KR20160142153A - Dampper Circuit used in the Dimmer Circuit of Electric Ballast for LED Lamp with Dimming Control Function - Google Patents

Abstract

The present invention relates to a dimming circuit of an electronic ballast stabilizer for an LED lamp with a dimming control function and, more specifically, to a dimming circuit device of an electronic ballast stabilizer for an LED lamp with a dimming control function which provides a damming circuit configured to improve suitability, compatibility and stability between a triac dimmer and an LED lamp for dimming control so as to minimize flicker phenomena and power loss and realize a good dimming feature.

Description

[0001] The present invention relates to a damper circuit used in a dimming circuit device of an electronic ballast for an LED bulb having a dimming control function,

The present invention relates to a dimming circuit for an electronic ballast for an LED having a dimming control function, and more particularly to a dimming circuit for dimming control, And a damping circuit capable of exhibiting good dimming characteristics while minimizing power loss. The present invention also relates to a dimming circuit device of an electronic ballast for an LED bulb having a dimming control function.

There are a magnetic ballast and an electronic ballast as a method for lighting an LED bulb. In the case of an electronic ballast, an LED can be stably turned on by converting an output current into a high frequency (25K to 50Khz) By lighting with high-frequency power source, luminous efficiency is improved by more than 15%, high-frequency lighting (blinking 5 to 100 thousand times per second) enables to supply good quality light which can not be detected by eyes, Since the semiconductor device is used, the loss due to self heat generation in the choke coil can be reduced by about 25%, so that the overall power saving effect is more than 35% compared to the magnetic type ballast. In the case of the magnetic ballast, the electromagnetic force generated in the choke coil and the iron core coil Vibration noise due to vibration of the motor can be removed, weight is reduced, heat generation is low, It is suitable for use in areas with poor power and bad power conditions in summer. And has many other advantages such as low temperature lighting and no distinction between used lamps.

Currently, a triac dimmer using two lines is widely used for dimming control of a lighting device. The triac dimmer shows a fairly good compatibility when controlling the brightness of a conventional lighting such as an incandescent lamp or a halogen lamp.

1A, when a pulse voltage / current is applied to the gate of the triac, the triac turns on and continues to turn on until the input voltage becomes zero ON) state. In order to turn off this triac, the current flowing through the triac should be less than the hold current of the triac. Generally, such a condition occurs at a point where the AC input voltage becomes zero, so that the brightness of the lighting apparatus can be controlled by controlling the position where the AC input voltage is turned on, that is, the phase as shown in FIG.

On the other hand, the holding current of the triac is generally about 10 to 50 mA, which is not a problem in the conventional lighting as shown in FIG. 2A. However, in the case of the LED lighting device, the AC input voltage In which case the triac turns off (TURN OFF) and the triac trigger circuit is re-actuated (re-actuated) so that the triac is regenerated again as shown in FIG. 2B A muting phenomenon (muti-firing or mis-firing) occurs, which causes a flickering phenomenon in the LED lighting device. In order to improve the compatibility with the triac dimmer in LED lighting equipment having such characteristics, a circuit is required to keep the AC input current flowing above the holding current constantly in the triac so that the triac does not turn off. This is called a bleeder circuit.

 In general, conventional incandescent lamps or halogen lamps are compatible with triac dimmers because they are constructed to emit light by heating resistors. On the other hand, LED lighting devices with diode characteristics must have a constant current circuit using semiconductor devices Therefore, an inductor or capacitor other than a resistor is additionally required, thereby constituting an LC resonance circuit.

Therefore, resonance due to the LC component may occur when the triac dimmer is turned on to control the dimming of the LED bulb (dimming control) in the case of an LED lighting apparatus, and as shown in FIGS. 3A and 3B Likewise, when AC input current falls below zero due to LC resonance (ringing current occurs), flickering phenomenon of LED lighting equipment occurs as the triac turns off (TURN OFF: Misfire) This problem can not be solved by the addition of the bleeder circuit described above (excessive current spikes may be induced to quickly charge capacitors in the input line at the time the triac dimmer is firing) In order to solve such a problem, a damper circuit is separately required as a circuit capable of suppressing a ring current due to LC resonance.

A basic driver circuit of an LED lighting device including an LED module 100, an LED control circuit 200 and an AC-DC rectification circuit 300 as shown in FIG. 4A and an EMI filter 400 as an additional configuration The LC resonance can be suppressed by adding a damping resistor as shown in FIG. 4B to the structure of FIG. 4B. The method using only the resistor is referred to as a passive damper 500.

