NO119448B - - Google Patents

Description

Device for lighting and feeding discharge fluorescent tubes.

The present invention relates to a device for using discharge tubes to produce light, in particular to achieve light effects in connection with illuminated advertisements.

The invention applies in particular to an application for ignition and feeding of discharge tubes for lighting, where the ignition takes place

progressively from one end of the tube to the other by applying a high-frequency voltage with variable amplitude, and where an energy transmission line is arranged between the output of the high-frequency oscillator and the tube to be ignited.

The devices that have been proposed so far to realize this effect have not made it possible to achieve good results, and they are practically not used industrially.

The purpose of the invention is to improve devices which make it possible by means of simple means and with little expense to achieve results that are completely satisfactory.

In the known devices of that nature

that pertains to the invention, there is arranged between the high-frequency oscillator and the tube to be ignited a feed line which is connected by mutual induction on one side to the output of the oscillator and on the other side to a circuit which is connected to the tube terminals. As this circuit should have low impedance, and as you have to lower the voltage at the input of the line and raise it at the output, the efficiency is low. Also, because of the two series connections, it is very difficult to load the oscillator correctly.

According to the invention is eliminated

this disadvantage in that one end of the

the transmission line is connected to the output of the high-frequency oscillator and the other end with a series connection of an impedance with high self-induction and a capacitive impedance, the tube being connected in parallel with the capacitive impedance.

Such a device makes it possible to effect a progressive ignition of several meters of pipe.

The inventor has become aware that it is advantageous to use frequencies of the order of 100 kp/s. The advantages this entails are essentially the following. This frequency lies outside those used for broadcasting. It means that, in order to achieve appropriate values for the overvoltage in the tuned circuit, relatively large values are obtained for the capacity that lies above the clamps on the tube while maintaining a relatively large ratio L/C. The values of this capacity are such that the parasitic capacities for the pipe and its assembly become vanishingly small. It is therefore possible to manufacture devices that will always function correctly in a factory manner.

The invention also ensures that the value of the self-inductive impedance in the transmitter circuit is approximately equal to the value of the capacitive impedance, as their resultant in this way is approximately equal to zero for the frequency f(l) which corresponds to complete ignition of the tube.

According to another distinctive feature of the invention, there is arranged progressive and successive ignition of several tubes, which e.g. are arranged so that they form a luminous advertisement, with a switching device which makes it possible, when a tube is lit, to feed this tube at the same time and immediately transfer the ignition to the following tube.

The feeding of a tube that is lit can be realized by replacing the variable high-frequency voltage with a high-frequency voltage or a voltage with mains frequency but with a constant voltage immediately after the ignition.

According to one embodiment of the invention, the switch device is made up of a set of chambers which are moved by means of a motor.

Other special features and advantages of the devices according to. the invention will be apparent from the following description which applies to embodiments which are shown as examples.

In the description, reference is made to the attached schematic drawings, where fig. 1 shows a diagram of the connection between a tube and the output of the oscillator. Fig. 2 and 3 show variants of the assembly and fig. 4 a schematic of an oscillator. Fig. 5 shows a diagram for a device with associated capacitors which makes it possible by means of just one oscillator to ensure the successive ignition of several tubes. Fig. 6 and 7 show diagrams for switch systems for the ignition and operation of several tubes. Fig. 8 shows a diagram of a device which makes it possible to use only one oscillator for ignition and operation.

The high-frequency oscillator 1 comprises, as shown in fig. 1 at its output a self-inductance 2 to which is connected the self-induction 3 in the circuit 4 which is the circuit through which the energy is sent between the oscillator and the light tube 5. In this circuit an inductive impedance 6 is mounted in series with the tube and in parallel with the tube a capacitor 7 .The circuit and the tube are connected to ground at one end.

It can be seen that this assembly only comprises a coupling, as this is realized between the windings 2 and 3. On the other hand, the placement of the self-inductance 6 and the capacitor 7 makes it possible to give this circuit the desired characteristic data to achieve an absolutely progressive ignition of the tube when the high-frequency voltage applied to the tube is increased.

When the tube 5 is extinguished, the high-frequency voltage whose amplitude is allowed to rise is applied to its end 5a. As this voltage rises, the tube lights up progressively along its length until it becomes fluorescent in its entirety.

Instead of the one in fig. 1 assembly shown, different variants can be used, such as those shown in fig. 2 (connection using an autotransformer 8) or fig. 3 (connection using a capacitor 9).

