KR102320590B1 - Dimmable led lghiting device - Google Patents

Abstract

The present invention relates to an AC-driven light-emitting device lighting device capable of dimming. According to the present invention, an AC-driven light emission exhibiting smooth dimming characteristics in all dimming levels using a triac dimmer configured to perform dimming control using phase control. A device lighting device is proposed.

Description

Dimmable light emitting device lighting device {DIMMABLE LED LGHITING DEVICE}

The present invention relates to a light emitting device (LED) lighting device, and more particularly, to a lighting device for an AC driving light emitting device capable of realizing stable AC driving and exhibiting an ideal level of dimming change using a dimmer.

In general, a light emitting diode (Diode) device, such as a light emitting device, could be driven only by a direct current (DC) power supply due to diode characteristics. Accordingly, the conventional light emitting device using a light emitting device is limited in its use, and must include a separate circuit such as a switching power supply (SMPS) in order to be used in an AC 220V power source currently used at home. Accordingly, there is a problem in that the circuit of the light emitting device is complicated, and the manufacturing cost thereof is increased.

In order to solve this problem, a number of light emitting cells are connected in series or in parallel, and research on a light emitting device that can be driven even by AC power is being actively conducted.

In order to solve the problems of the prior art as described above, a sequential driving method of a light emitting device using an AC power has been proposed. According to this sequential driving method, assuming a lighting device including three light emitting device groups, in a situation in which the input voltage increases with time, the first light emitting device group starts to emit light at Vf1 first, and At a high voltage Vf2, the second light emitting device group is connected in series with the first light emitting device group, so that the second light emitting device group starts to emit light, and at a higher voltage than Vf3, the third light emitting device group is connected to the second light emitting device group and a third light emitting device group connected in series with the first light emitting device group starts to emit light. In addition, in a situation in which the input voltage decreases with time, the third light emitting element group first stops emitting light at Vf3, the second light emitting element group stops light emission at Vf2, and the first light emitting element group last at Vf1 By stopping light emission, the light emitting element driving current is designed to approximate the input voltage.

On the other hand, dimming control of a light emitting device refers to a change in the luminescent flux or illuminance (Lux) of a light emitting device lighting device, that is, generally the brightness of a light source, according to an applied supply voltage. A dimmable light source refers to a device that performs such an illuminance control function in a lighting device. Such a light emitting device dimming device (Dimmable System) is provided in the light emitting device lighting device for reducing power consumption of the light emitting device lighting device and for efficient operation. In particular, heat generated due to a continuous light emitting operation in the light emitting device is a factor that deteriorates the quality and efficiency of the lighting operation. Therefore, it is common to add a dimming function to the light emitting device lighting device to reflect the user's needs and to reduce power consumption at the same time. In the light emitting device lighting device with a dimming function added, in the case of the light emitting device lighting device using the DC power as described above, the light emitting device lighting device is driven by converting AC power to DC using a switching power supply (SMPS) to drive the light emitting device lighting device. As it is easy to dim, a certain degree of dimming control characteristics can be expected. However, in the case of the AC driving light emitting device lighting device as described above, it is not easy to implement the dimming function because the light emitting device (the light emitting device is driven only by a voltage obtained by rectifying the AC power source), and to secure linearity in dimming control. In particular, in the case of a sequentially driven AC driven light emitting device dimming device, the time point at which the number of light emitting device groups is changed according to the magnitude of the driving voltage (for example, from one-stage driving to two-stage driving). (Internal Impedance of AC power supply line and dimmer) As a result, there is a problem that an unstable phenomenon may occur because the driving voltage is shaken due to a phenomenon in which the power supply voltage is temporarily lowered or raised at the same time as turning on or off in the next stage. In the case of the device, there is a problem in that an ideal illuminance change characteristic is not provided in all sections of the dimming level, and a phenomenon in which the luminous flux is irregularly changed in some dimming control sections.

The present invention is to solve the problems of the prior art as described above.

An object of the present invention is to provide an AC-driven light emitting device lighting device having ideal dimming characteristics over the entire range of the dimming level.

Another object of the present invention is to provide an AC-driven light emitting device lighting device exhibiting very good dimming characteristics in conjunction with a TRIAC dimmer configured to perform dimming control using phase cut control. .

Another object of the present invention is to provide an alternating current-driven light emitting device lighting device in which the shaking phenomenon of repeating lighting and turning off during sequential driving of groups of light emitting devices is improved.

Another object of the present invention is to provide an AC-driven light emitting device lighting device that performs more efficient dimming control by changing the phase-controlled driving voltage and the light emitting device driving current interlocked together according to the dimming level.

In addition, the present invention is a limiting function that maintains the driving current of the light emitting device for single-stage driving at a constant value even at the lowest dimming level, so that even if the first dimming level of the dimmer is too low, it is possible to eliminate the phenomenon of irregular brightness fluctuation Another object of the present invention is to provide a driving light emitting device lighting device.

In order to achieve the object of the present invention as described above and to achieve the specific effects of the present invention to be described later, the characteristic configuration of the present invention is as follows.

According to one aspect of the present invention, there is provided a dimmer for receiving AC power and controlling the input AC power according to a selected dimming level to generate and output the controlled AC power; a rectifying unit receiving the controlled AC power output from the dimmer and full-wave rectification to generate and output a driving voltage; a dimming level detection unit receiving the driving voltage, detecting the selected dimming level, and outputting the detected dimming level signal; a first light emitting element group to an nth light emitting element group (n is a positive integer equal to or greater than 2) each including one or more light emitting elements, each of which receives the driving voltage and is sequentially driven under the control of the light emitting element driving module; and determining the voltage level of the driving voltage, sequentially driving the first to nth light emitting device groups according to the determined voltage level of the driving voltage, and controlling the driving current of the light emitting device based on the dimming level signal There is provided an AC-driven light emitting device lighting device capable of dimming, characterized in that it comprises a light emitting device driving module for controlling the constant current.

Preferably, the light emitting device driving module may be configured to determine a reference value of the light emitting device driving current in proportion to the level of the dimming level signal, and to control the maximum value of the light emitting device driving current based on the determined reference value.

Preferably, the light emitting device driving module may be configured to differently control the size of the light emitting device driving current for each driving section.

Preferably, the light emitting device driving module may be configured to control so that the nth light emitting device driving current for the nth stage driving period sequentially increases from the first light emitting device driving current for the first stage driving period.

Preferably, the dimmer may be a TRIAC dimmer.

Preferably, the dimming AC driven light emitting device lighting device is connected between the triac dimmer and the rectifier, and flows a TRIAC trigger current to the AC power input or rectified voltage output. It may further include a firing current holding circuit that operates as a given or dummy load.

Preferably, the firing current maintaining circuit may be a bleeder circuit.

Preferably, the dimming AC-driven light emitting device lighting device may further include an EMI filter connected between the dimmer and the rectifier to attenuate high-frequency noise of the phase-controlled AC power source.

Preferably, the dimmable AC-driven light emitting device lighting device may further include a surge protection unit connected to an output terminal of the rectifying unit to protect a circuit.

Preferably, the dimming level detecting unit may be configured to detect the dimming level by averaging the driving voltage.

Preferably, the dimming level detection unit may include an RC integrating circuit.

Preferably, the dimming level detection unit may further include a voltage limiting circuit for limiting the driving voltage to a maximum voltage or less.

Preferably, the dimming level detection unit may be built as an rms converter inside the light emitting device driving module to convert the driving voltage into a DC signal.

Preferably, the light emitting device driving module may be configured to selectively enable and disable the dimming control function.

Preferably, the light emitting device driving module may further include an automatic detection circuit for automatically selecting whether to permit or prohibit the dimming control function by detecting whether the dimming circuit is connected.

Preferably, it may further include a driving voltage stabilizing unit for stepping down and stabilizing the driving voltage supplied to the light emitting device driving module.

The bleeder circuit is an active bleeder, and the light emitting device driving module includes a bleeder terminal; and a bleeder resistor connected to the bleeder terminal.

The light emitting device driving module may include a low voltage blocking circuit.

The light emitting device driving module includes a temperature control unit, and the temperature control unit detects the temperature of the light emitting device driving module and compares the detected temperature with at least two or more reference temperatures to stop or allow the driving of the light emitting device driving module, , The reference temperature at which the driving of the light emitting device driving module is stopped or allowed is different from each other.

The temperature controller permits the light emitting device driving module when the first reference temperature has a lower temperature than the second reference temperature, and the detected temperature is less than or equal to the first reference temperature, and the detected temperature is the second reference temperature. 2 When the reference temperature is higher than the reference temperature, the light emitting device driving module is stopped.

After the light emitting device driving module is stopped by the detected temperature, the temperature of the light emitting device driving module maintains a stopped state up to the first reference temperature.

The light emitting device driving module includes: a minimum voltage level correcting unit for compensating to increase the level of the driving voltage in the minimum section of the rated voltage; and a maximum voltage level correcting unit for compensating to decrease the level of the driving voltage in the maximum section of the rated voltage.

In the light emitting device driving module, a variable resistor for varying a driving current level of a light emitting device of the first to nth light emitting device groups is connected to an output terminal of the switch unit.

According to the first preferred embodiment of the present invention, it is possible to expect the effect of providing an AC-driven light emitting device lighting device exhibiting smooth dimming characteristics over the entire section of the dimming level.

In addition, according to the present invention, it is possible to expect the effect of providing an AC-driven light emitting device lighting device exhibiting good dimming characteristics in conjunction with a triac dimmer configured to perform dimming control using phase control.

In addition, according to the present invention, it is possible to expect an effect of providing an alternating current driving light emitting device lighting device in which irregular shaking phenomenon is improved when the groups of light emitting devices are sequentially driven.

In addition, according to the present invention, it is possible to provide an AC-driven light emitting device lighting device that performs dimming control more efficiently by using both a phase-controlled driving voltage and a size-adjusted driving current according to the dimming level. can be expected

In addition, according to the present invention, it is expected to provide an alternating current driven light emitting device lighting device capable of eliminating irregular shaking by maintaining the light emitting device driving current for single-stage driving at a predetermined value or more even at the lowest dimming level. can

1 is a view showing a schematic configuration of an AC-driven light emitting device lighting device capable of dimming according to a first preferred embodiment of the present invention.
2 is a circuit diagram of an AC-driven light emitting device lighting device capable of dimming according to a first preferred embodiment of the present invention.
3 is a diagram illustrating the configuration of a light emitting device driving module according to a first exemplary embodiment of the present invention.
4 is a circuit diagram of a light emitting device group driver according to a first exemplary embodiment of the present invention.
5 is a waveform showing a relationship between a driving voltage and a driving current of a light emitting device according to a dimming level according to the first exemplary embodiment of the present invention.
6A is a graph illustrating the relationship between dimming voltage, light output, and luminous flux according to the dimming level of an AC-driven light emitting device lighting apparatus capable of dimming according to a first preferred embodiment of the present invention.
6B is a graph showing the relationship that can be implemented according to an exemplary embodiment and the upper and lower limits of light output according to the dimming level of the dimming AC-driven light emitting device lighting device according to the first preferred embodiment of the present invention; am.
7 is a diagram illustrating a configuration of an LED driving module according to a second embodiment of the present invention.
8 is a circuit diagram of a light emitting device group driver according to a second embodiment of the present invention.
FIG. 9 is a diagram illustrating a driving current of a light emitting device group according to an adim control signal of FIG. 8 .
10 is a diagram illustrating a configuration of a temperature controller according to a second embodiment of the present invention.
11 is a diagram illustrating an LED driving timing by a temperature controller according to a second embodiment of the present invention.
12 is a graph showing the LED driving timing by correcting the maximum and minimum voltage levels according to the second embodiment of the present invention.
13 is a waveform showing the LED driving timing by the low voltage blocking circuit according to the second embodiment of the present invention.
14 is a circuit diagram illustrating a light emitting diode driving apparatus according to a third embodiment of the present invention.
15 is a waveform diagram illustrating a voltage waveform of an AC power input to a light emitting diode driving apparatus according to a third embodiment of the present invention, a current waveform, and a waveform of a driving voltage supplied to an LED group.
16 is a circuit diagram illustrating a light emitting diode driving device according to a fourth embodiment of the present invention.
17 is a circuit diagram illustrating an LED driving module according to a fifth embodiment of the present invention.
18 is a circuit diagram illustrating an LED driving module according to a sixth embodiment of the present invention.
19 is a circuit diagram illustrating an LED driving module according to a seventh embodiment of the present invention.
20 is a view showing a lighting apparatus for an AC-driven light emitting device according to an eighth embodiment of the present invention.
21 is a flowchart illustrating a method of driving a lighting device for an AC-driven light emitting device according to an eighth embodiment of the present invention.
22A and 22B are waveforms illustrating a relationship between a driving current of a light emitting device group according to a change in a dimming level according to an eighth embodiment of the present invention.
23 is a waveform diagram illustrating a relationship between a driving current and a bleeder current of a light emitting device group according to a change in dimming level according to the present invention.
24 is a waveform diagram illustrating a pulse width modulated signal according to dimming level control according to a pulse width modulated dimmer.
25 is a diagram illustrating the configuration of an AC-driven light emitting device lighting device capable of controlling color temperature (hereinafter referred to as a 'light emitting device lighting device') according to an embodiment of the present invention.
26 is a diagram illustrating the configuration of an AC-driven light emitting device lighting device capable of controlling color temperature according to another embodiment of the present invention.
27 is a waveform diagram illustrating a relationship between a driving voltage and a driving current of the light emitting device lighting device of FIG. 26 .
28 is a diagram illustrating the configuration of an AC-driven light emitting device lighting device capable of controlling color temperature according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0023] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be embodied in other embodiments without departing from the spirit and scope of the invention with respect to the first embodiment. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents to those as claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those of ordinary skill in the art to easily practice the present invention.

[Preferred embodiment of the present invention]

In an embodiment of the present invention, the term 'light emitting device group' refers to a plurality of light emitting devices (or a plurality of light emitting cells) connected in series/parallel/series-parallel to operate as a unit according to the control of the light emitting device driving module. This refers to a set of light emitting devices that are controlled (that is, turned on/off together).

In addition, the term 'light emitting device driving module' means a module for driving and controlling a light emitting device by receiving an AC voltage, and in this specification, it is described based on an embodiment of controlling the driving of a light emitting device using a rectified voltage, but this It is not intended to be limiting, and it should be construed in a comprehensive and broad sense.

In addition, the term 'first forward voltage level (Vf1)' refers to a threshold voltage level capable of driving the first group of light emitting devices, and the term 'second forward voltage level (Vf2)' refers to the first light emitting device connected in series. It means a threshold voltage level capable of driving the group and the second light emitting device group, and the term 'third forward voltage level (Vf3)' is a threshold voltage level capable of driving the first to third light emitting device groups connected in series. means That is, the 'n-th forward voltage level (Vfn)' refers to a threshold voltage level capable of driving the first to n-th light emitting device groups connected in series. Meanwhile, the forward voltage level for each light emitting device group may be the same or different depending on the number/characteristics of the light emitting devices constituting the light emitting device group.

