KR200359558Y1 - Improved dimmable electronics ballasts on-off circuit - Google Patents

Abstract

In the present invention, when the input of the light control ball is turned off, the storage capacitor C0 takes a high voltage and starts to discharge. However, since the voltage of the starting capacitor Cst of the zener diode D11 is high, Q3 is a P-channel FET. The gate becomes zero and the drain has the potential of the starting capacitor Cst, so that Q3 is turned on so that the potential of the starting capacitor Cst enters the fault terminal of the inverter IC so that the output of the inverter IC is forcibly stopped. Therefore, the fluorescent lamp flickers and disappears even when the input is turned off while the fluorescent lamp is turned on at a brightness of about 5% or 20% or less of the minimum brightness of the electronic dimmer, even when the input is turned off. .

Description

IMPROVED DIMMABLE ELECTRONICS BALLASTS ON-OFF CIRCUIT}

The present invention relates to a fluorescent lamp on-off circuit using a light control ballast, and more particularly to an improved dimming ballast on-off circuit for preventing the chewing phenomena generated when the fluorescent lamp is turned off at the lowest brightness of the light control ballast.

In general, in the case of using an electronic ballast, when the on-off switch is turned off, since the power consumption of the fluorescent lamp is large, the capacity of the storage capacitor is immediately discharged so that the fluorescent lamp seems to turn off immediately. Therefore, there is no discomfort.

However, in the case of using an electronic dimming stabilizer capable of dimming, when the on-off switch is turned off due to low power consumption of the fluorescent lamp at the lowest brightness (for example, near 5% or less than 20% of the maximum brightness), This can cause the light to flicker and slowly disappear.

The present invention has been made in view of the above, and an object of the present invention is to provide an improved light control ballast on / off circuit for preventing a chewing gum phenomenon generated when the fluorescent lamp is turned off at the lowest brightness of the light control ballast.

1 is a circuit diagram of a general dimming ballast,

2 is a graph showing a starting voltage state of a starting capacitor Cst with time;

3 is a circuit diagram of an improved light control ballast according to the present invention.

<Explanation of reference number>

CO-Storage Capacitor, Q1, Q2-FET,

L1-choke inductor, L11-auxiliary winding,

C1-block capacitor C2-resonant capacitor,

IC-Inverter IC, R-Overcurrent Detection Resistor,

Rst-starting resistance, Cst-starting capacitor,

Q3-P-channel FET.

In order to achieve the above object, the present invention includes an AC input power source, a bridge rectifier circuit for rectifying the input power source, and transistors Q1 and Q2 that are alternately turned on and off by an output of an inverter IC. Square wave oscillation unit which outputs square wave and outputs square wave, square wave signal flows in C1-L1-C2-R circuit in cathode preheating state before fluorescent lamp (FL) is turned on, and when fluorescent lamp is lit, the square wave is C1-L1-FL- A fluorescent lamp preheating lighting circuit for applying a driving voltage to the inverter IC through the auxiliary winding L11 while forming and flowing the R circuit, and a starting resistor Rst, a zener diode D11, a starting capacitor Cst, and a storage capacitor. (C0) and an inverter IC control unit including Q3, which is a P-channel FET, wherein the inverter IC control unit receives a high voltage to the storage capacitor C0 when the AC input is turned off. The discharge starts, but since the voltage on the starting capacitor Cst side of the zener diode D11 is high, the gate of Q3 becomes zero and the drain has the starting capacitor Cst potential, so that Q3 is turned on and the starting capacitor Cst An electric dimming ballast on / off circuit is provided, wherein a potential of the signal is input to the fault terminal of the inverter IC to force the output of the inverter IC to Q1 and Q2.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a circuit diagram of a general electronic light control ballast. In the figure, an AC input power source (AC input), a bridge circuit connected to the power source, a choke inductor L2 connected to one node of the bridge circuit, and a diode D0 for power factor correction following the choke inductor L2. , An overcurrent detection resistor (R) following the transistors Q1 and Q2 and Q2 which are sequentially connected to the diode D0, the battery capacitor C1 connected between the Q1 and Q2, the choke inductor L1 following the capacitor C1, A resonant capacitor C2 connected between the inductor L1 and the overcurrent detection resistor R, and a fluorescent lamp connected in parallel between the inductor L1 and the capacitor C2 and between the capacitor C2 and the resistor R. FL is provided.

