KR20170106266A - Led emitting device - Google Patents

Abstract

The present invention relates to a light emitting device using an LED, which includes at least two LED channels. If a power voltage supplied to the light emitting device using an LED reaches a preset threshold voltage, the power voltage is maintained as a threshold voltage for an overvoltage regulation period. Accordingly, the present invention can turn on the LED channel without delay by stably supplying the power voltage.

Description

LED EMITTING DEVICE

The present invention relates to an LED light emitting device, and more particularly, to an LED light emitting device capable of controlling an overvoltage generated when an LED is driven.

A light emitting device using LED (hereinafter referred to as LED light emitting device) supplies current to the LED to drive the LED. Then, the LED emits light of a luminance corresponding to the current. Such a LED light emitting device can be used as a light source or an illumination of an LCD.

The LED light emitting device emits light of a constant luminance by flowing a constant current in a state where a voltage equal to or higher than a threshold voltage is applied to an LED channel composed of a plurality of LEDs connected in series. The threshold voltage means a minimum voltage necessary to turn on all the plurality of LEDs constituting the LED channel.

The operation of supplying current to the LED channel to emit light is referred to as turn-on, and the operation of stopping the light emission by turning off the current supply to the LED channel is turned off.

The LED light emitting device may include a plurality of LED channels, and the current flowing in each LED channel is constantly controlled. A plurality of LED channels are connected in parallel, so that the power supply voltage applied to each of the plurality of LED channels is the same. The power supply voltage increases or decreases as the number of LED channels turned on among the plurality of LED channels increases or decreases. That is, as the number of turn-on LED channels increases, the supply voltage decreases and as the number of turn-on LED channels decreases, the supply voltage increases.

Then, the LED light emitting device senses the increase / decrease of the power supply voltage and controls the power supply voltage to be constant. Generally, the LED light emitting device controls the power supply voltage to be constant based on the lowest voltage of the channel voltage. The channel voltage means a voltage obtained by subtracting the voltage across the LED channel from the power supply voltage with the LED channel terminal voltage. The power supply voltage must be controlled based on the lowest channel voltage among the plurality of LED channel voltages so that a plurality of LEDs of all the LED channels can be turned on by the power supply voltage.

That is, the LED channel having the lowest channel voltage means that the voltage across the LED channel is the highest. If the supply voltage is lower than the highest voltage of the LED channel, which is generated when a constant current flows through the LED channel, the supply voltage is below the threshold voltage and the LED channel can not supply the current required to emit light. Therefore, the power supply voltage is controlled based on the lowest channel voltage among the plurality of LED channel voltages.

The lowest voltage among the plurality of LED channel voltages is sampled in the LED light emitting device and is maintained until a lower LED channel voltage is generated. When the number of turn-on LED channels is reduced, the power supply voltage is increased and no voltage lower than the sampled LED channel voltage is generated. If the sampled LED channel voltage is maintained in this situation, an overvoltage phenomenon of the supply voltage occurs.

In order to prevent this, the LED light emitting device controls the power supply voltage so that the power supply voltage falls to a predetermined stabilization voltage when the power supply voltage rises to a predetermined overvoltage reference voltage.

The number of LED channels turned on among the plurality of LED channels may increase during a period from the time when the power supply voltage rises to the overvoltage reference voltage to the time when the voltage falls to the stabilization voltage. Then, since the power supply voltage is decreased, it is difficult to supply a constant current to the LED channel. That is, there is an LED channel that can not turn on until the supply voltage rises to a voltage adequate to supply a constant current to all the LED channels to be turned on.

In this way, when the number of LED channels to be turned on increases while the overvoltage of the power source voltage is generated and the power source voltage is stabilized, there is a serious problem that the turn-on time of the LED channel is delayed.

In order to solve such problems, it is an object of the present invention to provide an LED light emitting device capable of stably supplying a power supply voltage and turning on an LED channel without delay.

