TW200810606A - A self-oscillating full-bridge electronic ballast - Google Patents

Abstract

The present invention discloses a self-oscillating full-bridge electronic ballast to reduce the current stress applied on the switches by full-bridge inverter. A first control coil, a second control coil, a third control coil, and a forth control coil control correspondingly a first switch, a second switch, a third switch, and a fourth switch to provide a resonant a high frequency rectangular voltage wherein the high frequency rectangular voltage is higher than which the prior art provides, and current stress applied on the first switch, the second switch, the third switch, and the fourth switch can be down.

Description

200810606 IX. DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to a self-excited electronic ballast, and more particularly to a self-excited electronic ballast having a full bridge converter architecture. [Prior Art] With the development of technology and the improvement of living standards, lighting has become an indispensable basic requirement in human life. In recent years, due to the booming development of various industries around the world, the frequent activities of commercial activities and the improvement of the quality of life at home, the use of electricity in the inscriptions has also increased, making the development of lighting systems that are efficient, comfortable, safe, and highly effective. It is also getting more and more attention. In most lighting systems, stabilizers are required to work. Please refer to FIG. 1 , which is a schematic circuit diagram of a conventional self-excited half bridge electronic ballast. The half bridge converter 22 controls the upper arm switch 26 by using the upper arm switch control line 24 and the lower arm switch. The coil controls the lower arm switch 30 such that the upper arm switch 26 and the lower arm switch 3 are switched to each other to provide a back-end circuit square wave AC voltage to drive the load 32. Please refer to Figs. 2a to 2B, which are schematic diagrams showing the current stress of each switch of the conventional self-excited half bridge electronic ballast. Please refer to FIG. 2A, which is a schematic diagram showing the current stress of the upper arm switch %. It can be found that the current stress on the upper arm switch 26 is very large. Similarly, please refer to FIG. 2B, which shows the lower arm switch 3. The current stress diagram of 〇 can be found that the current stress on the lower arm switch 3〇 is also very large, resulting in a large limitation of the output power of the half bridge electronic ballast and the need to select components with larger rated current specifications. Used, resulting in a rise of 200810606. SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a self-excited full-bridge electronic ballast whose current stress is required to be subjected to a current stress of a conventional self-excited half-bridge electronic female switch. Still small. Another object of the present invention is to provide a self-excited full-bridge electronic ballast in which the rated current value of the rectifier and the switch is smaller than the rated current of the rectifier and the switch used in the conventional half-bridge converter. . . . According to the above object of the present invention, a self-excited full-bridge electronic stability is proposed: 'at least one load; one power supply for providing a stable AC input voltage; and a rectifier' for converting a stable AC input voltage to - A stable DC voltage two-bridge full-bridge converter for converting a stable DC voltage into a square-wave AC voltage; a start-up circuit for starting a full-bridge converter; and a wobble circuit for converting a square-wave AC voltage Is the sine wave voltage and provides the sine wave voltage to the load; wherein, after the startup circuit starts the operation of the full bridge converter, the full bridge converter converts the stable DC voltage provided by the whole n into a square wave AC voltage and supplies it to the resonant circuit The resonant circuit converts the square wave AC voltage into a sinusoidal voltage to provide a sinusoidal voltage to the load and implement Zero Voltage Switching. According to a preferred embodiment of the present invention, the full bridge converter includes at least: a first switch 'electrical connection rectifier; a first control coil for controlling the first switch i to the second switch, the first switch in series; a second control coil for controlling the second switch; a third switch 'electrically connected to the rectifier II; - a third control 200810606 coil for controlling the third switch · a switch, #四开关, series third switch a fourth control coil for controlling the fourth bucket, the fourth switch, and a steering control coil, I for controlling the first control coil of the Thunderbolt A 10 watt t 罨 t machine direction, the second control coil The current side: the direction of the current to the third control coil and the direction of the fourth control coil current; i in the 'starting circuit to start the operation of the full bridge converter, the first switch, the second open · off:: three switches and The four switches begin to switch to each other