KR20230026897A - LED lighting apparatuses - Google Patents

Abstract

The present invention relates to an LED lighting device comprising a device that controls a power supply of an alternating current power source, wherein the LED lighting device of the present invention comprises: a direct current power supply device that controls a supply of power by converting an input alternating current voltage of the alternating current power source into an input direct current voltage; and an LED module in which a lighting state of multiple LED arrangements is controlled according to a size of a driving voltage. Therefore, the present invention enables an operation of the LED lighting device to be controlled by a touch operation of a user.

Description

LED lighting apparatus { LED lighting apparatuses }

The present invention relates to an LED lighting device, and more particularly, to an LED lighting device driving an LED module using a microcontroller as a control device.

A conventional LED lighting device is composed of a converter circuit using AC power and an LED array, and the converter circuit has a structure that converts AC power into a constant voltage source or constant current source suitable for driving the LED array. The converter circuit includes bulky inductors and passive elements of capacitors, and is composed of switching elements and control semiconductor elements to obtain required power. This structure is commonly used in a large-scale LED lighting device in the form of a street light as well as a small-scale LED bulb in the form of an LED bulb.

Now, the development history of LED lighting devices has been developed to some extent, and the exit from the market of incandescent bulbs has accelerated miniaturization, energy efficiency, and smart user access, and various types of LED lighting devices have been developed. In recent years, LED lighting devices in which bulky inductors and passive elements of capacitors have been removed have been introduced into the market. The expansion of the LED lighting device market accelerated the development of semiconductor circuits dedicated to driving LEDs, and finally, LED driving semiconductors capable of driving LED arrays without inductors and capacitors appeared in the LED lighting device market.

The driving method of the LED driving semiconductor used in the present invention does not turn on or off all the LEDs in the LED array, but turns on only the number of LEDs sufficient to light according to the magnitude of the input voltage and keeps the rest off. is to do In particular, in the present invention, an LED array is divided into 5 groups, and LED driving semiconductors controlled by group according to an input voltage are used.

The problems of the prior art LED lighting device, which is a problem to be solved by the present invention, are that it is difficult to implement various power supply patterns, a separate complex circuit is used when a dimming function is added, and a separate touch sensing dedicated semiconductor is used for touch sensing. is to use a small one. On the other hand, in order to drive the LED array, a converter using bulky elements such as inductors and capacitors is required.

Therefore, in the present invention, an LED lighting device including an LED module using an LED driving semiconductor device available in the market and a power supply device driving the same is made. This LED driving semiconductor device is a device that can control the lighting state of a plurality of LED arrays according to the magnitude of the driving voltage. The LED lighting device of the present invention includes a microcontroller, and the built-in program of the microcontroller processes the signal of the touch terminal for touch detection, and controls the lighting of the LED module by using the AC voltage cycle of the power supply as a unit time. include

Means for solving the above problems include a microcontroller, realize lighting time and brightness control by utilizing functions of the microcontroller, and make an LED lighting device controlled by a user's touch operation using a touch terminal.

The LED lighting device 100 includes a DC power supply 110 that controls power supply by converting an input AC voltage (VAC) of AC power into an input DC voltage (VDC) and a plurality of LEDs according to the magnitude of the driving voltage. It consists of an LED module 120 in which the lighting state of the array is controlled. The DC power supply 110 includes a DC power supply unit 111, a control power supply unit 112, a DC voltage sensor 113, a touch input unit 114, a control unit 115, and a DC power switch unit 116. The DC power supply unit 111 is composed of a rectifier circuit that converts an input AC voltage (VAC) of an AC power supply into an input DC voltage (VDC); The control power supply unit 112 is composed of a constant voltage circuit that converts an input direct current voltage (VDC) into a control device voltage (VCC); The DC voltage sensing unit 113 is composed of a voltage divider circuit that converts an input DC voltage (VDC) into a DC voltage input signal (VIN); The touch input unit 114 is composed of a circuit that converts a voltage change generated when a user touches the touch terminal T into a touch input signal TIN; The controller 115 is driven by the control device voltage VCC and includes a microcontroller U1 in which a control program is embedded; The DC power switch unit 116 is composed of a switch circuit connecting a reference point (GND) and one terminal of the LED module 120; The LED module 120 is driven by an input DC voltage (VDC) and an output switch voltage (VSW), and is characterized in that it is driven by the DC power supply (110).

