JPH04274196A - Lighting device - Google Patents

Abstract

PURPOSE:To wire easily and determine a lamp life correctly even when a plural fluorescent lamps are used by providing a detection circuit to detect a current through a filament power supply, and obtaining a filament breakage detection signal from this detection circuit. CONSTITUTION:A constant voltage is supplied from a filament power supply to each filament of fluorescent lamps 2a, 2b, so a predetermined current flows through it constantly, and thermoelectrons are generated taking this filament for an electrode. A current detecting circuit 5 detects that at least one point is broken for the filaments connected with an output of the filament power supply 3 by reduction of an input current to the power supply 3, and it outputs a breakage signal S. When this signal S is given to a base of a transistor Q6, the transistor Q6 gets off, and a transistor Q5 also gets off. A power is thus prevented from being supplied to a high voltage generating circuit 4, and action of a circuit 4 is stopped.

Description

[Detailed description of the invention]

0001

[Field of Industrial Application] This invention relates to a lighting device that lights up a fluorescent lamp having a filament as an electrode while passing a current through the filament, and more particularly to a lighting device that can easily determine the lifespan of a fluorescent lamp with simple wiring. be.

0002

2. Description of the Related Art FIG. 5 is a schematic diagram showing the construction of a lighting device for lighting a fluorescent lamp having a filament electrode of this type. In the figure, reference numeral 1 denotes a lighting device for lighting a hot cathode type fluorescent lamp 2 having a filament as an electrode, and power is supplied from an input terminal T. Further, thermal fuses F1 and F2 are arranged near the filament electrode of the fluorescent lamp 2, and the power is supplied to the lighting device 1 through these thermal fuses F1 and F2.

Current is constantly flowing through the filament of the fluorescent lamp 2 by the lighting device 1, and when a high voltage is applied between the electrodes of the filament from the high voltage generating circuit in the lighting device 1, a discharge occurs inside the lamp. Then, the fluorescent lamp 2 is turned on. Here, in the hot cathode type fluorescent lamp 2, an abnormal temperature rise occurs in the filament electrode portion at the end of its life, so this must be prevented. Therefore, thermal fuses F1 and F2 are arranged near the filament electrode portion, and these thermal fuses F1 and F2 are connected in series to the input power line of the lighting device 1. Then, due to an abnormal temperature rise in the filament electrode part, thermal fuses F1 and F
2 becomes disconnected, the input power to the lighting device 1 is cut off, and lighting of the fluorescent lamp 2 is stopped.

[0004] In addition to the above-mentioned method of providing thermal fuses F1 and F2, there are other methods and means for determining the end of the life of the fluorescent lamp 2 and stopping the lighting device 1 using a circuit.
There are following methods. That is, a circuit is provided to detect the discharge voltage or discharge current of the fluorescent lamp 2, and it is possible to determine the lamp life by increasing the discharge voltage, determining the lamp life by decreasing the discharge current, and detecting the asymmetry of the lamp voltage. There are methods such as detecting the temperature and determining the lamp life.

[0005]

[Problems to be Solved by the Invention] However, in conventional lighting devices having fluorescent lamps as described above, there are variations in the temperature rise of the filament electrode, so it is difficult to set the temperature of the thermal fuse or install it. This method is difficult, and thermal fuses are usually installed in the input power line of the lighting device, and they are placed at two electrodes for each fluorescent lamp, so wiring is troublesome, especially when connecting multiple fluorescent lamps. There is a problem in that there is a lot of wiring when lighting the lamp, which increases the cost.Also, when determining the lamp life by detecting the lamp voltage and lamp current, a detection circuit is required for each fluorescent lamp. However, when a plurality of fluorescent lamps are used, there are problems in that the cost is high and the circuit scale becomes large.

[0006] This invention was made in view of the above-mentioned problems. Even when a plurality of fluorescent lamps are used, wiring is easy, lamp life can be determined correctly, and costs are reduced. The present invention also aims to obtain a lighting device that can be downsized.

[0007]

[Means for Solving the Problems] The lighting device of the present invention includes:
In a lighting device that includes a fluorescent lamp having a filament as an electrode and lights up by applying a high voltage between the electrodes while supplying electric power to the filament, current detection detects an input current flowing to a filament power source that supplies electric power to the filament. The circuit is configured to obtain a filament breakage detection signal from this current detection circuit, and the filament breakage detection signal controls the operation of a high voltage generation circuit that applies a high voltage between the electrodes of the fluorescent lamp. The fluorescent lamp has a heat dissipation structure near the filament.

