DE1074753B - Circuit arrangement for a discharge lamp operated with a higher than normal output and having preheated electrodes - Google Patents

Description

The invention relates to a circuit arrangement for a operated with a higher than normal power Discharge lamp with preheated electrodes to which the current is fed via two sub-circuits and in which two arc spots are created on a filament.

There are circuit arrangements for increasing the output power and thus the brightness of a normal Fluorescent lamp without overloading and reducing the service life by means of the formation of two or several arc spots on an electrode known, which a transformer with two separate Output windings included. During the preheating time, the two existing filaments are switched on connected these output windings. After the time has elapsed by a usually thermally delayed start switch certain preheating time, the two terminals of the output windings with common Polarity at the ends of a filament and the two terminals with opposite polarity the ends of the other filament are switched, whereby a current flow over at least two separate discharge paths takes place.

The aim of the invention is a circuit arrangement using chokes, which the different Currents during preheat and discharge in a circuit with two arc spots controls with simple means.

This goal is achieved according to the invention by a stabilizing choke with two in the circuit symmetrically connected to the lamp, each connected to an electrode end and each individually and isolated arranged on the choke core and two with these each magnetically coupled further windings, which are in series with a thermal switch between the other ends of the electrodes and connected so that the magnetic flux of the preheating current is compensated in the magnetically coupled windings, as well as a further stabilizing choke with also two windings connected symmetrically to the lamp in the circuit, which on the one hand to the power source and on the other hand, via the windings of the first choke lying between the lamp electrodes, they are connected to the lamp electrodes, ⁴ ^ and with an auxiliary starting coil which is so connected between the thermal switch and one of the coils of the second choke that their magnetic flux generated by the preheating current is in the same direction as that of the winding of the second choke, so that the partial currents flowing into the respective heating wire ends in the operating state are equal.

Due to the special circuit of the windings on the choke together with the action of the starting circuit arrangement

for one with higher than normal

Power operated discharge lamp

with preheated electrodes

Applicant:
Keiji Tanaka, Nara City (Japan)

Representative: Dr. W. Müller-Bore, patent attorney,
Braunschweig, Am Bürgerpark 8

Takizo Kobayashi, Kawanshi City (Japan),
has been named as the inventor

switch ensures a sufficiently high preheating current without the start switch being excessive is claimed, and an even distribution of the two partial flows during the discharge forced.

The windings of each choke can also be arranged as secondary windings of a leakage field transformer be.

Furthermore, two-stage, attenuated lighting can be achieved by arranging an additional attenuation switch can be achieved.

In a circuit with a capacitor in series with the main circuit, expediently a saturable choke connected in parallel to each filament of the lamp, whereby the individual Circuit elements protected in the event of malfunctions, such as a filament being burned through or broken will.

The invention is explained in more detail below with reference to the drawing.

Fig. 1 shows the basic circuit of the. arrangement according to the invention;

Fig. 2 shows the arrangement of an attenuator switch in the basic circuit of Fig. 1;

■ Fig. 3 shows the arrangement of the individual windings of the chokes as secondary windings of a Stray field transformer;

4 shows an arrangement with a series capacitor and additional saturable chokes.

909 7287247

Fig. 1 shows an embodiment of the circuit arrangement according to the invention using the example of a commercially available FL-40 lamp with associated glow lamp FG-4P for 200VoIt and 60 watts.

The basic mode of operation should be explained with reference to the circuit diagram of this particular version will.

Coils 1 a, Ib ₁ 3 α and 3 & a choke ch _{x of} a load circuit are individually insulated wound on a common iron core. Coils 2 a and 2 & 4, and a starting auxiliary coil of a choke ch ₂ are isolated wound on the other iron core. When the electrical voltage is applied, the glow lamp responds first and this circuit is short-circuited. Consequently, a current component for preheating the cathode flows through a circuit x-1 af ^ -f ^ -3 a- 4-5-3 bf ₂ '-f ₂ -l by and a branch current component flows through a circuit x-2 α-4- 5-2 b-y. If the coils 3 a and 3 & are connected in opposite directions with the coils la and lfr , the magnetic flux caused by the current flow through the coils 3 α and 3 b acts during the preheating of the cathode in such a way that it is caused by the current through the coils 1 a and 1 b cancels induced magnetic flux. Therefore, the impedance of the preheat circuit decreases and a sufficient cathode preheat current flows.

