KR20010019883A - The method for restarting controlling of microwave lighting system - Google Patents

Abstract

PURPOSE: A restart control method for microwave lighting fixture is provided to reduce the restarting time of the fluorescent lamp and to prevent damage of other elements. CONSTITUTION: The restart control method for microwave lighting fixture includes the steps of radiating(S103) of fluorescent lamp placed within the resonator by using the microwave, stopping(S105) of high voltage supply to the magnetron based on the fluorescent lamp cut off status, measuring(S107) the magnetron temperature, comparing(S108) the measured temperature to the predetermined restart reference temperature for reducing the restarting time, and restarting(S110) the fluorescent lamp by resonating the resonator if the measured temperature reaches to the predetermined restart reference temperature. To radiate fluorescent lamp, the magnetron generates microwave(S102) by applying the high voltage(S101). The fluorescent lamp converts the generated microwave into light.

Description

Restart control method of microwave lighting system {THE METHOD FOR RESTARTING CONTROLLING OF MICROWAVE LIGHTING SYSTEM}

The present invention relates to a restart control method of a microwave lighting system for shortening the restart time of an electrodeless light bulb according to an installation environment (seasonal, weather) in the microwave lighting system, in particular the temperature of the electrodeless light bulb according to the installation environment Microwave lighting system to accurately measure and to restart in the state that the electrodeless bulb temperature is sufficiently low without restarting, and to shorten the restart time of the electrodeless bulb and to prevent damage to the magnetron and other parts The restart control method of the present invention.

In recent years, a microwave illumination system having an electrodeless light bulb disposed in a resonator has been developed, and has attracted attention because of its long life and good luminous efficiency.

FIG. 1 is a block diagram of a restart control apparatus of a conventional microwave lighting system. As shown therein, a magnetron 100 for generating a microwave and an electrodeless bulb 102 therein are provided, A resonator 103 for resonating a wave and discharging the converted light to the maximum when the microwave energy is converted into light in the bulb 102, and the resonator 103 for microwaves generated from the magnetron 100. The wave guide 104 and the rectifying unit 106 for lowering the commercial AC power (AC) input through the plug 105 to a sufficiently low level, rectifying it and converting it into a DC voltage and outputting the same, Standby power supply unit 107 for accumulating rectified DC voltage, operation panel 108 for generating various functional data, voltage and standby power of rectifier 106 A timer 109 operating by the accumulated voltage of the supply unit 107 to count time, and a controller 110 that compares the time counted by the timer 109 with the set restart time and generates a control signal accordingly. And a high pressure generator 101 for boosting the commercial AC power QAC input through the plug 105 to the magnetron 100 under the control of the controller 110.

Looking at the prior art configured as described above is as follows.

First, the commercial AC power source AC is input to the high voltage generator 101 and the rectifier 106 through the plug 105.

Then, the rectifying unit 106 downs the input commercial AC power to a constant level of AC voltage, rectifies and smoothes it and supplies it to the standby power supply unit 107 such as a large capacity capacitor, as well as a timer 109 and Supply to the control unit 110, respectively.

Here, the standby power supply unit 107 accumulates the voltage input from the rectifying unit 106 and stores the accumulated voltage only in the timer 109 and when the plug 105 is disconnected from an outlet not shown in the drawing. Supply to the control unit 110.

In this state, when the starter key is inputted to start the electrodeless bulb 102 in the resonator 103 from the operation panel 108, the controller 110 operates by the voltage supplied from the rectifying unit 106. To control the high pressure generator 101.

The high pressure generating unit 101 supplies the high pressure generated by boosting the commercial AC power (AC) input from the plug 105 by the control of the control unit 110 to the magnetron (100).

Accordingly, the magnetron 100 oscillates by high pressure to concentrate the microwave having a very high frequency to the electrodeless bulb 102 in the resonator 103 through the wave guide 104.

In connection with this, the electrodeless bulb 102 absorbs the energy of microwaves to generate light.

At this time, when the electrodeless bulb 102 emits light, the center temperature of the bulb 102 rises to thousands of degrees.

Therefore, in order to turn off the electrodeless bulb 102 and turn it on again, the controller 110 stops the operation of the high pressure generator 101 to start the electrodeless bulb 102 in order to lower the temperature of the bulb below a certain level. To finish.

Then, when the instruction is made through the operation panel 108 to start again, the controller 110 counts the current time through the timer 109 from the time point at which the electrodeless bulb 102 starts to start, and then restarts the set time. Compare with time.

When the reset time, for example, approximately 10 minutes, elapsed when the time read by the timer 109 has elapsed, the controller 110 controls the high pressure generator 101 to apply high pressure to the magnetron 100, as described above. The electrodeless bulb 102 in the resonator 103 is restarted by the energy of the microwave generated from the magnetron 100 to emit light.