[0008]

[Operation] In the lighting device of the present invention, the input current flowing to the filament power source is detected by the current detection circuit,
When this current decreases below, for example, a certain predetermined value, filament breakage is detected and a breakage detection signal is extracted.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a circuit diagram of a lighting device according to an embodiment of the present invention. In the figure, 1 is a lighting device for lighting hot cathode type fluorescent lamps 2a and 2b that use filaments as electrodes, and a filament power source 3 that supplies electrodes to the filaments of each fluorescent lamp 2a and 2b, and a high voltage between the filament electrodes. The high voltage generating circuit 4 applies a high voltage, and the current detecting circuit 5 detects the input current flowing to the filament power source 3. The filament disconnection detection signal S is obtained from the current detecting circuit 5. Note that this current detection circuit 5 has a direct current (DC) smoothed by a capacitor C1.
is now entered.

In the filament power supply 3, L1 is a stabilizing coil, T1 is an inverter transformer, the primary winding is connected to transistors Q1, Q2 and a capacitor C2,
A control winding and resistors R1, R2 are connected to the bases of these transistors Q1, Q2, and a secondary winding is connected to each fluorescent lamp 2a.
, 2b via a capacitor. In addition, in the high voltage generation circuit 4, C3 and L2 are smoothing and stabilizing capacitors and coils, T2 is an inverter transformer, and on the primary side, transistors Q3 and Q4, capacitor C4, and resistors R3 and R4 are installed like the above transformer T1. The secondary side is connected to the fluorescent lamp 2a through a capacitor.
It is connected to the filament on one side of 2b. Note that the filaments on opposite sides of the fluorescent lamps 2a and 2b are grounded. In addition, in FIG. 1, Q5 and Q6 are transistors, and R5
, R6, and R7 are resistors.

In the lighting device configured as described above, a constant voltage is supplied from the filament power source 3 to each filament of the fluorescent lamps 2a and 2b, and a predetermined current always flows, and heat is constantly generated using the filament as an electrode. Electrons are being generated. And high voltage generation circuit 4
When a high voltage is applied between the filament electrodes,
Discharge occurs inside the lamp, and the fluorescent lamps 2a and 2b are turned on. At this time, normally the transistor Q6 is on (ON) and the transistor Q5 is also on, and power is supplied to the high voltage generating circuit 4 through the transistor Q5.

Generally, in hot cathode type fluorescent lamps 2a and 2b as described above, thermoelectrons are emitted by heating the emitter coated on the filament electrode, but the emitter is worn out. When this happens, it becomes difficult to emit thermoelectrons, and abnormal heat generation occurs at the filament electrode. If the fluorescent lamps 2a and 2b continue to be lit while this abnormal heat generation is occurring, the filament made of tungsten or the like will evaporate due to the heat and the high voltage applied to the fluorescent lamps 2a and 2b. Eventually, a disconnection will occur. As a result of actual measurements, the time from when the emitter of the filament is consumed until the filament breaks is about several minutes to several tens of minutes.

The current detection circuit 5 of FIG. 1 detects that the input current of the filament power supply 3 decreases due to a break in at least one of the above-mentioned filaments connected to the output of the filament power supply 3. When there is a disconnection, a disconnection detection signal S is output. Then, when this detection signal S is given to the base of transistor Q6,
Transistor Q6 is turned off (OFF), and transistor Q5 is also turned off. Therefore, no power is supplied to the high voltage generation circuit 4, and the operation of the high voltage generation circuit 4 is stopped. In this way, abnormal conditions at the end of the life of the fluorescent lamps 2a and 2b can be detected, and the lamp life can be correctly determined.
Safety measures will be sufficient.

[0014] In the case of a spread lighting device that lights a large number of fluorescent lamps, by driving the filament of each fluorescent lamp with one filament power supply, the current for determining the lifespan of each fluorescent lamp can be increased. There is no need to provide a detection circuit for each fluorescent lamp, and the detection circuit can be shared. Therefore, even when a plurality of fluorescent lamps are used, wiring is easy, and costs and size can be reduced. At that time, fluorescent lamps 2a to 2 are lit as shown in FIG.
If the number of f is very large and one filament power supply is insufficient, multiple filament power supplies 3a,
3b, one current detection circuit 5a, 5b may be connected to each filament power source 3a, 3b, and the current flowing through each filament power source 3a, 3b may be detected separately. Furthermore, as shown in FIG. 3, the input power supply line of each filament power supply 3a, 3b may be made common and the current detection circuit 5 may be connected to this, and in either case, the lamp life of the fluorescent lamps 2a to 2f can be corrected. can be easily distinguished.