However, when only the resistor is used as described above, not only efficiency is reduced but also there is a problem that an LED driver circuit which requires high power due to energy loss of the resistor can not be constructed. Therefore, by using a semiconductor device to reduce the energy loss of the resistor, a method of constructing a damper circuit for increasing the efficiency by allowing a current to flow through the resistor for the initial time period in which LC resonance occurs and a current to flow through the semiconductor device in the remaining period And is referred to as an active damper.

As an example of such an active damper circuit, there is known a technique in which a damper circuit 500 having the configuration as shown in Fig. 5A is disposed between the LED control circuit 200 and the AC-DC rectification circuit 300, The input voltage and current waveform of the damper circuit 500 appear as shown in FIG. 5B. In other words, when the triac dimmer is ON at the beginning of M2 as shown in Figure 5b, the initial current will flow through R _AD LC inhibit resonance and, being a semiconductor Q _AD is ON after this M2 hours later the resistance R _AD The current flowing through the resistor is cut off, and the efficiency is increased by reducing the power consumption by the resistor. However, instantaneous voltage and current fluctuations occur at the point where the semiconductor _QAD is turned ON, and LC resonance is caused thereby. As a result, the input current instantaneously drops below zero as in the M23-transient period of the last waveform of FIG. 5B There is a problem that the triac dimmer is turned off.

An example of an active damper for LED driving using an active damper according to the related art having such a structure is illustrated in FIGS. 6A and 6B. An example of a circuit using SCR as a semiconductor element is shown in FIG. 6A, An example of a circuit using an FET as an element is shown in Fig. 6B. In the case of these circuits, the triac dimmer OFF phenomenon by LC resonance occurs in the same manner as the last waveform shown in Fig. 5B.

As described above, in order to improve the compatibility of the LED lighting apparatus with the conventional triad dimmer, the above-described bleeder circuit and damper circuit are required. The problem to be solved by the present invention is to provide a dimming control function The present invention provides a damper circuit for use in a dimming circuit of an electronic ballast for an LED light bulb, which provides a damper circuit of a more efficient structure so as to further reduce power consumption as a simple structure while solving the problems described above will be.

More specifically, the power loss due to the resistance, which is a basic element constituting the damper circuit, is minimized to suppress the decrease in efficiency due to the resistance, and furthermore, the instantaneous change in current is suppressed and the phenomenon that the triad damper is turned off by the LC oscillation phenomenon Thereby providing a damper circuit which can be basically shut off.

In order to achieve the above object, the present invention provides a dimming circuit device of an electronic ballast for an LED bulb having a dimming control function, the dimming circuit comprising: an AC-DC converter of a dimming circuit device including an LED module, an LED control circuit, and an AC- A damper circuit provided between a rectifying circuit and an LED control circuit,

A damping transistor is connected in parallel with the damping resistor while the capacitor connected to the charging resistor is charged with current through the damping resistor and the capacitor is charged above the set voltage to reach the base- A part of the damping current flowing through the damping resistor is branched into the damping transistor connected in parallel by being turned on and the current flowing from the collector of the damping transistor to the emitter is proportional to the voltage across the damping resistor connected in parallel thereto, Wherein the damping transistor is formed to operate in an amplification region in which a collector current corresponding to a product of an amplification factor and a base current flows, rather than a saturation region which is completely conductive, in a dimming control circuit of an electronic ballast for an LED bulb having a dimming control function It will provide a damper circuit for use in devices.

Here, the charging resistor has a larger value than the damping resistor to reduce energy loss, and when the base-emitter voltage of the damping transistor is turned on at a voltage lower than the saturation region, an LC resonance phenomenon A part of the current passing through the damping resistor is set to be energized in a non-saturation state so as to minimize the occurrence.

The voltage charged in the capacitor so that the damping transistor is turned on after a delay time at which the set time elapses after the AC input power is turned on and the triac dimmer in the LED control circuit is turned on, And the time constant of the capacitor.

According to the present invention, in an LED lighting device driving circuit provided with a Bleeder circuit and a Damper circuit for enhancing compatibility with an LED lighting device, the problems of a damper circuit according to the related art It is possible to further reduce power consumption as a simple configuration.

