KR102706818B1 - Led driving apparatus - Google Patents

Abstract

An LED driving device is disclosed. The LED driving device of the present invention is characterized by including a signal conversion unit that converts a signal state of a DRL (Daytime Running Light) ACT signal; a signal inversion unit that inverts the signal state of the DRL ACT signal to a high state or a low state through the signal conversion unit according to a turn signal power blink signal; and a signal maintenance unit that maintains the signal state of the DRL ACT signal converted through the signal inversion unit to a low state or a high state according to a turn-off signal.

Description

LED DRIVING APPARATUS

The present invention relates to an LED driving device, and more particularly, to an LED driving device capable of resolving dissatisfaction with color distribution without a separate MCU that stores the DRL ACT signal and controls the LED based on the DRL ACT signal by maintaining the DRL ACT signal in a low state even when the turn signal power blinking signal is not input after the turn signal power blinking signal is turned on and the DRL ACT signal becomes low.

Typically, vehicles are equipped with headlamps to ensure the driver's forward visibility when driving in dark places such as at night or through tunnels.

The light source of a headlamp uses a bulb, but recently, LED headlamps that use LEDs, which generate high efficiency with low power consumption, as a light source are gaining attention.

LED headlamps require an LED driving module (LDM: Led Driving Module) to drive the LED because direct power supply to the LED headlamps is not possible due to the electrical characteristics of the LED in vehicles that use 12V.

For headlamps with multiple functions, multiple LED driving modules are required to control each function.

The basic functions of headlamps include low beams, high beams, and a function to secure long-distance visibility during high-speed driving (Mortorway), a function to secure front-side visibility when driving on curves or at intersections (Sequential or Static Bending), a TURN signal, and a function to confirm the presence of a vehicle during daytime driving (DRL: Daytime Running Light & POSITION).

A combination type LED headlamp with full functionality requires an LED driving module to drive LEDs with various functions.

However, conventionally, when the TURN signal LED mounting part and the DRL LED mounting part are close together and turned on at the same time, color light distribution dissatisfaction may occur. Accordingly, when the TURN ACT DC signal is not received, the TURN act signal is remembered and the calculation is performed through the MCU in the LED driving module to resolve the color light distribution dissatisfaction.

However, in this case, if the TURN act DC signal is not received, the TURN signal power blink signal cannot be remembered without the MCU, so there was a problem that the DRL ACT signal transmitted immediately turns on/off as soon as the initial blink on/off signal changes.

The background technology of the present invention is disclosed in Korean Patent Publication No. 10-2017-0086946 (July 27, 2017), ‘Same Light-Emitting Surface Current Variable Circuit.’

The present invention has been made to improve the above-mentioned problems, and an object of one aspect of the present invention is to provide an LED driving device capable of resolving dissatisfaction with color distribution without a separate MCU that controls the LED based on the DRL ACT signal by maintaining the DRL ACT signal in a low state even when the turn signal power blinking signal is not input after the turn signal power blinking signal is turned on and the DRL ACT signal becomes low.

An LED driving device according to one aspect of the present invention is characterized by including a signal conversion unit that converts a signal state of a DRL (Daytime Running Light) ACT signal; a signal inversion unit that inverts the signal state of the DRL ACT signal to a high state or a low state through the signal conversion unit according to a turn signal power blink signal; and a signal maintenance unit that maintains the signal state of the DRL ACT signal converted through the signal inversion unit to a low state or a high state according to a turn-off signal.

The signal inversion unit of the present invention is characterized in that when a high signal is input as the turn signal power blinking signal, the signal conversion unit inverts the DRL ACT signal to a low state.

The signal conversion unit of the present invention includes a pull-up resistor that maintains the DRL ACT signal in a pull-up state; a signal conversion switch; and a signal conversion switch driver that inputs a signal for a switching operation of the signal conversion switch, wherein the signal conversion switch has a collector terminal connected to the pull-up resistor, an emitter terminal connected to ground, and a base terminal connected to the signal conversion switch driver, and is characterized in that it converts the DRL ACT signal into either a high state or a low state according to a signal input through the base terminal from the signal conversion switching driver.

The signal maintenance unit of the present invention comprises a signal maintenance switch; and a signal maintenance switch driver which inputs a signal for a switching operation of the signal maintenance switch to the signal maintenance switch, wherein the signal maintenance switch receives the turn-off signal through an emitter terminal, has a collector terminal connected to the signal inverting terminal, and has a base terminal connected to the signal maintenance switch driver, and is characterized in that it switches according to a signal input to the base terminal from the signal maintenance switch driver.

