BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention generally relates to a switching circuit, and more particularly, to a ballast switching circuit.
2. Description of Related Art
Fluorescent lamps are the most popular light sources in our daily lives. To improve the efficiency of fluorescent lamps significantly saves energy. Therefore, in recent development, issues such as efficiency improvement and power saving for a ballast of the fluorescent lamp are deeply concerned. FIG. 1 shows a conventional electronic ballast circuit having a resonant circuit. A half-bridge inverter consists of two switches 10 and 15, which are complementarily switched on/off with 50% duty cycle at a desired switching frequency. The resonant circuit is composed of an inductor 75, a capacitor 70 to operate a fluorescent lamp 50. A capacitor 55 connected in parallel with the fluorescent lamp 50 operates as a start-up circuit. Once the fluorescent lamp 50 starts up, the switching frequency is controlled to produce a required lamp voltage. The drawback of this circuit is high switching loss on switches 10 and 15. The parasitic devices of the fluorescent lamp, such as the equivalent capacitance, vary in response to the temperature variation and the age of the fluorescent lamp 50. Besides, the inductance of the inductor 75 and the capacitance of the capacitor 70 vary during the mass production.
An objective of the present invention is to provide a ballast circuit capable of automatically achieving soft switching operation for reducing the switching loss and improving the efficiency.
Another objective of the present invention is to develop a low-cost ballast circuit with high efficiency performance.
SUMMARY OF THE INVENTION
The present invention provides a ballast circuit for fluorescent lamps. A resonant circuit formed by a capacitor and a transformer is connected in parallel with the fluorescent lamp. A first transistor and a second transistor are coupled to the resonant circuit for switching the resonant circuit. The transformer having a first winding is connected in series with the fluorescent lamp. A second winding and a third winding of the transformer are used for generating control signals in response to a switching current of the resonant circuit.
The first transistor is turned on once the first control signal is higher than a first threshold. After a quarter resonant period of the resonant circuit, the first transistor is turned off once the first control signal is lower than a second threshold. The second transistor is turned on once the second control signal is higher than the first threshold. After a quarter resonant period of the resonant circuit, the second transistor is turned off once the second control signal is lower than the second threshold. Therefore, a soft switching operation is achieved for the first transistor and the second transistor.
BRIEF DESCRIPTION OF ACCOMPANIED DRAWINGS
The accompanying drawings are included to provide a further understanding of the present invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the present invention and, together with the description, serve to explain the principles of the present invention.
FIG. 1 shows a conventional electronic ballast circuit.
FIG. 2 shows a ballast circuit according to an embodiment of the present invention.
FIG. 3˜FIG. 6 respectively show four operation phases of the ballast circuit according to an embodiment of the present invention.
FIG. 7 shows the signal waveforms of the ballast circuit according to an embodiment of the present invention.
FIG. 8 shows a first control circuit according to an embodiment of the present invention.
FIG. 9 shows a second control circuit according to the embodiment of the present invention.
FIG. 10 shows a detection circuit according to an embodiment of the present invention.
FIG. 11 shows a one-shot circuit according to an embodiment of the present invention.
FIG. 12 shows a ballast circuit according to another embodiment of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
FIG. 2 shows a ballast circuit according to an embodiment of the present invention. A capacitor 70 and a transformer 80 are connected in series to form a resonant circuit for operating a fluorescent lamp 50. The resonant circuit produces a sine-wave current to drive the fluorescent lamp 50. A first transistor 20 is coupled to switch the resonant circuit. A first resistor 25 is connected in series with the first transistor 20 to detect a switching current for generating a first current signal VA. The first transistor 20 is controlled by a first switching signal S1. A second transistor 30 is coupled to the resonant circuit to supply an input voltage V+ to the resonant circuit. A second resistor 35 is connected in series with the second transistor 30 to detect the switching current for generating a second current signal VB. The second transistor 30 is controlled by a second switching signal S2. A first winding N1 of the transformer 80 is connected in series with the fluorescent lamp 50.