Since the LED lighting device of the present invention includes a microcontroller, various functions of the microcontroller can be utilized. The lighting time can be controlled and the dimming function can be implemented. If necessary, the operation of the LED lighting device may be controlled by a user's touch operation using the touch terminal.

1 is a circuit diagram of an LED lighting device including a touch terminal.
Figure 2 is a circuit diagram of an LED lighting device without a touch terminal.

The structure and function of the LED lighting device 100 of the present invention will be described with reference to FIGS. 1 and 2.

First, the concept of the LED lighting device 100 will be described. The LED lighting device 100 is driven by an input AC voltage (VAC) of AC power, and is composed of a DC power supply 110 and an LED module 120. The power supply required for lighting is provided by an electronic switch, which is controlled by an electronic control unit. The electronic control unit uses a commercially available microcontroller, which stores and executes the program. This program includes information for controlling power supply, and controls the power supplied to the LED module by outputting a control signal to the electronic switch. The electronic control device may use the period of the AC voltage of the AC power supply to determine the time of the control signal. To this end, a sensing circuit that converts the AC voltage into a rectified DC voltage and detects the DC voltage is required. The sensing circuit outputs a signal to the microcontroller by sufficiently attenuating the DC voltage to be in a voltage range that can be input to the microcontroller. The microcontroller receiving this signal processes the signal and extracts the cycle of the AC voltage.

Now, while looking at FIGS. 1 and 2, an embodiment of the LED lighting device 100 will be described in detail.

The LED lighting device 100 converts the input AC voltage (VAC) of AC power into an input DC voltage (VDC) and a reference point (GND), and as shown in FIG. 1, the input DC voltage as the user touches the touch terminal (T). It consists of a DC power supply 110 that controls the supply of (VDC) and an LED module 120 that controls the lighting state of a plurality of LED arrays according to the magnitude of the driving voltage. The DC power supply 110 drives the LED module 120 . In FIG. 2 , the supply of the input DC voltage (VDC) is controlled by a program embedded in the DC power supply device 110 without the touch terminal T.

The DC power supply 110 includes a DC power supply unit 111, a control power supply unit 112, a DC voltage sensor 113, a touch input unit 114, a control unit 115, and a DC power switch unit 116.

The DC power supply unit 111 is composed of a rectifier circuit that converts an input AC voltage (VAC) of AC power to an input DC voltage (VDC), and includes a bridge diode (B1). An input of the bridge diode is driven by an input AC voltage (VAC), and an output of the bridge diode represents an input DC voltage (VDC) and a reference point (GND). The DC power supply unit 111 drives the control power supply unit 112 , the DC voltage detector 113 and the LED module 120 .

The control power supply unit 112 is composed of a constant voltage circuit that converts an input direct current voltage (VDC) into a control device voltage (VCC), and includes a zener resistor (R1), a control voltage zener diode (Z1), and a zener voltage capacitor (C1). do. The voltage across the zener voltage capacitor represents the control device voltage (VCC) and the reference point (GND). The control device voltage VCC charges the zener voltage capacitor C1 with the zener voltage of the control voltage zener diode Z1 by the input direct current voltage VDC, and drives the control unit 115 .

The DC voltage detection unit 113 is composed of a voltage divider circuit that converts an input DC voltage (VDC) into a DC voltage input signal (VIN), a voltage sensing first resistor (R2), a voltage sensing second resistor (R3), It includes a voltage sensing zener diode (Z2). The voltage across the voltage sensing second resistor represents the DC voltage input signal VIN and the reference point GND. The voltage sensing zener diode Z2 serves to limit the DC voltage input signal VIN to a voltage that can be input to the control unit 115 . This DC voltage input signal (VIN) is input to the controller 115.

As shown in FIG. 1, the touch input unit 114 is composed of a circuit that converts a voltage change generated when a user touches the touch terminal T into a touch input signal TIN, and includes a touch signal input capacitor C2. . A voltage of a terminal connecting the touch signal input capacitor C2 and the controller 115 represents the touch input signal TIN. The touch signal input capacitor C2 serves to prevent electric shock current that may occur when a user touches the touch terminal T. The touch input signal TIN is input to the controller 115 . In the embodiment of FIG. 2 , there is no touch input unit 114 .

