KR100839848B1 - Driving control apparatus and method - Google Patents

Abstract

An apparatus and a method of driving control are provided to improve light emission efficiency by applying a predetermined current to a magnetron by varying a duty ratio of a pulse width modulation signal. An apparatus of driving control includes an input current detecting unit(60), a switch current detecting unit(50), and a pulse width modulation signal generating unit(70). The input current detecting unit detects an input current. The switch current detecting unit detects a current flowing on a switch of an inverter(20). The pulse width modulation signal generating unit varies a duty of a pulse width modulation signal for switching the switch of the inverter by comparing the input current and the switch current.

Description

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

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

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

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

100: power supply unit 200, 300: inverter

400: magnetron drive unit 500: magnetron

600: first drive control unit 610: first switch current detection unit

620: first pulse width modulation signal generation unit 630: first input current detection unit

700: second drive control unit 710: second switch current detection unit

720: second pulse width modulated signal generation unit 730: second input current detection unit

800: control unit

The present invention relates to a driving control apparatus, and to a driving control apparatus and method for applying a constant current to the magnetron to improve the luminous efficiency.

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. High pressure transformers should be molded with due consideration.

Here, the plasma lighting apparatus for driving the magnetron, in order to improve the light efficiency in terms of matching the bulb and the magnetron should drive the magnetron in a pulse type.

However, since the operation control apparatus of the conventional electrodeless lighting device does not drive the magnetron in a pulse type, the current applied to the magnetron is not constant according to the switching of the inverter, and thus the luminous efficiency of the electrodeless lighting device is lowered. There is a problem.

That is, in the related art, the operation control apparatus of the electrodeless lighting device uses a half bridge inverter in driving the magnetron, which cannot implement the magnetron in a pulse type due to its operation characteristics.

The present invention has been made to solve the problems of the prior art as described above, and compares the switch current and the input current flowing through the inverter, and varying the duty ratio of the pulse width modulated signal to switch the inverter on and off according to the comparison result It is therefore an object of the present invention to provide an operation control apparatus and method for applying a constant current to a magnetron to improve luminous efficiency.

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

An input current detection unit detecting an input current;

A switch current detection unit detecting a current flowing through a switch of the inverter;

And a pulse width modulated signal generation unit for comparing the input current with the switch current and varying the duty of the pulse width modulated signal for switching the switch of the inverter according to the comparison result.

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

In the operation control apparatus provided with the 1st inverter which drives the filament of a magnetron, and the 2nd inverter which drives the anode of a magnetron, respectively,

An input current detection unit detecting an input current;

The first switch current and the second switch current flowing through the switches of the first inverter and the second inverter are respectively detected, and the detected first and second switch currents are compared with the input currents, and the first switch current is determined according to the comparison result. It characterized in that it comprises a first drive control unit for controlling the switching of the second inverter, respectively.

Here, the first drive control unit,

A first switch current detecting unit detecting a first switch current flowing through the switch of the first inverter;

And a first pulse width modulated signal generating unit for comparing the first switch current with the input current and varying the duty ratio of the pulse width modulated signal based on the comparison result.

The first pulse width modulation signal generating unit,

When the input current is greater than the first switch current, the duty ratio of the pulse width modulated signal for switching the switch of the first inverter is reduced,

When the input current and the first switch current is less than, the duty ratio of the pulse width modulation signal for switching the switch of the first inverter is characterized in that to increase.

The second drive control unit,

A second switch current detecting unit detecting a second switch current flowing through the switch of the second inverter;

And a second pulse width modulated signal generation unit for comparing the second switch detection unit with the input current and varying the duty ratio of the pulse width modulated signal based on the comparison result.

The second pulse width modulation signal generating unit,

When the input current is greater than the second switch current, the duty ratio of the pulse width modulated signal for switching the switch of the second inverter is reduced,

When the input current and the second switch current is less than, the duty ratio of the pulse width modulation signal for switching the switch of the second inverter is increased.

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

An input current detection process for detecting an input current;

A switch current detection process of detecting a current flowing through a switch of the inverter;

And comparing the input current with the switch current and performing a duty variable process of varying the duty of the pulse width modulated signal for switching the switch of the inverter according to the comparison result.

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

In the control method of the operation control apparatus provided with the 1st inverter which drives the filament of a magnetron, and the 2nd inverter which drives the anode of a magnetron, respectively,

An input current detection process for detecting an input current;

A switch current detection process of detecting first and second switch currents flowing through the switches of the first and second inverters;

A duty variable process of comparing the input current with the first and second switch currents and varying the duty of the first and second pulse width modulation signals for switching the switches of the first and second inverters according to the comparison result; Characterized by performing.

