FI111791B - Ballast for at least one pair of parallel discharge gas discharge lamps - Google Patents

Abstract

A ballast for at least one pair of gas discharge lamps in parallel has a rectifier (G) to be connected to the a.c. mains and a converter (WR) connected downstream thereof. A series resonant circuit (LR, CR) is connected to the output of the converter. To the pair of lamps (L1, L2) is allocated a balancing transformer (TS1) having two counteraction windings (WS1, WS2). The two windings are interconnected at one end. The connection point is connected to that of the choke (LR) and of the resonant capacitor (CR) of the series resonant circuit. The other end of the two windings are connected to one electrode of the two lamps (L1, L2).

Description

111791

This invention relates to a ballast for at least one parallel gas discharge lamp pair according to claim 1.

According to Fig. 6 of Applicant EP 0 490 329 Ai, a ballast for two parallel gas discharge lamps 10 is known, in which the inverter is connected after two series resonant circuits to which one of the two gas discharge lamps is respectively connected.

Up to now, ballast technology has started from the assumption that two separate vibration circuits are also required for 2-lamp operation. This is because it has been assumed that by using a vibration circuit common to both lamps, the voltage of the oscillation circuit after the second lamp is lit will no longer be sufficient to light the other lamp. In general, it can be assumed that both lamps do not need to be lit simultaneously.

The present invention is based on the object of simplifying the known ballast.

25

The problem is solved by the features set forth in the section of the features of claim 1.

Surprisingly, the ballast according to the invention, despite the conceptual blocking reason described above, operates using only a single oscillation circuit. This is clearly due to the effect of the symmetry transformer. If one lamp is illuminated, the current 35 passing through the coil of this lamp and the symmetry transformer connected thereto causes a voltage in the other winding which is superimposed on the voltage produced in the 2 111791 oscillation circuit (normally acting on each winding of the symmetry transformer). The above-described overexposure of the voltages to the 5 lamps which have not yet lighted will also cause this to light up.

Lamp ignition can be controlled by monitoring lamp current. If it is found that after the first lamp is lit 10, the second lamp does not light, then as before, the frequency of the inverter can be lowered close to the resonance frequency of the resonant circuit, thereby increasing the ignition voltage of the second lamp which has not yet lit. This usually also results in the second lamp 15 being lit.

If more than one pair of lamps are to be used in parallel for the ballast, it is possible to use either a common symmetro-20 transformer with the same number of coil pairs of coils acting in the same direction, or a separate symmetry transducer with two windings.

This is the subject of claims 2 and 3.

Other embodiments of the invention are set forth in claims 3 to 9.

An example of a ballast according to the invention is described below with the aid of a single drawing.

The connecting device shown in the drawing comprises a bridge rectifier G which is connected to a network. The DC voltage generated by the rectifier-35 ice G is supplied to the first inverter 11R1791 with an asymmetric output. The inverter WR is supplied by the dc voltage generated by the rectifier G The inverter WR comprises the sensation of two interconnected switching elements.

5 The switching frequency must be adjustable. In this way, the inverter WR generates an output voltage of variable frequency at its output.

Connected to the output of the inverter WR is a series resonant 10 circuit comprising a choke LD and a resonant capacitor.

K

escort CR.

The alternating voltage across the resonant capacitor CR is supplied through the difference capacitor CT to two input pairs of L1, L1 and L1, L2. The separation capacitor CT may also be located between the inverter WR and the choke LR. It is shown in dotted lines in the drawing and is marked with a Chili with an index dot on it.

The first pair of lamps, L2, uses a first symmetry transformer Tg ^ having two coils acting in opposite directions Wgl, Wg2 * The other end of each of these coils is connected via a difference capacitor CT to a field of a choke LR and a resonant capacitor CR. The other end of each winding Wg1, Wg2 is coupled; . , to the other electrode of the corresponding lamp L1, L2. The other electrode of each lamp L1, the other electrode, is connected to the ground through a respective resistor, -R2. The current flowing through the lamp generates a voltage drop UL1 in the resistor R 1, which is used as a measure of the lamp current. The resistor R2 is affected by the voltage UL2, which is used to measure the current of the lamp L2.

111791 4

The lamps and L2 are directly annealed, wherein each of the glow coils is connected via annealing capacitors CR1 or C1, respectively.

The other pair of lamps Lg also utilizes a separate symmetry transformer T ^ having two coils acting in opposite directions Wg3, Wg4- Here too, each coil is connected at one end and the coupling point of the two coils is connected via a difference capacitor CT 10 to a choke LR and a resonator . One end of each coil Wg3, Wg1 is connected to the other electrode of the respective lamp Lg, respectively. Here, the other electrodes of each of the lamps Lg, are directly connected to one another. The coupling point is coupled to a coupling point of two symmetry capacitors Cg 1, Cg 2 connected in series between the earth and the direct current potential UD £ of the inverter WR.

Unlike the lamps L1, L2, the lamps of the lamps Lg, the annulus coil 20 are annealed by the annealing transformer TR1, T2. To this end, an annealing voltage is applied to the inlet windings WH1 'WH4 of each annealing transformer. The annealing transformer TR1 has two output coils WH2, WR3, respectively connected to one of the two glow coils of the lamp Lg. The Heh-25 weft transformer TR2 has two output coils WR5, Wr6, respectively connected to one of the two filament coils of the lamp.

