KR101530632B1 - Magnetron driving circuit for sulfur lamp - Google Patents

Abstract

The present invention relates to a technology for preventing a loss of electrical energy by properly cracking down the power supplied to a filament of a magnetron when operating the magnetron for a sulfur lamp. The present invention comprises: a comparator for comparing a detection voltage of an anode current of the magnetron supplied through a current sensor with a standard voltage, and outputting a trigger signal when the detection voltage of an anode current is higher than the preset standard voltage; and a timer for turning off a switch when a preset time has elapsed after being triggered by the trigger signal, and stopping an operation of a transformer which supplies a filament voltage of the magnetron.

Description

TECHNICAL FIELD [0001] The present invention relates to a magnetron driving circuit for a magnetron,

The present invention relates to a technique for controlling driving of a magnetron for an incandescent lamp, and more particularly, to a magnetron driving circuit for an incandescent lamp that prevents loss of electric energy when driving a magnetron for an incandescent lamp, thereby improving light conversion efficiency.

The light bulb is a next-generation lighting device that transmits microwaves generated from a magnetron to a bulb through a waveguide, thereby causing a substance (for example, sulfur) contained in the bulb to generate a plasma to emit light. Since such an electroluminescent lamp is a non-electrode-driven electrodeless lamp, it has a long lifetime of 20,000 hours or more, can operate in a relatively wide temperature range (-30 to 80 ° C), has excellent color rendering property of 80 or more, 90 [lumen / W].

The filament of the magnetron must be supplied with power in order to release the thermoelectrons from the filament of the magnetron for the flash lamp. However, the conventional magnetron drive circuit for the flash light was required to continuously supply power to the filament until the magnetron started to drive and then stopped.

As described above, the prior art magnetron drive circuit for the flash light has been required to continuously supply the voltage to the filament of the magnetron during the operation of the magnetron, resulting in an electric energy loss of about 20 to 30 W. In addition, due to the loss of electric energy, the capacity of the apparatus for supplying power to the filament must be made as large as that.

Disclosure of Invention Technical Problem [8] The present invention provides a magnetron for an electromagnetically driven magnetron which is capable of appropriately interrupting power supplied to a filament of a magnetron to prevent loss of electric energy.

According to an aspect of the present invention, there is provided a magnetron driving circuit for a flashlight including: a rectifier; A pulse width modulated signal generator for generating a pulse width modulated signal through a plurality of output ports; An inverter for performing a switching operation by a pulse width modulation signal outputted through an output port of a part of the plurality of output ports; A high voltage transformer driven by the rectifier and the inverter to output a high voltage; A voltage doubler circuit unit for rectifying the output voltage of the high voltage transformer in a double voltage system and supplying the rectified voltage to the magnetron; An ultraviolet light emitted by an electromagnetic wave supplied from the magnetron; A switching driver for performing a switching operation by a pulse width modulation signal outputted through the remaining output ports of the plurality of output ports; A transformer driven by the rectifier and the switching driver to output a voltage for heating the filament of the magnetron; A current sensor for detecting an amount of current flowing through the anode of the magnetron and outputting a positive polarity current detection voltage at a level corresponding to the amount of current; A comparator for comparing the positive current detection voltage with a reference voltage to output a trigger signal; And a timer for turning off the switch when a predetermined time has elapsed after triggered by the trigger signal, thereby blocking the pulse width modulation signal supplied to the switching driver.

According to another aspect of the present invention, there is provided a magnetron driving circuit for a flashlight including: a rectifier; An inverter which is switched by a pulse width modulation signal supplied through an output port of a plurality of output ports; A high voltage transformer driven by the rectifier and the inverter to output a high voltage; A voltage doubler circuit unit for rectifying the output voltage of the high voltage transformer in a double voltage system and supplying the rectified voltage to the magnetron; An ultraviolet light emitted by an electromagnetic wave supplied from the magnetron; A switching driver for performing a switching operation by a pulse width modulation signal outputted through the remaining output ports of the plurality of output ports; A transformer driven by the rectifier and the switching driver to output a voltage for heating the filament of the magnetron; And outputting the pulse width modulation signal to all of the plurality of output ports in an initial state of driving the magnetron, comparing a feedback voltage fed back from the anode side of the magnetron with a predetermined voltage, And a pulse width modulation signal generator that does not output a pulse width modulation signal to the remaining output port.