Here, the duty variable process,

Reducing the duty ratio of the first and second pulse width modulated signals for switching the switches of the first and second inverters when the input current is greater than the first and second switch currents;

And increasing the duty ratio of the first and second pulse width modulated signals for switching the switches of the first and second inverters when the input current is smaller than the first and second switch currents.

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 block diagram showing a configuration of an embodiment of the operation control apparatus of the present invention.

As shown in FIG. 1, the power supply unit 10, the inverter 20, the magnetron drive unit 30, the magnetron 40, the switch current detection unit 50, the input current detection unit 60, and pulse width modulation The signal generating unit 70 and the control unit 80 are provided.

The power supply unit 10 provides an operating power source for operating the magnetron 40.

The inverter 20 is switched by a pulse width modulation signal to output a current for driving the magnetron 40.

The magnetron driving unit 30 generates a high voltage by the current output from the inverter 20, and drives the magnetron 40 by the high voltage.

The switch current detection unit 50 detects a switch current flowing through the switch of the inverter 20.

The input current detection unit 60 detects an input current applied to the inverter 20.

The pulse width modulated signal generating unit 70 compares the input current with the switch current, and varies the duty of the pulse width modulated signal for controlling the switching of the inverter 20 based on the comparison result. .

Here, the pulse width modulation signal generating unit 70 reduces the duty ratio of the pulse width modulation signal for switching the switch of the inverter 20 when the input current is greater than the switch current, the input current is less than the switch current In this case, the duty ratio of the pulse width modulated signal for switching the switch of the inverter 20 is increased and output. At this time, the frequency of the pulse width modulated signal is fixed.

In this case, the magnetron 40 may control the duty of the pulse width modulated signal output from the pulse width modulated signal generating unit 70, thereby improving optical efficiency. That is, even if the voltage or current of the system is unstable due to changes in the external environment, the light efficiency can be improved by supplying a constant current to the magnetron.

The control unit 80 controls the magnetron to disable the operation of the pulse width modulation signal in order to prevent damage due to overvoltage or overcurrent, or external environment.

Such an operation of an embodiment of the present invention will be described.

First, power is supplied to the inverter 20 according to a start command of the first user, and the inverter 20 is switched by a preset pulse lock modulation signal (having a duty ratio preset according to the amount of light emitted by the magnetron). Drive 40).

In this state, the switch current detection unit 50 detects the switch current of the inverter 20 and applies it to the pulse width modulation signal generation unit 70, and the input current detection unit 60 supplies the inverter 20. The applied input current is detected and applied to the pulse width modulated signal generating unit 70.

Accordingly, the pulse width modulated signal generating unit 70 compares the switch current and the input current, and varies the duty ratio of the pulse width modulated signal according to the comparison result and applies it to the switch element of the inverter 20. do.

At this time, the pulse width modulation signal generating unit 70 reduces the duty ratio of the pulse width modulation signal for switching the switch of the inverter 20 when the input current is greater than the switch current, the input current is less than the switch current If the duty ratio of the pulse width modulation signal for switching the switch of the inverter 20 is increased.

Accordingly, the inverter 20 is switched by the pulse width modulation signal to apply a driving current to the magnetron driving unit 30, wherein the inverter 20 is provided with a high voltage transformer at a predetermined turns ratio A corresponding current is applied to the magnetron driving unit 30.

 Accordingly, the magnetron driving unit 30 applies a constant current to the magnetron 40, the magnetron 40 is driven by the constant current.

2 is a block diagram showing the configuration of another embodiment of the operation control device of the present invention, by separating the inverter for driving the magnetron and the inverter for driving the filament of the magnetron, so as to avoid the frequency interference generated when using the inverter The configuration can be prevented.

As shown in FIG. 2, the power supply unit 100, the first inverter 200, the second inverter 300, the magnetron driving unit 400, the magnetron 500, the first driving control unit 600, and the first 2, drive control unit 700 and control unit 800 are provided.

The power supply unit 100 provides an operating power source for operating the magnetron 500.

The first inverter 200 is switched by the first pulse width modulation signal to output a current for driving the filament of the magnetron 500.

The second inverter 300 is switched by the second pulse width modulation signal to apply a current for driving the magnetron 50 to the magnetron driving unit 400.

The magnetron driving unit 400 generates a high voltage by the current output from the second inverter 300, and drives the magnetron 500 by the high voltage.

