unit
Lighting control device comprising a. The method of claim 2,
The control block,
A switch unit for inputting a signal for turning on or off the plurality of lights to the controller, respectively;
A first connector connected to the controller to connect an external device through an ICD connector
Lighting control device further comprising. The method according to claim 2 or 3,
The control block,
It is connected to the control unit and connected to an external communication terminal through a USB terminal, and transmits data for displaying the illuminance signal and the motion detection signal for each area to the communication terminal, and the setting data transmitted from the communication terminal USB connection to transmit to
Lighting control device further comprising. The method of claim 2,
The lighting control block,
A second communication module unit performing bidirectional PLC communication through a second PLC circuit and separating and transferring a second data signal from a second power signal through a second signal transmission / reception circuit including a second insulation transformer;
Transmitting the illuminance signal and the motion detection signal to the control block through the second communication module unit, and interprets the illumination control control signal input through the second communication module unit to output the control signal for each area of the PWM method. With lighting controls,
A voltage generator for generating a voltage value using the control signal for each region;
A current amplifier for amplifying the current value of the generated voltage value and outputting it to the power block;
A digital variable resistor unit generating a digital resistance value according to a supply power control signal transmitted from the lighting controller and outputting the generated resistance value to the power block;
Connecting the output of the current amplifier and the digital potentiometer to the power block.
Lighting control device comprising a. The method of claim 5, wherein
The lighting control block,
A signal amplification unit for amplifying the motion detection signal sensed by the motion detection sensor to output to the illumination control unit
Lighting control device further comprising. The method according to claim 5 or 6,
And the voltage generator is configured to generate the voltage value using a ratio (duty value,%) of a high signal to a low signal of a PWM signal and a resistance relationship. The method according to claim 5, wherein
The power block,
A power supply unit supplying input AC power to the plurality of lights;
A power supply controller which is connected to the power supply unit and a voltage line, and adjusts and outputs a supply power current value of the supply power supplied to the plurality of lights through a comparator when the voltage value amplified by the current value is input; ,
Third connection unit for connecting the power supply control unit and the lighting control unit
Lighting control device comprising a. The method of claim 8,
The power supply control unit, the lighting control device to generate a variable resistor using the resistance value generated from the digital variable resistor unit, and to adjust the supply power current value through the generated variable resistor. The method according to claim 8 and 9,
The power supply control unit, the lighting control device for supplying driving power to the lighting control unit through the third connection when the predetermined voltage value is not input the state of the plurality of lights off.

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