WO1990014745A1 - Process and control cirucit for regulating the luminous intensity of tubular lamps with two incandescent filaments - Google Patents

Abstract

In a process for regulating the luminous intensity of tubular lamps with a heated cathode, a continuous voltage is applied between the cathode and the anode of the tubular lamp. This voltage is maintained and the tubular lamp is lit by an ignition pulse. The cathode is heated continuously during the operation of the lamp. The intensity of the current passing through the tubular lamp oscillates between a maximum current corresponding to the maximum luminous intensity, a current sufficient to maintain the luminous discharge and a minimum current which generates a luminous intensity at least two orders of magnitude less than the maximum luminous intensity. The periods of oscillation are shorter than the inertia of the eyes and the luminous intensity is adjusted by varying the temporal relationships between the maximum and minimum currents during each period. The control circuit is characterized by the fact that it comprises two limiting elements connected in parallel. The limiting threshold value of the first limiting element is equal to the current required to maintain the luminous discharge in the tubular lamp. The second limiting element consists of a controlled switch having a limiting threshold value equal to the operating current of the tubular lamp. The control input of the controlled switch is connected to a control circuit (5) which generates pulses of variable duration. In another embodiment, the first limiting element is absent and the switch is controlled by a control circuit which generates periodic pulses of controllable duration. The ignition circuit comprises a pulse generator which generates ignition pulses at the beginning of each period while the controllable switch is still switched off.

Description

 METHOD AND CONTROL CIRCUIT FOR CONTROLLING THE LIGHTNESS OF

FLUORESCENT TUBES WITH TWO THREADS

The invention relates to a method for regulating the

Luminous intensity of fluorescent tubes with a heated cathode, with one between the cathode and the anode on the fluorescent tube

DC voltage is applied and the fluorescent tube is ignited by an ignition pulse while maintaining this voltage.

The invention further relates to a control circuit for fluorescent tubes with a heated cathode, in which the filament of the fluorescent tube is connected to a current source supplying the heating voltage and between the heated cathode and the other electrode a direct voltage supply source and a current-limiting element connected in series and the Luminous tube is connected to an ignition circuit.

Reliable solutions for the continuous regulation of the luminous intensity of fluorescent tubes are not yet widespread. The light intensity of conventional incandescent lamps can be changed by changing the mean value of the supply voltage e.g. can be easily regulated by the phase control, on the other hand the switching on and off of fluorescent tubes takes a predetermined time due to the special properties of the ignition required for starting the gas discharge process. The ignition time is so long that the eye cannot perceive two successive ignitions as a single ignition, which means that the change in the on and off times could not lead to a light intensity control that was noticeable to the eye.

I have already tried to continuously regulate the luminous intensity of fluorescent tubes by shortening the ignition time. In such experiments, the required ignition circuits were relatively complicated and the conditions of the ignition were influenced by the external temperature. The object of the invention is to provide a method and a control circuit which enable the regulation of fluorescent tubes, in particular compact fluorescent tubes, in a simple and reliable manner. To solve the problem, it was assumed that the light intensity control does not require the gas discharge process in the fluorescent tube to be interrupted, although most of the difficulties result from the repeated starting of this process. If instead of the interruption of the gas discharge, the value of the discharge current is limited to such a low level at which the light intensity is not noticeable or only negligible, and to this minimum current with a predetermined repetition frequency, current pulses which are associated with the full light intensity - are arranged, are superimposed, the noticeable light intensity will depend on the ratio of the duration of the pulses and can be changed thereby. For such a process, the continuous heating of the cathode of the fluorescent tube is required. With the invention, a method for regulating the light intensity of fluorescent tubes with a heated cathode was created, in which a direct voltage is applied to the fluorescent tube between the cathode and the anode and the fluorescent tube is lit by an ignition pulse while maintaining this direct voltage, and is the invention characterized in that the cathode is continuously heated during operation, that the magnitude of the current flowing through the fluorescent tube is between a maximum current corresponding to the maximum light intensity and a current which is sufficient for maintaining the gas discharge and one in comparison the maximum luminous intensity is changed by at least two decimal orders of magnitude generating minimal luminous intensity in periods which are shorter than the inertia of the eye, and the luminous intensity by changing the temporal ratio of the maximum and minimum currents within b of the individual periods is regulated.