The control unit 115 is driven by the control device voltage VCC and includes a microcontroller U1 in which a control program is embedded. The control program includes a subroutine that creates a control output signal (VOUT) according to the DC voltage input signal (VIN) and the touch input signal (TIN), and the output timing and timing of the control output signal (VOUT) synchronized with the DC voltage input signal (VIN). A subroutine for determining the time, a subroutine for determining a change in the touch input signal TIN as a user touch operation, and a subroutine for storing a current state and determining a next state. In the embodiment of FIG. 2 , subroutines related to the touch input signal TIN are omitted. The control output signal VOUT is output to the DC power switch unit 116.

The DC power switch unit 116 is composed of a switch circuit connecting a reference point (GND) and one terminal of the LED module 120, and includes a switch resistor R4, a first NPN transistor Q1, and a second NPN transistor ( Q2) is included. The voltage of the connecting terminal represents the output switch voltage (VSW). The control output signal VOUT controls the state of the output switch voltage VSW, and supplies the input DC voltage VDC to the LED module 120 according to the state of the output switch voltage VSW. The NPN first transistor Q1 and the NPN second transistor Q2 constitute a Darlington circuit. This allows a large driving current in the output switch voltage VSW for a small current in the control output signal VOUT.

The LED module 120 is driven by an input direct current voltage (VDC) and an output switch voltage (VSW), and includes an LED module driving unit (U2), an LED module driving input resistor (R5), an LED module current control resistor (R6), and an LED A first array (LED1), a second array of LEDs (LED2), a third array of LEDs (LED3), a fourth array of LEDs (LED4), and a fifth array of LEDs (LED5) are included. The LED module driver U2 is a semiconductor device that drives a commercially available LED module. This semiconductor device is characterized in that the lighting state of the plurality of LED arrays is controlled according to the magnitude of the input DC voltage. In the low constant voltage range, only the LEDs of the first array of LEDs are turned on, and the others are turned off. As the voltage increases, the LEDs of the second array of LEDs, the third array of LEDs, the fourth array of LEDs, and the fifth array of LEDs are sequentially turned on. Therefore, by generating the control output signal VOUT in a specific time period of the input direct current voltage VDC, the lighting state and dimming function of the LED module can be implemented.

100: LED lighting device
110: DC power supply
111: DC power supply unit
112: control power unit
113: DC voltage detection unit
114: touch input unit
115: control unit
116: DC power switch unit
120: LED module
VAC: input alternating voltage
VDC: input direct current voltage
VCC: control unit voltage
VIN: DC voltage input signal
TIN: touch input signal
VOUT: control output signal
VSW: output switch voltage
GND: reference point
T: touch terminal

Claims (2)

