KR20150016650A - Power Supply Device for Lighting Apparatus connected and used to Triac Dimming Circuit - Google Patents

Abstract

The present invention relates to a power supply used in connection with a triac dimming circuit for an LED lamp.
According to the present invention, there is provided a power supply for a lighting apparatus connected to a triac dimming circuit,
A rectifying circuit connected to an output of the triac dimming circuit connected to the input ac power supply (Vin), for rectifying the AC output of the triac dimming circuit;
A linear drive type LED drive circuit connected to an output of the rectification circuit;
And a driving circuit connected to the output of the rectifying circuit for supplying a bleeding current to the triac dimming circuit before a current flows through the LED driving circuit for every cycle of the ripple current that is the output of the rectifying circuit, And a bleeding circuit which does not supply a bleeding current to the triac dimming circuit and does not supply a bleeding current to the triac dimming circuit for a specific period after the current does not flow through the LED driving circuit, do.
The power supply for the lighting apparatus of the present invention as described above minimizes the power loss of the bleeding circuit necessary for the triac dimming circuit and prevents the erroneous flicker and malfunction of the LED due to incompatibility with the triac dimming circuit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device for a lighting apparatus connected to a triac dimming circuit,

The present invention relates to a power supply used in connection with a triac dimming circuit for an LED lamp.

In most cases, a triac dimming circuit is attached to an illumination lamp in order to adjust the brightness in a lighting apparatus. In a conventional triac dimming circuit, as shown in FIG. 1, a resistance value of several tens of ohms The resistance value of the variable resistor Rv for dimming is set to the level of several tens of ohms and the variable resistor Rv is adjusted so as to minimize the electric charge in the capacitor C to reduce the power consumption in the dimming variable resistor Rv The speed is controlled to adjust the charging voltage of the condenser C to the incandescent lamp LAMP by adjusting the time point at which the charging voltage reaches the set voltage at which the triac is turned on Adjust the period of current flow. Of course, when the AC power supply voltage becomes 0V (Toff point in Fig. 2), the triac is turned off and the current is shut off in the incandescent lamp (LAMP).

However, in the case of an LED lamp or a fluorescent lamp, since the resistance value reaches several hundreds of ohms, the resistance value should be several megaohms to tens of megaohms in order to minimize unnecessary power consumption in the variable resistor Rv. If the variable resistor Rv is used with such a large resistance value, the current flowing through the variable resistor Rv is too weak to sufficiently reduce the charging speed, so that the Ton time in FIG. 2 is delayed too much.

Therefore, in order to solve the problem that the conventional triac dimming circuit can not be used for an LED lamp or a fluorescent lamp, in a prior art LED lamp or a dimming circuit for a fluorescent lamp, a bleeder circuit is used, The dimming function is performed by supplying a considerable current to the triac dimming circuit during a period in which no current flows in the fluorescent lamp, and a relatively efficient active breeder is often used.

However, even when such an active bleeder circuit is added, since various types of protection circuits are added to the commercial triad dimming circuit, malfunctions often occur simply with the voltage and current set values used in the active breeder, (Usable) is often not good.

In particular, when the LED driver circuit is an SMPS, it is difficult to fabricate a tri-dimming circuit for an LED driver circuit compatible with various SMPSs due to various SMPS methods and characteristics, If it is compatible with the circuit, it will be accepted as dimmable.

3, the bleeder (current extractor 6) is used to initially supply the current to cause the triad dimming circuit 2 to perform the dimming operation, but the triad dimming The current is supplied to the triac dimming circuit 2 so that the triac dimming circuit 2 is not turned off until the AC input voltage 1 falls to 0 V after the circuit 2 is turned on and the LED 3 is turned on So that the input current Iin has a waveform as shown in Fig.