In one embodiment, the individual periods -3-

started with the minimum current, and the current value is increased to the maximum value at the time which corresponds to the ratio mentioned and is maintained until the end of the period. The advantage of this solution lies in the simplification of the type of control.

To achieve reliable ignition, it is advantageous if the ignition pulses are repeated periodically at time intervals that are significantly longer than the periods mentioned. The invention also relates to a control circuit for fluorescent tubes with a heated cathode, in particular for compact fluorescent tubes, in which the filament of the fluorescent tube is connected to a current source supplying the heating voltage and between the heated cathode and the other electrode a direct voltage supply source and a so that a current-limiting element connected in series is connected, and the fluorescent tube is connected to an ignition circuit, and the control circuit according to the invention is characterized in that two current-limiting elements connected in parallel are provided, the limiting threshold value of the first limiting element being used to maintain the Gas discharge corresponding current in the fluorescent tube corresponds to the other limiting element being formed by a controlled switch, preferably a transistor, which has a limiting threshold value which corresponds to the operating current of the fluorescent tube corresponds to the fact that the control input of the controlled switch is connected to a control circuit which generates periodically repeating pulses with a variable pulse duration. The first limiting element is preferably formed by a resistor.

A preferred embodiment is characterized in that a transistor and a resistor connected in series are provided in the second limiting element, the collector-emitter path of the transistor being connected between the one terminal of the supply source and the aforementioned electrode of the light tube, and the Base of the transistor above -4-

an optical coupler is connected to the control circuit.

For the separation of the control and ignition circuits, it is particularly advantageous if an ignition electrode of this type is used, which is capacitively adapted to the envelope of the fluorescent tube and is connected to a pulse generator via a pulse transformer.

The life of the tube can be doubled if a tube with two filaments is used. If one filament is broken or loses its emissivity, the fluorescent tube remains functional with the other filament.

In an alternative embodiment it is no longer necessary to always maintain the ignited state of the fluorescent tube. In this case, the ignition at the beginning of the periods only has to take place when the switch is already in the closed state. The switching branch that determines the low tube current can be omitted here. Such a circuit arrangement is characterized in that the current-limiting element lies between the anode of the fluorescent tube and the positive terminal of the supply voltage and this element is connected in series with a controlled switch formed by an optical coupler, the limited current to the operating current of the Luminous tube corresponds, and the input of the optical coupler, which is galvanically isolated from the switching path, is connected to a control circuit which generates periodically repeating pulses with a controllable pulse duration, and a pulse generator is provided in the ignition circuit, but which already provides the ignition pulses at the beginning of the respective periods generated in the closed state of the controlled switch.

The invention is explained in more detail below by means of examples, reference being made to the accompanying drawings. On the drawing:

1 shows the circuit diagram of an embodiment of the circuit arrangement according to the invention, FIG. 2 shows the time diagram of the through the fluorescent tube -5-

flowing current, and Fig. 3 shows the timing diagram of the ignition pulses. FIG. 4 shows a time diagram relating to a further embodiment of the invention.

Fig. 1 shows a fluorescent tube 1 with two filaments, of which one filament 2 is connected to a power source 3, which supplies a constant heating voltage. The other filament 4 fulfills the role of the anode and is not heated. One end of the filament 2 is grounded and the grounding point also forms the negative pole of the DC power source. A transistor T1, and also one end of the resistors R1, R2 and R3 are connected to the terminal V + emitting a positive voltage. The resistor R2 functions as a collector resistor of a transistor T2, which forms part of an optical coupler OCS, and the collector of the transistor T2 is connected to the base of the transistor T1. One end of the resistors R4, R5 and R3 is connected to the filament 4. A light-emitting diode D is arranged in the optical coupler OCS, one end of which is connected to the resistor R1 and the other end to a control circuit 5, which is preferably formed by a register or a latch circuit.

In the embodiment shown in FIG. 1, the lighting of the fluorescent tube 1 is made possible by a capacitive ignition electrode 6, which covers a section of the envelope of the fluorescent tube 1. The ignition electrode 6 is connected via a pulse transformer 7 to a pulse generator 8, which generates the ignition pulses shown in FIG. 3. The operation of the circuit arrangement according to the invention is as follows:

The filament 2 of the fluorescent tube 1 is continuously heated with a nominal heating voltage. A DC voltage is connected to the terminal V +, which is somewhat higher than the anode voltage determined by the tube type, which is typically between 50-70 V in the commercially available compact fluorescent tubes. For the lighting of the fluorescent tube 1, the on Fig.