DC power that converts the input AC voltage (VAC) of AC power into an input DC voltage (VDC) and a reference point (GND), and controls the supply of the input DC voltage (VDC) as the user touches the touch terminal (T) feeding device 110; and
An LED module 120 driven by the DC power supply 110 and controlling the lighting state of a plurality of LED arrays according to the magnitude of the driving voltage,
The DC power supply 110 is composed of a rectifier circuit that converts an input AC voltage (VAC) of AC power to an input DC voltage (VDC), and includes a bridge diode (B1), and the input of the bridge diode is Driven by an input AC voltage (VAC), the output of the bridge diode represents the input DC voltage (VDC) and the reference point (GND), and the control power supply unit 112, the DC voltage detection unit 113 and the LED module DC power supply unit 111 for driving 120;
It is composed of a constant voltage circuit that converts the input direct current voltage (VDC) into a control device voltage (VCC), and includes a zener resistor (R1), a control voltage zener diode (Z1), and a zener voltage capacitor (C1), wherein the zener voltage The voltage across the capacitor represents the control device voltage (VCC) and the reference point (GND), the control power supply unit 112 for driving the control unit 115;
It is composed of a voltage divider circuit that converts the input direct current voltage (VDC) into a direct current voltage input signal (VIN), and includes a first voltage sensing resistor (R2), a second voltage sensing resistor (R3), and a voltage sensing zener diode (Z2). Including, the voltage of both ends of the voltage sensing second resistor represents the DC voltage input signal (VIN) and the reference point (GND), and the DC voltage inputting the DC voltage input signal (VIN) to the controller 115 a sensing unit 113;
It is composed of a circuit that converts a voltage change generated when a user touches the touch terminal T into a touch input signal TIN, includes a touch signal input capacitor C2, and the touch signal input capacitor and the control unit ( 115) represents the touch input signal TIN, and the touch input unit 114 inputs the touch input signal TIN to the control unit 115;
A microcontroller (U1) driven by the control device voltage (VCC) and having a built-in program for generating a control output signal (VOUT) according to the DC voltage input signal (VIN) and the touch input signal (TIN); , a controller 115 outputting the control output signal VOUT to a DC power switch 116; and
It is composed of a switch circuit connecting the reference point (GND) and one terminal of the LED module 120, and includes a switch resistor (R4), a first NPN transistor (Q1), and a second NPN transistor (Q2), The voltage of the terminal represents the output switch voltage VSW, the control output signal VOUT controls the state of the output switch voltage VSW, and the input DC voltage according to the state of the output switch voltage VSW. Includes a DC power switch unit 116 for supplying (VDC) to the LED module 120,
The LED module 120 is driven by the input DC voltage (VDC) and the output switch voltage (VSW), and includes an LED module driving unit (U2), an LED module driving input resistor (R5), and an LED module current control resistor (R6). ), a first array of LEDs (LED1), a second array of LEDs (LED2), a third array of LEDs (LED3), a fourth array of LEDs (LED4), and a fifth array of LEDs (LED5), the LED module driver ( U2) is an LED lighting device (100), characterized in that the lighting state of the LED arrays is controlled according to the magnitude of the input DC voltage (VDC) supplied by the switch operation of the DC power switch unit (116) . A DC power supply that converts the input AC voltage (VAC) of AC power into an input DC voltage (VDC) and a reference point (GND), and controls the supply of the input DC voltage (VDC) according to the program of the control unit 115 ( 110); and
An LED module 120 driven by the DC power supply 110 and controlling the lighting state of a plurality of LED arrays according to the magnitude of the driving voltage,
The DC power supply 110 is composed of a rectifier circuit that converts an input AC voltage (VAC) of AC power to an input DC voltage (VDC), and includes a bridge diode (B1), and the input of the bridge diode is Driven by an input AC voltage (VAC), the output of the bridge diode represents the input DC voltage (VDC) and the reference point (GND), and the control power supply unit 112, the DC voltage detection unit 113 and the LED module DC power supply unit 111 for driving 120;
It is composed of a constant voltage circuit that converts the input direct current voltage (VDC) into a control device voltage (VCC), and includes a zener resistor (R1), a control voltage zener diode (Z1), and a zener voltage capacitor (C1), wherein the zener voltage The voltage across the capacitor represents the control device voltage (VCC) and the reference point (GND), the control power supply unit 112 for driving the control unit 115;
It is composed of a voltage divider circuit that converts the input direct current voltage (VDC) into a direct current voltage input signal (VIN), and includes a first voltage sensing resistor (R2), a second voltage sensing resistor (R3), and a voltage sensing zener diode (Z2). Including, the voltage of both ends of the voltage sensing second resistor represents the DC voltage input signal (VIN) and the reference point (GND), and the DC voltage inputting the DC voltage input signal (VIN) to the controller 115 a sensing unit 113;
A microcontroller (U1) driven by the control device voltage (VCC) and having a built-in program for generating a control output signal (VOUT) according to the DC voltage input signal (VIN), wherein the control output signal (VOUT) Control unit 115 for outputting to the DC power switch unit 116; and
It is composed of a switch circuit connecting the reference point (GND) and one terminal of the LED module 120, and includes a switch resistor (R4), a first NPN transistor (Q1), and a second NPN transistor (Q2), The voltage of the terminal represents the output switch voltage VSW, the control output signal VOUT controls the state of the output switch voltage VSW, and the input DC voltage according to the state of the output switch voltage VSW. Includes a DC power switch unit 116 for supplying (VDC) to the LED module 120,
The LED module 120 is driven by the input DC voltage (VDC) and the output switch voltage (VSW), and includes an LED module driving unit (U2), an LED module driving input resistor (R5), and an LED module current control resistor (R6). ), a first array of LEDs (LED1), a second array of LEDs (LED2), a third array of LEDs (LED3), a fourth array of LEDs (LED4), and a fifth array of LEDs (LED5), the LED module driver ( U2) is an LED lighting device (100) characterized in that the lighting state of the LED arrays is controlled according to the magnitude of the input DC voltage (VDC) supplied by the switch operation of the DC power switch unit (116) .

Images