KR0129656Y1 - Fluorescent lamp starting device - Google Patents

Abstract

The present invention relates to a fluorescent lamp lighting device for preventing damage to the power control semiconductor device due to overcurrent when the fluorescent lamp is turned on by the on / off operation of the power control semiconductor device. A rectifying means for outputting, an initial driving means initially operated to preheat a filament of a fluorescent lamp by receiving a predetermined level of direct current output from the rectifying means, and receiving an output voltage of the rectifying means by an operation of the initial driving means A fluorescent lamp lighting device comprising a fluorescent lamp driving means for lighting a fluorescent lamp, the fluorescent lamp lighting device comprising: a direct current means receiving a output voltage of the rectifying means and outputting a direct current of a predetermined level; and receiving a direct current voltage of a predetermined level output from the direct current means; Overcurrent to detect overcurrent due to overload from power line supplied to fluorescent lamp And a switching means for stopping the operation of the fluorescent lamp driving means when an overcurrent is detected by the overcurrent detecting means and the fluorescent lamp off signal is output.

Description

Fluorescent lamp lighting device

1 is a block diagram of a fluorescent lamp lighting device in an embodiment of the present invention.

2 is a detailed circuit diagram of a fluorescent lamp lighting device in an embodiment of the present invention.

Figure 3 is a flowchart for explaining the lighting control operation of the fluorescent lamp lighting apparatus in an embodiment of the present invention.

4 is a voltage waveform diagram applied to the present invention,

(a) is a waveform diagram of a DC power supply voltage,

(b) is an output signal waveform diagram of the inverter 707 of FIG.

(c) is the signal waveform of point A in FIG.

(d) is the signal waveform of point B in FIG.

(e) is a signal waveform diagram of point C in FIG.

* Explanation of symbols for main parts of the drawings

1: AC power supply 2: rectification means

3: initial driving means 4: fluorescent lamp driving means

5: fluorescent lamp 6: DC means

7: overcurrent detecting means 8: switching means

408,415: power transistor 708: timer device

The present invention relates to a fluorescent lamp lighting device, and more particularly to a fluorescent lamp lighting device for preventing damage to the power control semiconductor device due to the over-current when the fluorescent lamp is turned on by the on / off operation of the power control semiconductor device.

In the conventional fluorescent lamp lighting device, when the switch is turned on through an on / off control means such as a power switch lamp to turn on the fluorescent lamp, and power is supplied to the fluorescent lamp lighting circuit, first, the filament of the fluorescent lamp is preheated, and the filament is preheated. The fluorescent lamp is configured to be turned on when the phase controlled power is supplied to the fluorescent lamp by the operation of the power control semiconductor element in which the on / off operation is continuously performed to turn on the fluorescent lamp.

In the fluorescent lamp lighting apparatus configured as described above, when the fluorescent lamp is defective or the end of life, overcurrent flows to the power control semiconductor device that supplies the phase-controlled power so that the fluorescent lamp is turned on, and heat is generated. The heat generated by the overcurrent is released through heat dissipation means attached to the power control semiconductor device.

When the heat dissipated through the heat dissipation means attached to the power control semiconductor element reaches a temperature higher than a predetermined level, a temperature fuse is attached to the heat dissipation means installed in the power control semiconductor element to cut off the power supplied to the fluorescent lamp lighting circuit. When the temperature is higher than the predetermined temperature, the temperature fuse is short-circuited to cut off the power input to the fluorescent lamp lighting circuit.

However, in the conventional fluorescent lamp lighting apparatus configured as described above, the temperature fuse attached to the heat radiating means of the power control semiconductor element controlling the lighting of the fluorescent lamp is operated to cut off the power supply voltage supplied to the circuit. The operation time of the temperature fuse is changed according to the attachment state of the temperature fuse attached to the heat dissipation means of the device, so that the power supply of the fluorescent lamp lighting circuit cannot be cut off immediately.