90/14745

-6-

3 ignition pulses shown connected to the ignition electrode 6. Theoretically, a single ignition pulse is sufficient for operation, in contrast, the ignition pulses are in periods of 1-2 sea. repeated, so that in the event of a possible and merely accidental interruption of the anode current, the fluorescent tube 1 returns to the ignited state. The size of the tube current generated is determined by the state of the output of the control circuit 5. In the active state of this output, the current flows through the resistor R1 and the light-emitting diode D, and the transistor T2 succeeds in the conductive state on the effect of the light control. In this state (if the tube has already been lit) the size of the anode current is practically determined only by the value of the resistor R4, and this size is typically around 150 mA. With such a current, the fluorescent tube 1 lights up with full light. The current value I "belonging to the completely lit state was shown in FIG. 2.

If the control circuit 5 is in the passive state and the transistor 1 is blocked, no current flows through the resistors R4 and R5. However, an anode current of approximately 1-1.5 mA will flow through resistor R3. The size of this minimum current I is selected such that the gas discharge in the fluorescent tube is still maintained in the operating temperature range. The size of the current I can be set by the value of the resistor R3. If only the minimal current I flows through the fluorescent tube, the discharge has so little energy that visible light is not generated at all or only with so little energy that the fluorescent tube 1 remains dark. The uninterrupted heating and the sustained gas discharge enable the size of the current flowing through the fluorescent tube 1 to be changed with the aid of the control circuit between two discrete values without inertia.

Fig. 2 shows z. B. the light intensity control of the tube 1 by pulse width modulation. The control circuit 5 is controlled in regular, for example 20 ms long intervals in the initial state, and within the individual periods the Transistor T2 is only opened for a predetermined period of time in accordance with the light intensity to be set by an external control. In the first two periods a and b according to FIG. 2, the current only takes up the value corresponding to the maximum light intensity in 25% of the full time, and because of the integrating effect and the sluggishness of the eye, only a quarter of the maximum light intensity is perceived. In the subsequent two periods c and d, the current flows for a longer time, which corresponds to 75% of the period. Accordingly, the perceived luminous intensity becomes three times greater than in the first two periods.

Although the aforementioned principle of the light intensity control does not determine when the pulse belonging to the maximum light intensity is to be generated within the individual periods, it is advantageous with regard to the control if the current flowing through the transistor T1 at the end of the individual periods is interrupted, and in the subsequent period, if the current has already been started, is maintained until the end of the period. When the current is interrupted via the transistor T1, the gas discharge is maintained by the parallel branch.

When the solution according to the invention was explained, an ignition which was released with the aid of the ignition electrode was described. The ignition can also by other known methods, such. B. be solved by the series connection of the ignition winding of an ignition transformer with the anode-cathode path of the fluorescent tube 1. The advantage of the described solution lies in the complete separation of the pulse control and ignition circuits, which is particularly advantageous when a large number of fluorescent tubes are controlled at the same time.

The use of the fluorescent tube 1 with two cathodes ensures a longer service life, since if the filament 2 breaks or loses its emission, the operation can be continued again by replacing it with the filament 4 (by inserting the fluorescent tube in its socket in the opposite direction) can, and only then the tube 1 can no longer be used -8th-

is when the second filament 4 breaks or loses its emission.

In an alternative possibility of the solution according to the invention, the resistor 3 can be omitted. In this case, the gas discharge is completely interrupted when transistor T2 is turned off. The light intensity control can now be solved with the control shown in FIG. 4. The fluorescent tube 1 is continuously heated and the DC voltage at terminal V + au is maintained. The starting times of the individual operating periods were designated in FIG. 4 with the times 0, 20, 40 and 60 ms. The transistor T2 is controlled in the conductive state immediately before these times. At the designated starting times, i.e. if the transistor T2 is already in the conductive state, the fluorescent tube 1 is ignited by the ignition electrode 6, and the transistor T2 is blocked at the times t1, t2 and t3 corresponding to the desired light intensity, and the current of the fluorescent tube 1 is interrupted. The fluorescent tube can therefore only light up during the duration of the pulses shown in FIG. 4.

