KR100259184B1 - Error voltage detecting circuit for electronic ballast - Google Patents

Abstract

PURPOSE: An error voltage detecting circuit for an electronic ballast is provided to install a separate secondary coil in a trans of an inverter and detect error voltage induced in the secondary coil, thereby generating constant output voltage though input voltage is fluctuated in a predetermined range. CONSTITUTION: A rectifier(301) removes noise contained in input AC voltage and rectifies the input AC voltage. A power factor improver(302) receives the voltage rectified by the rectifier(301), turns output voltage on/off using a power factor IC(302A) and an FET therein, and generates constant voltage of high efficiency by changing the ratio of on/off. An output voltage detector(303) comprises a separate secondary coil in an output trans of an inverter(304) to rectify and smoothen the voltage induced in the secondary coil and distribute the voltage into predetermined levels, and then supplies the distributed voltage to ports(INV,COMP) of the power factor IC(302A). The inverter(304) switches the output voltage of the power factor improver(302) to supply RF AC voltage to a lamp part(305).

Description

Error Voltage Detection Circuit of Electronic Ballast

The present invention relates to a technique for controlling a voltage supplied to an inverter side in an electronic ballast employing a power factor integrated device, and in particular, in the case of using an output voltage lower than an input voltage, a constant output voltage corresponding to an input voltage that varies within a predetermined range The present invention relates to an error voltage detection circuit of an electronic ballast capable of detecting an error voltage using a voltage induced in a secondary coil of a transformer.

When designing an electronic ballast using a power factor IC, a power factor improvement unit is usually designed using one of a boost, a buck-boost, and a flyback method. Currently, the most commonly used method is the boost method. In this case, the output voltage is increased by about 1.2 times the input voltage. When using the output voltage obtained by using this boost circuit, the overall cost increases and the reliability of the circuit is greatly reduced. When using the buck-boost, the output voltage can be lowered than the input voltage, so the stability can be pursued in circuit, but the cost can be reduced because additional parts are used to obtain a constant output voltage.

Therefore, the present invention is to use a buck-boost and in particular to use the voltage induced in the transformer of the inverter for error detection for a constant output voltage.

1 is a circuit diagram of an electronic ballast according to the prior art, and as shown therein, a rectifier 101 for removing noise contained in an input AC power source and performing full-wave rectification; Boost power factor improvement unit for generating a high-efficiency constant voltage in a manner of receiving the voltage rectified by the rectifying unit 101 and the output voltage to the power factor integrated device, and by varying the ratio of the on and off ratio (average) 102); The inverter 103 is configured to supply an AC power source having a predetermined frequency (25 kHz) to the lamp unit 104 by switching the output voltage of the power factor improving unit 102. The operation thereof will be described below.

When the input AC power supply of 60 Hz is turned on, the noise component is removed through the choke input filter CF, and then full-wave rectified by the bridge diode BD of the rectifying unit 101. The frequency of the full-wave rectified voltage is 120 Hz. to be. The full-wave rectified voltage is converted into a constant DC voltage by the power factor improving unit 102 again.

The DC voltage V _out output from the power factor improving unit 102 is supplied to the primary coil of the transformer TR1 through the reactor L1 and the zener diode ZD of the inverter 103 and alternately at high speed. As the currents flow through the primary coils of the transformer TR1 through the operating transistors Q1 and Q2, a voltage induced in the secondary coils is supplied to the lamp unit 104 each time. Therefore, through this process, the AC power of high frequency (25KHz) is supplied to the lamps LAMP1 and LAMP2, and the lamps LAMP1 and LAMP2 are turned on.

Referring to the operation of the power factor improving unit 102 in more detail as follows.

The power factor integrated device 102A is a boost type integrated device, which sets a threshold value to switch a field effect transistor (FET) based on the value, thereby providing a boost inductor BI. As energy is repeatedly stored and discharged, the output voltage Vout becomes higher than the input voltage Vin.

In general, a coil or a capacitor is used when the AC is smoothed to a constant level of DC voltage, but in this case, the phase angles of the input voltage and the input current do not coincide, which causes power loss and power factor. And THD is lowered. (P = V × I × cosθ, cosθ = Power factor) θ )

Accordingly, the power factor and T.H.D are improved by matching the phase angles of the input voltage and the input current using the power factor integration element 102A. In this case, P.F> 99% and T.H.D <10%.