Therefore, the present invention is made to solve the conventional problems as described above, the object of the present invention is to detect when the fluorescent lamp is defective or when the end of life to replace the fluorescent lamp by repeating the lighting and turn off at regular intervals Not only to notify the user of the time point, but also to provide a fluorescent lighting device that can prevent damage to the power control semiconductor device for controlling the lighting of the fluorescent lamp.

In order to achieve the above object, the fluorescent lamp lighting apparatus according to the present invention is provided with rectifying means for outputting a constant level of direct current by receiving AC power, and initially to preheat the filament of a fluorescent lamp receiving a constant level of direct current output from the rectifying means. A fluorescent lamp lighting device comprising an initial driving means for operating and a fluorescent lamp driving means for lighting a fluorescent lamp by receiving an output voltage of the rectifying means by an operation of the initial driving means, the fluorescent lamp lighting device comprising: a direct current having a predetermined level in response to an output voltage of the rectifying means. An overcurrent detection means for detecting an overcurrent caused by an overload from a power supply line supplied to the fluorescent lamp while receiving a DC voltage of a predetermined level output from the DC means, and an overcurrent is detected by the overcurrent detection means. When the fluorescent lamp off signal is output, the operation of the fluorescent lamp driving means And a switching means for stopping.

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

FIG. 1 is a block diagram of a fluorescent lamp lighting device according to an embodiment of the present invention, and FIG. 2 is a detailed circuit diagram of a fluorescent lamp lighting device according to an embodiment of the present invention.

In Fig. 1, reference numeral 2 denotes a rectifying means composed of a bridge circuit for rectifying the AC voltage supplied from the AC power supply 1 to output a DC voltage of a predetermined level, and 3 denotes the rectifying means 2. Is an initial driving means which is initially operated to preheat the filament of a fluorescent lamp by receiving a DC voltage of a predetermined level, and (4) is the rectifying means (2) in accordance with the operation start signal current of the initial driving means (3). (5) is a fluorescent lamp composed of a first fluorescent lamp 510 and a second fluorescent lamp 502 so as to be lit by the fluorescent lamp driving means 4 by receiving a DC voltage output from (6) is a direct current means for receiving a predetermined level of DC voltage output from the rectifying means (2) and outputting a reference voltage of a predetermined level, (7) is operated by receiving the output voltage of the direct current means (6), Inductor connected to the fluorescent lamp (5) And an overcurrent detecting means for detecting an overcurrent from the switch, and (8) receives the fluorescent lamp control signal output from the overcurrent detecting means (7) when the fluorescent lamp (5) is defective so that the fluorescent lamp (5) is turned off. Switching means for turning off the operation of 4). In the above description, the first fluorescent lamp 510 and the second fluorescent lamp 502 shown in FIG. 2 may also be used as one fluorescent lamp.

Reference numerals 503 and 504 denote capacitors for turning on the fluorescent lamp 5.

The initial driving means (3) receives a predetermined level of DC voltage output from the rectifying means (2) and divided voltage resistors (301) (302) connected in series to output a constant voltage, and the divided voltage to generate an initial starting voltage A capacitor 303 connected in parallel with the resistor 302, a diaak 304 which receives the starting voltage generated by the voltage divider resistor 302 and the capacitor 303 and outputs it to the fluorescent lamp driving means 4; When the resistor 305 connected in series to the output terminal of the diaak 304 and the fluorescent lamp driving means 4 are operated, the voltage dividing resistor 302 so that the initial driving voltage is not output from the diaak 304. A diode 306 is connected in series to the input terminal of the capacitor 303 and the diaak 304, and a resistor 307 is connected in series to the output cathode terminal of the diode 306. As shown in FIG.

