KR100652586B1 - Magnetron drive apparatus for electrodeless lighting system - Google Patents

Abstract

The present invention relates to a magnetron driving apparatus of an electrodeless illuminator, the conventional electrodeless illuminator can increase the light efficiency during pulse driving, but the pulse efficiency is not possible in the resonant half-bridge inverter has a low light efficiency. In view of the above problems, the present invention comprises an inverter circuit configured to form a closed loop in order of connection of a power supply, a resonant circuit, and a switch, and turn on the switch for less than a predetermined time in one cycle to charge the capacitor and the inductance with electromagnetic; A closed loop is formed by connecting high voltage transformers, diodes and magnetrons.The magnetron is oscillated by supplying and energizing the charged electromagnetic power to the magnetron when the switch is turned on by the high voltage transformer.Then, the magnetron oscillates by blocking the flow of current when the switch is turned off. It is composed of a driving circuit for stopping the power supply to the magnetron by pulse driving to activate the plasma state of the bulb has the effect of concentrating the power supplied to the bulb for a predetermined time to improve the light efficiency.

Description

MAGNETRON DRIVE APPARATUS FOR ELECTRODELESS LIGHTING SYSTEM}

1 is a block diagram showing the configuration of a magnetron driving device of a conventional electrodeless lighting device.

2 is an exemplary view showing an operation waveform of the magnetron driving device of FIG.

Figure 3 is a block diagram showing the configuration of a magnetron driving device of an electrodeless lighting device according to an embodiment of the present invention.

4 is an exemplary view illustrating an operation waveform of the magnetron driving device of FIG. 3.

** Description of the symbols for the main parts of the drawings **

31: inverter circuit 32: drive circuit

The present invention relates to a magnetron driving device of an electrodeless lighting device, and more particularly, to a magnetron driving device of an electrodeless lighting device which can increase the light efficiency of the electrodeless lighting device by supplying instantaneous power to the magnetron by pulse driving.

The electrodeless lighting device generates electromagnetic waves by supplying electric power to the magnetron, and transmits electromagnetic waves to the bulb through the waveguide, and the encapsulation material sealed in the bulb generates plasma to output light. The magnetron driving device of the electrodeless lighting device supplies power to the magnetron to oscillate the magnetron to output electromagnetic waves necessary for plasma generation of the bulb.

The magnetron driving device alternately turns on / off the switch to generate LC resonance, and boosts, steps down and rectifies through a high voltage transformer to supply a high voltage to the magnetron and to generate the electromagnetic wave to output electromagnetic waves.

1 is a block diagram showing the configuration of a magnetron driving device of a conventional electrodeless lighting device, as shown in the inverter circuit 11 which alternately turns on / off a switch to cause LC resonance; It consists of a drive circuit 12 which rectifies the voltage stepped up and down by the high voltage transformer and supplies a high voltage to the magnetron.

The inverter circuit 11 changes the switching frequency to increase or decrease the resonant voltage and current of the LC resonance, and the drive circuit rectifies the boosted and stepped down resonant voltage and current by the high voltage transformer to drive the magnetron. The operation waveform of the magnetron driving device is described below.

The inverter circuit 11 is a half-bridge inverter, which alternately turns on / off the switches S1 and S2 to cause LC resonance, and increases and decreases the resonance voltage and current according to the switching frequency. The operating waveforms S1 and S2 describe the on / off time intervals of the switches S1 and S2, and the operating waveforms V1 and i1 describe the magnitude of the voltage and current flowing through the primary coil of the high voltage transformer by the on / off period of the switch. do.

The voltage and current flowing in the primary coil of the high voltage transformer T1 induce voltage and current to the secondary coil of the high voltage transformer. The secondary coil of the high voltage transformer T1 is divided into a part connected to the cathode heater of the magnetron and a second stage for driving the magnetron MGT.

Inverter circuit 11 drives the magnetron (MGT) by stepping up and down the resonant voltage, current through the high-voltage transformer (T1) in accordance with the alternate on / off operation of the switch.