In other words, the power loss due to the resistance, which is a basic element constituting the damper circuit, is minimized to suppress the reduction in efficiency due to the resistance. Further, unlike the configuration of the active damper using the semiconductor device according to the prior art, (I _c ) corresponding to the multiplication of the amplification factor (h _fe ) and the base current (i _b ) rather than the saturation region which is the saturation region in which the base current Thereby preventing the phenomenon that the triac dimmer is erroneously turned off momentarily, thereby reducing the phenomenon of flashing of the LED lighting apparatus.

FIG. 1A is a general circuit configuration diagram of a triac dimmer, and FIG. 1B shows an AC input voltage phase control waveform applied to the circuit of FIG. 1A.
FIG. 2A is a voltage waveform diagram showing a state in which the triac is turned on in the case of conventional illumination, FIG. 2B is a voltage waveform diagram showing a state in which the triac is turned on in the LED lighting apparatus, Is a voltage waveform diagram in a state where a phenomenon occurs.
FIGS. 3A and 3B are diagrams showing currents showing a state in which the triac turns off (TURN OFF: Misfire) when the AC input current falls below zero due to LC resonance in the absence of a damper circuit in the LED lighting apparatus Fig.
4A is a block diagram of a basic driving circuit of an LED lighting apparatus, and FIG. 4B is a configuration diagram of a passive damper in which a damping resistor is added to the driving circuit shown in FIG. 4A.
FIG. 5A is a configuration diagram showing an example of an active damper used in an LED lighting apparatus, and FIG. 5B is an input voltage and current waveform diagram of such an active damper circuit.
6A and 6B are circuit diagrams showing an example of an active damper for LED driving using an active damper according to the related art.
FIG. 7A is a configuration diagram of an active damper circuit according to the present invention, and FIG. 7B is a circuit diagram showing a preferred embodiment of an LED driving circuit using the same.
8 is a voltage and current waveform diagram of a damper circuit according to the present invention.
9A and 9B are voltage and current waveforms at both ends of the damping resistor in the case of a passive damper using only a resistance of 10 OMEGA.
10A and 10B are voltage and current waveforms at both ends of a damping resistor in the case of an active damper constituted by combining a transistor and a resistor 330 Ω according to a preferred embodiment of the present invention.
11A to 11C are input voltage and input current waveforms of a 28 W-level drive circuit for a triac dimmer having an active damper constructed by combining a transistor and a resistor 330 Ω according to a preferred embodiment of the present invention.

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

FIG. 7A is a configuration diagram of an active damper circuit according to the present invention, FIG. 7B is a circuit diagram showing a preferred embodiment of an LED driving circuit using the same, and FIG. 8 is a circuit diagram of a damper circuit Voltage and current waveforms.

As shown in these figures, according to a preferred embodiment of the present invention, a dimming circuit device of an electronic ballast for an LED bulb having a dimming control function, comprising: an LED module 100; an LED control circuit 200; In the damper circuit 500 inserted between the AC-DC rectifier circuit 300 of the dimming circuit device including the DC rectifier circuit 300 and the LED control circuit 200,

A current is passed through the damping resistor R1 while the capacitor C1 connected to the charging resistor R2 is charged and the capacitor C1 is charged above the set voltage so that the damping transistor Q1 is charged with the base- The damping transistor Q1 connected in parallel with the damping resistor R1 is turned on as a base current flows to the damping transistor Q1 and a part of the damping current that has flowed through the damping resistor R1 flows through the damping transistor Q1 And the current flowing from the collector of the damping transistor Q1 to the emitter is proportional to the voltage across the damping resistor R1 connected in parallel thereto and the damping transistor Q1 is fully conducting particular that the formation is not a saturation zone to operate in the amplification region to flow the amplification factor (h _fe) and the base current collector corresponding to the product of (i _b) a current (i _c) The damper circuit is provided for use in light control circuit unit of the LED jeonguyong electronic ballast having a dimming control to a.

The charging resistor R2 has a larger value (for example, R2: 10 k? / R1: 100? 500?) Than the damping resistor R1 so as to reduce the energy loss, When the emitter voltage V _BE is turned on at a voltage (for example, 0.4 V) lower than the saturated region, a part of the current passing through the damping resistor R 1 is minimized to minimize the occurrence of LC resonance due to an additional instantaneous current change And is set to energize in a non-saturated state.

