KR100864655B1 - Driving control apparatus and method - Google Patents

Abstract

The present invention relates to an operation control apparatus and method in which an inverter for driving a filament and an anode of a magnetron is separated. It is to be done.

Description

Operation control device and method {DRIVING CONTROL APPARATUS AND METHOD}

1 is a circuit diagram showing a configuration for an operation control apparatus according to an embodiment of the present invention.

FIG. 2 is a circuit diagram showing the configuration of an embodiment of a drive control unit in FIG. 1; FIG.

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

100: control unit 200: first drive control unit

210: first pulse width modulated signal generating unit 220: first driving unit

300: second drive control unit 210: first pulse width modulated signal generating unit

220: first drive unit 400: first inverter

500: second inverter

The present invention relates to an operation control apparatus, and more particularly, to an operation control apparatus and a method for driving an anode and a cathode of a magnetron driving an electrodeless lighting device at different frequencies.

In general, an electrodeless lighting device is a lamp device that is recognized as a relatively new light source. The electrodeless lighting device forms an electrodeless bulb by placing a light emitting material such as argon into a quartz sphere having a diameter of 25 to 40 mm, and trapping the electrodeless bulb in a microwave cavity to generate a microwave discharge of 2.45 GHz with a magnetron. It is a lamp device to obtain a continuous spectrum of white light with high luminous efficiency and good color rendering in the light emitting material of the bulb.

In driving the magnetron of the electrodeless illuminator, the integrated transformer inverter, in which the high voltage transformer simultaneously drives the filament and the anode of the magnetron, drives the high voltage applied to the anode at least 10 KV before the filament of the magnetron is heated. In consideration of this, there is a problem in that the molding of the high pressure transformer.

In order to solve the problem, even if the inverter for driving the filament and the anode of the magnetron, the inverter for driving the filament and the anode of the magnetron if the drive frequency of the inverter for driving the filament and the anode of the magnetron does not occur There is a problem in that the driving frequency of the interference with each other to generate a flicker (FLICKER).

The present invention has been made to solve the problems of the prior art as described above, by controlling the difference between the filament of the magnetron and the drive frequency of the inverter for driving the anode over a certain interval to control the operation to eliminate the frequency interference And providing a method.

One embodiment of the operation control apparatus of the present invention for achieving the above object,

In the operation control device in which an inverter for driving the filament of the magnetron and the anode is separated,

And a control unit for controlling an operating frequency of the inverter for driving the filament of the magnetron and the inverter for driving the anode of the magnetron to be different by a predetermined interval or more.

One embodiment of the operation control apparatus of the present invention for achieving the above object,

A first inverter for outputting a current for driving the filament of the magnetron according to the first switching control signal;

A second inverter for outputting a current for driving the anode of the magnetron according to the second switching control signal;

A first drive control unit for outputting the first switching control scene for controlling the drive of the first inverter by a first control signal;

A second drive control unit which outputs the second switching control scene for controlling the drive of the second inverter by a second control signal;

And a control unit for outputting first and second control signals for controlling the output of the first and second switching control signals in the first and second driving control units, respectively.

Here, the first drive control unit,

A first pulse width modulated signal generating unit for generating a pulse width modulated signal having a fixed frequency and duty in accordance with the first control signal;

And a first driving unit for varying the frequency of the pulse width modulated signal and outputting a first switching control signal based on the frequency varying result.

In addition, the second drive control unit,

A second pulse width modulated signal generating unit for generating a pulse width modulated signal having a fixed frequency and duty in accordance with the second control signal;

And a second drive unit for varying the frequency of the pulse width modulated signal and outputting a second switching control signal based on the frequency varying result.

The present invention for achieving the above object,

In the operation control method of the electrodeless lighting device in which the filament of the magnetron and the inverter for driving the anode are separated,

A process of generating an operating frequency of the inverter for driving the filament of the magnetron and the inverter for driving the anode of the magnetron to be different by a predetermined interval or more.

Herein, the process of generating the operating frequency to be different from the predetermined interval may be performed.

Operating an inverter for driving the filament of the magnetron at a constant operating frequency;

After a predetermined time, the inverter driving the anode of the magnetron, characterized in that it comprises a step of operating at an operating frequency that is different from the operating frequency of the inverter for driving the filament of the magnetron by a predetermined interval or more.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation and operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

1 is a circuit diagram showing the configuration of the operation control apparatus of the present invention.

