KR0140444Y1 - An low voltage of natrium lamp for electronic ballast - Google Patents

Abstract

The present invention relates to an electronic low-pressure sodium ballast, the filter unit 10 for removing unnecessary noise of the voltage applied through the input terminal, the rectification and power factor correction unit 20 rectified by a DC voltage to improve the power factor, The rectifier and the power factor correction unit is applied to the DC voltage with improved power factor is applied to a constant voltage (VL) and the switching unit 30 for outputting, and the oscillation unit for generating oscillation when the constant DC voltage is applied ( 40, an amplifying unit 50 for amplifying the signal of the oscillating unit, an overvoltage detecting unit 61 for detecting the occurrence of overvoltage due to an abnormality in the ballast internal circuit, and the oscillating unit 40 in accordance with the operation of the overvoltage detecting unit. Oscillation control unit 62 for controlling the operation of the control unit and a series-parallel resonance unit 70 for resonating the output signal of the amplification unit 50 to the sine wave and applying it to the lamp L. And Complementing the stability of the lamp and stopping the oscillator in the event of an overcurrent prevents device breakage, improves power factor and reduces power consumption.

Description

Electronic low pressure sodium ballast

1 is a block diagram showing the configuration of the electronic low pressure sodium ballast of the present invention.

2 is a specific circuit diagram showing an electronic low pressure sodium ballast of an embodiment of the present invention.

(A)-(g) of FIG. 3 are the signal waveforms about the main part of FIG.

* Explanation of symbols for main parts of the drawings

10 filter unit 20 rectification and power factor correction unit

30: switch part 40: oscillation part

50: amplification unit 60: overvoltage detection control unit

61: overvoltage detection unit 62: oscillation control unit

70: series-parallel resonator IC1-1: switch

IC1-2: Overvoltage Controller IC2: Oscillator

C2, C3, C13 to C16: capacitors D1 to D3, D5, D6, D7, D17: diodes

LED: Light emitting diodes R18, R19: Resistance

TR1: transistor T3: transformer

L6, L7: coil L: lamp

VR: Variable resistor

The present invention relates to an electronic low pressure sodium ballast, and more particularly, to improve resonance characteristics, increase the power factor of the ballast, and reduce power consumption by using a frequency modulation oscillation using a frequency higher than a home frequency. It relates to a low pressure sodium ballast.

In the conventional electronic sodium ballast, the oscillation frequency of the transformer trans-coil winding type self-excited oscillation includes a high frequency ripple, which causes unnecessary noise, resulting in unnecessary noise. When the overcurrent occurs and the oscillation circuit inside the ballast is cut off, there is a problem in that unnecessary current is wasted due to the current flowing in the circuit continuously discharged through the ground.

In addition, in the case of separate oscillation (Separate oscillation) it was not efficient because the power factor is about 60%.

In addition, when confirming the abnormality of the lamp and the ballast, since the diode is conventionally used, the polarity of the diode must be adjusted so that work efficiency is reduced and accessories are wasted.

The present invention has been made to solve the conventional problems as described above, by using the oscillation of the frequency modulation method using a frequency higher than the home frequency to improve the lighting characteristics and power factor, protect the circuit elements and also reduce the power consumption It is an object of the present invention to provide an electronic low pressure sodium ballast.

In order to achieve the above object, the present invention provides a filter unit for removing unnecessary noise of an AC voltage applied through an input terminal, and a rectification and power factor correction unit for rectifying the output voltage of the filter unit with a DC voltage and improving the power factor. And a switch unit for detecting and controlling a starting voltage by inputting a DC voltage having improved power factor, an oscillator for outputting an oscillation frequency by inputting a constant voltage constant by the switch unit, and An amplifier for amplifying the oscillation frequency, an overvoltage detector for detecting the generation of overvoltage flowing in the ballast internal circuit, an oscillation controller for controlling the operation of the oscillator according to the operation of the overvoltage detector, and amplified by the amplifier. It characterized in that it consists of a series-parallel resonance unit for lighting the lamp by resonating the square wave frequency to a sine wave.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of the electronic low-pressure sodium ballast of the present invention, the filter unit 10 for removing unnecessary noise of the voltage applied through the input terminal, and rectifying the AC voltage passed through the filter unit to a DC voltage A rectification and power factor correction unit 20 for improving the power factor, a switching unit 30 for outputting a constant voltage (VL) by outputting a DC voltage having improved power factor by the rectification and power factor correction unit; An oscillator 40 for generating an oscillation when the constant DC voltage is applied, an amplifier 50 for amplifying a signal of the oscillator, and an overvoltage detector 61 for detecting occurrence of overvoltage due to an abnormality in an internal circuit of the ballast. ), An oscillation controller 62 for controlling the operation of the oscillator 40 according to the operation of the overvoltage sensing unit, and a series-parallel for resonating the output signal of the amplifier 50 to a sine wave and applying it to the lamp L. ball It consists of a part 70.