The fluorescent lamp driving means 4 is a current converter 405 that operates by receiving a current output through the resistor 305 from the diaak 304 of the initial driving means 3, and 1 of the current converter 405 Power transistors 408 and 415 which are alternately turned on / off by receiving the voltage induced from the secondary coils 410 and 412 to the secondary coils 410 and 412 through the resistors 406 and 413, and the power transistors. (408) and 415 are alternately turned on and off, the inductances 701 and 702 for generating a high frequency amplification voltage supplied to the fluorescent lamp 5 and the output terminal (+) of the rectifying means 2 (-). Capacitors 403 and 404 connected in series and parallel connection with the capacitors 403 and 404 respectively connected in series and generated in the inductances 701 and 702 and capacitors 403 and 404. It is composed of diodes 401 and 402 connected in series with each other to maintain a high frequency amplification voltage at a constant level of voltage.

Diodes 407 and 414 are respectively connected to the base terminals of the power transistors 408 and 415 and the one side terminals of the secondary coils 410 and 402 of the current converter 405. The power transistors 408 Each collector terminal and emitter terminal side of 415 are connected to diodes 409 and 416 for protecting the power transistors 408 and 415 due to reverse voltage, and the inductance 701 is a fluorescent lamp. 501 is connected between one side of the terminal connection terminal and one side of the primary coil 411 of the current converter 405, the inductance 702 and one side of the connection terminal of the second fluorescent lamp 502 It is connected between one side of the primary coil 411 of the fluorescent lamp current converter 405.

The direct current means 6 receives the voltage output from the rectifying means 2 through a resistor 603 and is in parallel with the zener diode 601 for maintaining and outputting a direct current voltage of a predetermined level. And a capacitor 602 connected to charge the output voltage.

When the overcurrent detecting means 7 is overloaded due to a defective lamp of the fluorescent lamp 5, an organic current is generated on the secondary sides 701 'and 702' of the inductances 701 and 702, and this organic current is generated. A diode 703 for half-wave rectifying, a capacitor 704 for smoothing the current output from the diode 703, and a zener diode connected in series with the capacitor 704 to pass only a voltage equal to or greater than a predetermined breakdown voltage ( 705, an inverter 707 for receiving and inverting the voltage output from the cathode terminal of the zener diode 705 through the resistor 706, and receiving the output voltage of the rectifying means 6 and at the same time receiving the inverter ( A timer semiconductor element 708 (hereinafter referred to as a timer element) that operates by receiving the output signal of the input signal 707 as an input terminal TIM, and a resistor 709 and a capacitor for setting a time constant of the timer element 708. 710, the (Vcc) terminal of the timer element 708 The (RST) terminal and the resistor 709 connected to each other are connected to each other, and the (DIS) (THR) terminal of the timer element 708 is connected to a connection point of the resistor 709 and the capacitor 710. .

The switching means 8 includes a transistor 802 that receives an output signal output from the output terminal OUT of the timer element 708 through a resistor 801, and a base terminal and an emitter of the transistor 802. It consists of a resistor 803 connected between the terminals, and the collector terminal of the transistor 802 is connected to the connection point of the secondary coil 412 and the resistor 413 of the current converter 405.

Hereinafter, the operation of the fluorescent lamp lighting apparatus will be described with reference to FIGS. 3 and 4. Where S denotes a step.

3 is a flow chart for explaining the lighting control operation of the fluorescent lamp lighting apparatus in an embodiment of the present invention, Figure 4 is a control voltage waveform applied to the present invention, (a) is a waveform diagram of the DC power supply voltage (b) is an output signal waveform diagram of the inverter 707 of FIG. 2, (c) is a signal waveform diagram of the point A signal of FIG. 2, (d) is a signal waveform diagram of the point B signal of FIG. Is the signal waveform of point C in FIG.

First, when the power switch (not shown) is turned on and AC voltage is supplied from the AC power supply 1 to the fluorescent lamp lighting circuit in step S1, the AC voltage supplied from the AC power supply 1 in step S1 to the bridge circuit in step S2. Received by the rectifying means (2) is made to output a DC voltage of a predetermined level to the initial drive means 3, the fluorescent lamp driving means 4 and the direct current means (6).