In addition, the term 'sequential driving method' refers to a light emitting device driving module that drives a light emitting device by receiving an input voltage whose size changes with time, and sequentially emits light from a plurality of groups of light emitting devices according to an increase in the applied input voltage. and means a driving method in which a plurality of light emitting device groups are sequentially turned off according to a decrease in an applied input voltage.

In addition, the term 'first stage driving period' refers to a time period in which only the first light emitting element group emits light, and the term 'second stage driving period' means that only the first light emitting element group and the second light emitting element group emit light. It means the time period for light emission. Accordingly, the 'nth stage driving period' refers to a time period in which all of the first to nth light emitting element groups emit light, but groups greater than or equal to the (n+1)th light emitting element group do not emit light.

Also, terms such as V1, V2, V3,..., t1, t2,..., T1, T2, T3, etc. used in this specification to indicate any specific voltage, specific time point, specific temperature, etc. is not used to indicate an absolute value, but a relative value used to distinguish each other.

Configuration and function of the light emitting device lighting device 1000

1 is a schematic configuration diagram of an AC-driven light emitting device lighting device capable of dimming (hereinafter referred to as a 'light emitting device lighting device') according to a first preferred embodiment of the present invention, and FIG. 2 is a first preferred embodiment of the present invention. It is a circuit diagram of an AC-driven light emitting device lighting device capable of dimming according to an embodiment. Hereinafter, with reference to FIGS. 1 and 2 , the configuration and function of the light emitting device lighting apparatus 1000 according to the present invention will be described in general.

First, the light emitting device lighting device 1000 according to the present invention includes a dimmer 100 , an EMI filter 110 , a rectifier 120 , a surge protection unit 130 , a dimming level detection unit 140 , and a light emitting device driving module 200 . ) and a light emitting device light emitting unit 300 .

The dimmer 100 according to the present invention receives an AC voltage (V _AC ) from an AC voltage source, and controls the input AC voltage (V _AC ) according to a dimming level selected according to a user's operation to generate controlled AC power. and output. The dimmer 100 according to the present invention includes a triac dimmer for controlling the phase of AC power (Phase cut) using a TRIAC, a pulse width modulation (PWM) dimmer, and an analog voltage dimmer for changing the AC voltage ( Analog Voltage Dimmer), and an equivalent dimmer. That is, the dimmer 100 according to the present invention generates/outputs controlled AC power by controlling the AC voltage according to the selected dimming level, and propagates the AC power (or the controlled AC power) controlled by the dimmer 100 . It should be borne in mind that any dimmer may be used as long as the dimming level selected by the dimming level detection unit 140 described later can be detected from the rectified controlled rectified voltage). Hereinafter, the present invention will be described focusing on an embodiment in which a triac dimmer is adopted as the dimmer 100 according to the present invention, but the scope of the present invention is not limited thereto, as long as it includes the gist of the present invention. , it will be apparent that embodiments using one of the various dimmers as described above also fall within the scope of the present invention.

When the dimmer 100 is implemented using the triac dimmer as described above, the dimmer 100 controls the AC power input based on the dimming level selected (or automatically selected) according to the user's operation in phase control (phase). cut) to generate and output a phase-controlled AC voltage. For the triac dimmer, a known technology is already adopted, and further detailed description thereof will be omitted. Meanwhile, although the dimmer 100 according to the present invention is illustrated as being included in one device in FIGS. 1 and 2 , this is for convenience of explanation and understanding, and is actually spaced apart from the light emitting device lighting device 1000 . It should be understood that the light emitting device may be installed and connected to the light emitting device lighting device 1000 through a conducting wire.

On the other hand, when the dimmer 100 is configured using a triac dimmer, it is necessary to process a TRIAC trigger current. Therefore, the light emitting device lighting device 1000 according to the present invention is connected between the dimmer 100 and the rectifier 120 to flow a triac firing current as an AC power input or a rectified voltage output or a dummy load. ) may further include a firing current maintaining circuit 105 operating as. In FIG. 2 , an example of such a firing current maintaining circuit 105 is illustrated as being implemented as a bleeder circuit consisting of a bleeder _{capacitor C B} and a bleeder resistor R _{B connected in series thereto.} have. However, it will be apparent to those skilled in the art that the firing current maintaining circuit 105 according to the present invention is not limited to the circuit shown in FIG. will be.

In addition, as described above, when the triac dimmer is used as the dimmer 100 according to the present invention, high-frequency noise is generated at the turn-on time due to the physical characteristics of the triac element. Such high-frequency noise may cause damage and malfunction of the light emitting device lighting device 1000, so it is preferable to remove it. 120) is provided between the input terminals. The noise canceller 110 according to the present invention performs a function of attenuating high-frequency noise of the phase-controlled AC voltage output from the dimmer 100 . Since a known technology is already adopted for the noise canceller 110 , a further detailed description thereof will be omitted.

The rectification part 120 according to the present invention also functions to generate a driving voltage (V _P) by rectifying the AC voltage phase control which is output from a dimmer 100, and outputs the generated drive voltage (V _P) . As the rectifying unit 120 , one of various well-known rectifying circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit may be used. A drive voltage (V _P) outputted from the rectifying unit 120 is output to the light-level detecting unit 140, a light-emitting element driving module 200, and the light emission section 300. FIG. 2 shows an embodiment in which the rectifier 120 is configured using a bridge full-wave rectifier circuit composed of four diodes.

On the other hand, the light emitting device lighting device 1000 according to the present invention further includes a surge protection unit 130 for protecting the light emitting device driving module 200 and the light emitting device light emitting unit 300 from overvoltage and/or overcurrent. can be The surge protection unit 130 is connected to the output terminal of the rectifier 120 and is configured to protect the components of the light emitting device lighting apparatus 1000 from overvoltage and/or overcurrent. In the embodiment shown in FIG. 2 , an embodiment in which the surge protection unit 130 of the present invention _{is composed of a resistor (R 1} ) and a TVS diode (TVS) is illustrated. The surge protection unit 130 is not limited to the circuit shown in FIG. 2 , and it will be apparent to those skilled in the art that one of a variety of known surge protection circuits may be employed as needed.

The light emitting device light emitting unit 300 according to the present invention may be composed of a plurality of light emitting device groups, and the plurality of light emitting device groups included in the light emitting device light emitting unit 300 is controlled by the light emitting device driving module 200 . Lights are emitted sequentially and turned off sequentially. 1 to 2, a light emitting device light emitting unit including a first light emitting device group 310, a second light emitting device group 320, a third light emitting device group 330, and a fourth light emitting device group 340 ( 300), it will be apparent to those skilled in the art that the number of light emitting device groups included in the light emitting device light emitting unit 300 may be variously changed as necessary.

In addition, depending on the configuration of the embodiment, the first light emitting device group 310 , the second light emitting device group 320 , the third light emitting device group 330 , and the fourth light emitting device group 340 are the same as each other or Or they may have different forward voltage levels. For example, the first light emitting element group 310, the second light emitting element group 320, the third light emitting element group 330, and the fourth light emitting element group 340 each include a different number of light emitting element elements. When configured, the first light emitting device group 310 , the second light emitting device group 320 , the third light emitting device group 330 , and the fourth light emitting device group 340 will have different forward voltage levels. On the other hand, for example, the first light emitting element group 310 , the second light emitting element group 320 , the third light emitting element group 330 , and the fourth light emitting element group 340 include the same number of light emitting element elements. In this case, the first light emitting device group 310 , the second light emitting device group 320 , the third light emitting device group 330 , and the fourth light emitting device group 340 will have the same forward voltage level. .

Light-level detecting unit 140 according to the present invention receives the driving voltage (V _P) outputted from the rectifying unit 120, detects the light control level to the currently selected on the basis of the input drive voltage (V _P), detection It may be configured to perform a function of outputting the dimmed level signal to the light emitting device driving module 200 . More specifically, the light-level detecting unit 140 according to the present invention is to average the driving voltage (V _P) of the voltage level change with time may be configured to detect a dimming level. As described above, according to the dimming level of the dimmer 100 is selected in accordance with the present invention because it is configured to cut the phase of the AC voltage (V _AC), detecting the light-level currently selected if the average the driving voltage (V _P) be able to do When the dimming level detecting unit 140 is configured in this way, the dimming level signal Adim corresponding to a specific dimming level output from the dimming level detecting unit 140 may be a DC signal having a constant voltage value. For example, when the dimming level is 100%, the corresponding dimming level signal (Adim) is 2V, and when the dimming level is 90%, the corresponding dimming level signal (Adim) is 1.8V, and the dimming level is 50% In the case of , the dimming level signal Adim corresponding thereto may be 1V, and the like. The value and range of the dimming level signal Adim corresponding to the specific dimming level can be changed by appropriately selecting the values of the circuit elements constituting the dimming level detecting unit 140 . In FIG. 2 , an embodiment in which the dimming level detection unit 140 is configured by an RC integrating circuit 144 including _{one resistor (R 4} ) and one capacitor (C _{1 ) is illustrated.} At this time, the resistor (R ₄ ) is to set the minimum light emitting device driving current (I _{LED ) limit.} Therefore, since the lowest light emitting device driving current (I _{LED ) limit is set through the resistor (R 4 ), the lowest light emitting device driving current (I LED} ) can be maintained even at the lowest dimming level. The dimming characteristics can be improved.

Meanwhile, more preferably, the dimming level detection unit 140 according to the present invention may further include a voltage limiting circuit 142 that limits the _{input driving voltage VP to a maximum voltage or less.} In general, the light-emitting element and the maximum voltage level is extremely high voltage of the drive voltage (V _P) to be supplied to the light emitting portion 300 and therefore, by accepting such a driving voltage (V _P) and detecting the light-level, the light-emitting element it When input is made to the driving module 200 , there is a risk that the light emitting device driving module 200 may be damaged. Thus, to solve this problem, the light-level detecting unit 140 according to the present invention up to a driving voltage (V _P) is an input voltage (e.g., 15V) comprises a voltage limitation circuit 142 for limiting or less can be configured. Referring to FIG. 2 , an embodiment in which this voltage limiting circuit 142 is _{implemented using resistors R 2 ,} R ₃ and a Zener diode ZD is shown. Here, the voltage limiting circuit 142 operates as a maximum dimming suppression circuit that reduces the allowable tolerance of the Zener diode ZD.

Referring to FIG. 2 for the dimming level detection unit 140 as described above, the dimming level detection unit 140 according to the first embodiment of the present invention includes three resistors R ₂ , R _{3 .} , R ₄ ), one capacitor C ₁ , and one Zener diode ZD. At this time, the resistor (R ₄ ) is for setting the minimum light emitting device driving current (I _LED ) limit, and the resistors (R _{2 ,} R ₃ ) and the Zener diode (ZD) operate as a maximum dimming suppression circuit.

Meanwhile, in FIGS. 1 and 2 , an embodiment in which the dimming level detection unit 140 of the present invention as described above is implemented as a separate circuit on the outside of the light emitting device driving module 200 is shown. Accordingly, the dimming level detection unit 140 according to the present invention may be implemented as an effective voltage converter (rms converter), and may be built in the light emitting device driving module 200 .

Light-emitting element driving module 200 according to the present invention receives the driving voltage (V _P) output from the rectifying part 120, and determines the magnitude of the driving voltage (V _P) is input, it is determined the drive voltage (V _P ) is configured to control sequential driving of the light emitting device light emitting unit 300 (more specifically, each of the plurality of light emitting device groups 310 to 340 included in the light emitting device light emitting unit 300) according to the size. In general, the maximum voltage level of the driving voltage (V _P) to be supplied to a light emitting device light emitting portion 300 is a considerably high voltage, therefore, that it is the light-emitting element driving module 200 to accept such a driving voltage (V _P) may damage it. In order to prevent this, the light emitting device lighting device 1000 according to the present invention includes a _{driving voltage stabilizing unit 150 between the driving voltage V P} input node and the driving voltage input terminal of the light emitting device lighting device 1000 . can do. 2, the driving voltage stabilization unit 150 according to the present invention may comprise a capacitor (C ₂₎ to stabilize the resistance (R ₆₎ and a drive voltage (V _P) for stepping down the drive voltage (V _P) can Of course, the driving voltage stabilizing unit 150 according to the present invention is not limited to that shown in FIG. 2 , and it will be apparent to those skilled in the art that one of various well-known circuits may be adopted as needed.

In addition, the light emitting device driving module 200 according to the present invention receives the dimming level signal (Adim) output from the dimming level detection unit 140, and based on the input dimming level signal (Adim), the light emitting device driving current (I) _LED ) can be configured to limit the maximum value. More specifically, the light emitting device driving module 200 according to the present invention determines the dimming controlled light emitting device driving current reference value Adim_I _ref in proportion to the input dimming level signal Adim, and drives the determined dimming controlled light emitting device It may be configured to perform constant current control on the light emitting device driving current I _LED based on the current reference value Adim_I _{ref .} If the light modulation control is performed in this manner, the phase control (that is, the phase is cut in accordance with the dimming level), the light emission time of the light emitting device light emitting portion 300 is controlled by the drive voltage (V _P), In addition, the detection Since the size of the light emitting device driving current (I _LED ) is simultaneously controlled based on the dimming level, smooth dimming characteristics appear over the entire section of the dimming level. In addition, through the configuration as described above, an effect of removing the irregular shaking phenomenon can be expected. The detailed configuration and function of the light emitting device driving module 200 according to the present invention will be described later with reference to FIGS. 3 to 5 .

Meanwhile, the light emitting device driving module 200 according to the present invention may be configured to selectively enable and disable the dimming control function. Whether to allow the dimming control function of the light emitting device driving module 200 may be configured through jumper setting. In addition, according to the configuration of the embodiment, an automatic sensing circuit (not shown) for automatically selecting whether to permit such a dimming control function may be included in the light emitting device driving module 200 . The automatic sensing circuit is configured to determine whether the dimming circuit is connected, and automatically select whether to allow the dimming control function according to whether the dimming circuit is connected. Such an automatic detection circuit, for example, detects the presence or absence of a triac dimming voltage, permits a dimming control function when a triac dimming voltage is present, and disables the dimming control function when a triac dimming voltage is not present. can be configured. In addition, various auto-sensing circuits may be used.