to convert the stable DC voltage provided by the rectifier into a square wave AC voltage and provide it to the Wei circuit. The spectrum oscillator circuit converts the square wave AC voltage into a sine wave voltage to provide a sine wave voltage. Load and realize the function of zero voltage switching. According to a preferred embodiment of the present invention, the full bridge converter may further include a first voltage limiting benefit, the first switch is connected in parallel to protect the first switch; and a second voltage limiter is connected in parallel to protect the second switch. a third voltage limiter is connected in parallel to protect the third switch; and a fourth voltage limiter is connected in parallel with the fourth switch to protect the fourth switch. According to a preferred embodiment of the present invention, a first voltage limiter, a second limiter, a third voltage limiter, and a fourth voltage limiter are respectively connected by two anodes, and the diodes are connected in series. Composed of. In accordance with a preferred embodiment of the present invention, the rectifier can be a half-wave rectifier or a full-wave rectification family and can further include a voltage stabilizing capacitor. According to a preferred embodiment of the present invention, the starting circuit includes at least one alternating current switching element 'for starting the operation of the full bridge converter; and one starting resistor, one end of the starting resistor is electrically connected to the rectifier, and the other end of the starting resistor is electrically connected to the alternating current. a switching element; and a starting capacitor for turning on the alternating current switching element. 200810606 In accordance with a preferred embodiment of the present invention, the rated current value of the switch, the rated current value of the third open switch, and the rectifier of the rectifier half-bridge electronic ballast are smaller. 'The rated current value of the first switch, the rated current value of the second switch, and the rated current value of the fourth switch are applied to the self-excited constant current value and the rated current value of the switch. [Embodiment] Lu, #参考帛3目A schematic diagram of a circuit of a self-excited full-bridge electronic ballast in accordance with a preferred embodiment of the present invention. The electronic AC power supply core-rectifier 211, a start-up circuit, a full-bridge-resonant circuit, and a load 212, wherein the load 212 can be, for example, a lamp tube, and can be, for example, a composite metal lamp, a cold cathode fluorescent lamp, or a line type. Fluorescent lamps, cathode fluorescent lamps, light-emitting diodes, xenon lamps, organic light-emitting diodes, and the like have small variations in lamp equivalent resistance and large lamps. > - In accordance with a preferred embodiment of the present invention, the rectifier 211 is operative to convert the alternating current &amplifier& parent input voltage to a regulated DC voltage. The rectifier 211 can be a half-wave rectifier including two diodes or a full-wave rectifier including four one-poles, and the rectifier 211 further includes a voltage-stabilizing valley Cdc 'the DC voltage provided by the rectifier 211. The waveform can be smoother. According to a preferred embodiment of the present invention, the starting circuit includes at least a starting resistor 214, a starting capacitor 216, an alternating current switching element (Dac) 2 18 and a discharge diode 219, wherein one end of the starting resistor 214 is electrically connected to the rectifier 211 'The other end is electrically connected to the starting capacitor 216 and the AC switching element 2 1 8 ° The rectifier 2 1 1 provides the DC voltage through the starting resistor 200810606 2 1 4 to the starting capacitor 2 1 6 Fenlei, #六& p目The day z1 is charged, causing the parent flow switching element 2丨8 to be turned on to start the operation of the full bridge converter. The discharge diode 219 is used to prevent the AC switching element 2丨8 from being retriggered. According to a preferred embodiment of the present invention, the full bridge converter includes at least a first switch 220, a first control coil 222, a first voltage limiter 223, a second switch 224, and a second control coil 226. The second voltage limiter 227, the third switch 228, the third control coil 23, the third voltage limiter 231, the fourth switch 232, the fourth control coil 234, and the fourth voltage limiter 236 And a steering control coil 238, wherein the first control coil 222, the second control coil 226, the third control coil 230, the fourth control coil 234, and the steering control coil 238 are all wound on the same core winding, and the first control The polarities of the coil 222 and the fourth control coil 234 are opposite to those of the second control coil 226, the third control coil 23A, and the steering control coil 238; the first voltage limiter 223, the second voltage limiter 227, and the third voltage limiting The 231 and the fourth voltage limiter 236 are each composed of two anodes connected in series with the Zener diodes. When the AC switching element 2 18 is turned on, current flows through the