The signal inversion unit of the present invention comprises a signal inversion switch; and a signal inversion switch driving unit that switches the signal inversion switch according to the turn signal power flashing signal, wherein the signal inversion switch receives the turn signal power flashing signal through a base terminal, has a collector terminal connected to the signal holding switch driving unit, and has an emitter terminal connected to ground, and is characterized in that it switches according to the turn signal power flashing signal input to the base terminal.

The signal inversion unit of the present invention is characterized by further including a reverse voltage blocking unit that blocks reverse voltage from being input to the base terminal of the signal inversion switch.

An LED driving device according to one aspect of the present invention is capable of resolving color distribution dissatisfaction without a separate MCU that stores the DRL ACT signal and controls the LED based on the DRL ACT signal by maintaining the DRL ACT signal in a low state even when the turn signal power blinking signal is not input after the turn signal power blinking signal is turned on and the DRL ACT signal becomes low.

An LED driving device according to another aspect of the present invention can reduce the cost of an LED driving module since there is no need to separately provide an MCU for DRL ACT signal control.

FIG. 1 is a circuit diagram of an LED driving device according to one embodiment of the present invention.
FIG. 2 is a diagram illustrating a DRL ACT signal according to on/off of a turn signal power blinking signal according to one embodiment of the present invention.

Hereinafter, an LED driving device according to an embodiment of the present invention will be described in detail with reference to the attached drawings. In this process, the thickness of lines and the size of components illustrated in the drawings may be exaggerated for the sake of clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, the definitions of these terms should be made based on the contents throughout this specification.

The implementations described herein may be implemented, for example, as a method or process, an apparatus, a software program, a data stream or a signal. Even if discussed only in the context of a single form of implementation (e.g., discussed only as a method), the implementation of the features discussed may also be implemented in other forms (e.g., as an apparatus or a program). The apparatus may be implemented using suitable hardware, software, firmware, and the like. The method may be implemented in a device such as a processor, which generally refers to a processing device including, for example, a computer, a microprocessor, an integrated circuit, or a programmable logic device. A processor also includes a communication device such as a computer, a cell phone, a personal digital assistant ("PDA"), and other devices that facilitate communication of information between end-users.

FIG. 1 is a circuit diagram of an LED driving device according to one embodiment of the present invention, and FIG. 2 is a diagram illustrating a DRL ACT signal according to on/off of a turn signal power blinking signal according to one embodiment of the present invention.

Referring to FIG. 1, an LED driving device according to one embodiment of the present invention includes a signal conversion unit (10), a signal inversion unit (20), and a signal maintenance unit (30).

The signal inversion unit (20) inverts the DRL ACT signal to a high state or a low state through the signal conversion unit (10) according to the turn signal power flashing signal. For example, when a high signal is input as the turn signal power flashing signal, the signal inversion unit (20) inverts the DRL ACT signal from a high state to a low state through the signal conversion unit (10). The signal conversion unit (10) will be described later.

The turn signal power flashing signal can be input from various controllers that control LED flashing, for example, in the vehicle body. The controller that controls LED flashing is not particularly limited.

The signal inversion unit (20) includes a signal inversion switch (Q1), a signal inversion switch driver (21), a reverse voltage blocking unit (22), a first resistor (R1), a first diode (D1), and a first capacitor (C1).

An NPN transistor can be used as the signal inversion switch (Q1).

The signal inversion unit (20) receives a turn signal power flashing signal from various controllers, such as those controlling LED flashing of the vehicle body. The turn signal power flashing signal is input to the base terminal of the signal inversion switch (Q1) through the first resistor (R1) and the first diode (D1).

The first resistor (R1) has one end connected to the above-mentioned controller and the other end connected to the anode of the first diode (D1) to prevent the signal conversion switch (Q3) from being damaged by the turn signal power blinking signal.

The first diode (D1) has its anode connected to the first resistor (R1) and its other end connected to the base of the signal inversion switch (Q1) to block the reverse voltage caused by the signal inversion switch driving unit (21) described later.

The first capacitor (C1) has one end connected between the first diode (D1) and the base terminal and the other end connected to ground to remove noise of the turn signal power blinking signal, thereby stabilizing the signal applied to the base of the signal inversion switch (Q1).

