DE1589215C3 - Circuit arrangement for Niederspanniingsleuchtstofflampen.die are fed from a vehicle battery or a similar direct voltage source - Google Patents

Description

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The invention relates to a circuit arrangement for low-voltage fluorescent lamps, which consist of a ' Vehicle battery or a similar DC voltage source with the interposition of a transistor inverter are fed with two transistors and the one by the electrode circuit Flowing heating current is used to control and ■ maintain the operation of the inverter and the electrode circuit from the series connection of the lamp electrodes, a capacitor and the secondary winding a supply transformer.

In vehicles, the lights are generally supplied from the vehicle battery. Using Low voltage fluorescent lamps require that between the battery and the An inverter is switched on. It is possible to use one for several lights A single inverter can be used, but you can also use a special inverter for each luminaire assign to. In the latter case, transistor inverters are mostly used, which are often used in the luminaire housing are built in. The inverter mostly works on a transformer whose secondary side the lamp and the heating coils of the lamp are connected. Both The inverter is put into operation when the luminaire is switched on and runs as long as the lamp is switched on. If the lamp fails, e.g. B. by a defect the connection contacts or on the fluorescent lamp as well as in the event of a short circuit at the inverter output and in the event that the lamp comes out of its sockets due to vibrations from the vehicle triggers, the inverter is shut down because the control circuit fails due to the failure of the ignition electrodes of the lamp for the transistors is interrupted.

In this known circuit arrangement, a capacitor is provided in the electrode bridge circuit, which should limit the heating current and bring it into a phase position suitable for the feedback. This capacitor, which is in series with a feedback winding, promotes the creation of harmonics, so that it is necessary to reduce the feedback current flowing through the capacitor compensate with corrective links. However, this correction can only be made for a medium lamp output set just right. The supply voltage of the fluorescent lamp must namely with a filter element, because otherwise the harmonic content through the capacitor in heating and Feedback loop becomes too large. When the lamp output changes due to voltage fluctuations In the primary supply network, the resistance of the fluorescent lamps is changed, and thus the phase position of the feedback loop then also changes. Is unfavorable when using of a capacitor in the electrode bridge circuit also means that its resistance is not that required for start-up and operation the fluorescent lamp has the necessary characteristics. Another disadvantage of this circuit arrangement lies in the fact that the harmonic component cannot be adequately shielded and therefore only with relatively small operating frequencies can be used to avoid interference with radio reception will.

The invention has set itself the task of providing a circuit arrangement for operating low-voltage fluorescent lamps to create from direct current networks, which has very favorable starting properties and allows operation at higher than audio frequencies

According to the invention, this object is achieved in that parallel to the "discharge path of the lamp and in series with the switching elements of the electrical circuit, the primary winding of one with its secondary winding the transistors controlling the control transformer is and that a resonant circuit from the Secondary winding, »the capacitor, the ignition electrodes and the primary winding with an increase in resonance as a result occurring voltage is used to ignite the lamp and switches the transistors via the secondary winding of the control transformer. According to an advantageous embodiment of the invention it is provided that the supply transformer and the control transformer works without stray fields. Included are the pulses generated by the winding and used to control the bases of the transistors due to resistance in series with the winding

and brought a capacitor connected in parallel into a suitable shape and phase position and the inverter is operated at a frequency of 20 kHz.

An embodiment of the invention is shown in the drawing and will be described in more detail below described.

Primary windings 1 and 1 'of a supply transformer 2 are alternately connected to DC voltage via the emitter-collector path of switching transistors 4 and 4' and a reverse polarity protection diode 5. The bases of switching transistors 4 and 4 'are applied via resistors 7 and T, respectively the secondary winding 6 b of a control transformer 6. A capacitor 8 is connected in parallel with the resistors 7, T and the secondary winding 6 b. The primary winding 6a of the control transformer 6 is fed the supply transformer 2 from the secondary winding 3 and is in series with a capacitor 9 and the ignition electrodes 11 and 12, a low voltage fluorescent lamp 10. A Zündhilfsstreifen 14 is located on one of an auxiliary winding 13 on the secondary of the supply transformer 2 generated tension.