The driving circuit 12 is classified into full-wave rectification and half-wave rectification. The illustrated driving circuit 12 is a half-wave rectifying circuit. The driving circuit 12 drives the magnetron MGT by half-wave rectifying the voltage stepped up and down by the high voltage transformer T1. do. The drive circuit 12 includes a second cutoff of the high voltage transformer T1; A capacitor C8 connected to the third block of the second stage; A diode D2 connected to the capacitor C8; A diode D3 connected to the anode of the diode D2; A resistor R4 connected to the anode of the diode D3; A magnetron (MGT) connected in parallel to the resistor (R4), the secondary coil of the high-voltage transformer (T1) connected to the cathode heater of the magnetron (MGT).

When current flows from the secondary stages 3 to 4 of the high voltage transformer T1, current flows through the capacitor C8 and the diode D2 to charge the capacitor C8, and conversely, the secondary stages 4 to 3 When the current flows into the burner, the charge charged in the capacitor C8 is discharged, so that the current ibm flows from the anode of the magnetron MGT to the cathode, which forms a closed loop through the diode D3 and the capacitor C8. Magnetron (MGT) is powered by the current (ibm) and oscillates and outputs electromagnetic waves.

The bulb receives the electromagnetic wave transmitted through the waveguide, and in the encapsulation material sealed in the bulb, plasma is generated due to an electron collision, thereby outputting light.

However, in the prior art as described above, the electrodeless lighting device increases the light efficiency during pulse driving, but the pulse efficiency is not possible in the resonant half-bridge inverter, so the light efficiency is low.

Accordingly, the present invention has been made in view of the above problems, and provides a magnetron driving device of an electrodeless lighting device that can increase the optical efficiency of the electrodeless lighting device by supplying instantaneous power to the magnetron by pulse driving. There is a purpose.

The present invention for achieving the above object comprises an inverter circuit for configuring a closed loop in the order of connection of the power supply, the resonant circuit, the switch and to turn on the switch for less than a predetermined time in one cycle to charge the electromagnetic in the capacitor and inductance; A closed loop is formed by connecting high voltage transformers, diodes and magnetrons.The magnetron is oscillated by supplying and energizing the charged electromagnetic power to the magnetron when the switch is turned on by the high voltage transformer.Then, the magnetron oscillates by blocking the flow of current when the switch is turned off. It is characterized by comprising a drive circuit for stopping the.

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

3 is a block diagram showing the configuration of a magnetron driving device of an electrodeless lighting device according to an embodiment of the present invention. As shown in FIG. 3, a closed loop is formed in the order of connection of a power supply Vd, a resonance circuit, and a switch S. Referring to FIG. And an inverter circuit 31 configured to charge the electromagnetic to the capacitor and the inductance by turning on the switch S for less than a predetermined time in one cycle; A closed loop is formed in the order of the connection of the high voltage transformer (T2), the diode (D1) and the magnetron (MGT), and the electromagnetic charge charged at the time of the switch S is boosted and stepped down by the high voltage transformer (T2) to the magnetron (MGT). It is characterized in that the drive circuit 32 is configured to supply the oscillation of the magnetron (MGT) and to stop the flow of current when the switch (S) off to stop the oscillation of the magnetron (MGT).

Inverter circuits for pulse driving include a full bridge, a one-stage resonant inverter, a flyback converter, a forward converter, and the like.

The inverter circuit 31 includes a power supply Vd for supplying a power supply voltage; A resonant circuit composed of a capacitor Cr connected to the plus end of the power supply Vd, an inductance M, and a first stage of a high voltage transformer; A switch S for switching the power supply of the resonant circuit on / off; It is composed of a diode (D5) connected in parallel to the switch (S) to discharge the electromagnetic of the magnetic inductance when the switch (S) off.

In addition, the driving circuit 32 boosts and lowers the voltage and current induced in the first stage of the high voltage transformer T2 at a predetermined ratio, thereby supplying power to the cathode heater of the magnetron, and supplying power to the driving circuit. Blocking; A diode (D1) and a resistor (Rd) for controlling and rectifying the current flow in the second stage; It is composed of a magnetron (MGT) is connected in parallel to the resistor (Rd) to receive the rectified current by the diode (D1) to emit electromagnetic waves.

The inverter circuit 31 turns on the switch S to charge the capacitor Cr and the inductance M with electromagnetic, and the voltage stepped up and down through the high voltage transformer T2 is induced in the second stage so that the current is diode D1. ), The magnetron (MGT) oscillates from the anode of the magnetron (MGT) to the cathode.