In addition, in FIG. 2 , the maximum light emitting device driving current setting resistance R ₅ is a resistance for setting the maximum light emitting device driving current limit when the dimming control function is prohibited or when the dimming level is 100%. Accordingly, by changing the resistance value of the maximum light emitting device driving current setting resistor R ₅ , the maximum light emitting device driving current reference value I _ref may be changed. Therefore, considering this together with the dimming level detection unit 140 mentioned above, in the light emitting device lighting device according to the present invention, the minimum light emitting device driving current limit _{can be set through the resistor R 4} , and the maximum light emission The device driving current limit may be set through the _{resistor R 5 .}

Configuration and function of the light emitting device driving module 200

3 is a configuration diagram of a light emitting device driving module according to a first preferred embodiment of the present invention, and FIG. 4 is a circuit diagram of a light emitting device group driving unit according to a first preferred embodiment of the present invention. Hereinafter, with reference to FIGS. 3 to 4 , the configuration and function of the light emitting device driving module 200 according to the present invention and the driving control process of the light emitting device lighting apparatus 1000 will be described in detail.

As shown in FIG. 3 , the light emitting device driving module 200 according to the present invention includes a plurality of light emitting device group drivers 220 and light emitting device driving for driving and controlling the light emitting device groups 310 to 340 . It may include a control unit 210 and an internal power generation unit 230 . Further, the light-emitting element driving module 200 is an integrated circuit (IC), as shown in can be implemented, and Fig. 3, the drive voltage (V _P), the driving voltage input terminal (VP) which is input in accordance with the invention, The dimming level signal input terminal (Adim) to which the dimming level signal (Adim) is input, _{the connection terminal (Rset) to which the maximum driving current setting resistance (R s} ) is connected, the ground terminal (GND) to the ground, the fourth light emitting element _{The fourth current path P 4} connected to the cathode terminal of the group 340 is connected to a connection terminal ST4, the cathode terminal of the third light emitting device group 330 and the anode terminal of the fourth light emitting device group 340. 3 current path (P _{3 ) is connected to the connection terminal (ST3), the second current path (P 2} ) between the cathode end of the second light emitting device group 320 and the anode end of the third light emitting device group 330 is connected It may include a connection terminal ST2 and a connection terminal ST1 to which _{the first current path P 1} between the cathode end of the first light emitting device group 310 and the anode end of the second light emitting device group 320 is connected. . In the embodiment shown in FIG. 3 , the light emitting device driving module 200 is illustrated to include eight terminals, but it will be apparent to those skilled in the art that the number of terminals may be changed as necessary.

The internal power generation unit 230 according to the present invention is to perform the functions for generating and supplying an internal direct current power source (V _cc) for driving the light-emitting element driving module 200 in step-down and smooth the drive voltage (V _P) is composed The internal power generation unit 230 may be implemented as a smoothing circuit composed of a resistor and a capacitor.

Sequence of a light emitting device drive control unit 210 of the light emitting element groups by the voltage level of rectifying the driving voltage (V _P) is determined, and the driving voltage (V _P), the voltage level of the input from 120 (310-340) configured to control the drive. In more detail, the light emitting device driving control unit 210 controls the driving voltage V _P in the first stage operation period in which the voltage level is between the first forward voltage level Vf1 and the second forward voltage level Vf2. Only the first current path P ₁ is connected and the remaining current paths are opened to control only the first light emitting device group 310 to emit light. Further, in the second stage operation section between the light-emitting element driving control unit 210 driving voltage in which the voltage level of (V _P), the second forward voltage level (Vf2), and the third forward voltage level (Vf3) the second current path Only (P ₂ ) is connected and the remaining current paths are opened to control the first light emitting device group 310 and the second light emitting device group 320 to emit light. Similarly, in the third stage operation period between the light-emitting element driving control unit 210, the voltage level of the drive voltage (V _P), the third forward voltage level (Vf3) and a fourth forward voltage level (Vf4) third current Only the path P ₃ is connected and the remaining current paths are opened to control the first to third light emitting device groups 310 to 330 to emit light. Further, the light-emitting element driving control unit 210, the voltage level of the drive voltage (V _P) of claim 4, the forward voltage level (Vf4) than the four-speed operation period the fourth current path (P _4), only the connection and the remaining current paths It is opened so that all of the first light emitting device group 310 to the fourth light emitting device group 340 emit light. Thus, through the same manner as described above, the light emitting device drive control unit 210 according to the present invention is configured to control the sequential operation of the light emission of the element group (310-340) in response to the voltage level of the driving voltage (V _P) .

_{In addition, the light emitting device driving control unit 210 according to the present invention determines the light emitting device driving current reference value (I ref} ), which is the standard of constant current control, according to the input dimming level signal (Adim) in order to perform the dimming control function, and , may be configured to output the determined light emitting device driving current reference value I _ref to the light emitting device group drivers 220 . At this time, the light emitting device driving current reference value I _ref output from the light emitting device driving control unit 210 is a reference value for constant current control of the _{light emitting device driving current I LED} in the light emitting device group drivers 220 . At this time, more preferably, the light emitting device driving control unit 210 according to the present invention drives the waveform of the light emitting device driving current in order to improve the power factor (PF) and total harmonic distortion (THD) characteristics. voltage a first drive current reference value (I _ref1), a second drive current reference value (I _ref2), a third drive current reference value (I _ref3) so as to be approximated to the waveform of (V _P), the fourth drive current reference value (I _ref4 ) by setting the values to be different from each other, the first _{to the fourth light emitting device driving current (I LED1} ) to the fourth light emitting device driving current (I _LED4 ) may be configured to approximate a sine wave. That is, the reference value may be set to sequentially increase from the first driving current reference value I _ref1 in the first stage driving period to the fourth driving current reference value I _{ref4 in the fourth stage driving period.} For explanation, assuming that the dimming level is selected as 100%, the fourth driving current reference value I _ref4 may be set to 100 mA, and the third driving current reference value I _ref3 is the fourth driving current reference value I _ref4 ) 80% ~ 95% of 80mA ~ can be set to any value of 95mA, the second drive current reference value (I _ref2) is a 65mA ~ 80mA 65% ~ 80% of the fourth drive current reference value (I _ref4) of may be set to any value, and the first driving current reference value I _ref1 may be set to any value among 30 mA to 65 mA, which is 30% to 65% of the fourth driving current reference value I _{ref4 .} Since the above example assumes that the dimming level is selected as 100%, as the dimming level is changed, the first driving current reference value (I _ref1 ) to the fourth driving current reference value (I _ref4 ) is determined according to the changed dimming level and the newly determined first driving current reference value I _ref1' to the fourth driving current reference value I _ref4' will be output. According to the configuration of the embodiment, here, the fourth driving current reference value (I _{ref4 ) may be the maximum light emitting device driving current (I LEDmax} ) set according to the resistance value of the maximum light emitting device driving current setting resistor (R ₅ ), and , the first driving current reference value (I _ref1 ), the second driving current reference value (I _ref2 ), and the third driving current reference value (I _ref3 ) are obtained by reducing the fourth driving current reference value (I _ref4 ) according to a preset reduction ratio, respectively. It may be a reference value. _{In the following, in order to distinguish from the maximum driving current reference value (I ref} ) when the dimming level is 100% or when the dimming control function is prohibited, the driving current when the dimming control function is allowed and the dimming level is not 100% The reference value is referred to as a dimming-controlled driving current reference value (Adim_I _ref ). Details according to the dimming level will be described later with reference to FIG. 5 .

The light emitting device group driving units 220 according to the present invention _{perform a function of connecting or opening each of the current paths P 1} to P ₄ under the control of the light emitting device driving control unit 210, and at the same time driving the light emitting device It is configured to perform constant current control for the current ILED. As shown in FIG. 3 , the first light emitting device group driver 222 is connected between the first light emitting device group 310 and the second light emitting device group 320 through a first _{current path P 1 ,} , is configured to connect or open _{the first current path P 1} according to the control of the light emitting device driving control unit 210 . In addition, the second light emitting device group driving unit 224 is connected between the second light emitting device group 320 and the third light emitting device group 330 through _{the second current path P 2 , and the light emitting device driving control unit (} 210) according to the control of the second current path (P ₂ ) It is configured to connect or open. Similarly, the third light emitting element group driver 226 is connected between the third light emitting element group 310 and the fourth light emitting element group 340 through _{the third current path P 3 , and the light emitting element driving control unit} According to the control of 210, the third current path (P ₃ ) is configured to connect or open. Finally, the fourth light emitting device group driver 228 is _{connected to the fourth light emitting device group 340 through the fourth current path P 4} , and under the control of the light emitting device driving controller 210 , the fourth current It is configured to connect or open the path P _{4 .}

In addition, each of the light emitting device group drivers 222 to 228 according to the present invention is configured to perform a constant current control function in addition to the on/off control function of the _{paths P 1} , P ₂ , P ₃ , and P _{4 .} 4 is a circuit diagram of the first light emitting device group driver 222 according to the first preferred embodiment of the present invention. Although the configuration of the first light emitting device group driving unit 222 is illustrated in FIG. 4 for convenience of explanation and understanding, the second light emitting device group driving unit 224 to the fourth light emitting device group driving unit 228 are also configured in the same manner. Referring to FIG. 4 , the configuration and function of the first light emitting device group driving unit 222 according to the present invention will be described in detail.

Referring to FIG. 4 , the first light emitting device group driver 222 according to the present invention includes one electronic switching device Q ₁ , one sensing resistor Rsense ₁ , and one differential amplifier OP ₁ . can In addition, the first light emitting device group driving unit 222 according to the present invention is _{connected to the switch SW 1} and connected to the pull-up resistor unit 410 connected to the Rset terminal or to the pull-up resistor unit 420 connected to the Adim terminal. can be connected Such a switch SW ₁ may be controlled by an automatic sensing circuit (not shown) as described above. That is, when the external dimming circuit is not detected or the dimming control function is prohibited according to the jumper setting, the automatic detection circuit controls the switch SW ₁ to connect the first light emitting device group driving unit 222 to the Rset terminal with a pull-up resistor connected to the Rset terminal. It is connected to the unit 410, and when an external dimming circuit is detected, the automatic sensing circuit controls the switch SW ₁ to connect the first light emitting device group driving unit 222 to the pull-up resistor unit 420 connected to the Adim terminal. do.

The electronic switching device (Q ₁ ) is turned on under the control of the light emitting device driving control unit 210 _{to connect the first current path (P 1} ), and is turned off to open the first current path (P ₁ ) is composed As the electronic switching device Q ₁ , a bipolar junction transistor (BJT), a field effect transistor (FET), or the like may be used, and the type thereof is not limited. 4 shows an embodiment in which the electronic switching device (Q ₁ ) is implemented as a P-type MOSFET (P-type MOSFET) according to the present invention.

_{The maximum first driving current reference value (I ref1} ) or dimming-controlled first driving current reference value (Adim_I _ref1 ) output from the light emitting device driving control unit 210 is input to the non-inverting input terminal of the differential amplifier (OP ₁ ) as a reference value, At the non-inverting input terminal of the differential amplifier (OP ₁ ), the voltage value across the sensing resistor (Rsense1) (ie, the first current path (P ₁ ) The voltage corresponding to the first light emitting device driving current (I _{LED1 ) flowing through the first current path (P 1 )} value) is entered. The differential amplifier OP ₁ compares the voltage value input through the non-inverting input terminal with the voltage value input through the inverting input terminal, and according to the comparison result, the first light emitting device driving current I _LED1 is maintained as the input reference value. A constant current control function is performed by controlling the gate voltage of the electronic switching element (Q _{1 ) so as to be able to do so.}

Similar to the first light emitting device group driving unit 222, the second light emitting device group driving unit 224 to the fourth light emitting device driving unit 228 according to the present invention also includes one electronic switching device, one sensing resistor, and one differential. It may be configured to include an amplifier.

Accordingly, the second light emitting device group driving unit 224 _{connects or opens the second current path P 2} , and the maximum second driving current reference value I _ref2 output from the light emitting device driving control unit 210 or dimming control Constant current control is performed so that the second driving current I _LED2 is maintained at the input reference value by using the second driving current reference value Adim_I _{ref2 as a reference value.} Similarly, the third light emitting device group driving unit 226 _{connects or opens the third current path P 3} , and the maximum third driving current reference value I _ref3 output from the light emitting device driving control unit 210 or dimming control The constant current control is performed so that the third driving current I _LED3 can be maintained at the input reference value by using the third driving current reference value Adim_I _{ref3 as a reference value.} Finally, the fourth light emitting device group driving unit 228 also _{connects or opens the fourth current path P 4} , and the maximum fourth driving current reference value I _ref4 output from the light emitting device driving control unit 210 or dimming By using the controlled fourth driving current reference value Adim_I _ref4 as a reference value, constant current control is performed so that the fourth light emitting device driving current ILED _{4 is maintained at the input reference value.}

of the dimming control of the light emitting device lighting device 1000 one example

5 is a waveform diagram showing the relationship between the driving voltage of the light emitting device and the driving current of the light emitting device according to the dimming level based on the positive half cycle of the AC voltage according to the first exemplary embodiment of the present invention. A dimming control process performed in the light emitting device lighting apparatus 1000 according to the present invention will be described in detail with reference to FIGS. 2, 3 and 5 .

First, there is illustrated the waveform of the driving voltage (V _P) and the light emitting device drive current (I _LED) in the case where the dimming level is set to 100%, the top (i.e., FIG. 5 (a)) in Fig. The following Table 1 is a table summarizing the relationship between the driving period, the operating state of the light emitting device groups, and the light emitting device driving current in this case.

drive section light emitting device
group 1 light emitting device
group 2 light emitting device
group 3 light emitting device
group 4 I _LED t1 to t2 ON OFF OFF OFF I _ref1 t2~t3 ON ON OFF OFF I _ref2 t3~t4 ON ON ON OFF I _ref3 t4 to t5 ON ON ON ON I _ref4 t5~t6 ON ON ON OFF I _ref3 t6 to t7 ON ON OFF OFF I _ref2 t7 to t8 ON OFF OFF OFF I _ref1

As shown in the figure, does not occur with respect to a phase control ac power supply (V _AC) selected dimming level is inputted is 100%. Thus, a phase control did not take place with respect to the drive voltage (V _P) accordingly. First, Fig. 5 (a), if the same as shown being an embodiment, light-level detecting unit 140 is detected, and the light-emitting element driving the detecting light-level signal (Adim) a dimming level by averaging the driving voltage (V _P) output to the module 200 . At this time, the dimming level detected is 100%, and the dimming level signal Adim input to the light emitting device driving module 200 becomes a constant voltage signal corresponding to the dimming level of 100%. Accordingly, in this case, the light emitting device lighting apparatus 1000 is controlled in the same manner as in the general four-stage sequential driving method.