The present invention can prevent the loss of electric energy of about 20 to 30 W by continuously supplying power to the filament of the magnetron by shutting off the power supplied to the filament of the magnetron at an appropriate time when driving the magnetron for flash light It is effective.

In addition, there is an advantage that the capacity of the device for supplying power to the filament of the magnetron can be made small.

1 is a block diagram of a magnetron drive circuit for an incandescent lamp according to an embodiment of the present invention.
2 (a) is a waveform diagram of a voltage supplied to the filament of the magnetron.
2 (b) is a waveform diagram of a voltage supplied to the anode of the magnetron.
3 is a block diagram of a magnetron drive circuit for an incandescent lamp according to another embodiment of the present invention.

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

FIG. 1 is a block diagram of a magnetron driving circuit for an incandescent lamp according to an embodiment of the present invention. The magnetron driving circuit 100 includes a rectifying part 110, a pulse width modulation signal generator 120, an inverter 130, A resonance capacitor portion 140A, a high voltage transformer T1, a voltage multiplying circuit portion 140B, a magnetron 150A, an emitter 150B, a switch SW, a switching driver 160A, a transformer T2, A comparator 160B, a comparator 160C, and a timer 160D.

Referring to FIG. 1, the rectifying unit 110 includes a rectifier 110A and a smoothing capacitor C1. The rectifier 110A converts the commercial AC power AC into a DC voltage and outputs it through the positive link voltage node LV_P and the negative link voltage node LV_N. To this end, the rectifier may include a bridge diode. The capacitor C1 is connected between the link voltage nodes LV_P and LV_N which are the output nodes of the rectifier 110A and smoothens the output voltage of the rectifier 110A to output a more complete DC voltage .

The pulse width modulation signal generator 120 outputs pulse width modulation signals (PWM1-PWM3) having predetermined duty ratios through corresponding output ports.

The inverter 130 has the MOS transistors M1 and M2 connected in series between the link voltage nodes LV_P and LV_N of the rectifier 110A. The MOS transistors M1 and M2 perform a switching operation in which they are alternately turned on by the pulse width modulation signals PWM1 and PWM2 output from the pulse width modulation signal generator 120, (T1) is driven.

The resonance capacitor unit 140A includes capacitors C2 and C3 connected in series between the two terminals of the MOS transistor M2. The capacitor C2 is equivalent to a capacitor of a secondary coil of the high voltage transformer T1. Capacitor C3 is a capacitor for resonant operation.

The leakage inductor L_i and the magnetizing inductor L_m connected to the primary coil of the high voltage transformer T1 are equivalents of the primary coil of the high voltage transformer T1.

When the high voltage transformer T1 is driven by the switching operation of the inverter 130 as described above, resonance occurs in the series circuit including the leakage inductor L_i, the magnetizing inductor L_m and the capacitor C3 , Whereby the MOS transistors M1 and M2 are turned on at a zero voltage to minimize power loss.

The voltage multiplying circuit section 140B receives the voltage induced in the secondary coil by the driving of the high voltage transformer T1 as described above, rectifies it in a voltage-doubling manner, and supplies it to the magnetron 150A. To this end, the voltage doubler circuit part 140B includes diodes D4 and D5 and capacitors C4 and C5.

At this time, the switching driver 160A performs a switching operation by the pulse width modulation signal PWM3 supplied from the pulse width modulation signal generator 120 through the switch SW, whereby the transformer T2 is driven, A filament voltage is supplied to the negative pole of the magnetron from the secondary coil of the transformer T2, whereby the hot electrons are emitted. The switching driver 160A may include various types of switching elements. In this embodiment, the switching driver 160A includes a MOS transistor M3. For reference, the transformer T2 is a transformer that outputs a low voltage (for example, 4V) as compared with the high voltage transformer T1.