The signal reversal switch (Q1) receives a turn signal power flashing signal through the base terminal, has a collector terminal connected to the signal maintenance switch driving unit (31), and has an emitter terminal connected to ground, and switches according to the turn signal power flashing signal input to the base terminal.

A signal inversion switch driver (21) is connected to the base of the signal inversion switch (Q1).

The signal inversion switch driver (21) inputs a voltage for the switch operation of the signal inversion switch (Q1) to the signal inversion switch (Q1). The signal inversion switch driver (21) includes a second resistor (R2) and an eighth resistor (R8), and the distribution voltage of the second resistor (R2) and the eighth resistor (R8) is input to the base terminal of the signal inversion switch (Q1), thereby turning on the signal inversion switch (Q1).

The reverse voltage blocking unit (22) has the anode terminal connected to the cathode terminal of the signal maintenance switch (Q2) and the other terminal connected to the second resistor (R2) of the signal inversion switch driving unit (21) to block the reverse voltage of the signal inversion switch driving unit (21).

The signal maintenance unit (30) maintains the signal state of the DRL ACT signal converted through the signal inversion unit (20) in a low state or a high state according to the turn off signal.

The signal maintenance unit (30) includes a signal maintenance switch (Q2) and a signal maintenance switch driving unit (31).

A PNP transistor can be used as the signal maintenance switch (Q2).

The signal maintenance switch (Q2) receives a turn-off signal through the emitter terminal, has a collector terminal connected to the signal inversion unit (20), and a base terminal connected to the signal maintenance switch driver (31), and switches according to a signal input to the base terminal from the signal maintenance switch driver (31).

The signal maintenance switch driving unit (31) includes a third resistor (R3) and a sixth resistor (R6).

The third resistor (R3) has one end connected to the above-mentioned controller and the other end connected to the sixth resistor (R6), and the sixth resistor (R6) has one end connected to the third resistor (R3) and the other end connected to the collector terminal of the signal inversion switch (Q1).

The distribution voltage distributed by the third resistor (R3) and the sixth resistor (R6) is input to the base terminal of the signal maintenance switch driver (31), and the signal maintenance switch (Q2) is turned on.

The signal conversion unit (10) converts the DRL ACT signal (a function that confirms the presence of a vehicle during daytime driving (DRL: Daytime Running Light & POSITION)) to either a high state or a low state.

That is, the signal conversion unit (10) converts the high state DRL ACT signal to a low state according to the signal of the signal inversion unit (20) when the DRL ACT signal is in a high state, and converts the low state DRL ACT signal to a high state according to the signal of the signal inversion unit (20) when the DRL ACT signal is in a low state.

The signal conversion unit (10) includes a pull-up resistor and a signal conversion switch (Q3).

The pull-up resistor is connected at one end to a pull-up power supply that supplies voltage to generate the DRL ACT signal as a pull-up voltage, and at the other end to a node that receives the DRL ACT signal to boost the DRL ACT signal to the pull-up voltage.

Here, the DRL ACT signal is input through the node between the pull-up resistor and the collector terminal of the signal conversion switch (Q3).

Hereinafter, the operation process of an LED driving device according to one embodiment of the present invention will be described.

Referring to Fig. 2, when the DRL ACT signal is input, the DRL ACT signal becomes a pull-up voltage by the pull-up resistor.

Meanwhile, when the DRL ACT signal is input as a high signal as described above, and the turn signal power flashing signal and the turn off signal are input respectively, the turn signal power flashing signal is distributed by the signal inversion switch driving unit (21) and input to the base terminal of the signal inversion switch (Q1), thereby turning on the signal inversion switch (Q1).

At this time, the first resistor (R1) prevents the signal conversion switch (Q3) from being damaged by the turn signal power flashing signal, and the first diode (D1) blocks the reverse voltage by the signal inversion switch driving unit (21). In addition, the reverse voltage blocking unit (22) blocks the reverse voltage of the signal inversion switch driving unit (21).

Meanwhile, as the signal inversion switch (Q1) is turned on, the turn-off signal is voltage-distributed by the signal maintenance switch driver (31) and input to the base terminal of the signal maintenance switch (Q2), and the signal maintenance switch (Q2) is turned on by the distributed voltage of the signal maintenance switch driver (31) input to the base terminal.

As described above, as the signal holding switch (Q2) is turned on, the voltage at the collector terminal of the signal holding switch (Q2) is distributed by the seventh resistor (R7) and the fourth resistor (R4) of the signal conversion switch driver (11) and input to the base terminal of the signal conversion switch (Q3), thereby turning on the signal conversion switch (Q3).