2 is a detailed circuit diagram showing the electronic low pressure sodium ballast of the embodiment of the present rule, wherein the filter unit 10 is composed of a circuit protection capacitor C1 (C2) and a transformer T1 for stepping down the input AC power supply AC. , The rectification and power factor correction unit 20 is a bridge diode (BP) for full-wave rectification of the output power of the transformer (T1) and the power factor correction capacitor (C3) (C4) and diode (D1) ( D2) (D3).

The switch unit 30 has resistors R1 to R3 connected to the base terminal and the collector terminal of the transistor TR1, and one input terminal of the switch IC1-1 has a resistor R4 (R5) and a capacitor C6. Is connected in parallel, and the other input terminal is connected with a resistor R6 and a diode D4, and the output terminal of the switch IC1-1 is connected to the base terminal of the transistor TR1.

The oscillator 40 includes an oscillator IC2, an integrated circuit of the variable resistor VR and capacitor C9 connected to the oscillator, resistors R11, R12, zener diodes ZD2, and capacitor C10. It is composed.

The amplifier 50 is connected to the resistor R13, R14, capacitor C11, resistor R15, R16, and capacitor C12 at the gate of the field effect transistors FET1 and FET2 through the transformer T2. Are each connected in parallel.

The overvoltage detection control unit 60 has a resistor R7 and a capacitor C7 connected to one input terminal, and the resistor R6 and the diode D4 of the switch unit 30 connected to the other input terminal. -2), an overvoltage detector 61 configured by connecting a resistor R20, a zener diode ZD1, and a capacitor C4, and an output terminal of the overvoltage controller IC1-2 to the base terminal of the transistor TR2. The oscillation control part 62 is connected and the resistor R9 and the capacitor C8 are connected to the collector terminal of the transistor TR2.

The series-parallel resonator 70 has a resistor R18 and a capacitor C13 connected in parallel with a lamp to one end of a primary coil L6 of a transformer T3, and the other end of the capacitor C15 and C16. Diodes D6 and D7 are connected in parallel, a light emitting diode LED and a resistor R19 are connected to the secondary coil L7 of the transformer T3, and a diode D5, a resistor R17 and a capacitor are connected to each other. It is configured in parallel connection.

FIG. 3 is a signal waveform diagram of the main part of FIG. 2, where a is a waveform diagram of the VH voltage rectified by the rectification and power factor correction unit 20, and b and c are diagrams of the series-parallel resonance unit 70. As shown in FIG. The waveform of the VL voltage during the normal operation of the lamp L induced by the secondary coil L7 of the transformer T3 and the waveform of the VL voltage in the no-load state in which the lamp L is not operated, and d is the oscillation part 40. Is a square wave pulse waveform diagram generated at, and e is a signal waveform amplified by the amplification unit 50, and f and g are resonant waveforms in normal operation and a no-load resonant waveform detected by the lamp L. FIG. Respectively.

Next will be described the operation and effect of the present invention made of the configuration as described above.

First, when an AC voltage is applied from the input terminal, the filter unit 10 cuts the low and high frequencies of the applied AC voltage and passes only the frequency of the appropriate region to the bridge diode BD.

The voltage applied to the bridge diode BD is full-wave rectified and output as a DC voltage, and the rectified DC voltage is supplied through a power factor correction capacitor C2 (C3) and a power factor correction diode D1 (D2) and D3. Noise is eliminated, and the power factor is improved to around 90% to detect the VH voltage waveform as shown in FIG. 3a at TP1.

