DE1924012A1 - Arrangement for operating a consumer via a transistor inverter - Google Patents

Description

Arrangement for operating a consumer via a transistor inverter The invention relates to an arrangement for operating a consumer via a transistor inverter with a stray field transformer. Such a transistor inverter can be used in particular for feeding discharge lamps, for charging batteries or the like from a low DC voltage or a rectified AC voltage, e.g. serve a 16 2/3 Hz alternating voltage.

Transistor inverters are often used to power fluorescent lamps with two transistors arranged in push-pull or an inverter with one transistor applied are the or di. Transistors in series with the primary winding a stray field transformer connected to the supply voltage.

When using transistor inverters to power fluorescent lamps It is often desirable to adjust the illuminance in the late evening or night hours to belittle. The same applies to other consumers, e.g. the Charging batteries requires a reduction in the power supplied.

When operating a consumer via a transistor inverter with a stray field transformer, this is according to the invention with particularly simple means This is possible because a step-by-step change in performance is possible in the primary and / or Secondary circuit of the stray field transformer arranged capacitor is provided, which can be switched on or off by a switch. In this way, for example the brightness of a fluorescent lamp is reduced to a few percent of its nominal value without a film effect occurring, the for operation with degraded Power required lamp operating conditions (correct observance the limit values of the high currents and the lamp operating voltage) are fully complied with.

In the case of a battery supply, the situation is similar (Compliance with the conditions with full charge or with trickle charge).

Two exemplary embodiments of the invention are shown in the drawing.

1 shows a transistor inverter for a two-stage brightness setting and FIG. 2 shows a modified circuit.

In Fig. 1, E1 and E2 are input terminals of a transistor inverter device 2, which is used for connection to an AC voltage network, e.g. with a voltage of 220 V are used.

A fuse S and a choke are connected to these input terminals a rectifier arrangement G1 is arranged. The throttle D is used in conjunction with a capacitor 14 for flattening current games. To the output of the rectifier G1 is a series of an oscillating capacitor 21, a primary winding 7 of a stray field transformer 6 and a transistor 5 arranged in parallel to the series connection of the oscillating capacitor 21 and the primary winding 7 is another transistor 4. The emitter-collector path of the transistor 5, an oscillation aid 16 is connected in parallel. The stray field transformer 6 has control winding 10, each of which is connected to base B via resistors 11, 12 one. Transistor verb den ist0 To ensure that the build-up capacitor 21 is only charged when the voltage at the input terminals E1, E2 is sufficient, the energy required to initiate and maintain the vibrations to run, the oscillation aid 16 is activated via a switching element (relay or thyristor) 20 put into operation.

The excitation coil of the relay is connected to the output via a resistor 20c of the rectifier G1 connected. The relay only closes its contact 20a when the voltage is at least half the nominal supply voltage.

The output of the transistor inverter device 2 has terminals Al bis A5, through which a consumer - in the present case a fluorescent lamp 3 with heatable electrodes - can be connected to the secondary winding 8 of the leakage field transformer 6 is.

In the embodiment of the transistor inverter device according to the invention 2 is a step-by-step change in power in the primary and / or secondary circuit of the leakage field transformer 6 arranged capacitor 24 is provided by a switch 23 can be switched on or off. Figure 1 shows a secondary side Arrangement of the Kondenstors 24 between secondary winding 8 and heating winding 9. Zur Remote control is the switch 23 via input terminals E3, E4 and the lines 25 connected to the capacitor 24. The transistor inverter device 2 is huber its input terminals E1, E2 can also be connected to a DC voltage source and although without any switching using the rectifier arrangement G1 as Pole protection.

If the transistor inverter device is connected to terminals El ,. E2 with an AC voltage source or also via the terminals El, E2 with a DC voltage source connected, the relay closes - if the supply voltage is sufficient - its Contact 20a, with which the transistor 5 bridges and the electrical circuit from the positive pole of the Rectifier G1 over the oscillating capacitor 21, the primary winding 7 of the stray field transformer, the oscillation aid 16 and the switching contact 20a to the negative pole of the rectifier G1 is closed. Due to the current flow in the primary winding 7 are in the control winding 10 generated control voltages that further block the closed transistor 4 and open the transistor 5. Now the current flows through the transistor 5 until the Oscillating capacitor 21 is charged. After charging the oscillating capacitor 21-the voltage on the control windings 10 is zero and the transistor 5 blocks again. Due to the decrease in the flux in the stray field transformer the transistor 4 is supplied with a control voltage in the opening sense, so that this opens. The oscillating capacitor 21 then discharges via the transistor 4 and the primary winding 7 and gives its ergis via the transformer to the fluorescent lamp 3. Here the transistor 4 controls the discharge of the capacitor 21. If the discharge current of the oscillating capacitor 21 has decayed, the effect is then increase in the negative flux in the leakage field transformer a control voltage, which opens the transistor 5 and blocks the transistor 4, so that the already the procedure described is repeated.

The switch 23 is opened to reduce the light output9 so the frequency of the transistor inverter and across the capacitor 21 decreases less energy is supplied, so that the fluorescent lamp when the heating currents are observed and the lamp operating voltage is operated with reduced brightness.

The connection of a capacitor on the secondary side is not suitable only for the circuit shown but also for a transistor inverter with transistors arranged in push-pull.

Figure 2 shows a primary-side arrangement of the capacitor 24, wherein this is connected in series with the oscillating capacitor 21. The one in parallel with the capacitor 24 arranged switch 23 is opened to reduce the light output. Included the frequency of the primary circuit increases significantly. This increase in frequency causes a greater inductive resistance, which increases the light output accordingly is throttled.

For remote control, the switch 23 can also be on the switching element a relay 26, whose control lines 27 to input terminals E5, E6 of the inverter device 2 are performed.

It is also possible to have the capacitor 24 in parallel with the swinging capacitor 21 to lay. Furthermore, combinations of parallel and series connections can be made will.

It is particularly advantageous to use a capacitor 24 both primary and as well as to be arranged on the secondary side. This way the frequency can control the transistor inverter can be kept roughly stable even when the power is reduced. At the same time you can very low power values, with fluorescent lamps very low brightness values can be achieved.

5 claims 2 figures

Claims (5)

Claims 1. Arrangement for operating a consumer over a transistor inverter with a leakage field transformer, characterized in that that to gradually change the power a in the primary and / or secondary circuit of the Stray field transformer (6) is arranged capacitor (24) is provided by a switch (23) can be switched on or off. 2. Arrangement according to claim 1, characterized in that the switch is arranged on a switching element of a relay (26), 3. Arrangement according to claim 1 or 2, characterized in that the capacitor (24) in series with an im Primary current circuit of the stray field transformer arranged component (21) of the transistor inverter is arranged. 4. Arrangement according to claim 1 or 2, characterized in that the Capacitor (24) in parallel with a primary circuit of the leakage field transformer (6) arranged component (21) of the transistor inverter lies. 5. Arrangement according to claim 1 or 2, characterized in that the Capacitor (24) between two parts of secondary windings (8, 9) of the leakage field transformer (6) is arranged.