As the signal conversion switch (Q3) is turned on, the DRL ACT signal, which is in the high state, becomes low.

Thereafter, even if the turn signal power blink signal becomes low, the turn-off signal is conducted by the signal maintenance switch (Q2) in the turn-on state. As a result, the voltage of the collector terminal of the signal maintenance switch (Q2) is distributed by the seventh resistor (R7) and the fourth resistor (R4) of the signal conversion switch driving unit (11) and is continuously input to the base terminal of the signal conversion switch (Q3), so that the signal conversion switch (Q3) continues to maintain the turn-on state, and as a result, the DRL ACT signal continues to maintain the low state.

Therefore, when the turn-off signal is input, even if the turn signal power blink signal repeats the turn-on and turn-off process, the DRL ACT signal continues to remain in the low state.

Meanwhile, in the above process, if the turn signal power flashing signal is not input and the signal inversion switch (Q1) is turned off and the turn-off signal is not input, the signal maintenance switch (Q2) is also turned off, and as a result, the turn-off signal is not conducted through the signal maintenance switch (Q2), so the signal conversion switch (Q3) is also turned off.

This causes the DRL ACT signal to transition from low to high.

In this way, the LED driving device according to one aspect of the present invention can resolve dissatisfaction with color distribution without a separate MCU that stores the DRL ACT signal and controls the LED based on the DRL ACT signal by maintaining the DRL ACT signal in a low state even when the turn signal power blinking signal is not input after the turn signal power blinking signal is turned on and the DRL ACT signal becomes low.

An LED driving device according to another aspect of the present invention can reduce the cost of an LED driving module since there is no need to separately provide an MCU for DRL act signal control.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Accordingly, the true technical protection scope of the present invention should be determined by the following patent claims.

10: Signal conversion section Q3: Signal conversion switch
11: Signal conversion switch driving unit 20: Signal inversion unit
Q1: Signal inversion switch 21: Signal inversion switch driver
22: Reverse voltage blocking section 30: Signal holding section
Q2: Signal holding switch 31: Signal holding switch driver

Claims (6)

A signal conversion unit that converts the signal state of the DRL (Daytime Running Light) ACT signal;
A signal inversion unit that inverts the signal state of the DRL ACT signal to a high state or a low state through the signal conversion unit according to the turn signal power blink signal; and
It includes a signal maintenance unit that maintains the signal state of the DRL ACT signal converted through the signal inversion unit in a low state or a high state according to the turn-off signal,
An LED driving device characterized in that the signal conversion unit includes a pull-up resistor that maintains the DRL ACT signal in a pull-up state; a signal conversion switch; and a signal conversion switch driver that inputs a signal for a switching operation of the signal conversion switch, wherein the signal conversion switch has a collector terminal connected to the pull-up resistor, an emitter terminal connected to ground, and a base terminal connected to the signal conversion switch driver, and converts the DRL ACT signal to either a high state or a low state according to a signal input from the signal conversion switch driver through the base terminal.
In the first paragraph, the signal inversion unit
An LED driving device characterized in that when a high signal is input as the turn signal power blinking signal, the DRL ACT signal is inverted to a low state through the signal conversion unit.
delete In the first paragraph, the signal maintenance unit
signal hold switch; and
Including a signal maintenance switch driving unit that inputs a signal for switching operation of the signal maintenance switch to the signal maintenance switch,
An LED driving device characterized in that the signal maintenance switch receives the turn-off signal through the emitter terminal, has a collector terminal connected to the signal inversion terminal, and has a base terminal connected to the signal maintenance switch driving unit, and switches according to a signal input to the base terminal from the signal maintenance switch driving unit.
In the fourth paragraph, the signal inversion unit
signal reversing switch; and
Including a signal reversal switch driving unit that switches the signal reversal switch according to the turn signal power flashing signal,
The above signal inversion switch is an LED driving device characterized in that it receives a turn signal power flashing signal through a base terminal, has a collector terminal connected to the signal maintenance switch driving unit, and has an emitter terminal connected to ground, and switches according to the turn signal power flashing signal input to the base terminal.
In the fifth paragraph, the signal inversion unit
An LED driving device characterized by further including a reverse voltage blocking unit that blocks reverse voltage from being input to the base terminal of the signal inversion switch.

Images