In step S2, when the DC voltage Vcc is output at a predetermined level, the fluorescent lamp driving means 4 receives the DC voltage Vcc output from the rectifying means 2 in step S3 to turn on the fluorescent lamp 5. In order to operate the DC voltage of a constant level at the connection point of the voltage dividing resistor 301 and the voltage dividing resistor 302 of the initial driving means 3 connected to each other in series with the output terminal (+) (-) of the rectifying means 2. When the output is received, the trigger current, i.e., the initial driving current, is received through the resistor 305 connected in series with the diak 304 by receiving a DC voltage of a predetermined level output from the connection point of the voltage divider resistor 401 and the voltage divider resistor 402. Output

When the initial driving current is output from the diaak 304 through the resistor 305, the power transistor 415 of the fluorescent lamp driving means 4 is turned on, and when the power transistor 415 is turned on at the step S3, the step S4 is performed. The current flows in the first and second fluorescent lamps 501 and 502 by the voltage charged in the capacitor 304, and thus the first and second fluorescent lamps 501 and 502 are discharged by the capacitors 503 and 504. The filament is preheated, and current flows through the primary coil 411 of the fluorescent lamp current converter 405 through the inductances 701 and 702 connected to the first and second fluorescent lamps 501 and 502. An organic current is generated in the coil 410 and the power transistor 408 is turned on by the generated organic current through the resistor 406 (at this time, the power transistor 415 is in an off state). Is generated, the power transistor 415 is turned on through the resistor 413 (at this time, the power transistor 408 is off). At the same time, the diode 306 receives a DC voltage output from the connection point of the voltage dividing resistors 301 and 302 and outputs a control signal current through a resistor 307 connected in series with the diode 306 so that the diaak ( OFF 304).

As described above, when the power transistors 408 and 415 are alternately turned on and off, the first and second fluorescent lamps 501 and 502 are continuously turned on.

At this time, when the current flow is described, when the power transistor 408 is turned on, the current flows in the direction of the inductance 701, 702 → the first and second fluorescent lamps 501, 502 → the capacitor 404. When the power transistor 415 is turned on, current flows in the direction of the capacitor 403 to the first and second fluorescent lamps 501 and 502 to the inductance 701 and 702 to the power transistor 415.

If the fluorescent lamp 5 is defective after the fluorescent lamp driving means 4 is operated at step S5 and the fluorescent lamp 5 is turned on, the secondary sides 701 'and 702' of the inductance 701 and 702 are defective. An organic current is generated at the output, and the generated organic current is half-wave rectified by the diode 703 and smoothed by the capacitor 704 to output a smoothed current. When the smoothed current is output from the capacitor 704, a voltage higher than or equal to a predetermined value, that is, the voltage at the point A of FIG. 2 is a breakdown voltage of the zener diode 705 in the control diode 705 connected inversely to the diode 703. If the result is determined to be greater than that and the result is that the potential of the point A of FIG. 2 is greater (YES) (that is, if the pulse of FIG. 4c is turned on), the zener diode 705 is energized to provide resistance. Current is output through 706, and a low level signal is output to the output side of the inverter 707. (The light is turned off in FIG. 4 (b).) In step S5, a low level signal is sent from the inverter 707 to the input terminal TIM of the timer element 708 due to the failure of the fluorescent lamp 5. When input, in step S6, the timer element 708 switches the high level signal current to the output terminal OUT according to the time constant determined by the resistor 709 and the capacitor 710, and the transistor 802 of the switching means 8. (I.e., when it is the 'on' signal of FIG. 4E), and when the transistor 802 receives the signal current through the bias resistor 801 to the base terminal in step S7, in step S8 The power transistor 415 is maintained in the off state, and the first and second fluorescent lamps 501 and 502 are turned off by the T time of FIG. 4 (e) in step S9.

