KR20030049251A - Apparatus for supplying power of gas pipe - Google Patents

Abstract

PURPOSE: A power supply of a gas pipe having a blackening prevention function is provided to prevent the drop form and the blackening by mixing a low frequency with a high frequency and controlling a duty ratio to supply power to the gas pipe. CONSTITUTION: A high-frequency duty control unit(10) clamps a waveform of an AC(Alternating Current) input power by a predetermined level and controls a high-frequency duty rate to provide it to a high-frequency switching unit(30). A DC(Direct Current) control unit(20) restricts a level of a DC voltage outputted from a bridge diode(BD1) and modulates a pulse width to provide it to the high-frequency switching unit(30) at low frequency. The high-frequency switching unit(30) mixes the high frequency and the low frequency outputted from the high-frequency duty control unit(10) and the DC control unit(20) to generate a high-frequency switching signal and transmit it to a high-voltage transformer driving unit(40).

Description

Apparatus for supplying power of gas pipe}

The present invention relates to a power supply of the gas pipe, in particular, the low-frequency and high-frequency mixing, the duty ratio (Duty Ratio) automatically adjusts the supply of power to the gas pipe (neon tube and argon tube) condensation occurs inside the tube The present invention relates to a power supply device for a gas pipe to prevent excessive blackening.

In general, the power supply of the neon tube and the argon tube is mainly composed of a mechanical core and a coil type, but in recent years, due to the development of components and industrial development, electronic power is converted into an electronic system using high frequency. It is a trend.

However, the conventional electronic neon tube (argon tube) power supply device as described above uses a high voltage and a high frequency, and a potential difference occurs due to a difference in the length of the output line according to the frequency, causing the following problems.

First, in the case of a neon tube to which an electronic power supply is applied, pea water droplets are formed inside the tube.

Second, in the case of the argon tube to which the electronic power supply is applied, the blackening phenomenon of the end of the tube gradually darkens.

That is, in the case of using a low frequency, even if the output line is slightly different because the frequency is low, blackening does not occur because the potential difference between the two ends of the tube is minute.

However, in the case of using a high frequency, if the length of the output line differs depending on the frequency, the potential difference between the two ends of the tube is relatively large, and mercury moves from the lower potential to the higher potential, causing the blackening phenomenon to occur remarkably as time passes.

When blackening occurs in the tube, the illuminance is relatively low, and the user must replace it with a new tube, in which case the user is economically burdened.

Accordingly, the present invention is proposed to prevent the water droplet flow phenomenon occurring in the conventional neon tube and the blackening phenomenon occurring in the argon tube.

An object of the present invention is to mix the low frequency and high frequency, and automatically adjust the duty ratio, and then supply power to the gas tube (neon tube and argon tube) to prevent the condensation and blackening occurring inside the tube. To provide a power supply.

The "gas pipe power supply device" according to the present invention for achieving the above object,

A bridge diode which full-wave rectifies the input AC power and outputs the DC voltage, a high voltage transformer driving unit for driving the high voltage transformer, and a gas tube (neon tube or argon tube) emitting light with the power output from the secondary side of the high voltage transformer. Gas pipe power supply of the,

A high frequency duty adjuster for clamping a waveform of the input AC power to a predetermined level and adjusting a high frequency duty ratio to provide a high frequency switching unit at a rear stage thereof;

A DC control unit for limiting the level of the DC voltage output from the bridge diode and modulating a pulse width to provide the high frequency switching unit at a low frequency;

And a high frequency switching unit for generating a high frequency switching signal and transmitting the high frequency switching signal to the high voltage transformer driver by mixing the high frequency and the low frequency output from the high frequency duty controller and the DC controller.

The high frequency duty adjustment unit,

A plurality of clamping diodes for clamping waveforms of the AC power input to a predetermined level;

A resistor and a capacitor for generating an oscillation frequency with an alternating current power source clamped by the plurality of clamping diodes;

And a pulse width modulator for adjusting the duty ratio of the high frequency by adjusting the pulse width of the high frequency in response to the oscillation frequency generated by the resistor and the capacitor.