A second winding N2 and a third winding N3 of the transformer 80 are used for generating a first control signal V1 and a second control signal V2 in response to the switching current of the resonant circuit. A first diode 21 is connected in parallel with the first transistor 20. A second diode 31 is connected in parallel with the second transistor 30. A first control circuit 100 generates the first switching signal S1 for turning on/off the first transistor 20 in response to the first control signal V1. A second control circuit 200 generates the second switching signal S2 for controlling the second transistor 30 in response to the second control signal V2. A third resistor 45 is coupled from the input voltage V+, which is supplied from a capacitor 40, to a capacitor 65 to charge the capacitor 65 once the power is applied to the ballast circuit. The capacitor 65 is further connected to the second control circuit 200 to provide a second supply voltage VCC2. When a voltage across the capacitor 65 is higher than a start-up threshold, the second control circuit 200 will start to operate. A fourth diode 60 is coupled from the third winding N3 of the transformer 80 to the capacitor 65 to further power the control circuits for switching the resonant circuit. A third diode 90 and a capacitor 95 form a charge pump circuit to provide a first supply voltage VCC1 to the first control circuit 100. The third diode 90 is connected from the capacitor 65 to the capacitor 95. The capacitor 95 is connected to the first control circuit 100.
FIG. 3˜FIG. 6 respectively show four operation phases of the switching circuit. When the second transistor 30 is turned on (the first operation phase T1), a lamp current IM will flow via the transformer 80 to generate the second control voltage V2. Meanwhile, the capacitor 95 is charged by the capacitor 65 via the third diode 90 and the second transistor 30. Once the lamp current IM decreases and the second control voltage V2 is lower than a second threshold VT2, the second transistor 30 will be turned off. After that, a circular current of the resonant circuit will turn on the first diode 21. The circular current is produced by the energy stored in the transformer 80. The energy of the resonant circuit will be circulated (the second operation phase T2). The lamp current IM flowing via the transformer 80 generates the first control signal V1. If the first control signal V1 is higher than a first threshold VT1, the first control circuit 100 will enable the first switching signal S1 to turn on the first transistor 20. Since the first transistor 20 is turned on at the moment that the first diode 21 is being conducted, a soft switching operation for the first transistor 20 is achieved (the third operation phase T3). When the lamp current IM decreases and the first control voltage V1 is lower than a second threshold VT2, the first transistor 20 will be turned off. Meanwhile, the circular current of the resonant circuit will turn on the second diode 31, and the energy of the resonant circuit will backward charge the capacitor 40 (the fourth operation phase T4). Therefore, the second transistor 30 is turned on at the moment that the second diode 31 is being conducted. This also achieves a soft switching operation for the second transistor 30.
FIG. 7 shows the waveform in four operation phases, in which VX represents the first control signal V1 or the second control signal V2. The first switching signal S1 is enabled once the first control signal V1 is higher than the first threshold VT1. After a quarter resonant period of the resonant circuit, the first switching signal S1 is disabled once the first control signal V1 is lower than the second threshold VT2. A resonant frequency fR of the resonant circuit is given by,
where L is the inductance of the first winding N1 of the transformer 80; C is the equivalent capacitance of the fluorescent lamp 50 and the capacitor 70.
The second switching signal S2 is enabled once the second control signal V2 is higher than the first threshold VT1. Also, after a quarter resonant period of the resonant circuit, the second switching signal S2 is disabled once the second control signal V2 is lower than the second threshold VT2.
FIG. 8 shows the first control circuit 100 according to an embodiment of the present invention. A first detection circuit 110 is coupled to the second winding N2 of the transformer 80 to detect the first control signal V1 for generating a first enable signal O1 and a first phase signal P1. The first enable signal O1 is enabled once the first control signal V1 is higher than the first threshold VT1. Detecting the waveform of the first control signal V1 produces the first phase signal P1 to indicate a quarter resonant period of the resonant circuit. A first comparator 130 is coupled to detect the first current signal VA for producing a first reset signal. The first reset signal is generated once the switching current is higher than a first over-current threshold VR1. The first enable signal O1 is supplied to an input of an AND gate 122 and an input of an AND gate 123. The first phase signal P1 is supplied to another input of the AND gage 122 via an inverter 121. An output of the first comparator 130 is connected to another input of the AND gate 123. An output of the AND gate 122 is connected to a set-input of a flip-flop 125. An output of the AND gate 123 is connected to a reset-input of the flip-flop 125. An output of the flip-flop 125 is connected to an input of an AND gate 127. Another input of the AND gate 127 is supplied with the first enable signal O1. The output of the AND gate 127 generates the first switching signal S1. Therefore, the first switching signal S1 is generated in response to the first enable signal O1, the first phase signal P1 and the first reset signal.