The inverter circuit 31 turns off the switch S, discharges electromagnetic current to the magnetic inductance through a diode D5 connected in parallel to the switch, and discharges it freewheeling, and is induced and flows in the second stage through the high voltage transformer T2. The current is blocked by the diode D1 and the oscillation of the magnetron MTG stops.

The cathode heater of the magnetron (MGT) connected to the secondary coil of the high-voltage transformer (T2) is preheated by receiving a current of about 10A and waits for electron emission required for oscillation.

The inverter circuit 31 controls the on time of the switch S to pulse-drive to supply instantaneous power to the driving circuit 32 to oscillate the magnetron MTG and stop the oscillation for a predetermined time, thereby repeatedly controlling the bulb. Activate the plasma state, pause, and then activate again.

FIG. 4 is an exemplary view showing an operation waveform of the magnetron driving apparatus of FIG. 3, and the operation of the magnetron driving apparatus will be described with reference to the drawing.

It is explained that the switch on / off time (S) of the operating waveform is differently set on and off according to the supply of instantaneous power of 30% or less of duty in one cycle on the time axis.

The primary cut-off voltage V1 of the high-voltage transformer indicates the power supply voltage Vd during the on time of the switch, the voltage (-Vd) for a predetermined time after the switch is turned on and off, and after the predetermined time has elapsed. Zero voltage is displayed until the switch is turned on.

The current i1 flowing through the switch rises steeply from the on time of the switch to the off time, and immediately after the off time, the current i1 is directly dropped from the highest point to the lowest point to represent zero current.

The current ibm flowing to the magnetron through the diode D1 rises steeply from the on time of the switch, steeply descends from the mid time of the on time due to the oscillation of the magnetron, and represents zero current from the off time of the switch.

The switch voltage Vsw represents the zero voltage during the switch-on time, the voltage 2Vd for the predetermined time from the switch-off time, and the voltage Vd from the time after the predetermined time to the next switch-on time.

As described in detail above, the present invention has the effect of concentrating the power supplied to the bulb for a predetermined time by supplying instantaneous power to the magnetron by pulse driving to improve the light efficiency.

In addition, when the total input power is the same, the magnetron is not driven equally, and the optical efficiency is increased by supplying instantaneous power to the magnetron for a predetermined time of 30 percent or less in one cycle to activate the plasma state of the bulb.

Claims (5)

A parallel resonant circuit comprising a power supply for supplying a power supply voltage, a capacitor and an inductor connected in series with the power supply, and a switching element and the switching element intermittently connected to the power supply and the resonant circuit to supply the resonant circuit. An inverter circuit connected in parallel and configured to include a diode for discharging the electromagnetic of the magnetic inductance when the power is interrupted; A high voltage transformer connected to the resonant circuit of the inverter circuit and a first stage to boost or step down the output voltage and current of the resonant circuit according to a winding ratio to guide the second stage to a second stage; A driving circuit including a diode connected to the second stage of the high voltage transformer to control current flow and rectified; and a resistor connected in series with the diode and the second stage of the high voltage transformer to become a path of a secondary current according to the operation of the diode. in; And And a magnetron connected to the resistor in parallel to receive a rectified secondary current according to the current control of the diode to emit electromagnetic waves. delete delete The method of claim 1, wherein the magnetron is The magnetron driving device of the electrodeless lighting device, characterized in that it comprises a cathode heater of the magnetron receives the output voltage and the current of the boosted or stepped secondary stage according to the winding ratio of the first and second stages of the high voltage transformer. An inverter circuit for controlling the switching of the power supply, a high voltage transformer receiving the output voltage and current of the inverter circuit as a primary terminal and outputting the voltage and current stepped up or down according to the winding ratio to a secondary terminal for outputting the voltage and current; In the magnetron driving apparatus of the electrodeless lighting device comprising a driving circuit connected to the secondary terminal of the high-voltage transformer and a magnetron discharged by the driving circuit to emit electromagnetic waves, A method of driving magnetrons in an electrodeless luminaire having a switching on / off time (S) for power supply of less than 30 percent duty in one cycle.

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