3, a considerable current is supplied to the triac dimming circuit 2 during a period in which no current flows through the LED 3 (a period from A to B and a period from C to D) as shown in Fig. 4 In the period from A to B, current is supplied to the triac dimming circuit 2 so that the triac dimming circuit 2 performs the dimming operation. However, in the period from C to D, Since a considerable current is supplied to the triac dimming circuit 2 irrespective of the dimming operation of the triac dimming circuit 2, a power loss occurs due to the power consumption of the triac dimming circuit 2 in the period from C to D, D is supplied to the triac dimming circuit 2, the triac dimming circuit 2 repeatedly turns on and off abnormally, causing the LED 3 to flicker.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems of the prior art and it is an object of the present invention to minimize the power loss of a bleeding circuit for use in connection with a triac dimming circuit and to prevent an abnormal LED flashing malfunction caused by incompatibility with a triac dimming circuit A power supply for a lighting device having a bleeding circuit is provided.

According to an aspect of the present invention, there is provided a power supply for a lighting apparatus connected to a triac dimming circuit,

A rectifying circuit connected to an output of the triac dimming circuit connected to the input ac power supply (Vin), for rectifying the AC output of the triac dimming circuit;

A linear drive type LED drive circuit connected to an output of the rectification circuit;

And a driving circuit connected to the output of the rectifying circuit for supplying a bleeding current to the triac dimming circuit before a current flows through the LED driving circuit for every cycle of the ripple current that is the output of the rectifying circuit, And a bleeding circuit which does not supply a bleeding current to the triac dimming circuit and does not supply a bleeding current to the triac dimming circuit for a specific period after the current does not flow through the LED driving circuit, do.

The power supply for the lighting apparatus of the present invention as described above minimizes the power loss of the bleeding circuit necessary for the triac dimming circuit and prevents the erroneous flicker and malfunction of the LED due to incompatibility with the triac dimming circuit.

FIG. 1 shows that a triac dimming circuit for an incandescent lamp is attached to a power supply in the prior art.
Fig. 2 shows the on / off timing of the triac dimming circuit in the prior art of Fig.
Figure 3 shows a power supply with a bleeding circuit for a triac dimming device in another prior art.
Figure 4 shows the input current waveform according to the prior art of Figure 3;
Figure 5 illustrates a power supply having a bleeding circuit for a triac dimming circuit in accordance with one embodiment of the present invention.
FIG. 6 shows the input current and the bleeding current waveform according to the invention of FIG.
Figure 7 illustrates a power supply having a bleeding circuit for a triac dimming circuit in accordance with another embodiment of the present invention.

Hereinafter, the present invention will be described more specifically with reference to Figs. 5 and 6. Fig.

5, the AC power supply Vin of the present invention is supplied to the triac dimming circuit 11 and the output of the triac dimming circuit 11 is supplied to the bridge diode circuit BR And supplied to the bleeder circuit 12 of the present invention after being rectified to form a pulsating flow.

A linear drive type LED drive circuit composed of a constant current source CCS1, a constant current source CCS2 and a capacitor C is connected to the output of the bridge diode circuit BR.

The resistance R1 of the bleeder circuit 11 has a low resistance value and the resistance R2 has a high resistance value.

Now, the operation of the present invention will be described in detail with reference to FIGS. 5 and 6. FIG. Here, FIG. 6 shows one cycle after being rectified in the bridge diode circuit BR, and this waveform is repeated every cycle.

6, when the input voltage Vin passes the A point (0 V), the transistor Q2 is turned off, and the voltage across the variable resistor Rv, the capacitor Cd, and the bridge diode BR flows through the resistor R2, The transistor Q1 is turned on and the bleeding current Id begins to flow into the resistor Rv and the capacitor Cd.

At this time, the charging of the capacitor Cd is started via the variable resistor Rv of the triac dimming circuit 11, and the charging speed is set to a value corresponding to the value of the variable resistor Rv corresponding to the brightness set by the user for dimming Lt; / RTI >

Since the resistor R1 has a low resistance value, a sufficient bleeding current Id is supplied to the resistor Rv and the capacitor Cd.