Referring to (a) of Figure 5, at a time point (t1) to reach the first forward voltage level (Vf1) to a voltage level increases in the driving voltage (V _P) with the passage of time, the light emitting element drive control section (210 ), the first light emitting device group driving unit 222 is turned on to _{connect the first current path P 1} , and accordingly, the first light emitting device driving current I through the first current path P1 _LED1 ) flows and the first light emitting device group 310 emits light. At this time, the light emitting device driving control unit 210 outputs the maximum first driving current reference value I _ref1 as a reference value for constant current control to the first light emitting device group driving unit 222 because the dimming level is 100%, and the first light emitting device group drive 222 is a first light emitting device drive current (I _LED1) for detecting, and the constant current to be maintained at a first light emitting device drive current (I _LED1) up to a first drive current reference value (I _ref1) control will perform

Subsequently, according to the control at the time point (t2) of reaching the second forward voltage level (Vf2) in voltage level is further increase of the driving voltage (V _P) with the passage of time, the light emitting element drive control section (210) of claim first light emitting element group driving section 222 is turned to be oN and the second current path (P ₂₎ is connected, whereby the second current path (P ₂₎ according-off and the second light emitting element group driving part 224 is turned Through the second light emitting device driving current I _LED2 flows, and the first light emitting device group 310 and the second light emitting device group 320 emit light. At this time, the light emitting device driving control unit 210 outputs the maximum second driving current reference value I _ref2 as a reference value for constant current control to the second light emitting device group driving unit 224 because the dimming level is 100%, and the second light emitting device group drive 222 is a second light emitting device drive current (I _LED2) of the detection, and the second light emitting device drive current (I _LED2) up to the constant current to be maintained second drive as a current reference value (I _ref2) control will perform

Similarly, under the control of the drive voltage (V _P), the third at a time point (t3) to reach the forward voltage level (Vf3), the light-emitting element driving control unit 210 to the voltage level the further rise of the lapse of time 2 The light emitting device group driver 224 is turned off and the third light emitting device group driver 226 is turned on to connect _{the third current path P 3 .} Accordingly, the third light emitting device driving current I _LED3 flows through the third current path P ₃ , and the first light emitting device group 310 to the third light emitting device group 330 emit light. At this time, the light emitting device driving control unit 210 outputs the maximum third driving current reference value I _ref3 as a reference value for constant current control to the third light emitting device group driving unit 226 because the dimming level is 100%, and the third light emitting device The group driver 226 detects the third light emitting device driving current (I _{LED3 ), and performs a} constant current control function so that the third light emitting device driving current (I _LED3 ) can be maintained at the maximum third driving current reference value (I ref3 ). will perform

Further, according to the control of the drive voltage (V _P), the fourth time point (t4) to reach the forward voltage level (Vf4), the light-emitting element driving control unit 210 to the voltage level the further increase in over a period of time a third The light emitting device group driver 226 is turned off and the fourth light emitting device group driver 228 is turned on to connect _{the fourth current path P 4 .} Accordingly, the fourth light emitting device driving current I _LED4 flows through the fourth current path P ₄ , and the first to fourth light emitting device groups 310 to 340 emit light. At this time, the light emitting device driving control unit 210 outputs the maximum fourth driving current reference value I _ref4 as a reference value for constant current control to the fourth light emitting device group driving unit 228 because the dimming level is 100%, and the fourth light emitting device The group driving unit 228 detects the fourth light emitting device driving current (I _{LED4 ), and performs a} constant current control function so that the fourth light emitting device driving current (I _LED4 ) can be maintained at the maximum fourth driving current reference value (I ref4 ) will perform

On the other hand, after the driving voltage (V _P) with the lapse of time it reaches the maximum value to the voltage level is lowered in the fourth forward voltage level (Vf4) at a time point (t5) which is less than the light emitting element drive control section 210 According to the control, the fourth light emitting device group driver 228 is turned off and the third light emitting device group driver 226 is turned on to connect _{the third current path P 3 .} Accordingly, the third light emitting device driving current I _LED3 flows through the third current path P ₃ , and the first light emitting device group 310 to the third light emitting device group 330 emit light. At this time, as described above, the third light emitting device group driving unit 226 detects the third light emitting device driving current I _LED3 , and the third light emitting device driving current I _LED3 is the maximum third driving current A constant current control function is performed to maintain the reference value (I _{ref3 ).}

In addition, the third light-emitting in response to a control at the time (t6) that the less than three forward voltage level (Vf3) and the driving voltage (V _P), the voltage level is lowered with the lapse of time, the light-emitting element driving control unit 210 The device group driver 226 is turned off and the second light emitting device group driver 224 is turned on to connect _{the second current path P 2 .} Accordingly, the second light emitting device driving current I _LED2 flows through the second current path P ₂ , and the first light emitting device group 310 and the second light emitting device group 320 emit light. At this time, in the same manner as described above, the second light emitting device group driving unit 224 performs a constant current control function so _{that the second light emitting device driving current I LED2} can be maintained at the maximum second driving current reference value I _{ref2 .} will perform

Finally, under the control of the drive voltage (V _P) at the time (t7) that the voltage level is lowered to be less than the second forward voltage level (Vf2), the light-emitting element driving control unit 210 with the lapse of time, the second The light emitting device group driver 224 is turned off and the first light emitting device group driver 222 is turned on to connect _{the first current path P 1 .} Accordingly, only the first light emitting device group 310 emits light, and the first light emitting device group driver 222 maintains the first light emitting device driving current I _LED1 at the maximum first driving current reference value I _ref1 . It performs a constant current control function.

Next, FIG stopped (i.e., 5 in (b)) has a relatively high light control level (e. G., 80%) of a drive voltage (V _P) and the light emitting device drive current (I when it is set in _{The waveform of the LED} ') is shown. The following Table 2 is a table summarizing the relationship between the driving period, the operating state of the light emitting device groups, and the light emitting device driving current in this case.

drive section light emitting device
group 1 light emitting device
group 2 light emitting device
group 3 light emitting device
group 4 I _LED ' t3~t4 ON ON ON OFF Adim_I _ref3' t4 to t5 ON ON ON ON Adim_I _ref4' t5~t6 ON ON ON OFF Adim_I _ref3' t6 to t7 ON ON OFF OFF Adim_I _ref2' t7 to t8 ON OFF OFF OFF Adim_I _ref1'

Referring to (b) of Figure 5, because dimming level of 80% was a phase control occurred with respect to the drive voltage (V _P), therefore, the time (t3) the drive voltage a voltage level of (V _P) is at 0V to maintain. Thus, Figure 5 (b), if the same as shown being an embodiment, light-level detecting unit 140 is detected, and the light-emitting element driving the detecting light-level signal (Adim) a dimming level by averaging the driving voltage (V _P) output to the module 200 . At this time, the detected dimming level will be 80%, and substantially the dimming level signal Adim input to the light emitting device driving module 200 will be a constant voltage signal corresponding to the dimming level of 80%. Accordingly, in the embodiment shown in FIG. 5B , the light emitting device driving module 200 performs dimming control based on a dimming level of 80%.

It is turned on the third current path (P ₃₎ - in which the voltage level at the time point (t3), the drive voltage (V _P), the third because the rise in the forward voltage level (Vf3), the third light emitting element group driving part 226 is turned Connected. Accordingly, the third light emitting device driving current I _LED3 ′ flows through the third current path P ₃ , and the first to third light emitting device groups 310 to 330 emit light. At this time, since the dimming level is 80%, the light emitting device driving control unit 210 sets the dimming controlled third driving current reference value (Adim_I _ref3 ) corresponding to the dimming level of 80% as a reference value for constant current control to the third light emitting device group driving unit ( 226). Here, the dimming-controlled third driving current reference value Adim_I _ref3 corresponding to the dimming level of 80% may be determined in various ways. In the first embodiment, the dimming-controlled third driving current reference value Adim_I _ref3 corresponding to the dimming level of 80% is "a*(the dimming level signal Adim corresponding to the dimming level of 80%)*( The maximum third driving current reference value (I _ref3 ))” may be determined (here, a is an arbitrary constant for making the light output or light flux of the light emitting device lighting apparatus 1000 equal to 80% of the maximum light output or light flux) ). Alternatively, in another embodiment, the dimming-controlled third driving current reference value Adim_I _ref3 corresponding to the dimming level of 80% may be determined as “b*0.8* (maximum third driving current reference value I _{ref3 )”.} (herein, b is an arbitrary constant for allowing the light output or light flux of the light emitting device lighting apparatus 1000 to be 80% of the maximum light output or light flux). Alternatively, in another embodiment, an equation or graph for the dimming level and the dimming-controlled third driving current reference values (Adim_I _ref3 ) is stored, and dimming is controlled using the equation or graph according to the detected dimming level. A third driving current reference value Adim_I _ref3 may be determined. In addition to a variety of other ways, and can be determined this light-controlled third drive current reference value (Adim_I _ref3), in proportion to the dimming level, notwithstanding the above, various modifications and transformation that is determined is the light-control control of the third drive current reference value (Adim_I _ref3) And it will be apparent to those skilled in the art that it falls within the scope of the present invention. The dimming-controlled first driving current reference value Adim_I _ref1 , the dimming-controlled second driving current reference value Adim_I _ref2 , and the dimming-controlled fourth driving current reference value Adim_I _ref4 may also be determined in the same manner.

At a time point t4 when the voltage level of the driving voltage V _P further increases to reach the fourth forward voltage level Vf4 over time, the third light emitting device is controlled by the light emitting device driving controller 210 . The group driver 226 is turned off and the fourth light emitting device group driver 228 is turned on to connect _{the fourth current path P 4 .} Accordingly, the fourth light emitting device driving current I _LED4 ′ flows through the fourth current path P ₄ , and the first to fourth light emitting device groups 310 to 340 emit light. At this time, the light emitting device driving control unit 210 outputs the dimming controlled fourth driving current reference value Adim_I _ref4 corresponding to the dimming level of 80% to the fourth light emitting device group driving unit 228, and the fourth light emitting device group driving unit 228 detects the fourth light emitting device driving current ILED _{4 ′} , and controls the constant current so that the fourth light emitting device driving current I _LED4 ′ is maintained at the dimming controlled fourth driving current reference value Adim_I _{ref4 .} function will be performed.

On the other hand, after the driving voltage (V _P) with the lapse of time it reaches the maximum value to the voltage level is lowered in the fourth forward voltage level (Vf4) at a time point (t5) which is less than the light emitting element drive control section 210 According to the control, the fourth light emitting device group driver 228 is turned off and the third light emitting device group driver 226 is turned on to connect _{the third current path P 3 .} Accordingly, the third light emitting device driving current I _LED3 ′ flows through the third current path P ₃ , and the first to third light emitting device groups 310 to 330 emit light. At this time, as described above, the third light emitting device group driving unit 226 detects the third light emitting device driving current I _LED3 ′, and the third light emitting device driving current I _LED3 ′ is 80%. A constant current control function is performed to maintain the dimming controlled third driving current reference value Adim_I _{ref3 corresponding to the dimming level.}

In addition, the third light-emitting in response to a control at the time (t6) that the less than three forward voltage level (Vf3) and the driving voltage (V _P), the voltage level is lowered with the lapse of time, the light-emitting element driving control unit 210 The device group driver 226 is turned off and the second light emitting device group driver 224 is turned on to connect _{the second current path P 2 .} Accordingly, the second light emitting device driving current I _LED2 ′ flows through the second current path P ₂ , and the first light emitting device group 310 and the second light emitting device group 320 emit light. At this time, in the same manner as described above, the second light emitting device group driving unit 224 has a dimming controlled second driving current reference value Adim_I corresponding to a dimming level of 80% of _{the second light emitting device driving current I LED2 ′. ref2} ) to maintain a constant current control function.

Finally, under the control of the drive voltage (V _P) at the time (t7) that the voltage level is lowered to be less than the second forward voltage level (Vf2), the light-emitting element driving control unit 210 with the lapse of time, the second The light emitting device group driver 224 is turned off and the first light emitting device group driver 222 is turned on to connect _{the first current path P 1 .} Accordingly, only the first light emitting device group 310 emits light, and the first light emitting device group driver 222 controls the first light emitting device driving current I _LED1 ′ to be dimmed corresponding to a dimming level of 80%. A constant current control function is performed to maintain the driving current reference value (Adim_I _{ref1 ).}

Next, the driving voltage VP and the light emitting device driving current ILED when a relatively low dimming level (eg, 40%) is set at the lower end of FIG. 5 (ie, FIG. 5(c)) The waveform of is shown. The following Table 3 is a table summarizing the relationship between the driving period, the operating state of the light emitting device groups, and the light emitting device driving current in this case.

drive section light emitting device
group 1 light emitting device
group 2 light emitting device
group 3 light emitting device
group 4 I _LED '' t4'~t5 ON ON ON ON Adim_I _ref4 '' t5~t6 ON ON ON OFF Adim_I _ref3 '' t6 to t7 ON ON OFF OFF Adim_I _ref2 '' t7 to t8 ON OFF OFF OFF Adim_I _ref1 ''

Referring to (c) of Figure 5, the light control level was a phase control occurred with respect to 40%, so the driving voltage (V _P), therefore, the time (t5 '), the voltage level of the drive voltage (V _P) 0V to is maintained as Thus, Fig. 5 (c), if the same as shown being an embodiment, light-level detecting unit 140 detects a light modulation level by averaging the driving voltage (V _P), the light-emitting element driving the detecting light-level signal (Adim) output to the module 200 . At this time, the detected dimming level will be 40%, and substantially the dimming level signal Adim input to the light emitting device driving module 200 will be a constant voltage signal corresponding to the dimming level of 40%. Accordingly, in the embodiment shown in FIG. 5C , the light emitting device driving module 200 performs dimming control based on a dimming level of 40%.

Is because the voltage level at the time point (t5), the drive voltage (V _P) raised to the fourth forward voltage level (Vf4), the fourth light emitting element group drive 228 according to the control of the light emitting element drive control section 210, turn- is turned on to connect the fourth current path (P ₄ ). Accordingly, the fourth light emitting device driving current I _LED4 '' flows through the fourth current path P ₄ , and the first to fourth light emitting device groups 310 to 340 emit light. At this time, the light emitting device driving control unit 210 outputs the dimming controlled fourth driving current reference value Adim_I _ref4 ′ corresponding to the dimming level of 40% to the fourth light emitting device group driving unit 228, and the fourth light emitting device group The driving unit 228 detects the fourth light emitting device driving current I _LED4 '', and the fourth light emitting device driving current I _LED4 '' is maintained at the dimming controlled fourth driving current reference value (Adim_I _ref4 '). It performs a constant current control function so that

On the other hand, after the driving voltage (V _P) with the lapse of time it reaches the maximum value to the voltage level is lowered in the fourth forward voltage level (Vf4) at a time point (t5) which is less than the light emitting element drive control section 210 According to the control, the fourth light emitting device group driver 228 is turned off and the third light emitting device group driver 226 is turned on to connect _{the third current path P 3 .} Accordingly, the third light emitting device driving current I _LED3 '' flows through the third current path P ₃ , and the first light emitting device group 310 to the third light emitting device group 330 emit light. At this time, as described above, the third light emitting device group driving unit 226 detects the third light emitting device driving current I _LED3 '', and the third light emitting device driving current I _LED3 '' emits light. A constant current control function is performed to maintain _{the dimming controlled third driving current reference value Adim_I ref3} ′ corresponding to a dimming level of 40% input from the device driving controller 210 .

