KR19990020703A - Gas pipe inverter eliminating high frequency noise and radiation noise - Google Patents

Abstract

The present invention relates to a gas pipe inverter that removes high-frequency noise and radiation noise from a power source that drives a gas pipe such as a neon tube, eliminates high-frequency noise and radiation noise which are caused by stable operation of a gas pipe, water drop phenomenon in a gas pipe, (EN) An inverter for generating a driving power for driving a gas pipe, comprising: an inverter for receiving a voltage having a low frequency (60 Hz) of commercial AC (AC IN) and a voltage having a predetermined high frequency to drive a gas pipe A high voltage transformer (HVT) 70 generating a high voltage mixed with low frequencies; Frequency filters 10 and 20 for removing high frequency noise and radiation noise generated from the commercial voltage input terminal AC IN and itself through the frame ground terminal FG; A high voltage generating unit (R _H ) for rectifying and outputting a voltage having passed through the low frequency filter (10); A low voltage generating unit (R _L ) for rectifying and outputting a voltage having passed through the high frequency filter (20); A switching unit 60 for receiving a signal having a predetermined high frequency and switching it according to a predetermined duty cycle to supply the switching signal to the high voltage transformer 70; And an oscillation unit 30 for generating a high frequency switching signal having a predetermined duty cycle in the switching unit 60 and receiving operating power from the low voltage generating unit R _L.

Description

Gas pipe inverter eliminating high frequency noise and radiation noise

The present invention relates to a gas tube inverter in which high frequency noise and radiation noise are removed, and more particularly, to a gas tube inverter which eliminates high frequency noise and radiation noise from a power source for driving a gas tube such as a neon tube, The blackening phenomenon occurring in the gas pipe inverter is eliminated.

As shown in FIG. 1, a conventional neon tube inverter circuit includes a high voltage generating unit (HV) generating a high voltage that drives a neon tube; A low voltage generating unit LV for generating a low voltage for switching control of the high voltage generating unit HV; (C _{X1, 2} , C _{Y1, 2} ) for removing high frequency noise (EMI) and radiation noise (RFI) flowing into the high voltage generating portion HV and the low voltage generating portion LV, , the filter has a primary coil and a capacitor (C _X1) that both ends of which are connected to one end of the primary coil and the secondary coil of the transformer (T _F) that acts as a choke coil, a transformer (T _F) and the secondary coil and consists of a capacitor (C _X2) that both ends of which are connected to the other end, the two are capacitors (C _{Y1, 2)} connected in parallel to be connected in series with the one capacitor (C _X2).

The high voltage generating unit HV is composed of a rectifying unit R _H connected to the other ends of the primary and secondary coils of the transformer T _F and rectifying the high voltage generating unit HV. A power transformer T _P which is connected to the other end of the primary and secondary coils of the transformer T _F to drop the voltage to a proper voltage and a secondary transformer T _{P of} the power transformer T _P , And a low voltage rectifier (R _L ) connected to the coil for rectifying the DC voltage.

The conventional neon tube inverter thus configured generates a neon tube drive current having a predetermined frequency by using the voltage of the high voltage generator and controls the switching of the neon tube drive current by using the voltage of the low voltage generator to drive the neon tube.

However, such a conventional neon tube inverter requires a separate transformer to generate a low voltage and a high frequency and a high voltage to generate a high frequency noise, and a droplet flows in the neon tube when the neon tube is driven. And blackening phenomenon in which the periphery of the electrode changes to black.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the conventional art, and it is an object of the present invention to prevent a high frequency noise and radiation noise from flowing into a driving voltage for driving a gas pipe such as a neon tube, The present invention provides a gas tube inverter that eliminates high frequency noise and radiation noise that reduces the number of transformers and improves productivity compared to conventional inverters, It has its purpose.

In order to achieve the above object, the present invention provides an inverter for generating a driving power for driving a gas pipe, the inverter having a voltage having a low frequency of commercial electricity and a voltage having a predetermined high frequency to drive the gas pipe A high voltage transformer for generating a high voltage mixed with high and low frequencies; A high / low frequency filter for eliminating high frequency noise and radiation noise generated from a commercial voltage input terminal and itself through a frame ground terminal; A high voltage generating unit for rectifying and outputting a voltage having passed through the high frequency filter; A low voltage generator for rectifying and outputting a voltage having passed through the low frequency filter; A switching unit for receiving a signal having a predetermined high frequency and switching it according to a predetermined duty cycle to supply the signal to the high voltage transformer; And an oscillation unit for generating a high-frequency switching signal having a predetermined duty cycle in the switching unit and receiving operating power from the low voltage generating unit. to provide.