In this case, when the pulse width modulation signal PWM3 is supplied at a high level, the MOS transistor (N-channel MOS transistor) M3 is turned on, whereby a current is supplied to the primary coil of the transformer T2 Flow. Subsequently, when the pulse width modulation signal PWM is supplied at a low level, the MOS transistor M3 is turned off. At this time, the electrical energy accumulated in the primary coil of the transformer T2 is transmitted to the secondary coil do. Thereafter, the MOS transistor M3 is turned on and off by the pulse width modulation signal PWM3 supplied as described above, thereby outputting the voltage through the transformer T2.

One of the taps of the primary coil of the transformer T2 is connected to the link voltage node LV_P of the rectifier 110A and the other of the taps is connected to one terminal of the MOS transistor M3. A diode D3 is connected in parallel to the MOS transistor M3 and a diode D6 is connected in parallel to the primary coil of the transformer T2.

The voltage output from the transformer T2 is transmitted to the magnetron 150A without being rectified. The magnetron 150A is provided with a filament for heating the negative electrode. In the present embodiment, the negative electrode and the filament are integrally formed.

The filament of the magnetron 150A is heated by a voltage as shown in FIG. 2 (b) supplied from the transformer T2, and the thermoelectrons are emitted from the cathode. Since the high voltage transformer T1 is driven through the above process, a DC voltage as shown in FIG. 2 (a) is supplied to the anode of the magnetron 150A, And moves to the anode.

At this time, the electromagnetic wave generated from the magnetron 150A is transmitted to the flashing light 150B through the waveguide WG, and the sealing material (for example, sulfur) sealed in the bulb of the flashing light 150B generates plasma, Whereby the flashing light 150B is turned on.

In order to prevent the unnecessary consumption of electric energy when the magnetron 150A continuously supplies the voltage to the filament of the magnetron 150A while the magnetron 150A is driven, in this embodiment, after the magnetron 150A starts to be driven When a predetermined time has elapsed, the voltage supplied to the filament of the magnetron 150A is cut off as shown in FIG. 2 (b), which will be described in more detail as follows.

The current sensor 160B detects the amount of current flowing through the anode of the magnetron 150A using a shunt resistor R connected between the positive terminal of the magnetron 150A and the ground terminal, And outputs the positive-polarity current detection voltage V_Idet.

The comparator 160C compares the positive current detection voltage V_Idet supplied from the current sensor 160B with the reference voltage Vref and when the positive current detection voltage V_Idet is higher than the reference voltage Vref , And outputs a trigger signal (TS). The reference voltage Vref may be adjusted using a variable resistor VR.

The timer 160D outputs a switching control signal CTL to the switch SW when a predetermined time elapses after being triggered by the trigger signal TS supplied from the comparator 160C to switch the switch SW, Off. One terminal of the switch SW is connected to the output terminal of the pulse width modulation signal PWM3 of the pulse width modulation signal generator 130 and the other terminal is connected to the gate of the MOS transistor M3.

Accordingly, the pulse width modulation signal PWM3 output from the pulse width modulation signal generator 120 is intercepted by the turned-off switch SW and is not transmitted to the gate of the MOS transistor M3.

Therefore, the switching operation of the MOS transistor M3 is stopped, whereby the driving of the transformer T2 is stopped. Accordingly, the voltage supplied to the filament of the magnetron 150A is also cut off as shown in (b) of FIG.

Of course, even if the voltage supplied to the filament of the magnetron 150A is cut off as described above, the magnetron 150A has already entered the RF oscillation mode, and the voltage It is possible to supply the electromagnetic wave to the flash light 150B through the waveguide WG.