second control coil 226. At this time, the third control coil 230 induces a current to flow in the direction of the second switch 228. When the voltage of the second control coil 226 exceeds the gate threshold voltage of the second switch 224, the second switch 224 is turned on. Similarly, when the voltage on the third control coil 230 exceeds the gate threshold voltage of the third switch 228. The third switch 228 will be turned on. The second voltage limiter 227 is coupled in parallel with the second control coil 226 to provide a second control coil 226 - a current release path. Similarly, the third voltage limiter 231 is coupled in parallel with the third control coil 230 to provide a third control coil 230 - current Release the path. The full-bridge converter starts work 200810606 After the 'parent flow switching element 218 will enter the off state and will not turn on during the full-bridge converter operation. 1 When the second switch 224 and the third switch 228 are turned on, there will be a current from: #振电路肌过转转控线圈238, at this time, the first control coil 222 will induce a current to the first switch 22〇 The direction of the flow, the fourth control coil 234 induces a current to flow in the direction of the fourth switch 232. When the voltage of the first control coil 222 exceeds the gate threshold voltage of the first switch 22, the first switch 220 is turned on, similarly, when the voltage on the fourth control coil 234 exceeds the gate of the fourth switch 232 At the extreme threshold voltage, the fourth switch 232 will be turned on. The first voltage limiter 223 is coupled in parallel with the first control coil 222 to provide a first* control coil 222 - a current release path. Similarly, a fourth voltage limiter 23 6 is coupled in parallel with the fourth control coil 234 to provide a fourth control coil 234. A current release path. When the first switch 220 and the fourth switch 232 are turned on, there is a current flow - flowing through the steering control coil 238 to the resonant circuit. At this time, the second control coil 226 induces a current to the second switch 224. Flowing, the third control " 2 turns 230 will also induce a current to flow in the direction of the third switch 228. When the voltage of the second control coil 226 exceeds the gate threshold voltage of the second switch 224, the second switch 224 will be turned on again. Similarly, when the voltage on the second coil 230 exceeds the gate critical voltage of the third switch 228. (4) Control = Switch 228 will also be turned on again. In accordance with a preferred embodiment of the present invention, the resonant circuit includes a resonant inductor 24A, a -filtered DC capacitor 242, and a resonant capacitor 244, wherein the resonant capacitor 244 is coupled in parallel with the load 212. The resonant circuit is used to convert the 10 200810606 square wave voltage outputted by the full bridge converter into a sinusoidal voltage and output to the load 212, and the resonant circuit also has the function of Zero Voltage Switching. As can be seen from the above description, the preferred embodiment of the present invention converts the DC voltage outputted by the rectifier into a square wave by switching between the first opening, closing 220 and the fourth switch 232 and the second switch 224 and the third switch 228. The AC voltage, the voltage value tbf of the square wave AC f voltage, is known to be higher in the square wave AC voltage supplied to the load by the self-excited half bridge electronic ballast. - Refer to Figures 4A through 4D, which are schematic diagrams showing current stresses of the first switch 220, the second switch 224, the third switch 228, and the fourth switch 232, respectively, in accordance with a preferred embodiment of the present invention. Please refer to FIG. 4, which is a schematic diagram showing the current stress of the first switch 220. It can be found that the current stress of the first switch 22〇 is smaller than that of the conventional self-excited half bridge electronic ballast. Referring to Fig. 4B, which illustrates the current stress of the second switch 224, it can be seen that the current stress of the second switch 224 is smaller than that of the conventional self-excited half-bridge electronic female device. Please refer to FIG. 4C, which is a schematic diagram showing the current stress of the second switch 228. It can be found that the third open || 228 (four) flow stress has a smaller switching current stress than the conventional self-excited half bridge electronic ballast. Referring to FIG. 4D, which illustrates the current stress of the fourth switch 232, it can be found that the current stress of the fourth switch 232 is smaller than that of the conventional self-excited half bridge electronic ballast. It can be reasonably inferred that the current stress of the whole muscle 211 is also smaller than that of the conventional self-excited half bridge electronic ballast. It will be apparent from the above-described preferred embodiments of the present invention that the first switch 220, the second switch 224, the third switch 228, and the fourth switch 11 200810606 are used to provide a higher drive for the back end circuit. Voltage to reduce the first