The auxiliary coil 4 is connected in the same direction as the coils 2 α and 2 & in the choke ch _z. Therefore, during the preheating of the cathodes, the impedance value of the coils 2 α and 2 b will temporarily increase due to the inductance caused by the auxiliary coil 4. As a result, the branch current component flowing through the circuit .τ - 2 a - 4 - 5 - 2 b - y is considerably reduced, and the current flow through the glow lamp 5 can be made equal to the value of the cathode preheating current of the lamp.

Thus, there is no disturbance or difficulty in terms of service life and in this circuit the operation of the glow lamp.

When the cathode preheating current flows and the start switch 5 is open, the fluorescent lamp 6 is ignited by the induced voltage surge, and the lamp currents are fed to the paths x-1 a-fj-6-fz-lb-y or x-2a-3a- f ± -6 - ^ - 3b-2b-y distributed.

In these high output lighting systems, it is desirable, with a view to extending the life of the lamp, that these branched currents are equal and equally distributed to one another. Therefore, the respective impedance values of the impedance elements 1 a, Ib, 2α + 3α and 2 & + 3 & in the discharge circuit are selected to be equal to each other. In this state of the system, the magnetic flux generated by the coils 1 α and 1 b is in the same direction as that of the coils 3 α and 3 b of the choke ch _v because during operation of the lamp the direction of the current flowing through the coils 3 σ and 3 b with respect to the current in the coils la and l & is opposite to the current direction during the time of preheating of the cathode.

Since the arc spot on the filament of the lamp is divided into two with the same load, the lamp is not overloaded and its service life is not reduced. From the results of various measurements of the lamp life, it was confirmed that even when the conventional standard lamp is operated at a ^{high output by increasing the lamp electric power by 50 e} / o, an estimated life of 7500 hours can easily be obtained under full illumination. The experiment was carried out by cyclically switching on the lighting for 3 hours and switching it off for 30 minutes.

As can be seen from the drawing, the capacitor 7 connected in parallel to the auxiliary coil 4 is smaller Capacity is intended to facilitate the starting process and is necessary because the choke 4 is parallel to the lamp and is in series with the glow lamp.

Fig. 2 shows a possible further embodiment of the

Arrangement according to the invention, in which, by adding only one attenuation switch Sd in the circuit of FIG. 1, a two-stage setting of the lighting to a high output power and a fixed setpoint power is made possible by switching the attenuation switch Sd on and off. Furthermore, even in the case of simultaneous lighting by a number of light sources, the graduated lighting adjustable to high output power and a fixed target power can be obtained simultaneously for all lamps by turning the aforementioned switch on and off.

The mode of operation during the weakened lighting phase, i. H. during the lighting phase with a fixed nominal power, is exactly the same as in the usual standard fluorescent lamp circuits. It just creates an arc spot on the filament on the side of the electricity supplying end. During the lighting phase with high output power, two arc spots are generated on a heating thread caused.

Fig. 3 shows a possible further embodiment of the circuit arrangement according to the invention, by means of the a 40-watt fluorescent lamp (FL-40) operated with a high output power from a 100-volt voltage source can be. In this embodiment, the coils of Fig. 1 are provided as secondary coils. It In a modification of the circuit of FIG. 1, a leakage transformer with two leakage passages is used. The basic mode of operation is the same as in FIG. 1.

Fig. 4 shows an embodiment of the circuit arrangement according to the invention with a main circuit with leading current. In this circuit there is a parallel to each cathode filament of the lamp, saturable choke provided.

The mode of operation of the throttle Lf will be described in detail below.

In the high output current lagging current arrangement of Fig. 1, no fatal errors can occur when operating in the normal operating condition and even in any abnormal condition that occurs. However, this is the case in the current branch with leading current when the fluorescent lamp is removed from the arrangement or the lamp has reached its service life and the heating wires on both electrodes are burned out or broken. Then the glow lamp still works in contrast to the usual standard fluorescent lamp circuits. She will usually repeat the process until it has blown and the contacts no longer lift up and shorted out. In the circuit branch of the load leading in phase, the inductive reactance part of the circuit increases in such an abnormal state. Therefore, when the current is advanced, the impedance of the entire circuit decreases so much that an excessively large current flows. Since this excessively large current flows only on the one reactor ch ₂ side, this reactor is overheated and damaged. Furthermore

this excessively large current increases the voltage across the series capacitor Cj and can cause destruction ■ cause its isolation. In a circuit arrangement for a operated with high output power Discharge lamp, occurrence of such an abnormal condition is very likely and inevitable. The reason for this is that if the lamp current is 70% greater than the value of the nominal lamp current is chosen, the discharge energy is so great that the lamp is almost at the end of its life burns out and is interrupted. Since the glow lamp is higher in the circuit arrangement described Output power still responds in the event of a filament fault, the lamp may be powered by itself the preheating of a cathode is ignited, and the discharge is in the form of a half-wave rectification continued. In the meantime, the remaining cathode heating wire will also burn through and interrupted will.