The first driving control unit 600 detects a first switch current flowing through a switch of the first inverter 200, and compares the detected first switch current with an input current to determine the first switch current. 1 Controls the switching of the inverter 200.

Here, the first driving control unit 600 detects the first input current detecting unit 630 for detecting the input current and the first switch current detecting the first switch current flowing through the switch of the first inverter 200. The unit 610 includes a first pulse width modulated signal generating unit 620 for comparing the first switch current with the input current and varying the duty ratio of the pulse width modulated signal based on the comparison result. .

The pulse width modulation signal generation unit 620 reduces the duty ratio of the pulse width modulation signal for switching the switch of the first inverter 200 when the input current is greater than the first switch current, the input current is the first If it is smaller than the switch current, the duty ratio of the pulse width modulated signal for switching the switch of the first inverter 200 is increased.

The second drive control unit 700 includes a second input current detection unit 730 for detecting an input current, and a second switch current detection unit for detecting a second switch current flowing through a switch of the second inverter 300 ( 710, a second pulse width modulated signal generating unit 720 for comparing the second switch current with the input current and varying the duty ratio of the second pulse width modulated signal based on the comparison result; .

The pulse width modulation signal generation unit 720 reduces the duty ratio of the pulse width modulation signal for switching the switch of the second inverter 300 when the input current is greater than the second switch current, the input current is a second If less than the switch current, the duty ratio of the second pulse width modulated signal for switching the switch of the second inverter 300 is increased.

The control unit 800 controls the operation of the pulse width modulated signal generating unit to protect the device having the magnetron from external factors (overcurrent, overvoltage, etc.).

This invention will be described from the operation of driving the filament of the magnetron.

First, power is supplied to the first and second inverters 200 and 300 by a start command of the first user, and the first and second pulse lock modulation signals (having a duty ratio preset according to the light emission amount of the magnetron) are preset. As a result, the first and second inverters 200 and 300 are switched to drive the magnetron 500.

In this state, the first drive control unit 600 detects the first switch current flowing through the switch of the first inverter 200, and compares the detected first switch current with the input current to the comparison result. Accordingly, the switching of the first inverter 200 is controlled.

Here, when the operation of the first drive control unit 600 will be described in more detail, first, the first input current detection unit 630 detects an input current applied to the first inverter 200, and the first switch current. The detection unit 610 detects the first switch current flowing through the switch of the first inverter 200 and applies it to the first pulse width modulation signal generation unit 620.

Accordingly, the first pulse width modulated signal generating unit 620 compares the first switch current with the input current, and varies the duty ratio of the pulse width modulated signal based on the comparison result.

That is, the pulse width modulation signal generation unit 620 reduces the duty ratio of the pulse width modulation signal for switching the switch of the first inverter 200 when the input current is greater than the first switch current, the input current is If less than the first switch current, the duty ratio of the first pulse width modulated signal for switching the switch of the first inverter 200 is increased.

Accordingly, the first inverter 200 is switched by the first pulse width modulation signal to drive the filament of the magnetron 500 with the driving current according to the first inverter 200.

On the other hand, the operation for starting the magnetron will be described. At this time, after the filament of the magnetron is operated, the magnetron is operated with a predetermined delay time (about 5 seconds) to oscillate.

First, the second drive control unit 700 detects the second switch current flowing through the switch of the second inverter 300, and compares the detected second switch current with the input current according to the comparison result. The switching of the second inverter 300 is controlled.

Here, if the operation of the second drive control unit 600 will be described in more detail, first, the second input current detection unit 730 detects an input current applied to the second inverter 300, and the second switch current. The detection unit 710 detects a second switch current flowing through the switch of the second inverter 200 and applies it to the second pulse width modulation signal generation unit 720.

Accordingly, the second pulse width modulated signal generating unit 720 compares the second switch current with the input current, and varies the duty ratio of the pulse width modulated signal based on the comparison result.

That is, the pulse width modulation signal generation unit 720 reduces the duty ratio of the second pulse width modulation signal for switching the switch of the second inverter 300 when the input current is greater than the second switch current, the input If the current is less than the second switch current, the duty ratio of the second pulse width modulated signal for switching the switch of the second inverter 300 is increased.

Accordingly, the second inverter 300 is switched by the second pulse width modulated signal to apply the driving current to the magnetron driving unit 400, wherein the inverter 300 is provided with a high voltage transformer. A current corresponding to a predetermined turns ratio is applied to the magnetron driving unit 400.

 Accordingly, the magnetron driving unit 400 applies a constant current to the magnetron 500, the magnetron 500 is driven by the constant current.