However, since the charging voltage of the capacitor Cd has not yet reached the voltage capable of turning on the triac, the triac is in the off state, so no current flows through the LED driving circuit, so that the input current Iin flows through the resistor Rv, The current flows through the capacitor Cd and the bridge diode circuit BR and the resistor R1 and the transistor Q1 so that the input current Iin flows through the point A as shown in the second input current Iin waveform of FIG. Iin gradually rise to a level low enough to perform a bleeding function of supplying an operating current to the triac dimming circuit 11. [

At the point B where the charging voltage of the capacitor Cd reaches a voltage at which the triac can be turned on, the triac is turned on so that the input voltage Vin is applied to the LED driving circuit through the triac, The LED starts to turn on.

When the current starts to flow in the LED drive circuit in this way, a voltage by the current (Is) x resistance (Rs) is formed in the resistor Rs from this point so that the transistor Q2 starts to be turned on and the transistor Q1 starts to turn off So that the bleeding current Id does not flow to the variable resistor Rv and the capacitor Cd.

At this time, since the resistance R2 has a high resistance value, the current flowing through the resistance R2 is weak, so that the power loss by the resistance R2 becomes negligible.

Next, when the voltage reaches the point C, the input voltage Vin starts to become lower than the voltage capable of turning on the LED, so that the LED is turned off and the LED driving current does not flow again. And the transistor Q2 is still turned on because the charge Rs is still discharged through the resistor Rs by the Rs x Cs time constant and the resistor Rs still takes a high voltage, So that the bleeding current Id due to the transistor Q1 does not flow.

As a result, after the point C, when the LED driving current does not flow again, the LED (LED) is also turned off during a specific period in which the voltage applied to the resistor Rs is attenuated by the Rs x Cs time constant to turn on the transistor Q2 And no weak current flows through the resistor R2 and the transistor Q2 so that the input current Iin hardly flows through the resistor R1 and the transistor Q1 .

At this time, when the transistor Q2 is turned on to the point D by setting the Rs x Cs time constant to a large value, no current flows to the LED as a whole from the point C to the point D as shown in FIG. 6, The bleeding current Id due to the transistor Q1 does not flow and only the weak current due to the resistor R2 and the transistor Q2 flows so that the input current I from the point C to the point D as shown in the second and third drawings in FIG. (Iin) and the bleeding current (Id) hardly flows.

Therefore, since the bleeding current Id hardly flows in the section between the points C and D, the loss of bleeding power in this section can be prevented, and the triac dimming that occurs when a large bleeding current flows in this section It is possible to prevent malfunction (on / off repetition) of the circuit.

On the other hand, when the Rs x Cs time constant is set to be small, the transistor Q2 is turned on only to a specific point E between the C and D points, and the transistor Q1 is turned on from the E point to the D point, As shown in the fourth and fifth drawings, no current flows in the LEDs from the point C to the point E, and neither the resistor R1 nor the bleeding current Id caused by the transistor Q1 flows, Only a weak current due to the transistor Q2 flows. However, from the point E to the point D, no current flows through the LED, but a weak bleeding current Id flows through the resistor R1 and the transistor Q1.

At this time, the bleeding current Id flows from the point E to the point D, but since the current magnitude is considerably weakened, the loss of the bleeding power in the section between the points E and D is very small, The bleeding power loss is very small over the entire section to the point, and since the bleeding current is low in the section between the points E and D, the triac dimming circuit malfunction (on / off repetition which occurs when a large bleeding current flows) Can be prevented.

On the other hand, in the LED drive circuit composed of the constant current source CCS1, the constant current source CCS2 and the condenser C, the constant current source CCS1 gradually charges the capacitor C and the constant current source CCS2 The discharge of the capacitor C is gradually made so that the waveform of the input current Iin is similar to the waveform of the input voltage Vin as in the period from the point B to the point C in Fig. As a driving circuit, it corresponds to a well-known technology, so a detailed description will be omitted.

Next, in FIG. 5, after sensing the current flowing through the LED drive circuit and after the point (point C) when no current flows in the LED drive circuit, until a specific point determined by the time constant of the resistor Rs and the capacitor Cs The current sensing method for preventing the bleeding current Id from flowing, but the voltage sensing method as shown in FIG.