An error detection method of the power factor integration device 102A is described as follows.

In the boost method using the power factor integration device 102A, the output voltage V _out is designed to increase by 1.2 times the input voltage V _in . In other words, the circuit is designed based on the output voltage (V _out ) as the input voltage (V _in ) is increased by switching the field effect transistor (FET) to store energy and supply it to the boost inductor (BI). Only then can the normal power factor be improved.

By using the voltages of the ports INV and COMP of the power factor integration element 102A with respect to the input voltage V _{in in the} range of ± 10%, a constant output voltage V _out can be obtained by detecting an error. Here, the port INV is an inverting input port of the error amplifier in the power factor integration element 102A, and the port COMP is an output port of the error amplifier.

First, in order to obtain a constant output voltage (V _out), thereby detecting the error on the output voltage (V _out). The resistors R6 and R7 are connected in series between the terminal of the output voltage V _out and the ground terminal, and the connection point of the resistors R6 and R7 is connected to the port INV of the power factor integration device 102A. ) Is connected. A constant current flows through the resistor R7 connected to the port INV at all times. If the output voltage V _out rises above the design value, an increased current flows toward the port INV, so that the output voltage V _out always maintains a constant level.

On the other hand, Figure 2 is a circuit diagram of a buck-boost method according to the prior art will be described as follows.

This buck-boost circuit, unlike the boost circuit, can be seen that the ground terminal of the capacitor C6 is connected to the + terminal side of the input terminal of the inverter 203. In the boost method, the output voltage V _out is higher than the input voltage V _in using the energy stored in the boost inductor BI and the voltage charged in the smoothing capacitor C3.

On the contrary, in the buck-boost method, the output voltage V _out lower than the input voltage V _in is obtained by using only the energy stored in the boost inductor BI. The buck-order to detect an error of the output voltage (V _out) in the boost system can not be compared with the output voltage (V _out) itself as the boost system output voltage (V _out by using a separate comparator (CP) Error will be detected.

However, in the conventional electronic ballast circuit, the boost method requires the output voltage to be higher than the input voltage. Therefore, when the input voltage is high, the inverter must be designed to correspond to the high output voltage. Of course, there was a defect that the reliability is lowered. In addition, in the buck-boost method, since a separate comparator is used to detect an error so that a constant output voltage can be obtained with respect to a changing input voltage, the cost is higher than that of the boost method.

Accordingly, a technical problem to be achieved by the present invention is to detect an error voltage so that a constant output voltage can be generated in response to an input voltage fluctuating within a predetermined range even when an output voltage of the power factor improving unit is designed to be lower than an input voltage. In order to provide an error voltage detection circuit of an electronic ballast for providing an additional secondary coil in a transformer of an inverter and detecting an error voltage by using a voltage induced in the secondary coil.

1 is a circuit diagram of an electronic ballast according to the prior art.

2 is another circuit diagram of an electronic ballast according to the prior art.

3 is an error voltage detection circuit diagram of an electronic ballast according to the present invention.

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

301: rectifier 302: power factor improvement

302A: power factor integration device 303: output voltage detector

303A: secondary coil 304: inverter

305: lamp unit TR1: trance

BD: Bridge Diode BI: Boost Inductor

FET: Field effect transistor Q1, Q2: Transistor

LAMP1, LAMP2: Lamp

Figure 3 is an exemplary embodiment of the error voltage detection circuit of the electronic ballast for achieving the object of the present invention, as shown in the choke input filter (CF), bridge diode (BD) and capacitor (C1, C2) A rectifier 301 configured to remove and full-wave rectify the noise included in the input AC power; A power factor integrated device 302A, a boost inductor BI, a field effect transistor FET, resistors R1-R5, capacitors C3-C7, diodes D5, D6, and the rectifier 301. Power factor to generate a high-efficiency constant voltage by supplying the rectified voltage and turning on and off the output voltage using the power factor integrated device 302A and the field effect transistor (FET) and changing the average of the on / off ratio. An improvement unit 302; It is composed of the secondary coil 303A, the diode D7, the resistors R6-R8, and the capacitor C8 of the output stage transformer TR1 of the inverter 304, and the voltage induced in the secondary coil 303A is obtained. An output voltage detector 303 for rectifying, smoothing and distributing again to a predetermined level and supplying the ports INV and COMP of the power factor integration element 302A in the power factor improvement unit 302; The power factor improvement unit 302 includes a power transistor Q1 and Q2, a transformer TR1, an inductor L1 and L2, a zener diode ZD, a diode D8 and D9, and a capacitor C9. It is composed of an inverter 304 for switching the output voltage of the lamp unit 305 to supply the AC power of a predetermined frequency (25kHz), the operation of the present invention configured as described in detail as follows.

