DEK0024463MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: December 28, 1954 Bekanintgemadht on October 25, 1956

GERMAN PATENT OFFICE

When circuits for lighting devices with at least one warm cathode fluorescent lamp and with ballast and resonant inductors depending on the type and number of used Differentiate between fluorescent lamps and the available mains voltage, various ballast and resonant inductors have been used so far. These different Choke coils must therefore be specially manufactured depending on the circuit, whereby the The effort and costs for the various circuits are relatively high.

A simplification in the structure of such circuits is achieved according to the invention by that in different, depending on the type and number of fluorescent lamps used and The existing mains voltage has different circuits as ballast and resonant inductors Uniform choke coils based on the modular principle, also suitable for glow starter operation or whole capacitive units can be used. Because such normal reactors in very can be made in large numbers and kept in stock, they can be manufactured cheaply

609 659/378

K 24463 VIII c 121 f

the, so that a simplification and cheaper in the construction of corresponding circuits or Lighting devices results.

The invention also relates to a lighting device with at least one warm cathode fluorescent lamp and with ballast and Vibration inductors and series capacitor, in which the one connected in parallel to the fluorescent lamp The resonant choke coil is of the same size and design as the series choke coil. In the drawing, various built up with the choke coils or capacitive units Circuits or lighting devices according to the invention shown for example.

Fig. Ι shows a circuit for a lighting device with a 20-watt fluorescent lamp 1 for a mains voltage of 220 volts Wickkmgs- = halves 4, 4 'of a normal 40-watt choke coil, consisting of a series capacitor 5 of 3.6 μ ¥ and a vibrating choke coil 6, which is formed by one half of a winding of a normal 40-watt choke coil, the second half of the winding is not used. The ignition electrode 8 arranged outside the fluorescent lamp ι extends • approximately over the entire length of the lamp .1 and is connected via the mass M of the armature and via a current limiting resistor 9 of 2 MΩ in such a way that between the ignition electrode 8 and the lamp cathode 2 the Voltage of the series capacitor 5 is. However, as in German Patent 915 249, this ignition electrode could also be connected to a lamp cathode via an intermediate member limiting the contact current, if the somewhat poorer ignition reliability achieved with it is also sufficient.

When switching on, the AC mains voltage A current flows through the aforementioned resonance circuit, which heats the cathodes 2, 3. Furthermore, the fluorescent lamp is ignited by the voltage of the oscillating choke coil 6 brought. After ignition, the resonant inductor 6 is practically short-circuited by the lamp I, and only a residual current flows through the cathodes 2 and 3 and the coil 6. The capacitor 10 out of 40,000 pF is used for radio interference suppression.

So the power factor is capacitive and is 0.33.

FIG. 2 shows a circuit similar to FIG. 1

for three connected in series. 20-watt fluorescent lamps 1, i 'and 1 ". The Vorschaltdrosselspule again has two winding halves 4, 4' of a normal 40-watt choke coil. The series capacitor 5 has a capacitance of 3.2 μΡ, and each of the three resonant inductor coils 6 , 6 'and 6 "consists of one half of the winding of a normal 40 watt inductor. The remaining parts and the operation of the circuit are the same as in Fig. 1. The power factor is approximately 0.73 capacitive.

3 shows a circuit for four 20 watt fluorescent lamps i, 1 ', 1 " and i'" connected in series. Here, too, the series choke coil has two winding halves 4, 4 'of a normal 40-watt choke coil. The series capacitor 5 has a capacity of 3.5 ^ F, and each of the four oscillating inductors 6, 6 ', 6 "and 6"' consists of one half of the winding of a normal 40 watt inductor. With this circuit, only three normal 40-watt choke coils are required here. Otherwise, the circuit and its mode of operation are the same as in FIG. 1. The power factor cos φ is 0.95 capacitive.

4 shows a circuit for two 40 watt fluorescent lamps 1 and 1 'connected in series. The ballast choke coil consists of the two winding halves 4, 4 'of a normal 40-watt choke coil. The series capacitor 5 has a capacity of 3.5 μΈ, and each oscillating inductor 6, 6 'consists of the two series-connected winding halves of a normal 40-watt inductor. A total of three normal choke coils are provided for this circuit. With a mains voltage of 220 volts and a frequency of 50 Hz, the power consumption is 99 watts and the power factor is approximately 0.86. One advantage of this circuit is that it is insensitive to voltage fluctuations. At line voltages of 180 to 250 volts z. B. the power consumption between 82 and 110 watts and the power consumption from 0.47 to. 0.56 Amp. Depending on the combination, the result is a more or less hard ignition insert, ie ignition takes place with insufficient or good cathode preheating, which has a strong influence on the service life of the fluorescent lamps. Since the preheating of the cathodes is not ideal in the circuit according to FIG. 4, there is a thermistor 7 and 7 in series with both resonant inductors 6 and 6 '. 7 'switched on. These thermistors 7, 7 'have z. B. a cold resistance of about 500 ohms and a warm resistance of less than .5 ohms. They ensure that the ignition of the fluorescent lamps 1, 1 'is delayed until the cathodes 2, 3 and 2', 3 'are heated. ■. .