The AC input power is turned on so that the damping transistor Q1 is turned on after a delay time when the set time elapses after the triac dimmer in the LED control circuit 200 is turned on The voltage V _c1 charged in the capacitor C1 is set to rise exponentially in accordance with the charging resistance R2 and the time constant of the capacitor C1 as shown in the following equation.

Vc = V (1 - e - ^{? / RC} )

According to the preferred embodiment of the present invention, the current i _R1 flows through the damping resistor R1 during the charging time of the capacitor C1 to prevent LC resonance, and the charging voltage of the capacitor C1 (Or 0.45 V), the damping transistor Q1 is turned on to flow the current that flows only in the damping resistor R1. Current flowing through the damping transistor (Q1) to flow the product _{(i c = h fe × i} b) the collector current (i _c) that corresponds to the amplification factor (h _fe) and base current (i _b). The current flowing in the damping transistor Q1 is proportional to the voltage across the damping resistor R1 connected in parallel, and operates in an amplification region that is not a fully conducting saturation region. When a semiconductor device used in a conventional active damper is turned on, the semiconductor device is operated in a saturation region, and a ringing phenomenon of LC resonance due to an additional instantaneous current change is exhibited. However, The damping transistor Q1, which is a semiconductor element used in the circuit, operates in the amplification region, not in the saturation region, so that current flows through the damping resistor R1 during the time that the capacitor C1 is charged to prevent LC resonance, When the charging voltage of the damping resistor R1 becomes equal to or higher than 0.4 V, the damping transistor Q1 is turned on to flow the current that flows only to the damping resistor R1. Current flowing through the damping transistor (Q1) to flow the amplification factor (h _fe) and base current (i _b) the collector current (i _c) that corresponds to the product of. (i _c = h _fe x i _b ) The current flowing in the damping transistor Q 1 is proportional to the voltage across the damping resistor R 1 connected in parallel, and operates in the amplification region rather than in the fully conducting saturation region.

This operation state will be described in more detail as follows.

1. When the triac dimmer is turned on and the current flows to the LED control circuit (converter), the main current flows through the damping resistor R1 before the damping transistor Q1 turns on (TURN ON) .

2. At this time, the capacitor C1 is charged while the current i _c1 that charges the capacitor C1 flows through the RC circuit charging resistor R2 connected in parallel with the damping resistor R1.

3. When the charging voltage of the capacitor C1 becomes the base-emitter voltage V _BE (approximately 0.4V threshold voltage) at which the damping transistor Q1 can be turned on, Is turned on.

4. When the damping transistor Q1 is turned on, the entire current i _tot flows through the damping resistor R1 and the damping transistor Q1. Most of the current flows through the damping transistor Q1 and the voltage across the damping resistor R1 (which is equal to the collector-emitter voltage V _CE of the transistor Q1) is reduced. (By V = iR)

5. As the voltage across the damping resistor R1 decreases, the voltage across the capacitor C1 decreases and the current i _Q1 flowing through the collector-emitter of the damping transistor _Q1 decreases.

6. The main current thus flows through the damping resistor R1 and the damping transistor Q1 according to the value of the amplification factor h _fe of the damping resistor R1, the charging resistor R2, the capacitor C1 and the damping transistor Q1. The current distribution of the current flowing in the current source is divided.

7. When the base voltage V _C1 of the damping transistor Q1 becomes 0.4 V or more, the damping transistor Q1 is turned on and the current flowing through the charging resistor R2 to the base of the damping transistor Q1 The collector current of the damping transistor Q1 is caused to flow in accordance with the formula i _c = h _fe x i _b (h _fe : amplification factor of the transistor) by the i _b value. As the collector current increases, the current flowing through the damping resistor R1 decreases (because the main current of the circuit is determined by the LED illuminator), the voltage V _R1 across the damping resistor _R1 is given by the equation V _R1 = i Reduced according to _R1 × R1.

8. Decrease the voltage across the damping resistor R1 → decrease the voltage across the capacitor C1 and decrease the current flowing to the base of the damping transistor Q1 through the charging resistor R2 → reduce the collector current i of the damping transistor Q1 _{c = h fe × i b)} → current increase flowing through the base of the damping resistor (current increase flowing through R1) → capacitor (C1) increases the voltage across, the damping through a charging resistor (R2) transistor (Q1) → damping transistor (Q1 ) → decrease the voltage of the damping resistor (R1).