According to an aspect of the present invention, there is provided an LED light emitting device including at least two LED channels, including: a power supply for supplying a power voltage to one end of the at least two LED channels; At least two channel current controllers connected to the other ends of the at least two LED channels and controlling a duty of a driving current flowing in each of the at least two LED channels; At least two sample / hold portions for sampling and holding a channel minimum voltage of each of the channel voltages of the at least two LED channels; A minimum voltage detector for detecting a small voltage among the at least two channel minimum voltages to generate a minimum voltage; A first error amplifier amplifying a difference between the power supply voltage and a predetermined first reference voltage to generate an overvoltage sensing voltage; And a second error amplifier amplifying a difference between the minimum voltage and a predetermined second reference voltage to generate an error signal. Wherein the power supply maintains the power supply voltage at the threshold voltage in accordance with the overvoltage detection voltage when the power supply voltage reaches a predetermined threshold voltage and when the power supply voltage becomes less than the threshold voltage, And can be controlled according to the error signal.

The present invention provides an LED light emitting device capable of stably supplying a power supply voltage and turning on an LED channel without delay.

1 is a view illustrating an LED light emitting device according to an embodiment of the present invention.
2 is a waveform diagram illustrating a power supply voltage, a channel voltage, and a channel state of the LED light emitting device according to the embodiment of the present invention.
3 is a waveform diagram showing a power supply voltage, a channel voltage, and a channel state occurring when a power supply voltage is controlled in a conventional manner.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention in the drawings, parts not related to the description are omitted. Like numbers refer to like parts throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between. Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view illustrating an LED light emitting device according to an embodiment of the present invention.

1, the LED light emitting device 1 includes two LED channels (LEDCH1 and LEDCH2), a channel control unit 100, two channel current control units 210 and 220, two sample / hold units A first error amplifier 500, a second error amplifier 600, a power supply 700, two distribution resistors R1 and R2, and a capacitor C ).

Although the LED light emitting device according to the embodiment of the present invention includes two LED channels, the present invention is not limited thereto. That is, the LED light emitting device may include at least two LED channels. The number of channel current control units and sample / hold units is determined according to the number of LED channels. Therefore, when the number of the plurality of LED channels is n, there are also n channel current control sections and sample / hold sections.

Each of the two LED channels (LEDCH1, LEDCH2) consists of four LEDs, but this is only for the sake of brevity of the LED channel. The number of LEDs can be set according to the light emission luminance required for the LED channel. The four LEDs included in each of the two LED channels (LEDCH1 and LEDCH2) are connected in series, and the voltages generated at the ends of the two LED channels (LEDCH1 and LEDCH2) are the channel voltages (CH1 and CH2). A power supply voltage VLED is applied to each of the two LED channels LEDCH1 and LEDCH2.

The voltage across the LED channel LEDCH1 is a voltage obtained by subtracting the channel voltage CH1 from the supply voltage VLED and the voltage across the LED channel LEDCH2 is a voltage obtained by subtracting the channel voltage CH2 from the supply voltage VLED.

The channel current controller 210 controls the driving current to flow through the LED channel LEDCH1. The channel current controller 210 may control the driving current of the LED channel LEDCH1 according to the dimming signal DM1 having a predetermined duty. Specifically, the channel current controller 210 causes a driving current of a predetermined magnitude to flow through the LED channel LEDCH1 during the duty of the dimming signal DM1.

 The channel current control unit 220 controls the driving current to flow through the LED channel LEDCH2. The channel current controller 220 can also control the driving current of the LED channel LEDCH2 according to a dimming signal DM2 having a predetermined duty. Specifically, the channel current control unit 220 causes a driving current of a predetermined magnitude to flow in the LED channel LEDCH2 during the duty of the dimming signal DM2.

The channel controller 100 generates a dimming signal DM1 and a dimming signal DM2 and transmits the dimming signal DM1 and the channel current controller 220 to the channel current controller 210 and the channel current controller 220, respectively. The channel controller 100 generates a dimming signal DM1 and a dimming signal DM2 according to the light emission brightness required for each LED channel and transmits the dimming signal DM1 and the dimming signal DM2 to the channel current controllers 210 and 220. [ That is, the dimming signal DM1 and the dimming signal DM2 are signals for controlling ON / OFF of the LED channels LEDCH1 and LECH2. In the embodiment of the present invention, the high level of the dimming signals DM1 and DM2 is a signal for turning on the LED channel, and the low level is for turning off the LED channel.

The sample / hold unit 310 samples and holds the minimum voltage (hereinafter referred to as a first channel minimum voltage) CHmin1 of the channel voltage CH1.

The sample / hold unit 320 samples and holds the minimum voltage (hereinafter referred to as a second channel minimum voltage) CHmin2 of the channel voltage CH2.