In addition, since the time must be counted continuously even when the plug 105 is unplugged from an outlet not shown in the drawing, the timer 109 uses the power stored in the standby power supply unit 107 such as a large capacity capacitor. By providing to the timer, the timer 109 continues to count time.

In this way, the restart control device of the microwave illumination system uses a timer to measure the time from when the electrodeless bulb stops emitting light, and when a certain time elapses, the magnetron is started to restart the electrodeless bulb in the resonator. It can be seen that.

However, the restart control apparatus of the conventional microwave lighting system as described above is that the temperature of the electrodeless bulb disposed in the resonator depends significantly on the installation environment, especially summer and winter.

For example, if the season is winter, there is a time delay in which the electrodeless bulb must wait until the restart time has elapsed even though it has cooled sufficiently to be restartable by the surrounding cold temperature. In the summer, when the temperature of the electrodeless bulb is not sufficiently cooled by the surrounding temperature, the electrodeless bulb is restarted immediately after the restarting time has elapsed, thereby causing the problem of the above-described magnetron and other parts being damaged. have.

In addition, in the case of unplugging the power cord by using a standby power supply such as a large-capacity capacitor, the price of the product is increased, and the structure also has a problem that is complicated.

Accordingly, an object of the present invention to solve the conventional problems as described above is to restart the control method of the microwave lighting system to provide a low-cost lighting system in terms of cost, and a more efficient and stable lighting system in terms of reliability. In providing.

Another object of the present invention is to provide a restart control method of the microwave lighting system to start the electrodeless bulb by adjusting the restart time according to the installation environment.

Still another object of the present invention is to accurately measure the temperature of an electrodeless bulb that depends on the installation environment, and to restart the electrodeless bulb in a state where the temperature of the electrodeless bulb is sufficiently dropped, without restarting the electrodeless bulb. The present invention provides a restart control method of a microwave lighting system to shorten the restart time of the battery and to prevent damage to the magnetron and other components.

Still another object of the present invention is to provide a restart control method of a microwave lighting system, which minimizes power consumption by not restarting in a non-restartable state of an electrodeless bulb.

Another object of the present invention is to provide a restart control method of a microwave lighting system to simplify the price and system implementation of the product by not using a large capacity capacitor and a timer.

1 is a block diagram of a restart control device of a conventional microwave lighting system.

Figure 2 is a block diagram of a restart control device of the present invention microwave lighting system.

3 is an operation flowchart for a restart control method of the microwave lighting system of the present invention.

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

100: magnetron 101: high pressure generating unit

102 electrodeless bulb 103 resonator

104: waveguide 107: standby power supply unit

108: operation panel 109: timer

110,200: control unit 201: magnetron temperature detection sensor

202: sensor signal processing unit

The present invention for achieving the object as described above is a first step of emitting a non-electrode bulb in the resonator by microwaves generated from the magnetron at high pressure supply, and determines the starting blocking state of the electrodeless bulb to determine the high pressure of the magnetron A second step of stopping the supply, a third step of measuring the temperature of the magnetron when restarting the starter of the electrodeless bulb in the resonator, and comparing the measured measurement temperature with the preset restart reference temperature A fourth step and a fifth step of measuring the temperature until the reference temperature is reached if the measured temperature is higher than the reference temperature, and restarting the electrodeless bulb in the resonator by oscillating the magnetron when the restarted reference temperature is reached. It is characterized by.

Hereinafter, with reference to the accompanying drawings in detail as follows.

FIG. 3 is a flowchart illustrating a restart control method of the microwave lighting system of the present invention. As shown in FIG. 3, a step of supplying a high pressure to the magnetron to generate a microwave (S101 and S102), and Emitting an electrodeless bulb in the resonator by the energy of microwaves (S103), lowering the central temperature of the electrodeless bulb by cutting off the high pressure supplied to the magnetron when the light emitting off key is input from the outside (S105); The step of measuring the temperature of the magnetron when the restart key is input (S107), and comparing the measured measurement temperature and the preset restart reference temperature (S108), and if the measured temperature is higher than the reference temperature reaches the reference temperature Measure the temperature until the magnetron oscillates when the restarted reference temperature is reached and restart the electrodeless bulb in the resonator. In operation S110, the light emission is performed.

Restart control apparatus of the microwave illumination system for performing the method consisting of each step in the above, as shown in Figure 2, the magnetron 100 for generating a microwave, and the magnetron by generating a high pressure at the external power input It has a high-pressure generator 101 for supplying to the 100, and the electrodeless bulb 102 inside, resonating the supplied microwave, the converted light when the microwave energy is converted into light in the bulb 102 The resonator 103 to discharge the maximal outward, the wave guide 104 for guiding the microwaves generated by the magnetron 100 to the resonator 103, and the electric energy by detecting the temperature of the magnetron 100. The magnetron temperature detection sensor 201 and the electrical signal obtained from the magnetron temperature detection sensor 201 The sensor signal processing unit 202 for outputting the shaping signal and the brightness of the electrodeless light bulb are recognized according to the level of the waveform obtained by the sensor signal processing unit 202, and the high voltage generator 101 is used according to the recognized brightness. The controller 200 is configured to determine whether the magnetron is started and suppressed.