In addition, the third light-emitting in response to a control at the time (t6) that the less than three forward voltage level (Vf3) and the driving voltage (V _P), the voltage level is lowered with the lapse of time, the light-emitting element driving control unit 210 The device group driver 226 is turned off and the second light emitting device group driver 224 is turned on to connect _{the second current path P 2 .} Accordingly, the second light emitting device driving current I _LED2 '' flows through the second current path P ₂ , and the first light emitting device group 310 and the second light emitting device group 320 emit light. At this time, in the same manner, the second light emitting element group drive 224 is light-controlled second drive current reference value corresponding to the dimming level of the second light emitting device drive current (I _LED2 '') is 40% as referred to above ( Adim_I _ref2 ') performs a constant current control function.

Finally, under the control of the drive voltage (V _P) at the time (t7) that the voltage level is lowered to be less than the second forward voltage level (Vf2), the light-emitting element driving control unit 210 with the lapse of time, the second The light emitting device group driver 224 is turned off and the first light emitting device group driver 222 is turned on to connect _{the first current path P 1 .} Accordingly, only the first light emitting device group 310 emits light, and the first light emitting device group driving unit 222 has _{a dimming controlled first light emitting device driving current I LED1} '' corresponding to a dimming level of 40%. 1 The constant current control function is performed so that the driving current reference value (Adim_I _{ref1 ') can be maintained.}

6A is a graph showing the relationship between dimming voltage, light output, and luminous flux according to the dimming level of an AC-driven light emitting device lighting apparatus capable of dimming according to the first preferred embodiment of the present invention, and FIG. 6B is the present invention. It is a graph showing the relationship that can be implemented according to an exemplary embodiment and the upper limit, the lower limit of the light output according to the dimming level of the dimming AC-driven light emitting device lighting device according to the first preferred embodiment of the present invention. As shown in FIGS. 6A and 6B , when the light emitting device lighting device 1000 according to the present invention is used, the light output and the light flux of the light emitting device lighting device 1000 are smooth over the entire range of the dimming level. Also, it can be confirmed that irregular shaking does not occur.

7 is a diagram illustrating the configuration of an LED driving module according to a second embodiment of the present invention, and FIG. 8 is a circuit diagram of a light emitting device group driving unit according to a second embodiment of the present invention.

9 is a diagram illustrating a driving current of a light emitting device group according to the Adim control signal of FIG. 8 , FIG. 10 is a diagram illustrating a configuration of a temperature control unit according to a second embodiment of the present invention, and FIG. 11 is a diagram of the present invention It is a view showing the LED driving timing by the temperature controller according to the second embodiment.

7 to 10 , the configurations except for the LED driving module 500 according to the second embodiment of the present invention are the same as those of the light emitting device lighting device according to the first embodiment of the present invention, and thus detailed description is omitted. decide to do

The LED driving module 500 includes an internal bias reference setting unit 511, a low voltage blocking circuit (UVLO), a start-up (Start-up, 512), a firing current reference setting unit 530, a temperature control unit 540, Active bleeder, dimming level detection unit 553, reference voltage selection unit 555, driving current setting unit 559, switch unit 570, first to fourth light emitting device groups (LED1 to LED4) includes The LED driving module 500 may control the driving of the first to fourth light emitting device groups LED1 to LED4 by an dimming level control signal according to the dimming level. Referring to FIG. 10 , at least one of the first to fourth light emitting device groups LED1 to LED4 may be selected and driven according to the dimming level control signal.

The internal bias reference setting unit 511 generates a driving voltage of the internal configuration of the LED driving module 500 by using the power supply voltage VCC. The internal bias reference setting unit 511 receives the power supply voltage (VCC) and the driving module enable signal from the start-up 512 and is supplied to the firing current reference setting unit 530 and the reference voltage selection unit 555. Each of them supplies a driving voltage. Here, the internal bias reference setting unit 511 is not particularly limited, but may provide a driving voltage of the temperature control unit 540 and may include a function of detecting a temperature.

The temperature control unit 540 detects the temperature of the LED driving module 500, allows the driving of the LED driving module 500 below the first reference temperature (enable), and above the second reference temperature, the LED driving module ( 500) is disabled.

Here, in the general LED driving module, driving of the LED driving module is permitted or prohibited above one reference temperature. Accordingly, in the general LED driving module, there is a problem in that the driving of the LED driving module is repeatedly permitted or prohibited around the one reference temperature, thereby causing a flicker phenomenon.

In the present invention, the temperature at which the driving of the LED driving module 500 is prohibited and the temperature at which the driving of the LED driving module 500 is allowed are different from each other. Accordingly, the temperature control unit 540 may improve the flicker phenomenon that may occur by setting the first and second reference temperatures at which the driving of the LED driving module 500 is allowed and prohibited to be different from each other and set to the same. The temperature controller 540 will be described in detail with reference to FIGS. 10 and 11 .

The low voltage blocking circuit UVLO has a function of blocking the low voltage driving by using the input driving voltage VP. Accordingly, the first to fourth light emitting device groups LED1 to LED4 are stably driven. The low voltage blocking circuit UVLO may include a first resistor R1 , first and second Zener diodes D1 and D2 , and a start-up 512 . Here, the low voltage blocking circuit UVLO is not limited to the above configuration, and various circuits for blocking the low voltage driving with a separate configuration may be used.

The start-up 512 generates a start enable signal informing the driving start time of the LED driving module 500 . The start-up 512 may generate a temperature controller enable signal POR for driving the temperature controller 540 .

The active bleeder includes a firing current reference setting unit 530 and a bleeder resistor R _BLD connected to a bleeder terminal. The active bleeder has a function for preventing malfunction of the dimmer. In particular, the active bleeder may select a capacity of _{the bleeder resistor R BLD} connected to the driving voltage VP so that the dimmer is normally driven by a reference current at which the dimmer operates or more.

A buffer 551 is located between the ADIM terminal and the dimming level detection unit 553 and the reference voltage selection unit 555 , and the RSET terminal is located between the reference voltage selection unit 555 and the driving current setting unit 559 . do.

A configuration for detecting a dimming level according to the phase-converted driving voltage by the dimmer and determining and driving a corresponding light emitting device driving current reference value will be omitted with reference to the first embodiment of the present invention.

Here, in the second embodiment of the present invention, the first to fourth driving current reference values for driving the first to fourth light emitting device groups LED1 to LED2 may be changed using the variable resistor R6. The variable resistor R6 may be connected to a switch terminal of the LED driving module 500 .

The temperature controller 540 will be described in detail with reference to FIGS. 9 and 10 .

9 to 11 , the temperature control unit 540 includes a temperature sensor TS, a first resistance Rt1, a second resistance Rt2, a first temperature detection unit 542, and a second temperature detection unit ( 543 ), a comparison unit 545 , and a control unit 547 .

The temperature control unit 540 detects the temperature of the LED driving module and controls the driving of the LED driving module to prevent malfunction of the LED driving module due to high temperature. The first and second temperature detectors 542 and 543 have first and second reference temperatures different from each other. For example, the first reference temperature may be 130°C, and the second reference temperature may be 150°C.

The comparator 545 outputs a high signal at a temperature control enable signal POR and a first reference temperature of the first temperature detection unit 542 (130° C. or less), and a low signal when the first reference temperature is exceeded. output a signal.

The selection unit 547 permits or prohibits the driving of the driving current setting unit using the signal input from the comparator 545 and the signal input from the second temperature detection unit 542 . Specifically, the second temperature detection unit 543 outputs a high signal at or above the second reference temperature (150° C. or above), and outputs a low signal below the second reference temperature. When a high signal is input from the comparison unit 545 , the selection unit 547 _{turns off the switching element Q 4} to allow the driving current setting unit to be driven to drive the LED driving module. On the other hand, when a high signal is input from the second temperature detection unit 543 , the selection unit 547 _{turns on the switching element Q 4} to prohibit the driving of the driving current setting unit to stop the LED driving module. make it Here, the selection unit 547 maintains the driving of the LED driving module in a stopped state until a high signal is input from the first temperature detection unit 542 after the driving is prohibited.

When described in more detail with reference to Table 4 below,

Temperature comparison department second temperature detection unit Q ₄ 0℃~130℃ High Low OFF 131℃~149℃ Low Low OFF 150℃~ Low High ON 149℃~131℃ Low Low ON (Hold)

Referring to Table 4, when the temperature of the LED driving module is in the range of 0°C to 130°C, the comparator 545 receives the high signal of the first reference temperature control unit 542 and the high signal of the temperature control unit enable signal POR. and outputs a high signal to the selection unit 547 , and the second temperature detection unit 543 outputs a low signal to the selection unit 547 because the detected temperature is less than 150°C. _{The selection unit 547 turns off the switch Q 4} using the high signal of the comparator 545 and the low signal of the second temperature detection unit 543 to allow the LED driving module to be driven.

When the temperature of the LED driving module is in the range of 131°C to 149°C, the comparison unit 545 selects the selection unit 547 by the low signal of the first reference temperature control unit 542 and the high signal of the temperature control unit enable signal (POR). A raw signal is output, and the second temperature detection unit 543 outputs a low signal to the selection unit 547 because the detected temperature is less than 150°C. _{The selection unit 547 turns off the switch Q 4} using the low signal of the comparator 545 and the low signal of the second temperature detection unit 543 to allow the LED driving module to be driven.

When the temperature of the LED driving module is 150° C. or higher, the comparator 545 sends a low to the selection unit 547 by the low signal of the first reference temperature control unit 542 and the high signal of the temperature control unit enable signal POR. The signal is output, and the second temperature detection unit 543 outputs a high signal to the selection unit 547 because the detected temperature is 150° C. or higher. _{The selection unit 547 turns on the switch Q 4} using the low signal of the comparator 545 and the high signal of the second temperature detection unit 543 to prohibit the driving of the LED driving module.

When the temperature of the LED driving module is in the range of 149°C to 131°C, the comparison unit 545 selects the selection unit 547 by the low signal of the first reference temperature control unit 542 and the high signal of the temperature control unit enable signal (POR). A raw signal is output, and the second temperature detection unit 543 outputs a low signal to the selection unit 547 because the detected temperature is less than 150°C. _{The selection unit 547 turns on the switch Q 4} using the low signal of the comparison unit 545 and the low signal of the second temperature detection unit 543 to prohibit the driving of the LED driving module. Here, in the section in which the temperature of the LED driving module is 149°C to 131°C, the low signal is converted to a high signal by the first temperature detection unit 542 from the section in which the temperature of the LED driving module is lowered from 150°C to less than 150°C. It is defined as a section to be A section in which the temperature of the LED driving module is 149°C to 131°C is a section in which a high signal is converted from a high signal to a low signal by the second temperature detection unit 543 to a section in which a low signal is converted to a high signal by the first temperature detection unit 542. It is defined as a hold section.

In the present invention, the temperature at which the driving of the LED driving module is prohibited and the temperature at which the driving of the LED driving module is allowed are different from each other. Therefore, the temperature control unit 540 sets the first and second reference temperatures (eg, 130° C., 150° C.) at which the driving of the LED driving module is permitted and prohibited to be different from each other to prevent the flicker phenomenon that may occur by setting the same. can be improved

12 is a graph showing the LED driving timing by correcting the maximum and minimum voltage levels according to the second embodiment of the present invention.

The LED driving module of the present invention further includes a maximum and minimum driving voltage level correction unit (not shown). A general LED driving module has a constant proportional driving voltage as the rated voltage increases. The maximum and minimum driving voltage level correction unit of the present invention compensates for the level of the reference driving voltage provided to the LED driving module in an arbitrary minimum rated voltage section, level is rewarded. Specifically, when the rated voltage of the LED driving module is AC 185V to 265V, the minimum driving voltage level correction unit increases a voltage level of approximately 5% of the basic driving voltage from the minimum rated voltage (AC 185V), and the maximum driving voltage The level compensator reduces the voltage level of about 5% of the basic driving voltage at the maximum rated voltage (AC 265V). That is, the maximum and minimum driving voltage level correcting unit of the present invention compensates the voltage level within ±5% of the reference driving voltage according to the magnitude of the rated voltage, thereby implementing a stable LED driving module even with changes in the rated voltage.

Therefore, the LED driving module of the present invention can implement stable driving by increasing or decreasing the driving voltage in the minimum and maximum sections of the rated voltage, respectively.

13 is a waveform diagram illustrating an LED driving timing by a low voltage blocking circuit according to a second embodiment of the present invention.

As shown in FIG. 13 , the low voltage blocking circuit (UVLO) of the present invention disables or enables the driving of the LED driving module in a driving voltage section having an arbitrary voltage level, thereby enabling the LED in an unstable low voltage section. By stopping the driving module, stable driving of the light emitting device group can be realized. The low voltage blocking circuit (UVLO) of the second embodiment is described by limiting the characteristic of stopping the driving of the LED driving module in a low voltage section of 20% or less, but the present invention is not limited thereto, and the low voltage section can be changed as much as possible.

14 is a circuit diagram illustrating a light emitting diode driving device according to a third embodiment of the present invention, and FIG. 15 is a voltage waveform and a current waveform of an AC power input to the light emitting diode driving device according to the third embodiment of the present invention. , is a waveform diagram showing the waveform of the driving voltage supplied to the LED group.

14 and 15 , the light emitting diode driving device according to the third embodiment of the present invention includes a power supply unit ( _VAC ), a full-wave rectification unit 910, an LED light emitting module 930, and an LED driving module 920. includes

The power supply unit V _AC generates a high-voltage AC voltage.

_{A fuse F 1} is provided between the power supply unit V _AC and the LED light emitting module 930 . The fuse F ₁ has a function of protecting wiring and circuits of the light emitting diode driving device by blocking the supply of an excessive input voltage above a certain voltage level through the power supply unit V _{AC .} Although not shown in the drawings, the fuse F ₁ may be replaced with resistors (not shown) connected to the input/output terminals of the power supply unit _VAC.

The full-wave rectifying unit 910 may include four diodes D1 to D4, and _{full-wave rectifies the AC voltage from the power source VAC} to generate a full-wave rectified voltage. In the present invention, the full-wave rectified voltage is defined as a driving voltage for driving the LED light emitting module 930 . In an embodiment of the present invention, a bridge full-wave rectification circuit using four diodes D1 to D4 is limitedly described, but the present invention is not limited thereto, and may be one of various rectification circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit.

The LED light emitting module 930 may be composed of a plurality of LED groups. For example, the plurality of LED groups includes first to fourth LED groups LED1, LED2, LED3, and LED4. The first to fourth LED groups LED1 , LED2 , LED3 , and LED4 may be sequentially driven by the LED driving module 920 . In an embodiment of the present invention, the LED light emitting module 930 composed of the first to fourth LED groups (LED1, LED2, LED3, LED4) is limitedly described, but the present invention is not limited thereto, and the number of LED groups varies. can be changed to Also, the number of LEDs of each of the first to fourth LED groups LED1, LED2, LED3, and LED4 may be the same or different. Here, the first to fourth LED groups LED1 , LED2 , LED3 , and LED4 may have different forward voltage levels.