220, the second switch 224, 黛: 戸 bow off » key SH J ^ brother two switch 228 and the fourth switch 232 electric 应力 stress. < From the above preferred embodiment of the present invention, another advantage of the present invention is that, when the current stress of the switch is reduced, the rated current value of the switch and the second thief applied to the present invention can be greatly reduced. To achieve cost savings: # Although the present invention has been disclosed in the preferred embodiment as above, but it is not the heart = this (four), any skilled person skilled in the art, without departing from the spirit and scope of the present invention, can be made into various The scope of protection of the present invention is defined by the scope of the appended claims. [Simple description of the map]

In order to make the present invention and others understandable, the following description of the preferred embodiments will be as follows, and the features, advantages and advantages will be more obvious and in accordance with the drawings. The circuit diagram of the self-excited half-bridge electronic ballast is shown in Figs. 2A to 2B. The current stress diagrams of the switches of the self-excited half-bridge electronic ballast of the conventional + Α λ , . The schematic diagram of the self-excited full-bridge electronic daughter device according to the preferred embodiment of the invention is not shown. 4th to 4D are respectively intended to be in accordance with the preferred embodiment of the present invention, the switch, the second switch 'third switch' off, and the fourth switch current stress indication 12 200810606. [Main component symbol description]

22: Half-bridge converter 24; 26; Upper arm switch 28: 30: Lower arm switch 32: 210: AC power supply 211 212 _• Load 214 216: Starting capacitor 218 219: Discharge diode 220 222: First control coil 223 224: second switch 226 227: second voltage limiter 228 230: third control coil 231 232: fourth switch 234 236 • • fourth voltage limiter 238 240: resonant inductor 242 244: resonant capacitor Cdc upper arm switch control coil Lower arm switch control coil load: rectifier starting resistor AC switching element first switch first voltage limiter second control coil third switch first third voltage limiter fourth control coil steering control coil filter DC capacitor voltage regulator capacitor 13

Claims (1)

200810606 X. Patent application scope 1 · A self-excited full-bridge electronic ballast, comprising at least: a load; a power supply 'to provide a stable AC input voltage; a rectifier' to convert the stable AC input voltage into one Stable DC voltage a full bridge converter for converting the stable DC voltage into a square wave AC voltage, the full bridge converter comprising at least: a first switch electrically connected to the rectifier; a first control coil for controlling the first a second switch, the first switch is connected in series; a second control coil is used to control the second switch; a third switch is electrically connected to the rectifier; and a second control coil is used to control the first switch a third switch, a fourth switch, the third switch is connected in series; a fourth control coil for controlling the fourth switch; and a steering control coil for controlling a current direction of the first control coil, the second Controlling a current direction of the coil, a current direction of the third control coil, and a current direction of the fourth control coil; - a start circuit for initiating the full bridge conversion to convert the square wave exchange from the special-spectral circuit; The sinus voltage is supplied to the load; wherein, after the startup circuit starts the operation of the full bridge converter, the 14th 200810606 switch, the second switch, the third switch, and The fourth switch starts to switch to each other to convert the stable DC voltage provided by the rectifier into the square wave AC voltage and provide the resonant circuit, and the resonant circuit converts the square wave AC voltage into the string wave voltage, u The sine wave voltage is supplied to the load, and the function of Zero Voltage Switching is implemented. ^ 2· The self-excited full-bridge electronic stability described in claim 1 is wherein the rectification|§ can be a half-wave rectifier or a full-wave rectifier. 4 3. The self-excited full-bridge electronic safety device described in claim 2, wherein the rectifier may further comprise a voltage stabilizing capacitor. - " 4. The self-excited full-bridge electronic stability of the invention as described in the scope of the patent application" wherein the full-bridge converter may further comprise: - a first voltage limiter is connected in parallel with the first switch to protect the first - a switch; - a second voltage limiter 'connects the second switch to protect the second switch; a third voltage limiter, the third switch is connected in parallel to protect the third switch; and - a fourth voltage limit The fourth switch is connected in parallel to protect the fourth switch. 5. As claimed in the patent application, wherein the first pressure limiter and the fourth voltage limiter are each described by two items. The self-excited full-bridge electronically stabilizes the second voltage limiter, the third voltage limiter and the anode opposite to the Zener diode series 15 200810606 6. The self-excited type as described in claim 1 The full-bridge electronic ballast, wherein the starting circuit comprises at least one AC switching element for starting the operation of the full-bridge converter; and a starting resistor, one end of the starting resistor is electrically connected to the rectifier, and the starting resistor is The other end is electrically connected to the alternating current switching element; and one The self-excited full-bridge electronic ballast as described in claim 1, wherein the first control coil, the second control coil, and the third The control limit ring, the fourth control coil and the steering control coil are both wound on the same core winding, and the polarities of the first control coil and the fourth control coil are opposite to the first control coil and the second control coil The steering control coils have opposite polarities. 16