The DC control unit,

A monostable multivibrator that maintains a metastable state for a predetermined time according to a time constant when a trigger signal is applied;

A resistor and a capacitor for generating an oscillation frequency corresponding to the output signal of the monostable multivibrator;

And a pulse width modulator for adjusting the duty ratio of the low frequency by adjusting the pulse width of the low frequency in response to the oscillation frequency generated by the resistor and the capacitor.

1 is a circuit diagram showing the configuration of a power supply of a gas pipe according to the present invention,

FIG. 2 is a circuit diagram illustrating an embodiment of the high frequency duty controller of FIG. 1.

3 is a circuit diagram illustrating an embodiment of the DC control unit of FIG. 1.

<Explanation of symbols for the main parts of the drawings>

10 ..... High Frequency Duty Adjuster

11 ..... Pulse Width Modulator

20 ..... DC Control

21 ..... Monostable Multivibrator

22 ..... Pulse Width Modulator

30 ..... high frequency switching unit

Hereinafter, described in detail with reference to the accompanying drawings, preferred embodiments of the present invention according to the technical spirit as described above.

1 is a circuit diagram showing a configuration of a power supply device for a gas pipe according to the present invention.

Here, reference numeral SW1 denotes a power switch, reference numeral F1 denotes a fuse to short circuit when a high voltage is introduced, and reference numeral TNR denotes a semiconductor element for power control, and reference numeral BD1 denotes an input AC power source. It shows a bridge diode which is full-wave rectified and converted to DC power.

In addition, reference numeral 10 denotes a high frequency duty adjusting unit for clamping the waveform of the input AC power to a predetermined level and then adjusting the high frequency duty ratio to provide the high frequency switching unit 30 at a later stage, and the reference numeral 20 denotes the bridge diode ( BD1) indicates a DC control unit that limits the level of the DC voltage output from the BD1 and modulates a pulse width to provide the high frequency switching unit 30 at a low frequency, and reference numeral 30 denotes the high frequency duty controller 10 and the DC controller 20. The high frequency switching unit generates a high frequency switching signal by mixing the high frequency and the low frequency output from the high frequency switching unit 40 to be described later.

In the figure, reference numeral 50 denotes a high voltage transformer (HVT) for supplying a high pressure to the gas pipe, R denotes a resistor, and C denotes a capacitor.

In the power supply of the gas pipe according to the present invention configured as described above, first, when the power switch SW1 is turned on, the AC power input AC120V to AC220V input through the fuse F1 and then full-wave rectified through the bridge diode BD1. And converted to a DC voltage, smoothed by the smoothing capacitor C3, and supplied to the collector terminals of the first switching element Q1 in the DC control unit 20 and the high voltage transformer driver 40 through the resistor R1. .

As illustrated in FIG. 3, the DC control unit 20 maintains a metastable multivibrator for a predetermined time according to the time constant R23 * C22 when a trigger signal TRIG is applied through the diode D22. And the oscillation generated by the resistor and capacitor (RT2) (CT2) and the resistor and capacitor (RT2) (CT2) for generating an oscillation frequency corresponding to the output signal of the monostable multivibrator (21). The pulse width modulator 22 adjusts the low frequency duty ratio by adjusting the pulse width of the low frequency corresponding to the frequency.

The DC control unit 20 configured as described above outputs a pulse from the monostable multivibrator 21 according to the time constant (R23 * C22), and the output pulse is applied to the time constant by the resistor and the capacitor (RT2) (CT2). Is transmitted to the pulse width modulator 22 at the oscillation frequency.

The pulse width modulator (PWM) 22 adjusts the pulse width of the direct current voltage DC15V limited by the diode D23 based on the oscillation frequency and transmits the pulse width to the high frequency switching unit 30 at low frequency.

Next, as illustrated in FIG. 2, the high frequency duty controller 10 includes a plurality of clamping diodes CD1 and CD2 for clamping a waveform of an input AC power to a predetermined level, and the plurality of clamping diodes CD1. A pulse width of a high frequency is generated in response to a resistor and a capacitor (RT1) (CT1) for generating an oscillation frequency with an AC power clamped by (CD2), and an oscillation frequency generated by the resistor and the capacitor (RT1) (CT1). And a pulse width modulator 11 for adjusting the duty ratio of the high frequency by adjusting.