The VH voltage is applied to the resistors R1 and R3 of the switch unit 30 to turn on the transistor TR1 so that the voltage flows. When the voltage VL reaches the predetermined voltage VL, the switch IC1-1 The reverse voltage is applied to the base of the transistor TR1 to turn off the transistor TR1 to maintain the VL voltage.

Since the VL voltage does not energize the zener diode ZD1 of the overvoltage detection control unit 60, the overvoltage detection control unit 60 does not operate.

On the other hand, when the output goes out normally, the constant voltage VL as shown in FIG. 3b as detected by TP2 at the emitter terminal of the transistor TR1 at the voltage induced by the secondary coil L7 of the transformer T3 continues to be 9 to 10V. The capacitor C8 is charged through the resistors R11, R12, and R20.

The voltage charged in the condenser C8 is discharged and applied to the oscillator IC2 to output the oscillation frequency output from the oscillator. Is a square wave pulse waveform as shown in FIG. 3d detected by TP3, and is applied to the transformer T2 of the amplifier 50 to generate two induced currents having different phases, respectively. ).

At this time, the positive voltage induced current of the transformer T2 is applied to the gate terminal of the field effect transistor FET2 so that the field effect transistor FET2 is turned on, and the square wave pulse generated by the oscillator 40 is detected at TP4. Amplified by a pulse-like pulse waveform, the amplified pulse resonates with a sine wave through the capacitors C12, C13 and C15 of the parallel-parallel resonance unit 70 and the primary coil L6 of the transformer T3. Turn on (L).

If the voltage applied to the gate terminal of the field effect transistor FET2 drops during the operation as described above, the field effect transistor FET2 is turned off, and thus a current is applied to the gate terminal of the field effect transistor FET1, thereby causing the field effect. Turn on transistor FET1.

As the field effect transistor FET1 is turned on, the pulse amplified as described above is transmitted to the sine wave through the capacitor C12 (C14) and the primary coil L6 of the transformer T3. The lamp L is turned on while resonating.

On the other hand, when the voltage applied to the gate terminal of the field effect transistor FET1 drops during the operation as described above, the field effect transistor FET1 is turned off, whereby a current is applied to the gate terminal of the field effect transistor FET2. The field effect transistor FET2 is turned on.

As the field effect transistors FET1 and FET2 are alternately turned on and off, as shown in FIG. 3e, square wave pulses are amplified and thus detected in TP5 through the parallel-parallel resonator 70, as in FIG. The lamp L is turned on while resonating with the sine wave.

Now, when the ballast is operating normally, the current flowing through the primary coil L6 of the transformer T3 is a normal current, so that a voltage is applied to both the resistor R8 of the overvoltage detector 61 and the capacitor C6. As it is not detected, the overvoltage controller IC1-2 of the oscillation controller 62 is not operated, and thus the oscillator IC2 of the oscillator 40 is not affected.

However, if the lamp is defective during operation as described above, or if an abnormality occurs in the lamp such as a no-load state, the voltage induced at both ends of the primary coil L6 of the transformer T3 increases due to the load variation, and accordingly, the transformer The voltage induced at both ends of the secondary-side coil L7 of T3 increases.

The poor lighting state of the lamp L due to the variation of the primary coil L6 of the transformer T3 is improved by adjusting the frequency through the variable resistor VR of the oscillator 40.

In addition, the voltage induced at both ends of the secondary coil L7 of the transformer T3 is applied to both ends of the zener diode ZD1 and the resistor R8 of the overvoltage detector 61, and both ends of the resistor R8. The voltage of the charges the capacitor C7.

When the voltage charged in the capacitor C7 is discharged and flows through the resistor R7, the overvoltage controller IC1-2 operates, and the output voltage of the overvoltage controller is the base end of the transistor TR2 of the oscillation controller 62. Is applied to the transistor TR2, and the collector current of the transistor TR2 is bypassed to ground V ₀ .

Accordingly, since the oscillator IC2 of the oscillator 40 is stopped and the current applied to the switching element of the amplifier 50 is cut off, the voltage flowing in the circuit is discharged and flows to the ground V ₀ .