The minimum voltage detector 400 detects the smaller one of the first and second channel minimum voltages CHmin1 and CHmin2 transmitted from the sample / hold units 310 and 320 to generate the minimum voltage Vmin.

The second error amplifier 600 compares the predetermined reference voltage VR2 and the minimum voltage Vmin to generate an error signal VE. A capacitor C is connected to the output terminal of the second error amplifier 600 to remove noise from the error signal VE and stabilize the feedback loop. The error signal VE is feedback information necessary for controlling the power supply voltage VLED.

The second error amplifier 600 includes an inverting terminal to which the minimum voltage Vmin is input and a non-inverting terminal to which the reference voltage VR2 is input. Vmin) is subtracted by a predetermined gain to generate an error signal VE.

The first error amplifier 500 amplifies the difference between the distribution voltage VD and the reference voltage VR1 that is distributed according to the resistance ratio of the resistors R1 and R2 to the power supply voltage VLED, (OVR). In the embodiment of the present invention, the resistor R1 and the resistor R2 are used to distribute the power supply voltage VLED, but the present invention is not limited thereto. The distribution voltage VD may be a voltage corresponding to the power supply voltage VLED. Two capacitors connected in series instead of the resistor R1 and the resistor R2 may be used to generate the distribution voltage VD.

The first error amplifier 500 amplifies the voltage obtained by subtracting the divided voltage VD from the reference voltage VR1 to a predetermined gain to generate the overvoltage sensing voltage OVR. The reference voltage VR1 is a voltage set for judging whether the power supply voltage VLED is overvoltage and the highest voltage of the allowable range of the power supply voltage VLED is the resistance ratio of the resistors R1 and R2 / (R1 + R2)) by a predetermined margin.

The power supply 700 receives the error signal VE and the overvoltage sensing voltage OVR and controls the power supply voltage VLED. The power supply 700 increases or decreases the power supply voltage VLED according to the error signal VE and increases the power supply voltage VLED to a critical value when the overvoltage detection voltage OVR becomes lower than a predetermined overvoltage reference voltage. Voltage (OVTH). At this time, the threshold voltage OVTH may be set to a voltage smaller by a predetermined margin than the level at which the power supply voltage VLED is determined to be an overvoltage. The overvoltage reference voltage can be set to the overvoltage reference voltage when the power supply voltage (VLED) is the threshold voltage (OVTH). A period in which the power supply voltage VLED is maintained at the threshold voltage OVTH is referred to as an overvoltage regulation period.

The distribution voltage VD is input to the inverting terminal of the first error amplifier 500 and the reference voltage is input to the non-inverting terminal. Thus, when the overvoltage sensing voltage OVR becomes lower than the overvoltage reference voltage, the overvoltage regulation period OVRP , See Fig. 2) starts.

On the contrary, when the reference voltage is input to the inverting terminal of the first error amplifier 500 and the divided voltage VD is input to the non-inverting terminal, if the overvoltage sensing voltage OVR becomes higher than the overvoltage reference voltage, The period (OVRP) begins.

The power supply 700 may be implemented as a DC-DC converter, and the duty of a power switch (not shown) that controls the operation of the DC-DC converter is controlled in accordance with the error signal VE. When the power supply voltage VLED is lowered, the minimum voltage Vmin is lowered, and the error signal VE increases. The power supply 700 increases the power supply voltage VLED by increasing the duty of the power switch when the error signal VE increases.

Conversely, when the power supply voltage VLED increases, the minimum voltage Vmin increases and the error signal VE decreases. The power supply 700 reduces the power supply voltage VLED by reducing the duty of the power switch when the error signal VE decreases. In this manner, the power supply 700 maintains the power supply voltage VLED constant.

Even if the power supply 700 controls the power supply voltage VLED in this way, the power supply voltage VLED can become an overvoltage. This is due to the feedback delay that occurs when the error signal VE is delivered to the power supply 700. The power supply 700 controls the power supply voltage VLED so that the power supply voltage VLED does not rise above the threshold voltage OVTH by using the overvoltage detection voltage OVR. That is, the power supply 700 maintains the power supply voltage VLED at the threshold voltage OVTH when the power supply voltage VLED reaches the threshold voltage OVTH.