The high frequency duty controller 10 configured as described above clamps the waveform to the plurality of clamping diodes CD1 and CD2, and sets the oscillation frequency to the time constant set by the resistor and the capacitor CT1 and RT1. It is generated and input to the pulse width modulator 11. The pulse width modulator 11 adjusts the duty of the high frequency corresponding to the input oscillation frequency, and then inputs the high frequency whose duty is adjusted to the high frequency switching unit 30.

The high frequency switching unit 30 alternately switches the two switching elements Q1 and Q2 in the high voltage transformer driver 40 by mixing the high frequency and the low frequency whose duty is adjusted as described above, and the switching element Q1. According to the alternating switching of Q2, the duty-adjusted voltage is applied to the primary side of the high voltage transformer 50.

Then, the high pressure transformer 50 boosts the voltage flowing to the primary side to a high pressure and outputs the secondary pressure, and the high pressure is output to the gas pipe.

In this case, the high pressure supplied to the gas pipe is supplied with a high pressure at which the potentials of both ends are adjusted, thereby preventing blackening due to the potential difference between both ends.

If the blackening phenomenon is prevented as described above, the life of the gas pipe is extended and the reliability of the product is improved.

That is, the present invention mixes high frequency and low frequency, adjusts the duty, and supplies high pressure to the gas pipe, thereby eliminating the potential difference between both ends of the gas pipe, thereby preventing blackening.

According to the " gas pipe power supply device " according to the present invention described above, the potential difference across the gas pipe does not occur by mixing the high frequency and the low frequency and automatically adjusting the duty, so that the blackening phenomenon due to the potential difference across the gas pipe is not shown. There is an advantage that can be prevented.

In addition, since it is possible to prevent the unbalance of the power supply to the gas pipe, there is an advantage that can prevent in advance the condensation of water generated in the neon tube.

In addition, since blackening and water droplets can be prevented in advance, the life of the product can be extended, and the reliability of the product is expected to be improved.

Claims (3)

Bridge diode BD1 for full-wave rectifying the input AC power and outputting the DC voltage, the high voltage transformer driver 40 for driving the high voltage transformer 50, and the power output from the secondary side of the high voltage transformer 50. In the conventional gas pipe power supply consisting of a gas pipe (neon tube or argon tube) A high frequency duty adjuster 10 for clamping the waveform of the input AC power to a predetermined level and then adjusting the high frequency duty ratio to provide the high frequency switch 30 to a rear stage; A DC control unit 20 for limiting the level of the DC voltage output from the bridge diode BD1 and modulating a pulse width to provide the high frequency switching unit 30 at a low frequency; And a high frequency switching unit 30 which generates a high frequency switching signal by mixing the high frequency and the low frequency output from the high frequency duty controller 10 and the DC controller 20 and transmits the high frequency switching signal to the high voltage transformer driver 40. Power supply of the gas pipe, characterized in that. The method of claim 1, wherein the high frequency duty controller 10, A plurality of clamping diodes (CD1) (CD2) for clamping the waveform of the input AC power to a predetermined level; A resistor (RT1) and a capacitor (CT1) for generating an oscillation frequency with an alternating current power clamped by the plurality of clamping diodes (CD1) (CD2); Power supply of the gas pipe, characterized in that the pulse width modulator 11 for adjusting the duty ratio of the high frequency by adjusting the pulse width of the high frequency in response to the oscillation frequency generated by the resistor (RT1) and the capacitor (CT1) . According to claim 1, The DC control unit 20, A monostable multivibrator 21 which maintains a metastable state for a predetermined time according to the time constant R23 * C22 when a trigger signal is applied; A resistor (RT2) and a capacitor (CT2) for generating an oscillation frequency corresponding to the output signal of the monostable multivibrator (21); Gas supply power supply device characterized in that it comprises a pulse width modulator 22 to adjust the low-frequency duty ratio by adjusting the pulse width of the low frequency corresponding to the oscillation frequency generated by the resistor (RT2) and the capacitor (CT2) .