 ; The above process is repeated and the transistor semiconductor device used in the damper circuit operates in the amplification region instead of the saturation region.

On the other hand, in the actual application design circuit, the current flowing through the damping resistor R1 and the damping transistor Q1 is automatically distributed according to the time constant of the circuit component in accordance with the main circuit current.

In the dimming circuit device of an electronic ballast for an LED bulb having a dimming control function including an active damper circuit formed by combining a damping resistor and a damping resistor (330?) According to the present invention having such a damping action, (Dimming Angle 135 °: orange ~ voltage waveform across the resistance / light blue ~ resistance current waveform) and Figure 10b (input power: 26W, dimming angle 90 °: orange ~ Figure 9a shows the voltage and current waveforms at both ends of the damping resistor as shown in Figure 9a (current waveforms through resistors), which waveforms are voltage and current waveforms across the damping resistor in the case of a passive damper using only a resistor 10 [ Power: 26 W, dimming angle 135 °: orange-to-resistance voltage waveform / light blue to current flowing through the resistor) and FIG. 9b (input power: 26 W, 11A (dimming angle 15 °: orange AC input voltage waveform / light blue AC (voltage) waveform showing the same shape as that of the dimming angle 90 °: orange: voltage across the resistance / voltage across the resistance / (Orange AC input voltage waveform / blue AC input current waveform) and FIG. 11c (Dimming Angle) 135 °: orange AC input voltage waveform / blue AC input current waveform) As shown in the input voltage and current waveforms of the 28-watt drive circuit for an acoustic damper, further ringing phenomenon due to additional LC resonance can be effectively removed. By flowing a high current through the damping transistor, While maximizing efficiency. In addition, by using the damping resistor R1 having a large value, a basic role as a damper can be faithfully performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

100: LED module
200: LED control circuit
300: AC-DC rectification circuit
400: EMI filter
500: damper circuit
R1: Damping resistance
R2: Charging resistance
C1: Capacitor
Q1: Damping transistor

Claims (4)

A dimming circuit device of an electronic ballast for an LED bulb having a dimming control function, the dimming circuit device comprising: an AC-DC rectification circuit of a dimming circuit device including an LED module (100), an LED control circuit (200), and an AC- In the damper circuit 500 provided between the circuit 300 and the LED control circuit 200,
A current is passed through the damping resistor R1 while the capacitor C1 connected to the charging resistor R2 is charged and the capacitor C1 is charged above the set voltage so that the damping transistor Q1 is charged with the base- The damping transistor Q1 connected in parallel with the damping resistor R1 is turned on as a base current flows to the damping transistor Q1 and a part of the damping current that has flowed through the damping resistor R1 flows through the damping transistor Q1 And the current flowing from the collector of the damping transistor Q1 to the emitter is proportional to the voltage across the damping resistor R1 connected in parallel thereto and the damping transistor Q1 is fully conducting particular that the formation is not a saturation zone to operate in the amplification region to flow the amplification factor (h _fe) and the base current collector corresponding to the product of (i _b) a current (i _c) A dimming control of LED jeonguyong dimming electronic ballast circuit that is used for the damper device of the circuit that includes a. The method according to claim 1,
The charging resistor R2 has a larger value than the damping resistor R1 so as to reduce the energy loss and when the base-emitter voltage V _BE of the damping transistor Q1 is turned on at a voltage lower than the saturation region And an electric current for passing through the damping resistor (R1) is set to be energized in a non-saturated state so as to minimize the occurrence of LC resonance due to an additional instantaneous current change. A damper circuit used in a dimming circuit device of a ballast. 3. The method according to claim 1 or 2,
The AC input power is turned on so that the damping transistor Q1 is turned on after a delay time after the set time elapses after the triac dimmer in the LED control circuit 200 is turned on voltage charged to the c1) (V _c1) is a LED dimming of jeonguyong electronic ballast having a dimming control function, characterized in that which is set to increase exponentially with the time constant of the charging resistor (R2) and a capacitor (c1) A damper circuit used in a circuit device. 4. The method according to any one of claims 1 to 3,
The main current flows through the damping resistor R1 and the current flowing through the damping transistor Q1 in accordance with the value of the amplification factor h _fe of the damping resistor R1, the charging resistor R2, the capacitor C1 and the damping transistor Q1. And the dimming control function of the damper circuit used in the dimming circuit device of the electronic ballast for LED bulb.

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