To eliminate the above-mentioned deficiency, the parallel choke Lf is designed as a saturable choke with the property that it has a very high impedance value in the range of small currents, but with currents that exceed a predetermined value, the impedance value drops quickly due to the saturation of the core .

The design data of the reactor Lf will be discussed below.

Since the heating wire of the lamp causes a final glow during the preheating or the short circuit of the start switch 5, the heating wire voltage is constant at around 10 volts and does not rise above this value even if the preheating current increases. The saturable choke is therefore expediently constructed in such a way that the impedance is very high up to a terminal voltage of around 13 volts, but the iron core quickly shows a saturation characteristic when the voltage is higher than this. By having this inductor L /, as shown in Fig. 4, in the circuit, such errors as faults due to damage to the load circuit due to heat and breakdown of the series capacitor can be avoided. In the event of a current interruption in the load circuit of the circuit arrangement according to the invention with a lagging circuit, the impedance value of the circuit will increase and therefore the electrical current will decrease. The load circuit will operate at a very light load and so no disturbance will be caused. In a circuit with a leading current, the conditions are completely opposite. If no throttle Lf parallel to the filament is added, the circuits Ia-Z ₁ - // - ^ α and lb-f ₂ -f ₂ '-3b will be open in the event of an interruption of the filament. Therefore, only the circuit x-Cs-2 a-4-5-2 by is switched, so that the inductive reactance of the circuit increases. However, since the capacitive reactance across the series capacitor Cs is constant, the impedance drops sharply, like that of the entire circuit, and an excessively large current is produced which can destroy the choke ch _2. In this case, the throttle Lf short-circuits the respective heating circuit and thus reduces the increase in the inductive reactance of the circuit and the strong increase in the current.

This remains essentially the same as when the cathode was heated in the normal state, and thus no disturbances are caused. An additional Throttle to be switched on.

Claims (5)

Patent claims: 1.Circuit arrangement for a discharge lamp operated with a higher than normal output with preheated electrodes, to which the current is fed via two partial circuits and in which two arc spots are created on a filament, characterized by a stabilizing choke (CA ₁ ) with two in the circuit symmetrical to the lamp switched windings (1 a, 1 V) each connected to one end of the electrode and each individually and isolated on the choke core and two further windings (3 a, 3 b) each magnetically coupled to these, which are connected in series with a thermal switch ( 5) are arranged between the other ends of the electrodes and are connected in such a way that the magnetic flux of the preheating current in the magnetically coupled windings (1 a, 3 a) (I b, 3 b) is compensated for and by a further stabilizing throttle (ch ₂ ) also with two windings (2 a, 2 b) arranged symmetrically to the lamp in the circuit, the one on the one hand to the power source and on the other hand via the windings (3 a, 3 b) lying between the lamp electrodes of the first choke to the lamp electrodes and with an auxiliary starting coil (4), which is between the thermal switch (5) and one of the coils (2 a , 2 b) the second choke is connected in such a way that its magnetic flux generated by the preheating current is in the same direction as that of the winding (2 a, 2 b) of the second choke, so that the partial currents flowing into the respective heating wire in the operating state are the same . 2. Circuit arrangement according to claim 1, characterized in that the windings each Chokes can also be used as secondary windings of a leakage transformer. 3. Circuit arrangement according to claim 1, characterized in that when using one Capacitor in series with the circuit creates a saturable inductor for each filament of the lamp is connected in parallel. 4. Circuit arrangement according to claim 1, characterized in that in order to achieve a two-stage, attenuated lighting between the coils (2 α and 2 b) of the second choke (ch _z ) and the power source weakening switch (Sd) are provided. 5. Circuit arrangement according to claim 1, characterized in that a further outer load choke (ch ₀ ) is connected in series with the circuit. References considered: U.S. Patent Nos. 2,318,072, 2,337,992; "Illuminating Engineering" magazine, August 1957, pp. 397 to 408. 1 sheet of drawings © 909 728/247 1.60