Referring to the operation and effect of the present invention configured as described in detail as follows.

First, when the operation panel 108 is operated to input the control unit 200 to activate the microwave illuminating device, the control unit 200 initially controls the high pressure generating unit 101.

Accordingly, the high pressure generating unit 101 operates to boost the commercial AC power input from the outside to high pressure and supply the same to the magnetron 100. (FIG. 3, S101)

The magnetron 100 is oscillated by the high pressure generated by the high-pressure generator 101, the microwave having a very high frequency is installed in the resonator 103 through the wave guide 104, the plasma generating medium is sealed Transfer to the electrode bulb 102. (S102)

Along with this, the electrodeless light bulb 102 absorbs the energy of microwaves to emit light, and the light is emitted to the outside by the resonator 103 (S103).

At this time, when the electrodeless bulb 102 emits light, the center temperature of the electrodeless bulb 102 rises to several thousand degrees due to heating due to microwave energy.

In such a state, when the start-off key of the operation panel 108 is input to turn off the start of the electrodeless light bulb 102 (S104), the controller 200 controls the high pressure generator 101 to control the magnetron 100. Blocks high pressure generation. (S105)

Then, the high pressure applied to the magnetron 100 is cut off, and as a result, the starting of the electrodeless light bulb 102 is turned off.

At this time, if the ignition key for turning on the electrodeless bulb 102 is input again from the operation panel 108 after a short time (S106), the controller 200 controls the temperature of the magnetron through the magnetron temperature detection sensor 201. (S107)

Here, there is a limit in measuring the temperature of the electrodeless bulb 102 in a non-contact manner, which makes it difficult to precisely control the temperature. Therefore, in order to precisely control, the temperature of the magnetron and the temperature of the electrodeless bulb change in proportion, and the magnetron temperature detection sensor 201 is mounted on the magnetron 100 to measure the temperature of the magnetron in a contact manner. The temperature of the electrodeless bulb is inferred by the input temperature proportional expression.

Therefore, the magnetron temperature detection sensor 201 detects the temperature of the magnetron in a contact manner, and supplies an electrical signal corresponding to the detected temperature to the sensor signal processing unit 202.

Accordingly, the sensor signal processing unit 202 waveform-forms an electrical signal corresponding to the temperature input from the magnetron temperature detection sensor 201 and transmits the waveform to the control unit 200.

Thereafter, the controller 200 infers the bulb temperature previously inputted with the levels of the input waveform.

This analogy is compared with the restart reference temperature set according to the temperature of the electrodeless bulb and the installation environment (seasonal, weather, etc.) (S108).

As a result of the comparison, if the current measurement temperature of the bulb is above the restart reference temperature, the temperature of the electrodeless bulb 102 is continuously measured until the temperature drops, and if the current measurement temperature of the bulb falls below the restart reference temperature, the high pressure generator ( 101 to control the supply of high pressure to the magnetron 100. (S109)

As a result, the magnetron 100 oscillates to concentrate the microwaves on the electrodeless bulb 102 in the resonator 103, so that the electrodeless bulb 102 is restarted.

In addition, when the electrodeless bulb 102 is automatically healed after being turned off by other causes, or when the power plug is unplugged and reinserted momentarily, the magnetron temperature is detected as described above without restarting. If the temperature of the proportional bulb falls below a certain level, ie, below the restart reference temperature, restart.

As described in detail above, the present invention continuously measures the temperature in the resonator depending on the installation environment, and restarts the electrodeless bulb only when the measured temperature drops below a certain level. There is an effect that the restart time of the electrode bulb is sufficiently shortened and the damage of the magnetron and other parts does not occur.

Claims (2)

A microwave lighting system in which a microwave is supplied to an electrodeless bulb in a resonator when a high voltage is generated, and the energy of the supplied microwave is converted into an energy of a light by the electrodeless bulb. A first step of causing the electrodeless bulb to emit light for a predetermined time; a second step of stopping the supply of the high pressure of the magnetron by determining the starting blocking state of the electrodeless bulb in the resonator; and restarting in the starting blocking state of the electrodeless bulb in the resonator And a third step of measuring a temperature in the resonator, a fourth step of comparing the measured temperature with a preset restart reference temperature, and if the measured temperature is higher than the reference temperature, measuring the temperature until reaching the reference temperature. When the restart reference temperature is reached, the magnetron is started to restart the electrodeless bulb in the resonator. Restart control method of the microwave lighting system, it characterized in that the fifth step consisting of copper. The method of controlling a restart of a microwave lighting system according to claim 1, wherein the measured temperature is detected by a contact through a magnetron temperature sensor.