The advantages of this control principle are particularly noticeable when the simultaneous control of a large number of fluorescent tubes 1 is required. Such a task can e.g. arise when operating the light display panel. The advantage lies in the fact that the pulse transformer 7 shown in FIG. 1 is suitable for the control of the ignition electrode of a large number of fluorescent tubes 1; the extinguishing times of the tubes, on the other hand, are controlled by the controller (ie by shutting off the Transistor T2) determined. The

Repeated ignition makes the task of maintaining the gas discharge superfluous, as a result of which the disruptive optical effect which comes from the light of the gas discharge maintained with a low current ceases.

Claims

- -Patent claims

1. A method for regulating the luminous intensity of fluorescent tubes with a heated cathode, in which a direct voltage is applied to the fluorescent tube between the cathode and the anode and the fluorescent tube is ignited by an ignition pulse while maintaining this direct voltage, characterized in that during operation the cathode is continuously heated so that the magnitude of the current flowing through the fluorescent tube is between a maximum current (I _M ) corresponding to the maximum light intensity and one which is still sufficient for maintaining the gas discharge and one in comparison to that maximum light intensity is changed by at least two decimal orders of magnitude lower light intensity generating minimum current (I) in periods that are shorter than the inertia of the eye, and the light intensity by changing the temporal ratio of the maximum and minimum current (I _M and I ) within the individual periods is valid.

2. The method according to claim 1, characterized in that the individual periods are started with the minimum current (Im), that the current value at the time corresponding to the above-mentioned ratio increases to the maximum value (I) and is maintained until the end of the period.

3. The method according to claim 1 or 2, characterized in that the ignition pulses are repeated periodically at time intervals which are substantially longer than the periods mentioned.

4. Control circuit for fluorescent tubes with a heated cathode, in particular for compact fluorescent tubes, in which the

Filament of the fluorescent tube to a current source supplying the heating voltage and between the heated cathode and the other electrode a DC voltage source and thus in Series-connected current-limiting element is connected, and the fluorescent tube is connected to an ignition circuit, characterized in that two elements limiting the current and connected in parallel are provided, the limiting threshold value of the first limiting element being the current corresponding to maintaining the gas discharge in the fluorescent tube ( I) corresponds to the fact that the other limiting element is formed by a controlled switch, preferably a transistor (Tl), which has a limiting threshold value which corresponds to the operating current (I _M ) of the fluorescent tube, that the control input of the controlled switch is connected to a control circuit ( 5) is connected, which generates periodically repeating pulses with variable pulse duration.

5. Control circuit according to claim 4, characterized gekennzeich¬ net that the first limiting element is formed by a resistor (R3).

6. Control circuit according to claim 4 or 5, characterized in that a transistor in the second limiting element

(T1) and a resistor (R5) connected in series therewith are provided, the collector-emitter path of the transistor (T1) being connected between the one terminal (V +) of the supply source and the aforementioned electrode of the light tube (1) and the base of the transistor (T1) is connected to the control circuit (5) via an optical coupler (OCS).

7. Control circuit according to one of claims 4 to 6, da¬ characterized in that it has an ignition electrode (6) which is capacitively adapted to the envelope of the fluorescent tube (1) and via a pulse transformer (7) on a pulse generator (8) is connected.

8. Control circuit according to one of claims 4 to 7, da¬ characterized in that it has a fluorescent tube (1) with two filaments.

9. Control circuit for fluorescent tubes with a heated cathode, in particular for compact fluorescent tubes, in which the filament of the fluorescent tube is connected to a current source supplying the heating voltage and between the heated cathode and the other electrode a direct voltage supply source and a current-limiting element connected in series is, and the fluorescent tube is connected to an ignition circuit, characterized in that the current-limiting element lies between the anode of the fluorescent tube (1) and the positive terminal (V +) of the supply voltage, and this element is controlled by a control element formed by an optical coupler (OCS) Switch is connected in series, the limited current corresponds to the operating current (I) of the fluorescent tube (1), and the input of the optical coupler (OCS), which is galvanically isolated from the switching path, is connected to a control circuit (5) which repeats periodically repeating pulses generated with controllable pulse duration, and in the Zünds a pulse generator is provided which generates the ignition pulses at the beginning of the respective periods but already when the controlled switch is closed.