In FIGS. 2 and 3, 6 is a switch circuit composed of the transistors Q5 and Q6 of FIG. / Turn off. Further, 7 in FIG. 3 is a fluorescent lamp circuit having the fluorescent lamps 2a to 2f of FIG. 2.

Further, it is desirable that the vicinity of the filaments of each of the fluorescent lamps 2a to 2f and the entire lighting device 1 have a heat radiating structure. In other words, when detecting the lamp life as described above, the lamp temperature increases between the time the emitter wears out and the time the filament breaks, which may cause damage to equipment using the lighting device. . Therefore, by taking heat dissipation measures as described above, it is possible to prevent the temperature near the filament electrode from exceeding the heat resistant temperature of the used part of the device before the filament breaks. FIG. 4 shows how the temperature near the filament electrode changes at that time, and (a) shows the case where no heat radiation measures are taken, and (b) shows the case where heat radiation measures are taken. In the figure, T1 indicates the indoor temperature, and T2 indicates the heat-resistant temperature of the device.If no heat dissipation measures are taken between the time when the emitter wears out and the time when the filament is disconnected at time t, the area near the filament electrode as shown in the figure. The temperature is the device's heat-resistant temperature T2
However, if heat dissipation measures are taken, it will not exceed the device's heat-resistant temperature T2. As this heat dissipation structure, for example, there is a method of forming a heat dissipation path.

In this way, the lifespan of multiple fluorescent lamps can be determined by detecting a decrease in the current of the common filament power supply due to filament breakage, and by combining this with heat dissipation measures, damage to the equipment can be minimized. can be limited. At that time, since filament breakage is detected, it is possible to detect not only abnormal conditions at the end of the fluorescent lamp's life.
It is also possible to detect filament breaks due to mechanical causes such as vibrations and shocks. In addition, in the conventional method of detecting lamp voltage, the longer the length of the fluorescent lamp, the higher the voltage, the shorter the lamp, the lower the voltage, and the thicker the tube diameter, the lower the voltage.
The thinner the lamp, the higher the voltage, so the detection voltage must be set according to the type of fluorescent lamp, making design difficult. However, in the method of the above-described embodiment, since the characteristics of the filament current are relatively stable, the design is easy and stable detection can be performed. Furthermore, the lamp voltage varies greatly with temperature, being high at low temperatures and low at high temperatures, so temperature correction is required when the operating temperature range is wide. At this point as well, since the filament current is stable,
The circuit design is easy and stable operation is possible.

[0018]

[Effects of the Invention] As described above, according to the present invention, a detection circuit for detecting the current flowing through the filament power supply is provided,
Since the filament breakage detection signal is obtained from this detection circuit, wiring is easy even when multiple fluorescent lamps are used, and lamp life can be accurately determined.
Further, the circuit design is easy, the filament breakage caused by mechanical causes can be detected, and the cost and size can be reduced.

[Brief explanation of the drawing]

[Figure 1] Circuit configuration diagram showing one embodiment of this invention

[Figure 2] Block diagram showing the circuit configuration when using multiple fluorescent lamps

[Figure 3] Block diagram showing the circuit configuration when using multiple fluorescent lamps

[Figure 4] Explanatory diagram showing changes in temperature near the filament electrode

[Figure 5] Block diagram showing a conventional example

[Explanation of symbols]

1. Lighting device 2a-2f Fluorescent lamp 3, 3a, 3b Filament power supply 4 High voltage generation circuit 5, 5a, 5b Current detection circuit

Claims (3)

[Claims] 1. A lighting device comprising a fluorescent lamp having a filament as an electrode and lit by applying a high voltage between the electrodes while supplying electric power to the filament, wherein an input current flows to a filament power supply supplying electric power to the filament. 1. A lighting device comprising: a current detection circuit for detecting a current detection circuit; and obtaining a filament breakage detection signal from the current detection circuit. 2. The lighting device according to claim 1, wherein the filament breakage detection signal causes the operation of a high voltage generation circuit that applies a high voltage between electrodes of the fluorescent lamp to be stopped. 3. The illumination device according to claim 1, wherein a heat dissipation structure is provided near the filament of the fluorescent lamp.