FIG. 9 shows the second control circuit 200 according to an embodiment of the present invention. A second detection circuit 210 is coupled to the third winding N3 of the transformer 80 to detect the second control signal V2 for generating a second enable signal O2 and a second phase signal P2. The second enable signal O2 is enabled once the first control signal V1 is higher than the first threshold VT1. Detecting the waveform of the second control signal V2 produces the second phase signal P2 to indicate a quarter resonant period of the resonant circuit. A second comparator 230 is coupled to detect the second current signal VB for producing a second reset signal. The second reset signal is generated once the switching current is higher than a second over-current threshold VR2. The second enable signal O2 is supplied to an input of an AND gate 212 and an input of an AND gate 213. The second phase signal P2 is supplied to another input of the AND gate 212 via an inverter 211. An output of the comparator 230 is connected to another input of the AND gate 213. An output of the AND gate 212 is connected to a set-input of a flip-flop 215. An output of the AND gate 213 is connected to a reset-input of the flip-flop 215. An output of the flip-flop 215 is connected to an input of an AND gate 217. Another input of the AND gate 217 is supplied with the second enable signal O2.
An output of the AND gate 217 is further connected to an OR gate 219. Another input of the OR 219 is coupled to an output of a one-shot circuit 400 to receive a one-shot signal. An output of the OR gate 219 generates the second switching signal S2. An input of the one-shot circuit 400 receives a start-up signal via an inverter 280. Two zener diodes 251, 252, two transistors 255, 256 and two resistors 253, 254 develop a start-up circuit 250 to generate the start-up signal in response to the second supply voltage VCC2. The zener diodes 251 and 252 determine a start-up threshold. The start-up circuit enables (logic-low) the start-up signal when the second supply voltage VCC2 is higher than the start-up threshold. In the mean time, the logic-low start-up signal will turn on the transistor 255 to short circuit the zener diode 251 and produce a turn-off threshold. The turn-off threshold is determined by the zener diode 252. Therefore, the start-up signal is disabled (logic-high) once the second supply voltage VCC2 is lower than the turn-off threshold. The first switching signal S1 is therefore generated in response to the one-shot signal, the second enable signal O2, the second phase signal P2 and the second reset signal.
FIG. 10 shows the circuit schematic of the detection circuits 110 and 210. A control signal VX represents the first control signal V1 or the second control signal V2. A first input resistor 330 and a second input resistor 340 are coupled to the transformer 80 for receiving the control signal VX (V1 or V2). A first current source 310 and a second current source 320 are coupled to the first input resistor 330 and the second input resistor 340 respectively. Input resistors 330, 340 and current sources 310, 320 provide level shifting to detect the signal waveform of the control signal VX. The resistance of input resistors 330 and 340 are equal. The current of the second current source 320 is higher than that of the first current source 310. Therefore the voltage generated at the second input resistor 340 is higher than the voltage generated at the first input resistor 330.
A differential voltage in between the first input resistor 330 and the second input resistor 340 determines the first threshold VT1. A third current source 315 is coupled to the second input resistor 340 via a control switch 316. A comparator 370 has an input coupled to the first input resistor 330. Another input of the comparator 370 is connected the first input resistor 330 via a delay circuit. The delay circuit is formed by a resistor 350 and a capacitor 355. An output of the comparator 370 generates a phase signal PX, which represents the first phase signal P1 or the second phase signal P2. The phase signal PX is further utilized to turn on/off the control switch 316. When the magnitude of the control signal VX is going down, the comparator 370 will output a logic-high signal to turn on the switch 316 and connect the third current source 315 and the second input resistor 340. Therefore, the second current source 320 associates with the third current source 315 to generate a higher voltage at the second input resistor 340, which determines the second threshold VT2. Therefore, the second threshold VT2 is higher than the first threshold VT1.
A comparator 380 has an input coupled to the first input resistor 330. Another input of the comparator 380 is connected to the second input resistor 340. The enable signals OX representing the first enable signal O1 or the second enable signal O2 is generated at an output of the comparator 380. FIG. 11 shows the one-shot circuit 400 according to an embodiment of the present invention. A current source 410 and a capacitor 430 determine an enable period of the one-shot signal.
FIG. 12 shows a ballast circuit according to another embodiment of the present invention. Since the first transistor 20 and the second transistor 30 are turned off before the energy of the resonant circuit is fully discharged, the energy is able to generate the circular current to turn on the diodes 21 and 31. Besides, the switching operation of transistors 20 and 30 can be detected by the polarity change from control signals V1 and V2. The transistor can be turned on immediately after the diode is conducted. Therefore, the present invention achieves soft switching operation and improves the efficiency of the ballast circuit.
While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.