In Fig. 7, for example, the resistor R1 has a resistance value of several megohms, the resistor R3 has a resistance value of several tens of ohms, and the resistor R2 has a resistance value capable of sufficiently supplying the bleeding current Omega).

Thus, at a low voltage level at which the input voltage rises at 0 V, the voltage at which the transistor Q1 has yet to be turned on can not be reached in accordance with the resistance ratio of the resistor R1 and the resistor R3, The transistor Q2 is turned on and the bleeding current Id flows through the resistor R2 and the transistor Q2 so that the capacitor Cs starts to charge.

When the charging voltage of the capacitor Cd reaches a voltage capable of turning on the triac according to the set variable resistor Rv, the triac is turned on and the input voltage Vin is supplied to the LED driving circuit.

Then, when the input voltage Vin reaches a voltage level at which the transistor Q1 can be turned on, the transistor Q1 starts to be turned on, the transistor Q2 starts to turn off, and the bleeding current Id is not supplied .

The transistor Q2 is turned on when the input voltage Vin reaches the peak value and falls again and the voltage across the resistor R3 falls below a voltage that can turn off the transistor Q1. The time point at which the transistor Q2 is turned on is delayed in accordance with the time constant of the capacitor Cs and the resistor R3 by the charge charged in the resistor R2 and the transistor Q2 is turned off for the delayed time, Q2 so that the bleeding current Id does not flow.

Of course, it is preferable to set this time constant appropriately so that the delayed time is close to the time when the input voltage Vin becomes 0 V as in the third drawing of FIG. 6. However, as shown in the fifth drawing of FIG. 6, Vin may be earlier than near the time point when the voltage becomes 0V.

As a result, even in the voltage sensing method shown in FIG. 7, the bleeding current does not flow for a considerable period (preferably, the input voltage reaches 0 V) during the drop of the input voltage, so that the power loss due to the bleeding circuit is significantly reduced , It is possible to prevent malfunction of the triac dimming circuit.

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 embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

Claims (5)

A power supply for a lighting apparatus used in connection with a triac dimming circuit,
A rectifying circuit connected to an output of the triac dimming circuit connected to the input ac power supply (Vin), for rectifying the AC output of the triac dimming circuit;
A linear drive type LED drive circuit connected to an output of the rectification circuit;
And a driving circuit connected to the output of the rectifying circuit for supplying a bleeding current to the triac dimming circuit before a current flows through the LED driving circuit for every cycle of the ripple current that is the output of the rectifying circuit, And a bleeding circuit which does not supply a bleeding current to the triac dimming circuit and does not supply a bleeding current to the triac dimming circuit for a specific period after the current does not flow through the LED driving circuit, A power supply for a lighting device used in connection with a triac dimming circuit. The method according to claim 1,
Characterized in that the specific period is determined by the time constant of the resistor (Rs) and the capacitor (Cs). The method according to claim 1,
In the linear driving type LED driving circuit,
A first constant current circuit (CCS2) connected in series with an LED lamp (LED) to supply a constant current;
A capacitor C connected in parallel to the series-connected LED and the first constant current source CCS2;
And a second constant current circuit (CCS1) connected to an output of the rectifying circuit for supplying a constant current to the LED lamp (LED), the first constant current source (CCS2) and the capacitor (C) A power supply for a lighting device used in conjunction with a dimming circuit. A power supply for a lighting apparatus used in connection with a triac dimming circuit,
A rectifying circuit connected to an output of the triac dimming circuit connected to the input ac power supply (Vin), for rectifying the AC output of the triac dimming circuit;
A linear drive type LED drive circuit connected to an output of the rectification circuit;
And supplies a bleeding current to the triac dimming circuit until the input voltage Vin reaches a specified voltage for every cycle of the ripple current that is the output of the rectifying circuit, And a bleeding circuit which does not supply a bleeding current to the triac dimming circuit for a specific period of time even if the input voltage Vin falls below a set specific voltage, The power supply for a lighting device being used in connection with a triac dimming circuit. 5. The method of claim 4,
Characterized in that the specific period is determined by the time constant of the resistor (R3) and the capacitor (Cs).

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