The LED light emitting module 930 includes first to fourth capacitors C ₁ . C ₂ , C ₃ , and C ₄ . The first to fourth capacitors C ₁ . C ₂ , C ₃ , C ₄ may be connected in parallel with the first to fourth LED groups LED1 , LED2 , LED3 and LED4 . Specifically, the first capacitor C ₁ and the first LED group LED1 are connected in parallel between the input terminal of the full-wave rectifier 910 and the second LED group LED2. The second capacitor C ₂ and the second LED group LED2 are connected in parallel between the first and third LED groups LED1 and LED3. The third capacitor C ₃ and the third LED group LED3 are connected in parallel between the second and fourth LED groups LED2 and LED4. The fourth capacitor C ₄ and the fourth LED group LED4 are connected in parallel between the third LED group LED3 and the LED driving module 920 .

The first to fourth capacitors (C ₁ . C ₂ , C ₃ , C ₄ ) are driving voltages defined as full-wave rectified voltages for driving the first to fourth LED groups (LED1, LED2, LED3, LED4). It has a function of preventing a flicker phenomenon caused by on/off of a switch that controls driving of each LED group by charging and supplying the charged compensation driving voltage to the LED group.

The LED light emitting module 930 includes first to third diodes D ₅ , D ₆ , and D ₇ . The first to third diodes D ₅ , D ₆ , and D ₇ may be connected between the first to fourth LED groups LED1 , LED2 , LED3 , and LED4 . Specifically, the first diode D ₅ is connected in series between the first and second LED groups LED1 and LED2. Also, the first diode D ₅ is connected in series between the first and second capacitors C ₁ . C _{2 .} The second diode D ₆ is connected in series between the second and third LED groups LED2 and LED3. Also, the second diode D ₆ is connected in series between the second and third capacitors C ₂ and C _{3 .} The third diode D ₇ is connected in series between the third and fourth LED groups LED3 and LED4. Also, the third diode D ₇ is connected in series between the third and fourth capacitors C ₃ and C _{4 .}

The first to third diodes (D ₅ , D ₆ , D ₇ ) are sequentially driven by the first to fourth LED groups ( LED1 , LED2 , LED3 , LED4 ) in the period in which the driving of the first to fourth LED groups is started and blocked. It has a function of allowing the compensation driving voltage charged in the fourth capacitors C ₁ . C ₂ , C ₃ , and C _{4 to be supplied to the LED group.}

Looking at the driving of the first to fourth LED groups (LED1, LED2, LED3, LED4), the first section is defined as a section in which the driving voltage is greater than or equal to the first forward voltage level (Vf1) and less than the second forward voltage level (Vf2), and , during the first period, the first LED group LED1 is driven under the control of the LED driving module 920 . Energy of the first forward voltage level Vf1 or higher and the second forward voltage level Vf2 is charged in the first capacitor C _{1 .}

The second section is defined as a section in which the driving voltage is greater than or equal to the second forward voltage level (Vf2) and less than the third forward voltage level (Vf3), and during the second section, the first and second LED groups LED1 and LED2 are driven. Energy of the second forward voltage level Vf2 or higher and the third forward voltage level Vf3 is charged in the second capacitor C _{2 .} Here, the first capacitor C ₁ supplies the compensated driving voltage charged in the current rising period of the switch for driving the second LED group LED2 through the first diode D ₅ to improve flicker. can

The third period is defined as a period in which the driving voltage is greater than or equal to the third forward voltage level (Vf3) and less than the fourth forward voltage level (Vf4), and during the third period, the first to third LED groups (LED1, LED2, LED3) are driven. Energy of the third forward voltage level Vf3 or higher and the fourth forward voltage level Vf4 is charged in the third capacitor C _{3 .} Here, the second capacitor C ₂ supplies the compensated driving voltage charged in the current rising period of the switch for driving the third LED group LED3 through the second diode D ₆ to improve flicker. can

The fourth section is defined as a section in which the driving voltage is greater than or equal to the fourth forward voltage level (Vf4) and less than the fifth forward voltage level (Vf5), and during the fourth section, the first to fourth LED groups (LED1, LED2, LED3, LED4) are driven. Energy of the fourth forward voltage level Vf4 or higher and the fifth forward voltage level Vf5 is charged in the fourth capacitor C _{4 .} Here, the third capacitor C ₃ supplies the compensated driving voltage charged in the current rising period of the switch for driving the fourth LED group LED4 through the third diode D ₇ to improve flicker. can

The light emitting diode driving apparatus of the present invention can control the first to fourth LED groups (LED1, LED2, LED3, LED4) with the same driving current with constant current.

Meanwhile, in the light emitting diode driving device according to the present invention, as shown in FIG. 15 , in order to improve the power factor (PF) and total harmonic distortion (THD) characteristics, the driving current of the LED light emitting module 930 is By setting the reference current values of the first to fourth LED groups (LED1, LED2, LED3, LED4) to be different from each other, the first to fourth LED groups (LED1, It can be configured to approximate the reference current of LED2, LED3, LED4) to a sine wave. For example, the fourth LED group LED4 may be configured to control the driving current to 100 mA by a constant current control signal of 4V. In addition, the third LED group LED3 may be configured to control the driving current in a constant current of 80mA to 95mA by a control signal of 3V. The second LED group LED2 may be configured to control a driving current of 65mA to 80mA with a constant current by a control signal of 2V. In addition, the first LED group LED1 may be configured to control the driving current in a constant current of 30mA to 65mA by a control signal of 1V.

As described above, in the light emitting diode driving device according to an embodiment of the present invention, the LED driving module 920 is switched on/off by sequential driving by the compensation driving voltage charged in the capacitors connected in parallel to each of the plurality of LED groups. There is an advantage in that the flicker phenomenon caused by the off can be improved.

In addition, according to the present invention, the power factor (PF) and total harmonic distortion (THD) characteristics can be improved by setting the reference current values of the first to fourth LED groups LED1, LED2, LED3, and LED4 to be different from each other.

16 is a circuit diagram illustrating a light emitting diode driving device according to a fourth embodiment of the present invention.

16 shows the light emitting diode driving device according to the fourth embodiment of the present invention except for the valley-fill circuit 940 in all configurations are the same as those of the light emitting diode driving device according to the embodiment of the present invention. A description will be omitted.

The valley-fill circuit 940 is connected between the full-wave rectifier 910 and the LED light emitting module 930 . The valley-fill circuit 940 has a function to improve the power factor PF. The valley-fill circuit 940 includes fourth to sixth diodes D ₈ , D ₉ , and D ₁₀ , fifth and sixth capacitors C _{5 ,} C ₆ , and a resistor R .

As described above, in the light emitting diode driving device according to another embodiment of the present invention, the LED driving module 920 is switched on/off by sequential driving by the compensation driving voltage charged in the capacitors connected in parallel to each of the plurality of LED groups. There is an advantage in that the flicker phenomenon caused by the off can be improved.

In addition, in the present invention, the valley-fill circuit 940 is connected between the full-wave rectifier 910 and the LED light emitting module 930 to improve the power factor (PF) characteristics.

17 is a circuit diagram illustrating an LED driving module according to a fifth embodiment of the present invention, FIG. 18 is a circuit diagram illustrating an LED driving module according to a sixth embodiment of the present invention, and FIG. 19 is a seventh circuit diagram of the present invention It is a circuit illustrating an LED driving module according to an embodiment.

17 to 19 , the LED driving modules 920 , 1020 , and 1120 may be variously changed.

Referring to FIG. 17 , the LED driving module 920 includes a first constant current driving circuit QM ₁ and a first resistor R ₁ connected to a first LED group LED1 , and the first constant current driving circuit A first Zener diode (DZ ₁ ) for stable constant current driving of (QM ₁ ) is included. In addition, the LED driving module 920 includes a second constant current driving circuit (QM ₂ ) and a second resistor (R ₂ ) connected to the second LED group (LED2), and the second constant current driving circuit (QM ₂ ) A second Zener diode (DZ ₂ ) for stable constant current driving is included. In addition, the LED driving module 920 includes a third constant current driving circuit (QM ₃ ) and a third resistor (R ₃ ) connected to the third LED group (LED3), and the third constant current driving circuit (QM ₃ ) A third Zener diode (DZ ₃ ) for stable constant current driving is included. In addition, the LED driving module 920 includes a fourth constant current driving circuit (QM ₄ ) and a fourth resistor (R ₄ ) connected to the fourth LED group (LED4), and the fourth constant current driving circuit (QM ₄ ) A fourth Zener diode (DZ ₄ ) for stable constant current driving is included.

The first to fourth constant current driving circuits QM ₁ , QM ₂ , QM ₃ , QM ₄ are n-type depletion metal-oxide semiconductor field-effect transistors (MOSFETs), junction gate field- Effect Transistor), MOSFET (Metal-Oxide Semiconductor Field-Effect Transistor), and BJT (Bipolar Junction Transistor) can be variously changed.

18 and 19, the LED driving module (1020, 1120) includes a driving control unit (1021, 1121), the first to fourth resistors (R ₁ , R _{2 ,} R _{3 ,} The sizes of R ₄ ) may all be changed the same or differently.

Here, according to the control signals Vc ₁ , Vc ₂ , Vc ₃ , Vc ₄ or Vc ₅ , Vc ₆ , Vc ₇ , Vc _{8 of} the driving controllers 1021 and 1121 , the first to fourth constant current driving circuits QM ₁ , QM ₂ , QM ₃ , QM ₄ ) can be controlled.

_{The present invention is a constant current driving circuit (QM 1} , QM ₂ , QM ₃ , QM of the LED driving module (920, 1020, 1120) by sequential driving by a compensation driving voltage charged in a capacitor connected in parallel to each of a plurality of LED groups ₄ ) has the advantage of improving the flicker phenomenon caused by on/off.

In addition, according to the present invention, the power factor (PF) and total harmonic distortion (THD) characteristics can be improved by setting the reference current values of the first to fourth LED groups LED1, LED2, LED3, and LED4 to be different from each other.

20 is a view showing a lighting device for an AC-driven light emitting device according to an eighth embodiment of the present invention, and FIG. 21 is a view showing a method of driving the lighting device for an AC-driven light emitting device according to an eighth embodiment of the present invention. It is a flowchart.

As shown in FIG. 20, the lighting device of the AC-driven light emitting device of the present invention includes a triac dimmer 1200, a firing current maintaining circuit 1205, a rectifier 1220, a dimming level control unit 1240, and a light emitting device driving module. 1300 and a light emitting device light emitting unit 1400 .

The triac dimmer 1200 receives an AC voltage (V _AC ) from an AC voltage source, and generates an AC voltage whose phase is modulated according to the dimming level selected by the user's manipulation of the input AC voltage (V _{AC ).} The triac dimmer 1200 generates a phase-controlled AC voltage by phase-cutting _{the AC voltage V AC} according to the dimming level selected by the user. Since the triac dimmer is a known technology, a detailed description thereof will be omitted.

The firing current maintaining circuit 1205 is connected between the triac dimmer 1200 and the rectifier 1220, and flows the triac firing current as an AC power input or a rectified voltage output or operates as a dummy load. It may further include a firing current holding circuit 1205. For example, the firing current holding circuit 1205 may be a bleeder circuit including a bleeder capacitor and a bleeder resistor connected in series thereto. Here, the firing current maintaining circuit 1205 according to the present invention is not limited to the bleeder circuit, and one of the voltage stabilization circuits may be adopted.

The rectifier 1220 rectifies the phase-modulated AC voltage to generate a driving voltage, and outputs the generated driving voltage. The rectifier 1220 is not particularly limited, and one of various well-known rectifier circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit may be used. For example, the rectifier 1220 may be a bridge full-wave rectifier circuit composed of four diodes. The driving voltage generated by the rectifier 1220 is output to the dimming level control unit 1240 , the phase modulation reference setting unit 1250 , the light emitting device group driving module 1280 , and the light emitting device light emitting unit 1400 .

The light emitting device light emitting unit 1400 includes a plurality of light emitting device groups. The plurality of light emitting device groups are sequentially emitted and turned off. Although the description is limited to the first to fourth light emitting device groups 1410 to 1440, the light emitting device light emitting unit 1400 is not limited thereto, and the number of light emitting device groups may be variously changed. The first to fourth light emitting device groups 1410 to 1440 may have different forward voltage levels, respectively. For example, when the first to fourth light emitting device groups 1410 to 1440 each include a different number of light emitting devices, they have different forward voltage levels.

The dimming level control unit 1240 has a function of detecting the currently selected dimming level based on the driving voltage provided from the rectifying unit 1220 and outputting the detected dimming level signal to the light emitting device driving module 1300 . More specifically, the dimming level control unit 1240 according to the present invention may detect the dimming level by averaging the driving voltage whose voltage level changes with time. _{Since the triac dimmer 1200 is configured to cut the phase of the AC voltage VAC} according to the dimming level selected by the user, the currently selected dimming level can be detected when the driving voltage is averaged. The detected dimming level signal may be a DC signal having a constant voltage value. For example, when the dimming level is 100%, the corresponding dimming level signal is 2V, when the dimming level is 90%, the corresponding dimming level signal is 1.8V, and when the dimming level is 50%, the corresponding dimming level signal is may be 1V, and so on. The dimming level signal corresponding to the dimming level may be changed in various circuit designs. For example, an RC integrator circuit or the like can be used.

The light emitting device driving module 1300 includes an internal power generating unit 1301 , a dimming level detecting unit 1260 , a driving level detecting unit 1250 , a bleeder current detecting unit 1303 , and a driving current controlling unit 1280 .

The internal power generating unit 1301 supplies driving power that can operate each of the components.

The dimming level detector 1260 has a dimming level reference value. The dimming level reference value may be preset and changed by a user. Specifically, the dimming level reference value may be set in a section in which a defect such as flicker occurs or in a shortest driving section in which all of the first to fourth light emitting device groups 1410 to 1440 are driven by a low dimming level. For example, the dimming level reference value may be set within a period in which all of the first to fourth light emitting device groups 1410 to 1440 are driven.

The driving current control unit 1280 compares the dimming level reference value of the dimming level detection unit 1260 with the dimming level signal Adim, and when the dimming level signal Adim is lower than the dimming level reference value, first to fourth Driving of the light emitting device groups 1410 to 1440 may be blocked.