During the overvoltage regulation period (OVRP), the duty of the power switch is controlled according to the overvoltage sense voltage (OVR). That is, the power supply 700 controls the duty of the power switch so that the overvoltage sense voltage OVR is maintained at the overvoltage reference voltage when the overvoltage sense voltage OVR is lower than the overvoltage reference voltage. Then, the power supply voltage VLED is maintained at the threshold voltage OVTH.

For example, the overvoltage reference voltage is set to zero. When the overvoltage detection voltage OVR becomes a voltage smaller than 0, the power supply adjusts the duty of the power switch so that the overvoltage detection voltage OVR is maintained at 0, that is, the distribution voltage VD is equal to the reference voltage VR1 Thereby maintaining the same voltage. At this time, the reference voltage VR1 may be set to an appropriate value for maintaining the power supply voltage VLED at the threshold voltage OVTH.

Hereinafter, a driving method of the LED light emitting device according to the embodiment of the present invention will be described with reference to FIGS.

2 is a waveform diagram illustrating a power supply voltage, a channel voltage, and a channel state of the LED light emitting device according to the embodiment of the present invention. In FIG. 2, the power supply voltage VLED is shown as being raised by the turn-off of the LED channel LEDCH1, but the present invention is not limited thereto.

The power supply voltage VLED must be equal to or higher than the highest threshold voltage of the plurality of LED channels plus the current source driving minimum voltage for driving the current source of each channel. This voltage is called the power threshold voltage. If the power supply voltage VLED is lower than the power threshold voltage, a non-operating channel of the plurality of LED channels may occur.

3 is a waveform diagram showing a power supply voltage, a channel voltage, and a channel state occurring when a power supply voltage is controlled in a conventional manner.

As shown in Fig. 2, the LED channel LEDCH2 is turned on at time T1 and both LED channels LEDCH1 and LEDCH2 are turned on during the period T1-T2. Since the LED channel LEDCH2 is turned off before the time point T1, the channel voltage CH2 of the LED channel LEDCH2 is maintained at a voltage similar to the power supply voltage VLED. The minimum voltage Vmin is the first channel minimum voltage CHmin1 of the LED channel LEDCH1 sampled before the time point T1.

After time point T1, the power supply 700 increases the output power to supply the current required for the two LED channels. In this case, although the power supply voltage VLED is shown to be maintained constant during the time T1-T2, the present invention is not limited to this, and the power supply voltage VLED may be decreased or decreased and then kept constant.

When the LED channel LEDCH1 is turned off at time point T2, the power supply voltage VLED starts to rise. The power supply voltage VLED is increased because the LED channel LEDCH1 is turned off in a situation where the output power of the power supply 700 is high in order to supply current to the two channels.

As described above, the power supply device 700 controls the power supply voltage VLED according to the error signal VE. The error signal VE is a signal generated according to the minimum voltage Vmin so that the power supply voltage Vmin is maintained at the first channel minimum voltage CHmin1 of the LED channel LEDCH1 sampled before the time point T1, The output power of the device 700 is constant. Therefore, the power supply voltage VLED starts to increase from the turn-off time of the LED channel LEDCH1.

The channel voltage CH1 of the LED channel LEDCH1 is a voltage similar to the supply voltage VLED since the LED channel LEDCH1 is turned off after the time point T2, . The channel voltage CH2 of the LED channel LEDCH2 rises together with the increase of the power supply voltage VLED since it is the voltage difference across the LED channel LEDCH2 at the power supply voltage VLED.

When the rising power supply voltage VLED reaches the threshold voltage OVTH at the time point T3, the power supply voltage VLED is maintained at the threshold voltage OVTH after the time point T3 and the channel voltage CH1 of the LED channel LEDCH1 ) Also remain constant. The channel voltage (CH2) of the LED channel (LEDCH2) also remains constant after the time point T3.

When the LED channel LEDCH1 is turned on again at the time T4, the power supply voltage VLED starts to decrease. At this time, since the power supply voltage VLED is a voltage sufficient to turn on the two LED channels (LEDCH1, LEDCH2), the LED channel (LEDCH1) is turned on without delay. Since the power supply voltage VLED becomes smaller than the threshold voltage OVTH after the time point T4, the power supply device 700 controls the power supply voltage VLED according to the error signal VE.

From time point T5 onward, the power supply voltage VLED is kept constant as the power supply threshold voltage.