3 is a block diagram showing another embodiment of the present invention. In comparison with FIG. 1, a switch SW, a comparator 160C for controlling the switching operation of the switch SW, a timer 160D, (VR) is omitted.

Instead, when the pulse width modulation signal generator 120 compares the feedback voltage V_FB fed back from the connection point of the magnetron 150A and the shunt resistor R with a preset voltage, 1 except that the pulse width modulation signal PWM3 supplied to the gate of the MOS transistor M3 of the NMOS transistor 160 is no longer output.

As a result, after the start of the operation of the magnetron 150A, when the predetermined comparison condition is satisfied, that is, when the filament is heated by the required amount, the voltage supplied to the filament is automatically cut off, .

Although the preferred embodiments of the present invention have been described in detail above, it should be understood that the scope of the present invention is not limited thereto. These embodiments are also within the scope of the present invention.

110: rectification part 110A: rectifier
120: pulse width modulation signal generator 130: inverter
140A: Resonance capacitor section 140B:
150A: Magnetron 150B: Yellow light
160A: Switching driver 160B: Current sensor
160C: comparator 160D: timer
T1: High-voltage transformer T2: Transformer

Claims (9)

A rectifier, a pulse width modulated signal generator for generating a pulse width modulated signal through a plurality of output ports, a plurality of output ports A high voltage transformer driven by the rectifier and the inverter to output a high voltage; a voltage multiplying circuit part for rectifying the output voltage of the high voltage transformer by a voltage of a voltage and supplying the rectified voltage to the magnetron; In a driving circuit of a magnetron for an ophthalmic lamp including an electron beam or the like which emits light by supplied electromagnetic waves,
A switching driver for performing a switching operation by a pulse width modulation signal outputted through the remaining output ports of the plurality of output ports;
A transformer driven by the rectifier and the switching driver to output a voltage for heating the filament of the magnetron;
A current sensor for detecting an amount of current flowing through the anode of the magnetron and outputting a positive polarity current detection voltage at a level corresponding to the amount of current;
A comparator for comparing the positive current detection voltage with a reference voltage to output a trigger signal; And
And a timer for turning off the switch when a predetermined time has elapsed after triggered by the trigger signal so that the pulse width modulation signal supplied to the switching driver is cut off.
The apparatus of claim 1, wherein the switching driver
And output through the remaining output port And a MOS transistor which is turned on or off by a pulse width modulation signal to drive the transformer.
3. The drive circuit of claim 2, wherein the MOS transistor is connected in parallel with a diode.
3. The driving circuit according to claim 2, wherein the MOS transistor is an N-channel MOS transistor.
The drive circuit of claim 1, wherein the current sensor detects an amount of current flowing through the anode of the magnetron using a shunt resistor.
6. The driving circuit of claim 5, wherein the shunt resistor is connected between the positive pole of the magnetron and the ground terminal.
2. The driving circuit of claim 1, wherein the reference voltage is controlled by a variable resistor.
The driving circuit according to claim 1, wherein the switch has one terminal connected to the remaining output port and the other terminal connected to an input terminal of the switching driver.
A high-voltage transformer driven by the rectifier and the inverter and outputting a high voltage; and an inverter for converting the output voltage of the high-voltage transformer into a double voltage And a discharge voltage circuit unit for supplying the voltage to the magnetron, and a discharge lamp for emitting light by an electromagnetic wave supplied from the magnetron, the drive circuit comprising:
A switching driver for performing a switching operation by a pulse width modulation signal outputted through the remaining output ports of the plurality of output ports;
A transformer driven by the rectifier and the switching driver to output a voltage for heating the filament of the magnetron; And
And a control unit configured to compare the feedback voltage fed back from the anode side of the magnetron with a preset voltage to output a predetermined comparison condition after starting to output the pulse width modulation signal pulse width modulation signal to all of the plurality of output ports in the initial state of driving the magnetron And a pulse width modulation signal generator for outputting a pulse width modulation signal to the remaining output port when the pulse width modulation signal is satisfied.

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