In addition, the driving current controller 1280 sequentially controls the first to fourth groups of light emitting devices 1410 to 1440 according to the voltage level of the driving voltage input from the rectifier 1220 . That is, the AC-driven light emitting device lighting device has first to seventh sections for sequentially driving the first to fourth light emitting device groups 1410 to 340 . The first section is defined as a section in which the voltage level of the driving voltage input from the rectifying unit 1220 is between the first forward voltage level and the second forward voltage level, and during the first section, only the first current path (P ₁ ) It is connected to the first group of light emitting devices 1410 to emit light. Also, in the second section, the voltage level of the driving voltage input from the rectifier 1220 is defined as a section between the second forward voltage level and the third forward voltage level, and during the second section, the second current path P ₂ ) are connected, and the first and second light emitting device groups 1410 and 1420 emit light. Also, in the third section, the voltage level of the driving voltage input from the rectifier 1220 is defined as a section between the third forward voltage level and the fourth forward voltage level, and during the third section, the third current path P ₃ ) is connected to the first to third light emitting device groups 1410 to 1430 to emit light. In addition, in the fourth section, the voltage level of the driving voltage input from the rectifier 1220 is defined as a fourth forward voltage level section, and during the fourth section, the fourth current path P ₄ is connected to the first to fourth sections. Four light emitting device groups 1410 to 1440 emit light. In addition, the fifth section is defined as a section in which the voltage level of the driving voltage input from the rectifier 1220 is between the fourth forward voltage level and the third forward voltage level, and during the fifth section, the third current path (P _{3 )} ) is connected to the first to third light emitting device groups 1410 to 1430 to emit light. In addition, the sixth section is defined as a section in which the voltage level of the driving voltage input from the rectifier 1220 is between the third forward voltage level and the second forward voltage level, and during the sixth section, the second current path P ₂ ) are connected, and the first and second light emitting device groups 1410 and 1420 emit light. In addition, the seventh section is defined as a section in which the voltage level of the driving voltage input from the rectifier 1220 is between the second forward voltage level and the first forward voltage level, and during the seventh section, the first current path (P _{1 )} ) is connected, so that the first light emitting device group 1410 emits light. The first and seventh sections may be defined as a first-stage driving section, the second and sixth sections may be defined as a second-stage driving section, and the third and fifth sections may be defined as a third-stage driving section It can be defined as a section, and the fourth section can be defined as a fourth stage driving section.

The light emitting device driving module 1300 further includes a driving level detecting unit 1250 for controlling the driving current level of the first to fourth light emitting device groups 1410 to 1440 according to the dimming level. The driving level detection unit 1250 may be set proportionally according to the dimming level. The driving level detection unit 1250 includes a preset driving current resist to correspond to the dimming level.

Referring to FIGS. 20 and 21 , in the method of driving the lighting device of the AC-driven light emitting device of the present invention, an AC voltage whose phase is modulated by the triac dimmer 1220 is generated according to the dimming level selected by the user's operation. .(S100)

The rectifier 1220 rectifies the phase-controlled AC voltage to generate a driving voltage, and outputs the generated driving voltage (S200).

The dimming level control unit 1240 has a function of detecting the currently selected dimming level based on the driving voltage provided from the rectifying unit 1220, and outputting the detected dimming level signal to the light emitting device driving module 1300. ( S300)

The light emitting device driving module 1300 compares the dimming level signal with the dimming level reference value. (S400) The light emitting device driving module 1300 compares the dimming level signal with the dimming level reference value, and the dimming level is preset. When the dimming level is less than the reference value, all driving of the first to fourth light emitting device groups 1410 to 1440 is stopped. When the dimming level signal is equal to or greater than the dimming level reference value, the light emitting device driving module 1300 provides a driving current corresponding to the dimming level to at least one of the first to fourth light emitting device groups 1410 to 1440. (S500) Here, the light emitting device driving module 1300 compares the dimming level signal with the dimming level reference value during the driving period of the first to fourth light emitting device groups 1410 to 1440.

When the dimming level signal is less than the dimming level reference value, the light emitting device driving module 1300 cuts off the driving current supplied to the first to fourth light emitting device groups 1410 to 1440. (S600) Here, the The light emitting device driving module 1300 compares the dimming level signal with the dimming level reference value while the first to fourth light emitting device groups 1410 to 1440 are stopped. Accordingly, the light emitting device driving module 1300 of the present invention compares the dimming level signal with the dimming level reference value during the driving section and the driving stop section of the first to fourth light emitting device groups 1410 to 1440, thereby providing a dimming level According to this change, driving of the first to fourth light emitting device groups 1410 to 1440 may be controlled. The dimming level reference value may be defined as a minimum driving value for driving the first to fourth light emitting device groups 1410 to 1440 . Accordingly, when the dimming level signal is less than the minimum driving value for driving the first to fourth light emitting device groups 1410 to 1440 , the driving current supplied to the first to fourth light emitting device groups 1410 to 1440 is cut off.

According to the present invention, it is possible to prevent non-uniform luminance including flicker by blocking the driving current of the entire first to fourth light emitting device groups 1410 to 1440 at a dimming level less than a preset dimming level reference value. In particular, according to the present invention, in a plurality of sequentially driven light emitting device groups, flicker occurring in a period in which each group is turned off in a maximum driving period (a four-stage driving period and a three-stage driving period based on the maximum four-stage driving period) and non-uniform dimming characteristics can be improved.

In addition, the present invention blocks the driving current of the entire first to fourth light emitting device groups 1410 to 1440 based on a preset dimming level reference value, thereby improving the dimming characteristics that vary according to the characteristics of the triac dimmer 1200 Thus, the compatibility of the dimmer can be improved.

22, the light emitting device driving module 1300 of the present invention limits the supply period of the driving current supplied to the first to fourth light emitting device groups according to the seed light level signal based on the dimming level reference value. Alternatively, the first to fourth light emitting device groups may be controlled according to varying dimming characteristics by controlling the magnitude of the driving current or controlling the supply period of the driving current and the magnitude of the driving current.

23 is a waveform showing a relationship between a driving current and a bleeder current of a light emitting device group according to a change in dimming level according to the present invention, and FIG. 24 shows a pulse width modulation signal according to dimming level control according to a pulse width modulation dimmer. one waveform.

As shown in FIG. 23, in the lighting device of the AC driving light emitting device of the present invention, at the maximum (100%) without the driving voltage dimming control input from the rectifier, the bleeder current is the hold current section in the maximum forward voltage section. have

In addition, in the Mid (50%) in which the driving voltage input from the rectifying unit includes dimming control of 50%, the bleeder current starts the latch current section from the time when the light emitting device driving current is supplied, and holds The current section may extend from the latch section.

In addition, in the 20% section including the dimming control in which the driving voltage input from the rectifier is 20% of the lighting device, the bleeder current starts the latch current section from the time when the light emitting device drive current is supplied, and the hold current section may extend from the latch section.

As the above lighting device, a pulse width modulation (PWM) dimmer as well as a TRIAC dimmer may be used. 23 and 24 , the lighting device of the present invention may control the driving current supplied to the light emitting device group by using a pulse width modulation (PWM) dimmer.

In the lighting device of the AC-driven light emitting device of the present invention, the size of the light emitting device driving current is controlled in proportion to the dimming level set by the user, thereby exhibiting smooth dimming characteristics over the entire section of the dimming level. In addition, the lighting device of the AC-driven light emitting device of the present invention can improve flicker or non-uniform dimming characteristics by blocking the driving current provided to the entire group of light emitting devices at a dimming level lower than a preset dimming level reference value. For example, in the present invention, flicker and non-uniform dimming characteristics can be improved by limiting the entire driving of the plurality of light emitting device groups in a section less than a preset dimming level reference value (a section gradually decreasing in the fourth stage driving section). Here, the dimming level reference value may be set within a range between 90 and 0 based on the first period of the modulated AC voltage.

In addition, the present invention can improve the compatibility of the dimmer by improving the dimming characteristics that vary according to the characteristics of the dimmer.

25 is a diagram illustrating the configuration of an AC-driven light emitting device lighting device capable of controlling color temperature (hereinafter referred to as a 'light emitting device lighting device') according to an embodiment of the present invention.

As shown in FIG. 25, the lighting device of the AC-driven light emitting device capable of controlling the color temperature of the present invention includes a dimmer 2100, a firing current holding circuit 2105, a rectifier 2120, a first dimming level detection unit 2140, It includes a second dimming level detection unit 2141 , a first driving module 2150 , a second driving module 2160 , and first and second light emitting device light emitting units 2170 and 2180 . The lighting device of the light emitting device may use a dimmer 2100 to control the color temperature according to a user's selection. That is, according to the present invention, the color temperature can be changed by individually controlling the driving of the first and second light emitting device light emitting units 2170 and 2180 based on the AC voltage modulated by the dimmer 2100 .

The dimmer 2100 receives an AC voltage (V _AC ) from an AC voltage source, and generates and outputs AC power modulated to a dimming level selected by a user's manipulation of the _{input AC voltage (V AC ).} The dimmer 2100 uses a triac (TRIAC) to control the phase of AC power (Phase cut) a triac dimmer, a pulse width modulation (PWM) dimmer, an analog voltage dimmer for changing the AC voltage (Analog Voltage Dimmer) , and dimmers equivalent thereto. That is, the dimmer 2100 generates/outputs the AC voltage modulated according to the selected dimming level, and the dimming level selected by the dimming level detector 2140 to be described later from the AC voltage modulated by the dimmer 2100. Any dimmer may be used as long as it is capable of being detected. The dimmer 2100 describes the present invention a triac dimmer as an embodiment, but the scope of the present invention is not limited thereto, and as long as it includes the gist of the present invention, among various dimmers as described above It will be apparent that embodiments using one also fall within the scope of the present invention.

The dimmer 2100 receives an AC voltage ( _VAC ) from an AC voltage source, and generates an AC voltage whose phase is modulated according to the dimming level selected by the user's manipulation of the input AC voltage ( _VAC). The dimmer 2100 generates a phase-controlled AC voltage by phase-cutting _{the AC voltage V AC} according to the dimming level selected by the user. Here, since the triac dimmer is a known technology, a detailed description thereof will be omitted.

The firing current maintenance circuit 2105 is connected between the dimmer 2100 and the rectifier 2120, and provides a triac firing current as an AC power input or a rectified voltage output or operates as a dummy load. It may further include a firing current holding circuit (2105). For example, the firing current maintaining circuit 2105 may be a bleeder circuit including a bleeder capacitor and a bleeder resistor connected in series thereto. Here, the firing current maintaining circuit 2105 according to the present invention is not limited to the bleeder circuit, and one of the voltage stabilization circuits may be adopted.

The rectifier 2120 rectifies the phase-modulated AC voltage to generate a driving voltage, and outputs the generated driving voltage. The rectifier 2120 is not particularly limited, and one of various well-known rectifier circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit may be used. For example, the rectifier 2120 may be a bridge full-wave rectifier circuit composed of four diodes.

Each of the first and second dimming level detection units 2140 and 2141 detects a currently selected dimming level based on the driving voltage provided from the rectifying unit 2120, and the first and second dimming levels according to the detected dimming level, respectively. It has a function of outputting the level signals Adim1 and Adim2 to the first and second driving modules 2150 and 2160, respectively. More specifically, the first and second dimming level detectors 2140 and 2141 according to the present invention may detect the dimming level by averaging the driving voltages whose voltage level changes with time. _{Since the dimmer 2100 is configured to cut the phase of the AC voltage V AC} according to the dimming level selected by the user, when averaging the driving voltages, the currently selected dimming level can be detected. The first and second dimming level signals Adim1 and Adim2 may be DC signals having a constant voltage value corresponding to the dimming level. The first and second dimming level signals Adim1 and Adim2 have values inversely proportional to each other. For example, when the dimming level is 80%, the first dimming level signal Adim1 is 1.8V corresponding to the 80% dimming level, and the second dimming level signal Adim2 is the first dimming level signal Adim1 ) and inversely proportional to 0.2V. When the dimming level is 20%, the first dimming level signal Adim1 is 0.2V corresponding to a dimming level of 20%, and the second dimming level signal Adim2 is the first dimming level signal Adim1 and inversely proportional to 1.8V. Here, when the dimming level is 50%, the first dimming level signal Adim1 is 1.0V corresponding to a dimming level of 50%, and the second dimming level signal Adim2 is the first dimming level signal ( Adim1) may be inversely proportional to 1.0V.

The first driving module 2150 controls the first light emitting device light emitting unit 2170 in response to the first dimming level signal Adim1. For example, the first driving module 2150 sequentially drives the first light emitting device groups LED1-1 to LED1-4 for a plurality of sections (first to seventh sections). The first section is defined as a section in which the voltage level of the driving voltage input from the rectifier 2120 is between the first forward voltage level and the second forward voltage level, and during the first section, the first current path P _1-1 ) is connected, and the 1-1 light emitting device group LED1-1 emits light. Also, in the second section, the voltage level of the driving voltage input from the rectifier 2120 is defined as a section between the second forward voltage level and the third forward voltage level, and during the second section, the second current path P _{1 -2} ) is connected to the 1-1 and 1-2 light emitting device groups LED1-1 and LED1-2 to emit light. In addition, the third section is defined as a section in which the voltage level of the driving voltage input from the rectifier 2120 is between the third forward voltage level and the fourth forward voltage level, and during the third section, the third current path (P _{1 ) -3} ) is connected, and the 1-1 to 1-3 light emitting device groups LED1-1 to LED1-3 emit light. In addition, in the fourth section, the voltage level of the driving voltage input from the rectifier 2120 is defined as a fourth forward voltage level section, and during the fourth section, the fourth current path P _1-4 is connected to the first The light emitting device groups LED1-1 to LED1-4 emit light. In addition, the fifth section is defined as a section in which the voltage level of the driving voltage input from the rectifier 2120 is between the fourth forward voltage level and the third forward voltage level, and during the fifth section, the third current path (P _{1 ) -3} ) is connected, and the 1-1 to 1-3 light emitting device groups LED1-1 to LED1-3 emit light. Also, in the sixth section, the voltage level of the driving voltage input from the rectifier 2120 is defined as a section between the third forward voltage level and the second forward voltage level, and during the sixth section, the second current path P _{1 -2} ) is connected to the 1-1 and 1-2 light emitting device groups LED1-1 and LED1-2 to emit light. In addition, the seventh section is defined as a section in which the voltage level of the driving voltage input from the rectifier 2120 is between the second forward voltage level and the first forward voltage level, and during the seventh section, the first current path P _{1 -1} ) is connected, so that the 1-1 light emitting device group LED1-1 emits light. The first and seventh sections may be defined as a first-stage driving section, the second and sixth sections may be defined as a second-stage driving section, and the third and fifth sections may be defined as a third-stage driving section It can be defined as a section, and the fourth section can be defined as a fourth stage driving section. Each of the first light emitting device groups LED1-1 to LED1-4 may have different forward voltage levels. For example, when the first light emitting device groups LED1-1 to LED 1-4 each include a different number of light emitting devices, they have different forward voltage levels. The first light emitting device light emitting unit 2170 may sequentially emit light corresponding to the AC voltage whose phase is modulated according to the first dimming level signal Adim1 of the first driving module 2150, and emit cool white light. can be implemented

The second driving module 2160 controls the second light emitting device light emitting unit 2180 in response to the second dimming level signal Adim2. For example, the second driving module 2160 may sequentially drive the third light emitting device groups LED2-1 to LED2-4 for a plurality of sections (first to seventh sections). A detailed description of the sequential driving of the second light emitting device light emitting unit 2180 will be omitted with reference to the description of the first driving module 2150 and the first light emitting device light emitting unit 2170 . The present invention is not limited thereto, and the second driving module 2160 may further include a pulse width modulator (not shown). The second light emitting device light emitting unit 2180 may be driven to correspond to a pulse width modulation signal from the second driving module 2160 . For example, the second light emitting device light emitting unit 2180 may be composed of red LED light emitting devices, and may implement warm white.