The effect of the present invention will be described with reference to FIG. 3 in comparison with a conventional LED light emitting device that does not include the overvoltage regulation period OVRP.

As shown in FIG. 3, when the first one of the two LED channels at the time T11 is turned off, the power source voltage starts to increase. At time T12, the power supply voltage starts to decrease due to overvoltage protection operation. As the power supply voltage decreases, the second LED channel voltage also decreases. At time T13, the continuously monitored second LED channel voltage becomes less than the first LED voltage that was sampled and held until time T13.

Then, from the time point T13, the minimum voltage is changed to the second LED channel voltage. The reduced power supply voltage is lower than the minimum turn-on voltage of the second LED channel at time T14, and the second LED channel can not maintain the turn-on state. At time T14, the second LED channel voltage becomes smaller than the second LED current source driven minimum voltage, which is the minimum voltage necessary to sink the current to the second LED channel. Then no current flows through the second LED channel.

Since the second LED control signal is turned on at time T14, the switch connected between the second LED channel and the ground terminal is turned on by the second LED control signal, so that the second LED channel voltage becomes close to zero. Since the minimum voltage from the time T14 is the second LED channel voltage, the power supply voltage is controlled based on the second LED channel voltage.

When the power supply voltage becomes the voltage level at which the overvoltage protection operation is released at the time point T15, the overvoltage protection operation is canceled and the power supply voltage starts to rise. The power supply voltage starts to become higher than the minimum turn-on voltage of the second LED channel from the time point T16 and the second LED channel voltage starts to be higher than the second LED current source driven minimum voltage, so that the second LED channel is turned on.

When the first LED control signal for turning on the first LED channel is inputted at the time T17, the first LED channel voltage becomes a voltage close to the zero voltage. At time T17, the power supply voltage is lower than the first LED channel minimum turn-on voltage, and the first LED channel voltage is also smaller than the first LED current source driven minimum voltage. Therefore, even if the first LED control signal for turning on the first LED channel is inputted, the first LED channel is not turned on.

The time point T17 minimum voltage is changed to the first LED channel voltage, and the LED light emitting device increases the power supply voltage according to the lowered minimum voltage.

At time T18, the power supply voltage becomes the minimum turn-on voltage of the first LED channel, and the first LED channel voltage becomes the first LED current source driven minimum voltage. Then, the first LED channel is turned on, and the power supply voltage starts to be kept constant.

A problem arises that the second LED channel is not turned on during the period T14-T16 in which the second LED control signal for turning on the second LED channel is inputted. Also, a problem arises that the first LED channel is not turned on during the period T17 to 18 during which the first LED control signal for turning on the first LED channel is input. .

In order to solve such a problem, the present invention sets an overvoltage regulation period (OVRP) in which a power supply voltage is maintained at a predetermined threshold voltage. Then, the power supply voltage is reduced by the overvoltage protection operation, and the problem that the LED channel can not be turned on at a desired point can be solved.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are illustrative and explanatory only and are intended to be illustrative of the invention and are not to be construed as limiting the scope of the invention as defined by the appended claims. It is not. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: LED light emitting device
100:
210, 220: Channel current control section
310, 320: sample / hold unit
400: minimum voltage detector
500: first error amplifier section
600: second error amplifier section
700: Power supply

Claims (1)

In an LED light emitting device including at least two LED channels,
A power supply for supplying a power supply voltage to one end of the at least two LED channels;
At least two channel current controllers connected to the other ends of the at least two LED channels and controlling a duty of a driving current flowing in each of the at least two LED channels;
At least two sample / hold portions for sampling and holding a channel minimum voltage of each of the channel voltages of the at least two LED channels;
A minimum voltage detector for detecting a small voltage among the at least two channel minimum voltages to generate a minimum voltage;
A first error amplifier amplifying a difference between the power supply voltage and a predetermined first reference voltage to generate an overvoltage sensing voltage; And
And a second error amplifier amplifying a difference between the minimum voltage and a predetermined second reference voltage to generate an error signal,
The power supply device includes:
The power supply voltage is maintained at the threshold voltage in accordance with the overvoltage detection voltage when the power supply voltage reaches a predetermined threshold voltage, and when the power supply voltage becomes smaller than the threshold voltage, the power supply voltage is controlled in accordance with the error signal Lt; / RTI >

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