Further, the resistor R and the other node of the bridge circuit are connected, and the start capacitor Cst and the start resistor are connected to the node n3 between the node n1 of the connection line and the connection line between the bridge circuit and Q1. Rst is connected, and a storage capacitor C0 is connected between the node n2 and the node n4.

In addition, an inverter IC is connected to the gates of the Q1 and Q2 FETs, and the auxiliary winding L11 of the inductor L1 is input to the Vcc of the inverter IC as a power source through the diode D1, and the starting resistor Rst ) And a node n5 between the start capacitor Cst.

In such an operation of the electronic dimming ballast, the power from the input (AC input) is converted into a pulse current in the bridge circuit, and the direct current is charged via the power factor correction inductor L2 and the diode D0 to charge the capacitor C0. Then, the starting capacitor Cst is charged through the starting resistor Rst.

When the charging voltage of the starting capacitor Cst reaches the starting voltage of the inverter IC, the transistors Q1 and Q2 start to oscillate.

On the other hand, the square wave by alternating on-off of Q1 and Q2 flows in a C1-L1-C2-R circuit in the cathode preheating state before the fluorescent lamp is turned on. Since the auxiliary winding L11 is induced in the inductor L1, the induced voltage is rectified by the rectifying diode D1 and input to the inverter IC as a driving power source. However, when the starting capacitor Cst tries to reach the starting voltage of the inverter IC, Q2 and Q1 start oscillation, and the voltage of the starting capacitor Cst falls, but there is a starting voltage hysteresis section of the inverter IC so that the output of the inverter IC Since the inverter output continues to come out within the hysteresis section without stopping immediately, the inverter IC driving power is induced to the auxiliary winding L11 within this period. (See Figure 2).

When the fluorescent lamp FL is turned on by the square wave by alternating on-off of Q1 and Q2, the circuit is composed of C1-L1-FL-R. When the power is turned off while the lamp is turned on, the storage capacitor C0 has a high Since the voltage is applied and the starting capacitor (Cst) is also energized, the fluorescent light flickers slowly until one of the storage capacitor (C0) or the starting capacitor (Cst) 2 discharges quickly, which uses a dimmer ballast. In this case, it becomes more prominent at or near the minimum brightness of 5% or 20%.

The present invention employs the novel wiring in Fig. 3 to improve this phenomenon. 3, in addition to the configuration of FIG. 1, the zener diode D11 is connected between the starting resistor Rst and the starting outlet Cst, and the gate of Q3, which is a P-channel FET, is the starting resistor Rst and the zener diode. A node is connected to node n6 between D11, a drain is connected to Vcc of the inverter IC, a source is connected to a fault of the inverter IC, and between node n6 between the starting resistor Rst and the zener diode D11 and the gate. A resistor R11 and a capacitor C11 are respectively connected between the connecting line of and the connecting line between the node n5 and the diode D1.

Referring to the operation of such a circuit, the power from the input (AC input) is converted into a pulse current in the bridge circuit, and the direct current is charged via the power factor correction inductor L2 and the diode D0 to charge the capacitor C0. Then, the zener diode D11 is passed in the reverse direction through the starting resistor Rst to start charging the start capacitor Cst (the reverse direction of the zener diode is the same as the forward direction of the general diode). At this time, the gate potential is higher than that of the drain of Q3, which is a P-channel FET, so that Q3 is not conductive.

When the charging voltage of the starting capacitor Cst reaches the starting voltage of the inverter IC, the transistors Q1 and Q2 start to oscillate.