One can of course use any suitable oscillator type which makes it possible to obtain a variable high frequency voltage on the tube.

Fig. 4 shows a diagram of a particularly advantageous embodiment. This scheme includes an oscillator stage 10 whose frequency can be regulated by means of a variable capacitor 11 present in the circuit. The self-induction 12 in this oscillator stage is decoupled with a self-induction 13 placed in the grid circuit for the output tube 14 whose anode self-induction 2 is connected to the circuit for the energy supply as shown above.

When you vary the capacitor 11, you vary the frequency of the oscillations produced by the oscillator 10 and consequently the frequency at the output of the tube 14. It follows that a variable voltage appears on the terminals of the tube 5, which voltage begins with a minimum value when the circuit is out of tune and increases, until a maximum value is reached when there is resonance in this circuit for the frequency it is tuned for.

Let f„ be the resonance frequency for the circuit consisting of the self-induction 3, the line 4, the self-induction 6, the capacitor 7 and the tube 5, this frequency being the one for which the tube 5 is fully lit. There are then two ways in which you can get to this frequency, namely either by starting from lower frequencies or by starting from higher frequencies. In practice, it is advantageous to start from high frequencies and to reduce the value until resonance is achieved. Namely, when the tube is lit, its capacity increases due to the ionization of the gas.

The ratio % ^LC therefore decreases. If one therefore starts from higher frequencies than the resonance frequency and allows the frequencies to decrease, the variation of this ratio will take place in the same direction as the variation of the frequency, which makes it possible to achieve a progressive ignition.

As stated above, the oscillator should successively serve for progressive lighting of several fluorescent tubes such as e.g. together form an illuminated advertisement. The form in fig. 5 shows a device according to the invention which makes it possible to realize the successive ignition of these tubes.

In this device, two identical capacitors are used, but their movable plates 15 and 16 are offset by 180°. These moving plates are mounted on the same shaft 17 which is driven by means of a motor 18. On the other hand, the fixed plates 19 and 20 of these capacitors are connected to the anode circuit of the oscillator tube 10 by means of a vane whose blade 21 is controlled by a cam 22 which in turn is driven by the motor 18. This device, which is shown as an example, could just as easily be located between the grid for the tube 10 (fig. 4) and the mass or between the grid and the anode of the tube 10, i.e. in parallel with the capacitor lia.

Thanks to this device, the capacitors function alternatively and in such a way that suddenly, when a tube is fully ignited, which takes place when the capacitor that caused the ignition reaches its maximum value, the frequency acquires such a value that the tube is extinguished by switching, which is realized by means of the contact 21, of the first capacitor to the second which, according to the construction, is at its minimum value, and the circuit is started again to ignite the following tube, etc.

To ensure the operation of a tube that has been ignited, a reversing device is used by means of which a tube that has been ignited is immediately fed from a source with a constant high frequency voltage or mains voltage. This reversing device is connected to the previously shown reversing system in order, after ignition, to provide for the replacement of the variable high-frequency voltage with a constant high-frequency voltage or mains voltage.

The form in fig. 6 shows an example of such switching.

The various tubes 5—5'—5" ... form, for example, the elements of a light advertisement and are for this purpose arranged one after the other to, for example, form the letters of a word, and are connected to the line 4 by means of of turns 23—23'—23" ... When the tubes are extinguished, a high-frequency voltage whose amplitude is increased is applied to the end 5a of the tube 5, in the manner previously described. As this voltage increases, the tube lights up progressively along its length until it becomes completely fluorescent. When the tube 5 is thus lit, the inverter 22 breaks the tube's connection with the source HF with variable voltage and ensures the supply of the line 4' to light the following tube 5'.

The inverters 24—24'—24"....are connected to the inverters 23—23'—23"....so that at the same time as an inverter 23 breaks the corresponding pipe from the variable high voltage, the inverter 24 which is associated with the tube for its connection with the supply from the constant frequency to ensure the operation of the tube.

In the embodiment shown in fig.

6, the operation of each tube that has been ignited is ensured from the mains at normal frequency by means of transformers 25—25'—25". Choking coils 26—26'—26" ... are provided to stop the high frequency during ignition .

The reversing pairs 23—24, 23'—24', 23"—24".... are controlled by means of cams moved by the motor 18, the curve of these cams and their angular displacement are determined so that the desired functions are ensured, i.e. a successive replacement of high frequency supply with variable voltage to a tube which is fired with the alternative constant voltage for the operation and connection of variable high frequency voltage to the following tube.