On the other hand, when the voltage flowing in the circuit is lower than the VL voltage, the switch unit IC1-1 of the switch unit 30 operates the transistor TR1 to apply the VL voltage to the oscillation unit 40 again. It works.

In addition, by using the light emitting diode (LED) and the resistor (R19) connected to the secondary coil (L7) of the transformer (T3) of the series-parallel resonance unit 70 it can be confirmed whether the lamp (L) and the ballast is abnormal. .

That is, when the lamp L and the ballast operate normally without abnormality, the light emitting diode LED is continuously turned on, and when the lamp L is abnormal and the ballast is normal, the light emitting diode LED blinks repeatedly on and off. When the lamp L is in a normal / stabilizer abnormal state, the light emitting diode LED is turned off to immediately check whether there is an abnormality.

The above design improves the stability of the ballast and the lamp L by improving the resonance characteristics by using the oscillation of the frequency modulation method, and detects the flow of the overcurrent by the overvoltage sensing controller 60 to generate the overcurrent oscillator 40. ) To prevent damage to the circuit elements and to reduce the power consumption, and the power factor correction capacitors C2 and C3 and the power factor compensation diodes D1 and D2 to the rectification and power factor correction unit 20. (D3) is combined and configured, and the capacitors C15 (C16) and the diodes (D6) and (D7) are connected in parallel to the output side of the series-parallel resonance unit 70, thereby improving the power factor to about 90%.

In addition, by using the light emitting diode (LED) and the resistor (R19) connected to the secondary coil (L7) of the transformer (T3) of the series-parallel resonance unit 70, it is possible to check the abnormality of the lamp (L) and the ballast, The poor lighting state of the lamp L due to the fluctuation of the primary coil L6 of the transformer T3 may be improved by using a variable resistor VR for adjusting the frequency.

Claims (3)

A filter unit 10 for removing unnecessary noise of a voltage applied through an input terminal, and rectifying an AC voltage passing through the filter unit, and power factor correction capacitors C2 and C3 power factor correction diodes D1, D2 and D3. And a rectifier and power factor correction unit 20 for improving the power factor by combining and configuring the transistors, and a DC voltage whose power factor is improved by the rectification and power factor correction unit as an input and outputs a constant voltage of a constant voltage VL. Oscillation frequency is output by the oscillator IC2 which is a frequency oscillation method by inputting the switch unit 30 which consists of the switch unit IC1-1 which controls (), and the constant voltage VL regulated by this switch unit as an input. The oscillation section 40, the amplification section 50 for amplifying the oscillation frequency generated by the oscillation section, the overvoltage sensing section 61 for detecting the generation of the overvoltage flowing in the ballast internal circuit, and the operation of the overvoltage sensing section. Control the operation of the oscillator 40 The oscillation controller 62, a resistor R18 and a capacitor C13 connected in parallel with the lamp L are connected to one end of the primary coil L6 of the transformer T3, and the other end of the capacitor C15 ( C16) and diodes D6 and D7 are connected, and the light emitting diode LED and the resistor R19 are connected to the secondary coil L7 of the transformer T3, and the diode D5, the resistor R17 and the capacitor are connected. Electronic low pressure sodium ballast characterized in that it comprises a parallel-parallel resonator (70) for connecting the parallel (C14) is a square wave pulse amplified by the amplifying section 50 to a sine wave to light the lamp (L). . The light emitting diode (LED) and the resistor (R19) of the secondary coil (L7) of the transformer (T3) of the series-parallel resonator (70) to determine the abnormality of the lamp (L) and the ballast. The light-emitting diode (LED) turns on when the lamp (L) and the ballast are operating normally without abnormality, and the lamp (L) turns on / off when the abnormality and the stabilizer are normal, and the lamp (L) is normal. Electronic low pressure sodium ballast, characterized in that the ballast is turned off when abnormal. The electronic low voltage according to claim 1, wherein the poor lighting state of the lamp L due to the variation of the primary coil L6 of the transformer T3 is adjusted by the variable resistance VR of the oscillator 40. Sodium ballast.