1 is a circuit diagram showing a conventional gas-tube inverter,

2 is a circuit diagram showing a gas pipe inverter in which high frequency noise and radiation noise are removed according to the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

10: low frequency filter 20: high frequency filter

30: oscillation section 40: phase correction circuit

50: Noise filter 60: Switching part

70: High voltage transformer 80: Current sensor

The configuration and operation of a gas pipe inverter in which high frequency noise and radiation noise are eliminated according to the present invention will be described in detail with reference to one embodiment of the present invention.

FIG. 2 is a circuit diagram showing a gas pipe inverter in which high frequency noise and radiation noise are removed according to the present invention. FIG.

As shown in FIG. 2, the gas-tube inverter in which the high-frequency noise and the radiation noise according to the present invention are eliminated has a configuration in which a voltage having a low frequency (60 Hz) of a commercial electric power AC IN and a voltage having a predetermined high- A high voltage transformer (HVT) 70 for generating a high voltage in which high and low frequencies are mixed to drive the high voltage transformer 70; A low-frequency filter 10, 20 for removing a high-frequency noise and a radiation noise generated by the commercial voltage input terminal AC IN and itself through a frame ground terminal FG; A high voltage generating unit (R _H ) for rectifying and outputting a voltage having passed through the low frequency filter (10); A low voltage generating unit R _L for rectifying and outputting the voltage passed through the high frequency filter 20; A switching unit 60 for receiving a signal having a predetermined high frequency and switching it according to a predetermined duty cycle to supply the switching signal to the high voltage transformer 70; And an oscillation unit 30 for generating a high-frequency switching signal having a predetermined duty cycle in the switching unit 60 and receiving operating power from the low voltage generating unit R _L.

The high-voltage transformer 70 detects the overload or no-load of the output terminals 72 and 73 of the high-voltage transformer to stop the output of the high-voltage transformer 70. The transformer 70 detects the load of the high- sensor (current sensor, 80) is, and is joined, the larger rent sensor (80) and a rectifier diode (D _R) that by rectifying the load signal connection, the load signal rectified by the rectifier diode (D _R) Voltage converter (R _D1 ) for converting the voltage into a voltage is connected to the current sensor 80. A distributor (R _D2 ) for distributing the load signal at a predetermined voltage ratio is connected to the voltage converter (R _D1 ).

A Zener diode (D _Z ) for determining a reference voltage is connected to the distributor (R _D2 ), and a signal exceeding a reference voltage is generated, that is, a load signal sensed by the current sensor (80) And is connected to the oscillation unit 30 to stop oscillation of the oscillation unit 30 if the oscillation frequency is higher than a predetermined reference voltage.

The frequency setting resistor R _T and the capacitor C _{T are} connected to the oscillation unit IC 31 to determine the oscillation frequency of the oscillation unit 30 and the duty cycle of the oscillation unit 30 is determined The variable resistor for duty control R _DT is connected to the oscillation unit IC 31.

The gas pipe driving power source boosted by the high-voltage transformer 70 is synthesized with a low frequency of 60 Hz, which is the frequency of commercial electricity, and a high frequency oscillated by the oscillation unit 30, Since it is necessary to control the oscillation state of the structure wave by sensing the phase difference between the two signals, the SCR and the capacitor (C _P ) need to be controlled. Is added to the oscillation section (30).

The switching unit 60 receives a predetermined high frequency output from the oscillating unit 30 and performs switching according to the duty cycle adjusted by the duty control resistor R _DT . A pair of damping resistors (damping resistors) 62 which damp at both ends of a pair of coils 62 and 63 opposed to the primary coil 61 are connected to the primary coil 61 connected to the oscillation unit 30 R _{DP1, 2} , and a pair of switching FETs (field effect transistors, Q _1, Q ₂ ). The output of the switching FETs (Q1 _, Q2) is input to the input terminal (71) of the high voltage transformer (70).

A noise filter (not shown) composed of a resistor R _F and a capacitor C _F is disposed between the oscillation unit 30 and the switching unit 60 to remove noise included in the signal output from the oscillation unit 30 50 are connected.

The low and high frequency filters 10 and 20 are for eliminating high frequency noise and radiation noise included in the power supplied to the high voltage generating part and the low voltage generating part. The low frequency filter 10 connected to the high voltage generating part is a capacitor C _{X1, 2)} and a coil (T _F) is made of a capacitor of a high-frequency filter 20 is the intermediate terminal is connected to the sub-voltage generation are connected to each other in series so as to be connected to the frame ground (frame ground, FG) pair (C _{Y1 and 2} and a capacitor C _Y3 connected in parallel to the pair of capacitors C _{Y1 and} C ₂ .