On the other hand, when it is determined in step S5 that the potential of the point A in FIG. 2 is lower than the breakdown voltage of the zener diode 705, the zener diode 705 is turned off, and thus the timer element 708 output terminal. The switching means 8 does not operate by outputting a low-level signal at, and the fluorescent lamp 5 continues to be turned on by the operation of the fluorescent lamp driving means 4.

As described above, when the fluorescent lamp is defective, the fluorescent lamp is repeatedly turned on / off.

As described above, according to the fluorescent lamp lighting apparatus according to the present invention, a rectifying means for receiving a AC power and rectifying the bridge to output a voltage of a predetermined level, and a fluorescent lamp for lighting the fluorescent lamp by on / off alternating operation of the current converter and the power transistor. An overcurrent detecting means for detecting an overcurrent by receiving a predetermined operating voltage from a driving means, a direct current means for reducing the DC voltage output from the rectifying means to a voltage having a predetermined level, and a fluorescent lamp control signal output from the overcurrent detecting means. It consists of switching means for receiving on / off operation, and it detects when the fluorescent lamp is defective and reaches its end of life, and repeatedly turns on or off the fluorescent lamp to immediately inform the user of the time of replacement of the fluorescent lamp, as well as lighting the fluorescent lamp. To prevent breakage of power transistors And it is.

Claims (4)

Rectification means for receiving an AC power and outputting a direct current at a predetermined level; initial drive means for initially operating to preheat the filament of a fluorescent lamp receiving a constant level of direct current output from the rectification means; and operation of the initial drive means. A fluorescent lamp lighting device comprising a fluorescent lamp driving means for lighting a fluorescent lamp by receiving an output voltage of the rectifying means, the fluorescent lamp lighting device comprising: a direct current means receiving a output voltage of the rectifying means and outputting a direct current of a predetermined level; Overcurrent detection means for detecting an overcurrent caused by an overload from a power line supplied to the fluorescent lamp at the same time as receiving a DC voltage of a level; and when the overcurrent is detected by the overcurrent detection means and a fluorescent lamp off signal is output, the operation of the fluorescent lamp driving means is performed. Fluorescence characterized by consisting of switching means for stopping Lighting apparatus. The overcurrent detecting means (7) according to claim 1, wherein when the overcurrent detecting means (7) overloads due to a defective lamp of the fluorescent lamp (5), an organic current is applied to the secondary side (701 ') (702') of the inductance (701) (702). A voltage generated by the diode 703 for half-wave rectifying the induced current, a capacitor 704 for smoothing the current output from the diode 703, and a voltage equal to or greater than a predetermined breakdown voltage in series with the capacitor 704. A zener diode 705 passing through the bay, an inverter 707 receiving and inverting the voltage output from the cathode terminal of the zener diode 705 through the resistor 706, and an output voltage of the direct current means 6 A timer semiconductor element 708 (hereinafter referred to as a timer element) that operates upon receiving the output signal of the inverter 707 as an input terminal TIM and sets a time constant of the timer element 708 A resistor 709 and a capacitor 710, the timer element 7 The (RST) terminal connected to the (Vcc) terminal of the 08 and the resistor 709 are connected to each other, and the (DIS) (THR) terminal of the timer element 708 is the resistor 709 and the capacitor 710. Fluorescent lamp lighting device, characterized in that connected to the connection point. The transistor 802 of claim 1, wherein the switching means 8 receives an output signal output from the output terminal OUT of the timer element 708 through the resistor 801, and the transistor 802. And a resistor 803 connected between the base terminal and the emitter terminal, and the collector terminal of the transistor 802 has a connection point between the secondary coil 412 and the resistor 413 of the fluorescent lamp current converter 405. Fluorescent lamp lighting apparatus characterized in that connected to. The method according to claim 1, wherein the overcurrent detecting means (7) and the switching means (8) detect the overcurrent when the fluorescent lamp (5) is defective to protect the power transistors (408) (415) and repeat. Fluorescent lamp lighting device characterized in that for detecting the time of replacing the fluorescent lamp by the on / off operation.