The operation of the parts except for the error detection operation by the power factor improving unit 302 and the output voltage detection unit 303 is the same as in the conventional art.

That is, when the input AC power supply of 60 Hz is turned on, the noise component is removed through the choke input filter CF, and then full-wave rectified by the bridge diode BD of the rectifying unit 301. The power factor improving unit 302 converts the constant DC voltage. In addition, the DC voltage output from the power factor improving unit 302 is converted into an AC power source having a predetermined frequency (25 kHz) by the inverter 304 and supplied to the lamp unit 305, whereby the lamps LAMP1 and LAMP2 ) Lights up.

Hereinafter, the error detection operation by the power factor improving unit 302 and the output voltage detection unit 303 will be described in detail.

In the power factor improvement unit 302, a predetermined level of DC is applied to the port INV of the power factor integration element 302A to obtain a constant output voltage V _out with respect to the input voltage V _in that varies within a range of ± 10%. A voltage (eg 2.5V) is supplied, and when the voltage fluctuates, an amount of current corresponding to the fluctuation flows to the port COMP so that an error is detected. In this way, a constant output voltage (V _out ) can be obtained for an input voltage (V _in ) which varies within a ± 10% range.

Here, the port INV is an input port of an error amplifier in the power factor integration element 302A, and the port COMP is an output port of the error amplifier.

By the way, the voltage supplied to the ports INV and COMP of the power factor integration element 302A, unlike the conventional method, uses a voltage induced in the secondary coil 303A of the transformer TR1 of the inverter 304. do.

That is, the AC voltage induced in the secondary coil 303A of the transformer TR1 is rectified and smoothed by the diode D7 and the capacitor C8, and the smoothed DC voltages are resistors R6 and R7. By a predetermined partial pressure ratio, from which the DC voltage of 2.5V is supplied to the port INV.

If the input voltage V _in of the power factor improving unit 302 is fluctuated, the voltage induced in the secondary coil 303A of the transformer TR1 is also changed accordingly. The amount of current that is varied among the currents supplied to the port INV is supplied to the port COMP.

Therefore, the power factor integrated device 302A can detect the error voltage based on the amount of current input through the port COMP, so that the output voltage V _out is always constant regardless of the variation of the input voltage V _in . I can keep it.

Here, the resistor R8 of the output voltage detector 303 is used to remove the noise component included in the voltage induced in the secondary coil 303A of the transformer TR1.

As described in detail above, in the present invention, when the output voltage of the power factor improving unit is designed to be lower than the input voltage, the present invention provides a separate secondary coil in the transformer of the inverter and uses the voltage induced in the secondary coil. By detecting the error voltage, it is possible to always generate a constant output voltage in response to the fluctuating input voltage.

Claims (2)

A rectifier 301 which removes noise contained in the input AC power supply and rectifies the wave; A method of supplying the rectified voltage by the rectifying unit 301 and using the internal power factor integrated device 302A and the field effect transistor (FET) to turn on and off the output voltage and to average the on and off ratios. A power factor improving unit 302 for generating a high efficiency constant voltage; A separate secondary coil is provided in the output transformer of the inverter 304 to rectify and smooth the voltage induced in the secondary coil to a predetermined level, and then, in the power factor improving unit 302, the power factor integrated device 302A. An output voltage detector 303 for supplying to the ports INV and COMP of the plurality of terminals; And an inverter (304) for switching the output voltage of the power factor improving unit (302) to supply a high frequency AC power to the lamp unit (305). The resistor R6 of claim 1, wherein the output voltage detector 303 connects the output terminal of the secondary coil 303A of the output transformer of the inverter 304 through the diode D7 and the resistor R8, and is connected in series. And a capacitor (C8) connected in parallel with (R7) to the ground terminal, respectively, and the connection points of the resistors (R6) and (R7) are connected to the ports INV and (COMP) of the power factor integration element 302A. And an error voltage detection circuit for an electronic ballast.

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