Fig. 5 shows a circuit for a 40-watt fluorescent lamp ι and for a mains voltage of 125 volts. In addition to a series choke coil consisting of two winding halves 4, 4 ', an oscillating choke coil 6 is used, the winding halves of which are connected in series. In this circuit, two normal 40-watt inductors and a series capacitor 5 of 5 μΡ are required. The power consumption is 58 watts with a capacitive power factor of around 0.93. Together with an upstream autotransformer, this circuit would result in a universal device for e.g. 110, 125, 145, 220 volts. The induction in the magnetic core of the autotransformer can be chosen so that instead of a capacitive one, an inductive power factor of cos φ ^ o.9 results.

FIG. 6 shows a variant of the circuit according to FIG. 5, also for a 40 watt fluorescent lamp and a mains voltage of Ί10 to 130 volts

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at a frequency of 50 Hz. In this circuit, the ballast choke coil 4 consists of two normal 40-watt choke coils connected in parallel and symmetrically connected to both Metz conductors, and the series capacitor 5 has a capacity of 7 μ ¥. A normal 40-watt choke coil is therefore required for this circuit. The light output is much better and the operation is accordingly more economical.

At 110 volts, 50 Hz the power consumption is ·. 49 watts, the primary current 0.51 Amp. And the cos φ about 0.88 capacitive.

Fig. 7 shows a circuit for two series-connected 65 watt fluorescent lamps 1 and 1 'for 220 volts, 50 Hz. The series reactor consists of two symmetrical, parallel connected normal 40 watt chokes 4, 4 '. Furthermore, each of the oscillating inductors 6, 6 'consists of one each normal 40 watt inductor, so here so.

a total of four such reactors are required. The series capacitor 5 has a capacitance of 5 / iF. In order to ensure perfect preheating, an NTC thermistor 7 is switched on in each of the two oscillating circuits. The power consumption at 220 volts, 50 Hz is 136 watts, the primary current 0.7 Amp. And the cos φ about 0.88.

Fig. 8 shows a circuit for a 100 watt

. Fluorescent lamp 1 at a mains voltage of 125 volts and a frequency of 50 Hz. As a series reactor here are three normal 40 watt chokes 4, 4 'and 4 "parallel and symmetrical switched into both mains conductors. Furthermore, the resonant choke coil is connected by two parallel normal 40 watt reactors 6 and 6 'formed.

The series capacitor 5 has a capacity of 14 / tF. A thermistor 7 is switched into the resonant circuit for better preheating of the lamp cathodes 2, 3. The power consumption at 125 volts is 120 watts, the primary current is 1.15 amps and the cos φ about 0.83 capacitive. With a pre-transformer, e.g. B. 125, 145, 220 volts, the result would be a perfect universal circuit for all common mains voltages and with a cos φ of about 1.0.

9 shows a circuit for two ioo-Wa, tt fluorescent lamps 1 and 1 ' connected in series for a mains voltage of 220 volts, 50 Hz 4, 4 'and 4 ". Furthermore, each of the two oscillating inductors is formed by two normal 40-watt inductors 6, 6' or 6", 6 '"connected in parallel. In total, the circuit has seven such inductors. The series capacitor 5 has a capacity of _11; "F. Further, a thermistor is in each resonant circuit switched 7 and 7 'the power consumption is at 220 volts, 225 watts, the current is 1.26 amp and the cos φ about 0.82 capacitive... Although a relatively large amount of 40 watt choke coils is required for this circuit, this circuit is still much more economical than the previous 100 watt devices, which can only be produced in small series It must be taken into account that the relatively expensive starters and starter mountings otherwise required for these lamps, as well as the blocking choke for the compensation capacitor, are omitted.

As can be seen from the above example, a large number of circuits are possible for practically all warm cathode fluorescent lamps that occur. For example, similar circuits as in Fig. Ι to 3 for 20-watt fluorescent lamps for 13, 14 and 15 watts and also for circularly curved lamps, .z. B. 22, 32 and 40 watts, possible, only the size of the series capacitor has to be chosen slightly different. All of these circuits can work without an ignition switch and meet all requirements for interior lighting, such as: B. compensation, throttling, clean ignition with sufficient preheating, satisfactory lamp life, proper radio interference suppression, good light output, etc. It has been shown that some of these circuits do not work satisfactorily ^{with normal fluorescent lamps at temperatures below 10 to 15 0 C.} On the other hand, these circuits can still be operated properly with so-called cold-resistant fluorescent lamps up to about 0 ° C.