Fig. 7 shows a variant of the preceding scheme, and where the operation of the lit tubes is achieved by means of a source with a constant high-frequency voltage. The arrangement functions in every respect in a similar way as in the example that has just been described and is shown in fig. 6.

After the various tubes 5—5'—5".... which form a light advertisement are lit, the extinguishing of the whole is effected, and the ignition is resumed with the first tube, etc. The angular displacement of the combs and their curves may make it possible to achieve this extinguishment.

However, this function should be realized with great accuracy if one wants to avoid that certain tubes remain lit for a certain time, even if this time is very short, after the other tubes have been extinguished. In order to avoid that the curves on the comb have to be made very precisely, an accuracy which will otherwise be difficult to preserve after a period of use, the following device can be used.

The device comprises a switch 27 which is controlled by a cam in such a way that immediately after the complete lighting of the last lamp, the breaking of the screen circuit 29 from the output lamp 14 and the breaking by means of the switch 28 which is connected to the preceding lamp, is ensured by the supply circuit ( Fig. 6).

As shown in fig. 8 use an oscillator 30 which provides a high-frequency voltage with a constant frequency (e.g. of 120 kp/s) and from which the two circuits are fed. One of these circuits comprises a variable impedance 31 and the output stage 14, as this impedance makes it possible from the constant frequency oscillations from the oscillator 30 to apply a variable voltage to the grid in the lamp 14 and therefore obtain the voltage with a fixed high frequency but with variable amplitude for the ignition of the tubes. The second circuit comprises an amplifier 32 in order to achieve at the output the necessary constant high frequency for the operation of the tubes.

It is of course that the invention does not

is limited to the embodiments that are

described and shown above, but that the invention can be carried out with many variants, especially in so far as it concerns the oscillator type which

can be used to achieve on the clamps of

the fluorescent tube a high-frequency voltage with variable amplitude. Likewise, the device according to the invention can be used in

case where you light the pipe from both

its ends, providing for an artificial

zero point between the ends. The fluorescent tubes that

used, may be without electrodes, as these

replaced by external connections. They can be

matted or not and have any

shape. They can therefore be spherical or spherical

similar.

Claims (10)

1. Device for ignition and feeding of discharge tubes for lighting, where the ignition takes place progressively from one end of the tube to the other by applying a high-frequency voltage with variable amplitude, and where an energy transmission line is arranged between the output of the high-frequency oscillator and the tube to be ignited, characterized in that one end of the energy transmission line is connected to the oscillator's output and the other end with a series connection of an impedance with high self-induction and a capacitive impedance, the tube being connected in parallel with the capacitive impedance. 2. Device according to claim 1, characterized in that the value of the self-induction impedance is approximately equal to the capacitive impedance for the frequency at which the tube is switched on in its entirety. 3. Device according to claim 1, characterized in that the frequencies used are of the order of 100 k/ps. 4. Device according to claim 1, characterized in that the oscillator is of the type that delivers an adjustable frequency and that the circuit formed by the inductive impedance and the capacitive impedance comes into resonance at a frequency value corresponding to the maximum voltage suitable for complete ignition of the tube. 5. Device according to claim 4, characterized in that the frequency of the oscillator is regulated from a maximum value which is higher than that which corresponds to the beginning of the ignition of the tube and then progressively brings it to the value which corresponds to full ignition of the tube! 6. Device according to claim 1, characterized in that only one oscillator is used for successive ignition of several tubes. 7. Device according to claim 6, characterized in that the oscillator for regulating its frequency comprises two equal, variable capacitors which are offset by 180° in relation to each other and which act in turn so that after complete ignition of a tube without interruption over to the ignition of the following tube. 8. Device according to claim 7, characterized in that the capacitors are moved synchronously and that a switch which is connected so that it is controlled by the capacitors makes it possible for it to work successively so that the connection with the oscillator is broken from a tube that is lit and that a connection is established with the oscillator of the following tube. 9. Device according to claim 1, characterized in that it comprises a reversal system which makes it possible to replace the adjustable high-frequency voltage after the ignition of a tube with a high-frequency voltage or mains voltage with constant amplitude. 10. Device according to claim l/characterized in that it comprises a constant high-frequency source from which, on the one hand, a high-frequency voltage with adjustable amplitude can be obtained for lighting the tubes and, on the other hand, produce a high-frequency voltage with constant amplitude for operating the tubes.