DE1917281A1 - Fully electronic starter for fluorescent tubes - Google Patents

Description

ADDITIONAL PATENT APPLICATION Fully electronic starter for fluorescent tubes The invention relates to starters for fluorescent tubes.

It is well known that fluorescent lamps are only allowed in series with a current limiter, usually a choke. In addition, the glow electrodes should be preheated be because a cold start has an adverse effect on the life of the fluorescent tubes affects. Furthermore, the starter should have an or during or at the end of the heating emit several high-voltage impulses, thus also with older fluorescent tubes or safe ignition is guaranteed at a very low ambient temperature. the However, high-voltage pulses must not be so strong that a cold start is possible is.

These conditions are mostly achieved today in the following way: A Fluorescent lamp is in series with a choke that acts as a series resistor after ignition works, on the net. One pole is connected to each of the two glow electrodes, the other two connections are connected to each other via a glimine igniter.

If this arrangement is now connected to the network, lights up at first the glow plug of the glow igniter. This heats up its bimetal switch and short-circuits. Therefore flows through the throttle and the two filaments a strong current that makes them glow. This causes electrons to go into the Gas sent to prepare the gas discharge. In the meantime, however, is the Bimetal switch cools down and suddenly opens the circuit.

This creates a high voltage surge in the choke. This occurrence repeats itself until the fluorescent lamp has ignited. The current is going through limits the throttle to the correct value; at the fluorescent lamp the rated voltage of approx. 110 volts. But the glow lamp can no longer use it ignited, the bimetal switch remains cold and open.

The glow starter described above, which is mostly used today, has considerable Disadvantage ; because it has a mechanical contact, it has a limited lifespan, because the holder material evaporates relatively quickly. Also, by the abrupt Opening and closing of the bimetal starter and the resulting induced in the choke Voltage surges put a lot of stress on the glow electrodes of the fluorescent tubes, which has a negative effect on the service life of the tubes. Also occurs in case of Verwenaung this starter has a longer ignition delay and usually a strong flicker of the Fluorescent tubes on, which is extremely annoying.

If there is a non-starting tube in the socket, it will continue to flow a strong heating current, which after some time warms up the tube ends so that the Frames become soft and unusable.

There are already starters that have one or more of these disadvantages not have, but none yet, which eliminate all these disadvantages. They are also mostly very expensive and often mechanical, semiconductor-based starters that have these disadvantages do not have, have already been described in a patent specification from.

This additional patent further improves the starters described therein. The voltage-dependent resistance shown in Fig. 1 is improved by Fig. II. In this case, parallel to the semiconductor (1) e 'in capacitor (2) is in series with a Zener diode (3) wired together with the choke coil of the The ballast forms a resonance circuit that is used to ignite the fluorescent tube supplies a few high-voltage pulses.

The capacitance of aes capacitor (2) is such that the through the resonance generated high voltage pulses do not allow a cold start. The breakdown voltage the zened diode (3) is below the mains voltage, but above the burning voltage of the Fertilizer tubes. The circuit works as follows When the power is switched on, the semiconductor (1) controls through and the resonance circuit begins to work because the mains voltage is above the breakdown voltage of the Zener diode (3). If the The glow electrodes of the fluorescent tube are hot, they ignite due to the high voltage pulses and the operating voltage is set on the starter. Through this the semiconductor can (1) can no longer be controlled and heating current no longer flows.

At the same time the resonance circuit breaks down because the voltage at ' the Zener period (3) can no longer reach its breakdown voltage. Through this high-voltage impulses cannot be emitted and the ignition is ended.

The circuit according to Figure III can be further improved.

This works in principle like the circuit according to Figure II, only that the heating current not only by igniting the tube but also by heating the NTC resistor (4) can be switched off.

The heating can be achieved by thermal coupling to the Zenerdioåe (5) or the semiconductor (6) can be achieved. When using an NTC type smaller Power, no external heating of the same is necessary, approx.cie self-heating after a few seconds so lowers the resistance, the semiconductor (6) ate no more can be controlled. this circuit ensures that the heating current is switched off if the tube does not start.

The thermistor (4) in the circuit according to Fig. 111 can be replaced by a PTC thermistor (7) must be replaced as shown in Figure IV. The way of working is the same like @ei the starter according to Fig. III

Claims (4)

PATENT CLAIMS 1) Fully electronic starters for fluorescent tubes characterized in that parallel to a voltage-dependent resistor switched semiconductor is a capacitor, which together with the ballast forms a resonance circuit, which is required to ignite a fluorescent lamp high voltage generated. 2) Fully electronic starter for fluorescent lamps according to claim 1) aaaurch that an element is connected to the capacitor, which interrupts the resonance circuit after ignition of the fluorescent lamp. 3) Fully electronic starter for fluorescent lamps according to claim 2) characterized in that since the resonance circuit switch off element one in Berie with the capacitor lying - Zener diode is. 4) Fully electronic starter for fluorescent lamps according to claim 3), 2), 1), characterized in that the one drawn as a voltage-dependent resistance Semiconductors not only due to the changed shape of the curve on the fluorescent lamp applied voltage is switched off, but also by a temperature-dependent Resistance.