The gas pipe inverter having the high frequency noise and radiation noise according to the present invention configured as described above operates as follows.

The noise introduced through the AC input terminal AC IN to the high voltage generating part R _H and the low voltage generating part R _L by the low and high frequency filters 10 and 20 is removed by the low frequency filter 10, High frequency noise, such as high frequency noise and radiation noise, generated by itself is bypassed through the frame ground terminal FG.

The voltage having the frequency of commercial electric power that has passed through the low frequency filter 10 is supplied to the output terminals 72 and 73 of the high voltage transformer 70 by capacitors and is rectified by the high voltage generating unit R _H , is inputted to the FET (Q ₁₎ of the switching unit 60, it is switched and input to the input terminal 71 of the high voltage transformer (70).

The voltage rectified by the low voltage generating unit R _L is input to the driving power source of the oscillating unit 30 to generate the oscillation frequency setting resistor R _T and the capacitor C _T , And the duty cycle of the frequency output by the resistance R _DT , which is a resistance for duty control, is determined.

The high frequency signal oscillated by the oscillation unit 30 is removed by the noise filter 50 and is input to the switching unit 60 so that the commercial voltage is switched according to the oscillation frequency, And the high-frequency transformer 70 synthesizes the high-frequency current by the high-voltage transformer 30 and inputs the high-voltage transformer 70 to the input terminal 71.

And, bonded to the above-described high voltage transformer 70, the output state of the high voltage transformer 70. That is, the load current flowing through the large rent sensor 80 for detecting an overload or no-load condition is rectified by the rectifier diode (D _R) The voltage is converted to a voltage by the voltage conversion resistor R _D1 and it is determined whether the reference voltage is exceeded by the divider resistor R _D2 and the control diode D _Z so that the oscillation is stopped if the voltage is overload or no load. In this way, it is determined whether or not the phase of the low frequency coincides with the phase of the high frequency, and the phases of the high frequency and the low frequency are always output in accordance with the phase correction circuit 40 (SCR, _CP ).

The gas tube inverter eliminates high-frequency noise and radiation noise according to the present invention, which is constructed as described above, prevents high-frequency noise and radiation noise from flowing into a driving voltage for driving a gas pipe such as a neon tube, thereby improving driving efficiency of the gas tube And prevents generation of water droplets and blackening phenomenon occurring in the electrode portion when the neon tube is driven, and provides an effect of improving the productivity by reducing the number of transformers compared to the conventional inverters.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Various changes and modifications may be made by those skilled in the art.

Claims (5)

An inverter for generating driving power for driving a gas pipe, A high voltage transformer (HVT) 70 for generating a high voltage mixed with a high frequency and a low frequency for driving a gas pipe by receiving a voltage having a low frequency (60 Hz) of a commercial AC (AC IN) and a voltage having a predetermined high frequency ; Frequency filters 10 and 20 for removing high-frequency noise and radiation noise generated from the commercial voltage input terminal AC IN through the frame ground terminal FG and a low- A high voltage generating unit (R _H ) for rectifying and outputting the high voltage; A low voltage generating unit (R _L ) for rectifying and outputting a voltage having passed through the high frequency filter (20); A switching unit 60 for receiving a signal having a predetermined high frequency and switching it according to a predetermined duty cycle to supply the switching signal to the high voltage transformer 70; And an oscillation unit (30) for generating a high-frequency switching signal having a predetermined duty cycle in the switching unit (60) at all times and receiving operating power from the low voltage generating unit (R _L ) Gas - tube inverter with high frequency noise and radiation noise removed. A current sensor (80) of a transformer type for detecting the amount of an output current to stop the output by detecting an overload or no load of the output terminals (72, 73) of the high voltage transformer (70) Wherein the high frequency noise and the radiation noise are removed. The gas turbine inverter according to claim 1, further comprising a frequency setting resistor (R _T ) and a capacitor (C _T ) for stabilizing the oscillation frequency of the oscillating unit (30). The gas tube inverter according to claim 1, further comprising a duty control variable resistor (R _DT ) for determining a duty cycle of an oscillation frequency oscillated by the oscillation unit (30), wherein high frequency noise and radiation noise are removed. The apparatus according to claim 1, further comprising a phase correction circuit (40) for detecting a phase difference between the two signals to control the oscillation state of a high frequency so as to match the phase between the high frequency and the low frequency, Gas pipe inverter.