As shown in FIG. 1, a first inverter 400, a second inverter 300, a first drive control unit 200, a second drive control unit 300, and a control unit 100 are configured. .

The first inverter 400 outputs a current for driving the filament of the magnetron by the first switching control signal.

The second inverter 500 outputs a current for driving the anode of the magnetron by the second switching control signal.

The first driving control unit 200 outputs a first switching control signal for controlling the driving of the first inverter 400 by a first control signal.

Here, the first switching control signal has a different period and the duty is the same signal.

The second driving control unit 300 outputs a second switching control signal for controlling the driving of the second inverter 500 by a second control signal.

Here, the second switching control signal has a different period and the duty is the same signal.

The first driving control unit 200 may include a first pulse width modulation signal generation unit 210 for generating a pulse width modulation signal having a fixed frequency and duty according to the first control signal, and the pulse width. And a first driving unit 220 for varying the frequency of the modulated signal and outputting a first switching control signal based on the frequency varying result.

The second driving control unit 300 may further include a second pulse width modulation signal generation unit 310 for generating a pulse width modulation signal having a fixed frequency and duty according to the second control signal, and the pulse width modulation. And a second driving unit 320 for varying the frequency of the signal and outputting a second switching control signal based on the frequency varying result.

Here, the first and second pulse width modulated signal generating units 210 and 310 preferably use a relatively low-cost timer 555, and the duty and frequency are fixed.

In addition, the duty is preferably to enable up to 15% of the duty by applying a diode.

In addition, the waveform of the pulse width modulation signal output from the first and second pulse width modulation signal generating unit 210, 310 is preferably output to about 15V or more.

2 is a circuit diagram showing the configuration of a preferred embodiment of the first, second drive control unit 200, 300.

In addition, the control unit 100 sequentially outputs the first and second switching control signals according to a preset delay time, that is, after outputting the first switching control signal, a predetermined time elapses. The first and second control signals for outputting the second switching control signal are output.

Such operation of the present invention will be described.

First, the control unit 100 receives the first and second control signals for controlling the driving of the first and second inverters 400 and 500, respectively, and the first and second drive control units 200 and 300 respectively. To apply.

That is, the control unit 100 sequentially outputs the first and second control signals according to a preset delay time, that is, the control unit 100 outputs the first switching control signal and then presets the first and second control signals. After a predetermined time, the first and second control signals are output to output the second switching control signal.

Accordingly, the first drive control unit 200 outputs a first switching control signal for driving the first inverter 400 by the first control signal, and the second drive control unit 300. The second control signal outputs a second switching control signal for driving the second inverter 500 by the second control signal.

Here, the first and second switching control signals, the periods are different from each other, the duty is the same signal.

Here, the operation of the first and second drive control units 200 and 300 will be described in detail.

First, when the operation of the first drive control unit 200 is described, the first pulse width modulated signal generating unit 210 generates a pulse width modulated signal having a fixed frequency and duty and applies it to the first drive unit 220. Accordingly, the first driving unit 220 varies the frequency of the pulse width modulated signal applied from the first pulse width modulated signal generating unit 210 and has a first switching control having a frequency according to the frequency varying result. The signal is output and applied to the first inverter 400.

At this time, the second drive control unit 300 is activated after a predetermined time after the first drive unit is operated.

That is, the second pulse width modulated signal generating unit 310 of the second drive control unit 300 generates a pulse width modulated signal having a fixed frequency and duty and applies it to the second drive unit 320. The second driving unit 320 varies the frequency of the pulse width modulation signal applied from the second pulse width modulation signal generating unit 310 and outputs a second switching control signal having a frequency according to the frequency variation result. The second inverter 500 is applied.

Accordingly, the first inverter 400 outputs a current for driving the filament of the magnetron by the first switching control signal output from the first driving unit 220.

Here, the first inverter 400 is, for example, a Class E class resonant inverter, and when the switching element S1 is turned on, a current is excited to the high voltage transformer, and when the switching element S1 is off, the high voltage transformer is turned off. The excited current has an operating characteristic such that the current excited by the resonance capacitor C1 resonates.