On the other hand, the square wave by alternating on-off of Q1 and Q2 flows in a circuit composed of C1-L1-C2-R in the cathode preheating state before the fluorescent lamp is turned on. Since the auxiliary winding L11 is induced in the inductor L1, the induced voltage is rectified by the rectifying diode D1 and input to the inverter IC as a driving power source. However, when the starting capacitor Cst tries to reach the starting voltage of the inverter IC, Q2 and Q1 start oscillation, and the voltage of the starting capacitor Cst falls, but there is a starting voltage hysteresis section of the inverter IC so that the output of the inverter IC Since the inverter output continues to come out within the hysteresis section without stopping immediately, the inverter IC driving power is induced to the auxiliary winding L11 within this period. (See Figure 2).

When the fluorescent lamp FL is turned on by the square wave by alternating on-off of Q1 and Q2, the circuit is composed of C1-L1-FL-R. When the power is turned off in this lit state, the storage capacitor C0 is turned off. Discharge starts because of a high voltage, but since the voltage on the starting capacitor Cst of the zener diode D11 is high, the gate of Q3 becomes zero and the drain has a starting capacitor Cst potential, so that Q3 When turned on, the potential of the starting capacitor (Cst) is signaled to the fault terminal of the inverter IC to forcibly stop the output of the inverter IC.

As described above, according to the present invention, even when the input is turned off while the fluorescent lamp is turned on at a brightness of about 5% or 20% or less, which is the minimum brightness of the electronic dimmer, the phenomenon of the fluorescent lamp flickering and disappearing is eliminated. It is effective.

Claims (2)

AC input power, A bridge rectifier circuit for rectifying the input power source, A square wave oscillator having transistors Q1 and Q2 alternately turned on and off by an output of an inverter IC to output square waves; In the preheating state of the fluorescent lamp FL, a square wave signal flows in a C1-L1-C2-R circuit, and when the fluorescent lamp lights up, the square wave flows in a C1-L1-FL-R circuit. A fluorescent lamp preheating lighting circuit for applying a driving voltage to the inverter IC through an auxiliary winding (L11), And an inverter IC control unit comprising a starting resistor (Rst), a zener diode (D11), a starting capacitor (Cst), a storage capacitor (C0), and Q3, a P-channel FET, The inverter IC control unit, When the AC input is turned off, the storage capacitor C0 takes a high voltage and starts to discharge. However, since the voltage on the starting capacitor Cst side of the zener diode D11 is high, the gate of Q3 becomes zero and drains. Has a starting capacitor (Cst) potential, so that Q3 is turned on so that the potential of the starting capacitor (Cst) is signaled to the fault terminal of the inverter IC, or is connected to other protection circuits to output the outputs of the inverter IC to Q1 and Q2. An improved dimmer ballast on / off circuit, characterized in that it is forced to stop. AC input, AC bridge, a bridge circuit connected to the power supply, a choke inductor L2 connected to one node of the bridge circuit, and a diode D0 and a diode D0 for power factor correction following the choke inductor L2. Q1 and Q2, the overcurrent detecting resistor R following Q2, the battery capacitor C1 connected between Q1 and Q2, the choke inductor L1 following the capacitor C1, and the inductor L1. And a resonant capacitor C2 connected between the overcurrent detection resistor R and a fluorescent lamp FL connected in parallel between the inductor L1 and the capacitor C2 and between the capacitor C2 and the resistor R. Equipped, The resistor R and the other node of the bridge circuit are connected, and the start capacitor Cst and the start resistor Rst are connected to the node n3 between the node n1 of the connection line and the connection line between the bridge circuit and Q1. ) Is followed by a storage capacitor (C0) between the node (n2) and the node (n4), The gates of the Q1 and Q2 are connected to the inverter IC, and the auxiliary winding L11 of the inductor L1 is input to the Vcc of the inverter IC as a power source through the diode D1, while the starting resistor Rst and the starting capacitor are In the dimming ballast configured to connect the node n5 between Cst, Zener diode (D11) is connected between the starting resistor (Rst) and the starting outlet (Cst), the gate of the P-channel FET Q3 is connected between the starting resistor (Rst) and the zener diode (D11), drain is followed by Vcc of the inverter IC The source is connected to the fault of the inverter IC, A resistor R11 and a capacitor C11 are respectively connected between a connection line between the node n6 and the gate between the starting resistor Rst and the zener diode D11 and between the node n5 and the diode D1. An improved dimming ballast on / off circuit, characterized in that following.