JPS6340039B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a lighting device for a fluorescent lamp used for night lighting indoors or outdoors.

Generally, this type of fluorescent lamp lighting device causes an oscillation transistor to oscillate when a switch is turned on, and this oscillation generates a high voltage on the secondary side of an oscillation transformer, and this high voltage lights the fluorescent lamp. However, for example, in this lighting device, if the switch is turned on with the fluorescent tube removed, that is, with no load, a large current will flow through the oscillation transistor, causing thermal runaway damage to the oscillation transistor. In addition, there was a problem in that the battery power was wasted.

In view of the above problems, the present invention aims to prevent thermal runaway destruction of the oscillation transistor and wasteful consumption of battery power when the switch is turned on with the fluorescent tube removed, that is, with no load. This is the purpose.

The basic configuration of the present invention for achieving the above object is to connect the primary winding of the oscillation transformer and the filament preheating winding of the fluorescent tube on the secondary side of the oscillation transformer, and connect them to the battery power source. A diode connected to the negative side and between the filament preheating winding and the filament of the fluorescent tube, the anode side of which is located on the negative side of the battery power source, and the cathode side of which is located on the filament side of the fluorescent tube; The base of the no-load protection transistor is connected to the cathode side of the diode, and the collector thereof is connected to the base circuit of the oscillation transistor.

According to the present invention, with the above configuration, when the switch is turned on with the fluorescent tube removed, that is, with no load, the base current of the no-load protection transistor does not flow, so that current also flows to the oscillation transistor. As a result, thermal runaway destruction of the oscillation transistor and wasteful consumption of the battery power source, which are conventional, can be prevented.

Hereinafter, one embodiment of the present invention will be described based on the drawings. In the figure, 1 is the battery power supply of the car, which is a 12V DC battery power supply. 2 is an on-off switch connected to the positive side of the battery power source 1; 3 is an electrolytic capacitor connected in parallel to the battery power source 1; this electrolytic capacitor 3 is provided to reduce the internal impedance of the battery power source 1; It is something that was given. 4 is an oscillation transistor; 5 is a no-load protection transistor; this transistor 5 uses the base resistor 6 of the oscillation transistor 4 as a collector resistor. 7 is a resistor connected between the base and emitter of the no-load protection transistor 5;
9 is a capacitor connected in series to the base resistor 6 of the oscillation transistor 4;
A connection point 9 is connected to the emitter of the oscillation transistor 4. 10, 11, 12, 13, 14
are windings wound around the same ferrite core, and constitute the oscillation transformer 15. The primary winding 11 of this oscillation transformer 15 and the oscillation transformer 1
Filament preheating winding 14 that preheats one filament 16a of the fluorescent tube 16 on the secondary side of 5.
are connected, and these are connected to the negative side of the battery power supply 1. Further, the other filament 16b of the fluorescent tube 16 is connected to the filament preheating winding 12 on the secondary side of the oscillation transformer 15. 18 is a capacitor connected in parallel with the high voltage winding 13 on the secondary side of the oscillation transformer 15;
7 is a fluorescent lamp current control capacitor connected between one of the capacitors 18 and one of the filament preheating windings 12. 19 is a diode connected between the filament preheating winding 14 and one filament 16a of the fluorescent tube 16;
The anode side of this diode 19 is located on the negative side of the battery power source 1, and the cathode side is located on the negative side of the battery power source 1.
6 is connected so as to be located on one side of the filament 16a. The base of the no-load protection transistor 5 is connected to the cathode side of the diode 19 via a resistor 20, and the collector is connected to the base of the oscillation transistor 4 via the base resistor 6 and the primary winding 10. ing. Reference numeral 21 denotes a metal reflecting plate, and this metal reflecting plate 21 is connected to the negative side of the battery power source 1 so that it also serves as a proximal conductor.

The operation in the above configuration will be explained. First, when the fluorescent tube 16 is properly installed,
When the switch 2 is turned on, the base current of the no-load protection transistor 5 flows through the resistor 20, one filament 16a of the fluorescent tube 16, and the filament preheating winding 14 to the negative side of the battery power supply 1, so no-load protection is achieved. transistor 5 is turned on.
When turned on, the oscillation transistor 4 is also turned on via the base resistor 6 to cause blocking oscillation, and this oscillation generates a high voltage on the secondary side of the oscillation transformer 15, which lights up the fluorescent tube 16.

On the other hand, if the switch 2 is turned on with the fluorescent tube 16 removed, that is, with no load,
Since the base current of the no-load protection transistor 5 does not flow due to the breakage in one filament 16a of the fluorescent tube 16, the no-load protection transistor 5 is turned off. Due to this off, the oscillation transistor 4 is cut off and no current flows, so
Thermal runaway destruction of the oscillation transistor 4 will no longer occur. Further, by cutting off the oscillation transistor 4, unnecessary consumption of the battery power source 1 can be prevented.

As described above, according to the present invention, when the switch is turned on with the fluorescent tube removed, that is, with no load, the structure is such that no current flows through the oscillation transistor, unlike the conventional method. This prevents the oscillation transistor from being destroyed by thermal runaway, and also prevents wasteful consumption of the battery power source.

[Brief explanation of the drawing]

The figure is a circuit diagram of a lighting device for a fluorescent lamp according to an embodiment of the present invention. DESCRIPTION OF SYMBOLS 1...Battery power supply, 2...Switch, 4...Oscillation transistor, 5...No-load protection transistor, 11...Primary winding, 14...Filament preheating winding, 15...Oscillation transformer, 16 ...Fluorescent tube, 16a...Filament, 19...Diode.

Claims (1)

[Claims] 1. In a fluorescent lamp lighting device that causes an oscillation transistor to oscillate when a switch is turned on, this oscillation generates a high voltage on the secondary side of an oscillation transformer, and this high voltage lights a fluorescent tube. Connect the side winding to the filament preheating winding of the fluorescent tube on the secondary side of the oscillation transformer, connect these to the negative side of the battery power supply, and connect the filament preheating winding and the filament of the fluorescent tube. , connect a diode whose anode side is located on the negative side of the battery power supply and whose cathode side is located on the filament side of the fluorescent tube, and further connect the base of a no-load protection transistor to the cathode side of the diode, and connect the collector thereof. A lighting device for a fluorescent lamp connected in series to the base circuit of the oscillation transistor.