10 shows a circuit for a 40 watt lamp with 0.42 amp. For 220 volts, 50 Hz. In this circuit, two normal 40 watt choke coils 6 and 11 with winding halves connected in series are used as oscillating chokes in series . As a result, an ignition voltage of over 400 volts can be achieved, which results in good ignition reliability without the need for an ignition electrode. The Vordirossel also consists of a normal 40 watt choke with two identical winding parts 4 and 4 '. The series capacitor 5 has a capacitance of 3.6 / tF, and the power factor of this circuit is about 0.5 capacitive. The series capacitor 5 can form a unit with the series reactor 4, 4 '. Such units consisting of a series reactor and capacitor are used in large quantities in overcompensated ballasts for glow starter operation. The fact that the same capacitive n ₀ units as are used for overcompensated ballasts for glow starter operation can also be used in the circuit according to FIG. 10 results in a considerable advantage, since these units do not have to be manufactured separately. In order to achieve good preheating of the lamp cathodes 2 and 3, an NTC thermistor 7 with an approximately 100 ohm cold resistance is switched into the ignition circuit.

Fig. 11 also shows a circuit for a 40 watt fluorescent lamp for mains voltage 220 volts, 50 Hz, - but with an inductive power factor of around 0.5. The series capacitor 5 is connected here in parallel with the lamp in series with a normal 40 watt choke 6. the Choke 6 and the series capacitor 5 can be used here

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Claims (10)

Patent claims: 1. Circuit for lighting devices with at least one warm cathode fluorescent lamp and with ballast and oscillating inductors' and series capacitor, characterized in that in different, each according to the type and number of fluorescent lamps used and the existing mains voltage differing circuits as ballast and resonant inductors according to the The modular principle of uniform choke coils, also suitable for glow starter operation, or whole capacitive units can be used. 2. Lighting device with at least one warm cathode fluorescent lamp and with also form the same capacitive unit as used for ballasts for glow starter operation and for the circuit according to FIG. xo. The capacitance of the series capacitor 5 is advantageously from about 3 to 3.5 μ F. The choke also serves again a standard 40-watt ballast with two identical coil parts 4 and 4 ', and when Störschutzkondensator 10 satisfies a capacity of about 50,000 pF. As in the circuit according to FIG. 10, the ignition voltage is above 400 volts, which results in very good ignition reliability without the use of an ignition electrode. Furthermore, for better preheating of the lamp cathodes 2 and 3, as in the circuit according to FIG. 10, a thermistor 7 with approximately 1000 ohm cold resistance is connected into the ignition circuit. The two circuits according to FIGS. 10 and 11 can advantageously be combined to form a so-called dual circuit for operating two lamps, with a power factor of approximately 1 resulting. Used as a single circuit, the combination can be selected so that the prescribed power factor is created for the entire lighting system. FIG. 12 shows in principle the circuit according to FIG. 11, but with an additional ignition electrode 8, which via a contact current limiting resistor 9 again in such a way to the Series capacitor 5 is connected that between a lamp cathode and the ignition electrode, which can also consist of the valve itself, the capacitor voltage is. The interposition the thermistor 7 is insignificant; it could also have the same effect on a be switched on at another point of the ignition circuit connected in parallel to the lamp. This circuit with Ignition electrode should be used especially in systems with very low ambient temperatures and also for means Control transformers, adjustable lighting systems in cinemas, theaters, etc. are advantageous be applied. In the same way, of course, the circuit according to FIG. 10 can also be used add an ignition electrode. Ballast and oscillating inductor and series capacitor according to Claim 1, characterized in that that the resonant choke coil connected in parallel to the fluorescent lamp is of the same dimensions and design as the Series reactor. . 3. Lighting device according to claims ι and 2, characterized in that a choke coil together with a series capacitor, forms a capacitive unit that is also suitable for glow starter operation. 4. Lighting device according to claims 1 and 2, characterized in that the upstream, switching and oscillating inductors consist of normal 40-watt inductors with two symmetrical winding halves. 5. Lighting device according to claims 1, 2 and 4 with short fluorescent lamps, the voltage of which is less than 70 volts, characterized in that only one of the oscillating inductor for each lamp two symmetrical winding halves of a normal 40 watt choke coil is used. 6. Lighting device according to claims 1, 2, 4 and 5 with two -connected in series Fluorescent lamps, characterized in that the oscillating choke coil for one The winding halves used in the lamp are connected with respect to the direction of the winding in such a way that that the current flowing in the oscillating circuits flows through the two winding halves in the same direction. 7. Lighting device according to claims 1, 2 and 4, at which operating currents greater than 0.5 Amp. Occur in the resonance circuit, as a result characterized in that two or more identical normal coils are used as ballast and resonant inductors 40 watt chokes are connected in parallel. 8. Lighting device according to claims 1, 2 and A for fluorescent lamps, which one Have an operating voltage of more than 70 volts, characterized in that the two are used as the oscillating inductor for each lamp symmetrical winding halves of a normal 40 watt choke coil connected in series are. 9. Lighting device according to claims 1, 2 and 4 for fluorescent lamps which require a high ignition voltage, characterized in that at least two normal 40-watt choke coils are connected in n ₀ series as the oscillating inductor. 10. Lighting device according to claims ι and 3, characterized in that to achieve an inductive power factor a capacitive unit, consisting of a series capacitor and a choke coil, parallel to the Fluorescent lamp is connected as an oscillating unit in the ignition circuit. For this purpose 2 sheets of drawings © 609 659ß78 10.56