Here, the first and second inverters 200 and 300 use Class E class resonant inverters.

 That is, the present invention compares and changes the duty ratio of the pulse width modulated signal for driving the switch of the filament of the magnetron and the inverter for driving the anode and the input current by comparing the input current (current generated during switching of the inverter) with the magnetron, The magnetron is driven at a constant current to improve luminous efficiency.

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 compares the switch current flowing through the inverter with the input current, and applies a constant current to the magnetron by varying the duty ratio of the pulse width modulated signal for switching the inverter on and off according to the comparison result. Therefore, there is an effect of improving the luminous efficiency.

Claims (14)

An input current detection unit detecting an input current; A switch current detection unit detecting a current flowing through a switch of the inverter; And a pulse width modulation signal generating unit for comparing the input current with the switch current and varying the duty of the pulse width modulation signal for switching the switch of the inverter according to the comparison result. According to claim 1, wherein the pulse width modulation signal generating unit, When the input current is greater than the switch current, the duty ratio of the pulse width modulated signal for switching the switch of the inverter is reduced, And the duty ratio of the pulse width modulated signal for switching the switch of the inverter when the input current is smaller than the switch current. According to claim 1, wherein the pulse width modulation signal generating unit, Operation control device for outputting pulse width modulated signal with fixed frequency. In the operation control apparatus provided with the 1st inverter which drives the filament of a magnetron, and the 2nd inverter which drives the anode of a magnetron, respectively, An input current detection unit detecting an input current; The first switch current and the second switch current flowing through the switches of the first inverter and the second inverter are respectively detected, and the detected first and second switch currents are compared with the input currents, and the first switch current is determined according to the comparison result. And a first and second drive control unit for respectively controlling switching of the second inverter. The method of claim 4, wherein the first drive control unit, A first switch current detecting unit detecting a first switch current flowing through the switch of the first inverter; And a first pulse width modulated signal generating unit for comparing the first switch current with the input current and varying the duty ratio of the pulse width modulated signal based on the comparison result. The method of claim 5, wherein the first pulse width modulation signal generating unit, When the input current is greater than the first switch current, the duty ratio of the pulse width modulated signal for switching the switch of the first inverter is reduced, And a duty ratio of a pulse width modulated signal for switching a switch of the first inverter when the input current and the first switch current are smaller than the input current. The method of claim 4, wherein the second drive control unit, A second switch current detection unit detecting a second switch current flowing through the switch of the second inverter; And a second pulse width modulated signal generating unit for comparing the second switch detecting unit with the input current and varying the duty ratio of the pulse width modulated signal based on the comparison result. The method of claim 7, wherein the second pulse width modulation signal generating unit, When the input current is greater than the second switch current, the duty ratio of the pulse width modulated signal for switching the switch of the second inverter is reduced, And a duty ratio of a pulse width modulated signal for switching a switch of the second inverter when the input current and the second switch current are smaller than the input current. An input current detection process for detecting an input current; A switch current detection process of detecting a current flowing through a switch of the inverter; And a duty varying process for comparing the input current with the switch current and varying the duty of the pulse width modulated signal for switching the switch of the inverter according to the comparison result. The method of claim 9, wherein the duty variable process, Reducing a duty ratio of a pulse width modulated signal for switching a switch of the inverter when the input current is greater than a switch current; And increasing the duty ratio of the pulse width modulated signal for switching the switch of the inverter when the input current is smaller than the switch current. The pulse width modulated signal of claim 9 or 10, wherein Operation control method of an electrodeless lighting device that is a fixed frequency signal. In the control method of the operation control apparatus provided with the 1st inverter which drives the filament of a magnetron, and the 2nd inverter which drives the anode of a magnetron, respectively, An input current detection process for detecting an input current; A switch current detection process of detecting first and second switch currents flowing through the switches of the first and second inverters; A duty variable process of comparing the input current with the first and second switch currents and varying the duty of the first and second pulse width modulation signals for switching the switches of the first and second inverters according to the comparison result; Operation control method comprising. The method of claim 12, wherein the duty variable process, Reducing the duty ratio of the first and second pulse width modulated signals for switching the switches of the first and second inverters when the input current is greater than the first and second switch currents; And increasing the duty ratio of the first and second pulse width modulation signals for switching the switches of the first and second inverters when the input current is less than the first and second switch currents. The method of claim 12 or 13, wherein the first and second pulse width modulated signal is Operation control method of an electrodeless lighting device that is a fixed frequency signal.

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