After powering the ballast, the switching converter wRattness is selected to be relatively much higher than the resonance frequency of the series resonant circuit formed by the choke LD and the resonant capacitor CR. In this state, the voltage drop across the resonant capacitor CD is relatively small so that none of the lamps can light up. In this situation, however, the filament coils of the lamps are preheated (this applies particularly to lamps L1, L1). After preheating of the filament coils, the frequency of the inverter WR is reduced, with the consequence that the voltage acting on the resonant capacitor increases the closer the resonant frequency of the series resonant circuit becomes to the frequency of the inverter WR. When the voltage applied to the resonant capacitor CR is high enough, one lamp of each lamp pupil first lights up. The current through the lamp 10 induces a voltage in the coil connected to the second lamp of the respective symmetry transformer which superimposes on the ignition voltage of the second lamp, with the result that the second lamp also lights. If there is no ignition of the second lamp, as can be seen, for example, in the case of the lamps L 1, L 2, by the voltages U 1, the frequency of the inverter WR is further lowered so that it no longer approaches the resonant frequency of the series resonant circuit. In this way, the corresponding second lamp is finally forced to light as well.

20

It is essential that each pair of lamps has two lamps. i or each pair of lamps uses only a single · · * series resonant circuit. This operation allows the invention; : simpler to make a ballast in accordance with 25 and cheaper.

Instead of the two symmetry transformers shown in the drawing, a single symmetry transformer (not shown) can be used, in which case the / 30 has four coils, the two of which are acting in opposite directions.

* * * * 1 »

Claims (9)

1. A ballast for at least one parallel-powered gas discharge lamp (L3, L4), comprising a rectifier connected to an AC network, an inverter (WR) connected thereto, a symmetry transformer with two opposite windings connected to one another at its coupling to one another. one of the electrodes in one of the two gas discharge lamps (Llf L2) at its other end, the other electrodes of the two gas discharge lamps (L1, L2) being connected to each other, characterized in that for the two gas discharge lamps (L1, L2) after the output of the inverter (WR), only one series resonant circuit is coupled, which is formed by a choke (Lh) and a resonant capacitor (CR), and that the coupling point of one of the two windings of the symmetry transformer (Tsl) is alternately coupled the coupling point of the choke (LR) and the resonant capacitor (CR). 2. Ballast according to claim 1, characterized in that for a second parallel-driven 'gas discharge lamps (L3, L4) supply for both lamps (Li, L2; L3, L4) there is a separate symmetry transmission. formator (TSi; TS2) provided with two opposite windings (WSi, WS2 / · Ws3, WS4), which at one end are correspondingly connected to each other, and the other end of which is connected .. to one of the electrodes in the respective lamps. both gas discharge lamps (Lx, L2; L3, L4), the other electrodes of the two gas discharge lamps being coupled to each other so that for both lamps (Li, L2; L3, L4) After the output of the inverter (WR), only one serial resonant circuit is coupled, which is formed by a choke (LR) and a resonant capacitor (CR), and that the coupling point of each symmetry transformer (TSi; TS2) is both winding (Wsl ) WS2; WS3, WS4) are alternately connected to the choke point of the choke (LR) and resonant capacitor (CR). 3. Ballast according to claim 1, characterized in that, for all other parallel-powered gas discharge lamps (L3, L4), a single symmetry transformer is provided for all lamps 10 with a number of winding pairs corresponding to the number of lamps with opposite windings, all of which at one of them. one end of which is connected to one another, and the other end of which is connected to one of the electrodes in one of the gas discharge lamps in the associated lamp, the other electrodes in the gas gas discharge lamps in the associated lamp being connected to each other, so that for all lamps of the inverter (fwR) output is only a series resonant circuit, which is formed by a choke (LR) and a resonant capacitor (CR), and that the switching point of the winding of the common symmetry transformer is connected to the switching point for • *; ··, the choke (LR) and the resonant capacitor (CR) . • · I • I '»> Ballast according to any of the preceding claims, characterized in that the inverter ... (WR) output terminal is at a reference potential »» ', .1 (ground) and that the end of the resonant capacitor (CR) • t choke (LR) away end also lies at the reference *: ** potential (ground). I I • ft 111791 11 Ballast according to claim 1, characterized in that the other electrodes connected to each other in the gas discharge lamps of the lamp or each lamp (Li, L2) are directly or via a resistor intermediate circuit coupled to the reference potential (earth). 6. Ballast according to claim 4, characterized in that the other electrodes connected to each other in the lamp or each lamp (Li, L2) of the lamp 10 are connected directly or via a resistor intermediate circuit to the connection point for two in series connected symmetry capacitors CS ( ), that the terminating terminal away from one of the symmetry capacitor's (CS2) junction points is at the reference potential (ground), and that the terminal terminating away from the other symmetry capacitor (CSi )'s terminating point is on the inverter (WR) input DC potential (Udc). 7. Ballast according to any of the foregoing: ·:; The claims, characterized in that the * · 1: coupling point between the opposite windings of the symmetry transformer or each symmetry transformer is one for the choke (LR) and the re- • sonon capacitor (CR ) via a decoupling capacitor 25 (CT) · »» I * »t>; Ballast according to any of the preceding patent claims, characterized in that the throttle (LR) is t · 1: directly connected to the inverter (WR). • »111791 12 9. Ballast according to any of claims 1-7, characterized in that the throttle (LR) is connected to the inverter (WR) via a decoupling capacitor (CT) · »* * • · ·» »