To start up the inverter and the lamp 10, one terminal 16 is connected to negative and one terminal 17 is connected to positive direct voltage potential. As a result, the base of the transistor 4 'receives a positive voltage pulse via a capacitor 15 and switches its emitter-collector path through, while the transistor 4 blocks. A current flows from terminal 17 through the primary winding Γ of the supply transformer 2 and the collector-emitter path of the transistor 4 'and the diode 5 to the terminal 16.This creates a voltage in the secondary winding 3 and the additional winding 13 of the supply transformer 2 induced. The voltage generated by the secondary winding 3 drives a current through the capacitor 9, the ignition electrodes 11 and 12 and the primary winding 6a of the Steuertransfonnators 6. The ignition electrodes are heated and a voltage is induced in the secondary coil 6 and that the potential at the base of transistor 4 'lowers and the potential at the base of transistor 4 increases, so that both transistors tip over and transistor 4 is now turned on. The direct current from terminal 17 to terminal 16 now no longer flows through the primary winding 1 ', but through the primary winding 1 of the supply transformer 2, so that the polarities on the ignition electrodes and the control. ^ transformer are also reversed again until the transistors 4 and 4 'tip over again. The dimensions of the individual switching elements are so dimensioned that a switching frequency of approximately

ίο 20 kHz results. The inductances of the feed transistor 2 and of the control transformer 6 as well as the capacitance of the capacitor 9 are designed to occur at the ends of the primary winding 6a of the control transformer 6 due to resonance step-up high voltage and the low voltage fluorescent lamp is ignited 10th After the breakdown voltage between the ignition electrodes 11 and 12, the primary winding 6 is practically a short-circuited so that no undue resonance voltage peaks more may occur. By the ignition electrodes 11 and 12 and the secondary winding 6 a now flows only a small residual current which is sufficient, however, b for controlling the transistors via the inductive coupling to the secondary winding. 6 The shape and the phase position of the control pulses for the bases of the transistors 4 and 4 'are set by the resistors 7 and 7' and a capacitor 8 connected in parallel.

The circuit arrangement according to the invention is particularly advantageous because it ignites the low-voltage fluorescent lamp 10 quickly and safely even under very unfavorable conditions, such as low temperatures and undervoltage in the supply network due to the excessive voltage on the primary winding 6 α of the control transformer 6 due to resonance. Another advantage is the possibility of using transformers with practically no stray field for supply and control, because this avoids the formation of an outwardly effective field and thus any radio interference even when the inverter is operated at very high frequencies, for example above the audible audio frequencies is excluded. The use of high frequencies in turn enables a very clear structure with relatively small switching elements.

1 sheet of drawings

Claims (4)

Patent claims: 1.Circuit arrangement for low-voltage fluorescent lamps that are fed from a vehicle battery or a similar DC voltage source with the interposition of a transistor inverter with two transistors and in which the heating current flowing through the electrode circuit is used to control and maintain the operation of the inverter and the electrode circuit is made up of the series connection of the lamp electrodes, a capacitor and the secondary winding of a supply transformer, characterized in that parallel to the discharge path of the lamp (10) and in series with the switching elements of the electrode circuit the primary winding (6 a) one with its secondary winding (6 b) the transistors. (4, 4 ') controlling the control transformer (6) and that a resonant circuit consisting of the secondary winding (3), the capacitor (9), the ignition electrodes (11, 12) and the primary winding (6 a) with a voltage occurring due to excessive resonance for The lamp is ignited and the transistors (4, 4 ') are switched over via the secondary winding (6 b) of the control transformer. 2. Circuit arrangement according to claim 1, characterized in that the feed transformer (2) and the control transformer (6) work without stray fields. 3. Circuit arrangement according to claim 1 and 2, characterized in that the Se-. secondary winding (6 b) generated to control the bases of the transistors (4, 4 ') serving pulses by in series with the secondary winding (6 b) resistors (7, T) and a parallel connected capacitor (8) in a suitable shape and Phased are brought. 4. Circuit arrangement according to claim 1 to 3, characterized in that the inverter operates at a frequency of 20 kHz.