By the above-described method, when the switching element (S1) is turned on / off resonates at a predetermined period, the resonant current is induced in the secondary side in proportion to the turn ratio of the high-voltage transformer, the induced current is the filament of the magnetron Drive.

Next, the second inverter 500 outputs a current for oscillating the magnetron of the magnetron by the second switching control signal output from the second driving unit 320.

In this case, the second inverter 500 is driven after a predetermined time (5 seconds) after the first inverter 400 is driven by the second switching control signal, the second inverter 500 also Similar to the first inverter 400, a Class E resonant inverter, in which a current is excited in a high voltage transformer when the switching device S2 is turned on, and a current excited in the high voltage transformer when the switching device S2 is turned off. Is resonated by the resonant capacitor.

In the above-described method, when the switching element is turned on / off, the resonance occurs at a constant cycle, and the resonant current is induced in the secondary side in proportion to the turn ratio of the high voltage transformer.

When the induced current flows from '3' to '4' of the secondary-side high voltage transformer, it flows through the capacitor C8 and the diode D2 and is charged in the capacitor C8, and the induced current is 2 In case of flowing from '4' to '3' of the secondary high voltage transformer, it flows from the anode of the magnetron to the cathode and flows through the diode D3 and the capacitor C8 to form a closed loop to oscillate the magnetron.

That is, the present invention controls the difference between the driving frequency of the filament of the magnetron and the inverter driving the anode at a predetermined interval (3Khz) or more, so as to eliminate the frequency interference between the filament of the magnetron and the inverter driving the anode. will be.

Although the preferred embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope of the claims.

As described above, the present invention has the effect of eliminating frequency interference by eliminating frequency interference by controlling the filament of the magnetron at a predetermined interval of the driving frequency of the inverter for driving the anode, thereby eliminating flicker.

In addition, the present invention by separating the magnetron drive inverter and the filament drive inverter, there is an effect that can be miniaturized by eliminating unnecessary insulation distance.

Claims (9)

In the operation control device in which an inverter for driving the filament of the magnetron and the anode is separated, And a control unit for controlling an operating frequency of an inverter for driving the filament of the magnetron and an inverter for driving the anode of the magnetron to be different by a predetermined interval or more. A first inverter for outputting a current for driving the filament of the magnetron according to the first switching control signal; A second inverter for outputting a current for driving the anode of the magnetron according to the second switching control signal; A first drive control unit for outputting said first switching control signal for controlling the drive of said first inverter by a first control signal; A second drive control unit which outputs the second switching control signal for controlling the drive of the second inverter by a second control signal; And a control unit for outputting first and second control signals for controlling the output of the first and second switching control signals, respectively, in the first and second drive control units. The method of claim 2, wherein the first and second switching control signal, And a duty cycle in which the periods are different from each other and the duty is the same pulse width modulated signal. The method of claim 2, wherein the control unit, And a first and second control signal for sequentially outputting the first and second switching control signals according to a predetermined delay time. The method of claim 4, wherein the control unit, And outputting the second switching control signal after a predetermined time elapses after outputting the first switching control signal. The method of claim 2, wherein the first drive control unit, A first pulse width modulated signal generating unit for generating a pulse width modulated signal having a fixed frequency and duty in accordance with the first control signal; And a first driving unit for varying a frequency of the pulse width modulated signal and outputting a first switching control signal based on the frequency varying result. The method of claim 2, wherein the second drive control unit, A second pulse width modulated signal generating unit for generating a pulse width modulated signal having a fixed frequency and duty in accordance with the second control signal; And a second driving unit for varying a frequency of the pulse width modulated signal and outputting a second switching control signal based on the frequency varying result. In the control method of the operation control device separated from the inverter for driving the filament of the magnetron and the anode, And generating an operating frequency of the inverter for driving the filament of the magnetron and the inverter for driving the anode of the magnetron to be different by a predetermined interval or more. The method of claim 8, wherein the generating of the operating frequency by a predetermined interval or more includes: Operating an inverter for driving the filament of the magnetron at a constant operating frequency; And after a certain time, operating the inverter driving the anode of the magnetron at an operating frequency that differs from the operating frequency of the inverter driving the filament of the magnetron by a predetermined interval or more.

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