The light emitting device lighting device according to an embodiment of the present invention realizes cool white by controlling the driving of the first and second light emitting device light emitting units 2170 and 2180 according to the dimming level selected by the dimmer 2100 control. The color temperature may be controlled by controlling the driving ratio of the first light emitting device light emitting unit 2170 and the second light emitting device light emitting unit 2180 for realizing warm white.

26 is a diagram illustrating the configuration of an AC-driven light emitting device lighting device capable of controlling color temperature according to another embodiment of the present invention.

As shown in FIG. 26 , the AC-driven light emitting device lighting device capable of controlling color temperature of the present invention includes a first rectifying unit 2220 , a first driving module 2250 , and a first light emitting device light emitting unit 2270 .

In addition, the lighting device of the light emitting device includes a dimmer 2200 , a second rectifying unit 2221 , a dimming level detecting unit 2240 , a second driving module 2260 , and a second light emitting device light emitting unit 2280 .

The light emitting device lighting device includes the first driving module 2250 for driving the first light emitting device light emitting unit 2270 and the second light emitting device light emitting unit 2280 according to the dimming level selected according to the user's selection. By individually controlling the driving second driving module 2260, the color temperature may be controlled. That is, the AC voltage modulated by the dimmer 2200 (eg, a phase-modulated AC voltage) may be supplied to the second light emitting device light emitting unit 2280 for adjusting the color temperature to change the color temperature. Here, the second light emitting device light emitting unit 2280 may be a red light emitting device.

The first rectifying unit 2220 receives an AC voltage V _AC from an AC voltage source, rectifies the AC voltage to generate a driving voltage, and outputs the generated driving voltage. The first rectifying unit 2220 is not particularly limited, and one of various well-known rectifying circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit may be used. For example, the first rectifier 2220 may be a bridge full-wave rectifier circuit including four diodes.

The first driving module 2250 controls the first light emitting device light emitting unit 2270 in response to the driving voltage input from the first rectifying unit 2220 . For example, the first driving module 2250 sequentially drives the first light emitting device groups LED1-1 to LED1-4 for a plurality of sections (first to seventh sections). A detailed description of the sequential driving of the first light emitting device light emitting unit 2270 will be omitted with reference to the light emitting device lighting device according to an embodiment of the present invention.

The dimmer 2200 receives an AC voltage ( _VAC ) from an AC voltage source, and generates an AC voltage whose phase is modulated according to a dimming level selected by a user's manipulation of the input AC voltage ( _VAC). Here, the dimming level corresponds to the color temperature. The dimmer 2200 is a triac dimmer that controls the phase of AC power using a TRIAC (Phase cut), a pulse width modulation (PWM) dimmer, and an analog voltage dimmer that changes the AC voltage (Analog Voltage Dimmer) , and dimmers equivalent thereto. That is, the dimmer 2200 generates/outputs the AC voltage modulated according to the selected dimming level, and the dimming level selected by the dimming level detector 2240 to be described later from the AC voltage modulated by the dimmer 2200. Any dimmer may be used as long as it is capable of being detected. The dimmer 2200 describes the present invention a triac dimmer as an embodiment, but the scope of the present invention is not limited thereto, and as long as it includes the gist of the present invention, among various dimmers as described above, It will be apparent that embodiments using one also fall within the scope of the present invention.

The second rectifying unit 2221 rectifies the phase-modulated AC voltage to generate a driving voltage, and outputs the generated driving voltage. The second rectifying unit 2221 is not particularly limited, and one of various well-known rectifying circuits such as a full-wave rectifier circuit and a half-wave rectifier circuit may be used. For example, the second rectifier 2221 may be a bridge full-wave rectifier circuit composed of four diodes.

The dimming level detection unit 2240 detects the currently selected dimming level based on the driving voltage provided from the second rectifying unit 2221, and transmits the dimming level signal Adim according to the detected dimming level to the second driving module ( 2260) has a function to output. More specifically, the dimming level detection unit 2240 according to the present invention may detect the dimming level by averaging the driving voltage whose voltage level is changed over time. _{Since the dimmer 2200 is configured to cut the phase of the AC voltage V AC} according to the dimming level selected by the user, when averaging the driving voltages, the currently selected dimming level can be detected. The dimming level signal Adim may be a DC signal having a constant voltage value corresponding to the dimming level.

The second driving module 2260 controls the second light emitting device light emitting unit 2280 in response to the dimming level signal Adim. For example, the second driving module 2260 sequentially drives the second light emitting device groups LED2-1 to LED2-4 for a plurality of sections (first to seventh sections). A detailed description of the sequential driving of the second light emitting device light emitting unit 2280 will be omitted with reference to the light emitting device lighting device according to an embodiment of the present invention. Without being limited thereto, as another embodiment, the second driving module includes a pulse width modulator, and the second light emitting device light emitting units are connected in series to each other so that they can all be driven simultaneously, and the pulse width modulated signal from the pulse width modulator is not limited thereto. can be driven in response to For example, the second light emitting device light emitting unit may be composed of red LED light emitting devices, and may implement warm white.

The light emitting device lighting device according to another embodiment of the present invention controls the driving of the second light emitting device light emitting unit 2280 according to the dimming level selected by the control of the dimmer 2200, thereby realizing the first light emission to realize cool white. The color temperature may be controlled by driving the device light emitting unit 2270 and simultaneously controlling the driving of the second light emitting device 2280 realizing warm white.

27 is a waveform diagram illustrating a relationship between a driving voltage and a driving current of the light emitting device lighting device of FIG. 26 .

As shown in FIG. 27 , in the light emitting device lighting device according to another embodiment of the present invention, _{the first light emitting device light emitting unit sequentially receives an AC voltage (VAC} ) from an AC voltage source and rectifies it in response to a driving voltage generated. is driven For example, the first light emitting unit is sequentially driven for a plurality of sections (first to seventh sections) within one cycle.

Referring to the first LED current, the light emitting unit of the first light emitting device is constantly and sequentially driven within one cycle.

Meanwhile, the AC voltage Vp whose phase is modulated through the dimmer according to the user's selection may be divided into a plurality of sections (first to third sections) according to the magnitude of the phase modulated. Here, the plurality of sections is not limited to the first to third sections, and may be divided into four or more sections. For example, a plurality of sub-sections may be further included in the first to third sections. In another embodiment of the present invention, the phase is divided into a Low section, a Mid section, and a High section according to the modulated magnitude.

The light emitting part of the second light emitting device is sequentially driven in response to a driving voltage obtained by rectifying the phase-modulated AC voltage. Here, the on section of the driving voltage and the size of the current level of the light emitting unit of the second light emitting device vary according to the magnitude of the phase modulation.

Referring to the second LED Current, it can be seen that the On section and the current level size of the second light emitting unit light emitting unit are different according to the size of the phase modulated within one cycle.

28 is a diagram illustrating the configuration of a light emitting device lighting device capable of controlling color temperature according to another embodiment of the present invention.

As shown in FIG. 28 , a light emitting device lighting apparatus according to another embodiment of the present invention includes first and second dimmers 2300 and 2301 , first and second rectifying units 2320 and 2321 , and first and second dimmers 2300 and 2301 . 2 dimming level detection units 2340 and 2341 , first and second driving modules 2350 and 2360 , and first and second light emitting device light emitting units 2370 and 2380 . The lighting device of the light emitting device may control luminance and color temperature according to a user's selection by using the first and second dimmers 2300 . That is, according to the present invention, the luminance can be changed by controlling the driving of the first light emitting device light emitting unit 2370 based on the AC voltage modulated by the first dimmer 2300 . Here, the first light emitting device light emitting unit 2370 may include a blue LED light emitting device and a yellow phosphor to realize white.

The color temperature may be changed by controlling the driving of the second light emitting unit 2380 based on the AC voltage modulated by the second dimmer 2301 . Here, the second light emitting device light emitting unit 2380 may be composed of a red LED light emitting device.

The first and second driving modules 2350 and 2360 selectively include functions of enabling and disabling the dimming control function.

The first and second dimmers 2300 and 2301, first and second rectifying units 2320 and 2321, first and second dimming level detectors 2340 and 2341, first and second driving modules 2350 and 2360 ), and the first and second light emitting device light emitting units 2370 and 2380 will not be described in detail with reference to the light emitting device lighting device according to an embodiment of the present invention.

In the light emitting device lighting device according to another embodiment of the present invention, by controlling the driving of the first light emitting device light emitting unit 2370 according to the dimming level selected by the control of the first dimmer 2300, the overall luminance is stably The color temperature may be controlled by controlling the driving of the second light emitting device light emitting unit 2380 according to the dimming level selected by the control of the second dimmer 2301 .

Although various embodiments have been described above, the present invention is not limited to specific embodiments. In addition, components described in a specific embodiment may be applied identically or similarly to other embodiments without departing from the spirit of the present invention.

1000: light emitting device lighting device
100: dimmer 105: firing current circuit
110: EMI filter 120: rectifying unit
130: surge protection unit 140: dimming level detection unit
200: light emitting device driving module 300: light emitting device light emitting unit
210: light emitting device driving control unit 220: light emitting device group driving unit
UVLO: low voltage cut-off circuit 540: temperature control unit

Claims (67)

a dimmer that receives AC power and controls the input AC power according to a selected dimming level to output the controlled AC power;
a rectifying unit for receiving the controlled AC power output from the dimmer and full-wave rectification to output a driving voltage;
a dimming level detection unit receiving the driving voltage, detecting the selected dimming level, and outputting the detected dimming level signal;
Light emitting including a first light emitting element group to an nth light emitting element group (n is a positive integer of 2 or more), each of which is sequentially driven under the control of the light emitting element driving module by receiving the driving voltage device light emitting unit; and
The voltage level of the driving voltage is determined, and sequential driving of the first to nth light emitting device groups is controlled according to the determined voltage level of the driving voltage, and the driving current of the light emitting device is controlled based on the dimming level signal. Includes a light emitting device driving module for constant current control,
The light emitting device driving module simultaneously controls the light emission time and the size of the driving current of the light emitting device light emitting unit according to the dimming level signal,
The light emitting device driving module may include a first driving current reference value to an nth driving current reference value that is a driving current reference value of the first light emitting device group to the nth light emitting device group, the first light emitting device group to the nth light emitting device group Set to have different values for sequential driving, and set the first driving current reference value to the nth driving current reference value based on the dimming level signal.
The method according to claim 1,
The light emitting device driving module controls the maximum value of the driving current of the light emitting device based on a reference value of the driving current determined in proportion to the level of the dimming level signal.
delete The method according to claim 1,
The light emitting device driving module is a light emitting device lighting device, characterized in that the control so as to sequentially increase the nth light emitting device driving current for the n-th driving section from the first light emitting device driving current for the first stage driving section.
The method according to claim 1,
The dimmer is a light emitting device lighting device, characterized in that the triac (TRIAC) dimmer.
6. The method of claim 5,
The light emitting device lighting device capable of dimming,
A firing current maintenance circuit connected between the triac dimmer and the rectifier to flow a TRIAC trigger current to the AC power input or a rectified voltage output or operate as a dummy load Light emitting device lighting device, characterized in that it further comprises.
7. The method of claim 6,
The light emitting device lighting device, characterized in that the firing current maintaining circuit is a bleeder circuit.
6. The method of claim 5,
The light emitting device lighting device capable of dimming further comprises an EMI filter connected between the dimmer and the rectifier to attenuate high-frequency noise of a phase-controlled AC power source.
The method according to claim 1,
The light emitting device lighting device capable of dimming further comprises a surge protection unit connected to an output terminal of the rectifying unit to protect a circuit.
The method according to claim 1,
The dimming level detector detects the dimming level by averaging the driving voltage.
11. The method of claim 10,
The light emitting device lighting device, characterized in that the dimming level detection unit comprises an RC integration circuit.
11. The method of claim 10,
The dimming level detector further comprises a voltage limiting circuit for limiting the driving voltage to a maximum voltage or less.
The method according to claim 1,
The light emitting device lighting device, characterized in that the dimming level detection unit is built into the light emitting device driving module as an effective voltage converter (rms converter) to convert the driving voltage into a DC signal.
The method according to claim 1,
The light emitting device driving module is a light emitting device lighting device, characterized in that it is possible to selectively enable (enable) and disable (disable) the dimming control function.
15. The method of claim 14,
The light emitting device driving module further comprises an automatic detection circuit for automatically selecting whether to allow or disable the dimming control function by detecting whether the dimming circuit is connected.
The method according to claim 1,
The light emitting device lighting device capable of dimming,
The light emitting device lighting device according to claim 1, further comprising a driving voltage stabilizing unit for stepping down and stabilizing the driving voltage supplied to the light emitting device driving module.
8. The method of claim 7,
The bleeder circuit is an active bleeder,
The light emitting device driving module includes a bleeder terminal; and
and a bleeder resistor connected to the bleeder terminal.
The method according to claim 1,
The light emitting device driving module includes a low voltage blocking circuit.
The method according to claim 1,
The light emitting device driving module includes a temperature control unit,
The temperature controller detects the temperature of the light emitting device driving module and compares the detected temperature with at least two or more reference temperatures to stop or allow the driving of the light emitting device driving module, and stop or allow the driving of the light emitting device driving module The reference temperature is different from each other in the light emitting device lighting device.
20. The method of claim 19,
The at least two or more reference temperatures include a first reference temperature and a second reference temperature,
In the temperature control unit, the first reference temperature has a lower temperature than the second reference temperature,
When the detected temperature is less than the first reference temperature, allowing the light emitting device driving module,
A light emitting device lighting device for stopping the light emitting device driving module when the detected temperature is equal to or greater than the second reference temperature.
21. The method of claim 20,
After the light emitting device driving module is stopped by the detected temperature, the temperature of the light emitting device driving module maintains a stopped state up to the first reference temperature.
The method according to claim 1,
The light emitting device driving module includes: a minimum voltage level correcting unit for compensating to increase the level of the driving voltage in the minimum section of the rated voltage; and
and a maximum voltage level correcting unit for compensating for a decrease in the level of the driving voltage in the maximum section of the rated voltage.
The method according to claim 1,
The light emitting device driving module includes a light emitting device lighting device having a variable resistor connected to an output terminal of a switch unit for varying a driving current level of a light emitting device of the first to nth light emitting device groups.
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