EP0922376A1 - Electronic ballast for gas discharge lamps - Google Patents

Abstract

An electronic ballast for gas discharge lamps has a rectifier (1) that can be connected to a voltage supply source, a condenser circuit which is connected to the rectifier and consists of a first capacitor (2) and a second capacitor (3), a series circuit which is connected to the capacitor connections and consists of a first controllable switch (4) and a second controllable switch (5) which can be alternately switched, and a load circuit which is connected to the connection point between the first and second switches and consists of a series resonance circuit composed of a resonance inductance (6) and of a resonance capacitor (7), as well as of a gas discharge lamp (8) connected thereto. In addition, a transformer is provided whose first winding (9) is connected to the connection point between the first and second capacitor (2, 3) and whose second winding (10) is connected to the resonance capacitor (7).

Description

 Electronic ballast for gas discharge lamps

The present invention relates to an electronic ballast for gas discharge lamps. In particular, the invention relates to an electronic ballast for gas discharge lamps according to the preamble of claim 1

Such an electronic ballast is known for example from AT 386 103 B or DE 33 19 739 C2 and an embodiment is shown in FIG. 6. The electronic ballast comprises a rectifier 1 that can be connected to a supply voltage source, for example a full-bridge or multi-way rectifier to an output of the Rectifier 1 is connected to a circuit arrangement comprising at least a first capacitance 2 and at least a second capacitor 3. This capacitor circuit arrangement is connected to a series circuit comprising two controllable switches 4 and 5 and a Giattungs electrolytic capacitor. At the connection point between the two switches 4 and 5 the actual load circuit with the gas discharge lamp 8 to be controlled and a resonance circuit with a resonance inductance 6 and a resonance capacitor 7 connected in parallel with the gas discharge lamp can also be connected. Furthermore, a D rossel coil 1 1 between the rectifier 1 and the first capacitor 2 also be present, a diode 12 between the first capacitor 2 and the first switch 4 is necessary

The function of this circuit is briefly explained below. If the output voltage of the rectifier is lower than the voltage at the series circuit of the capacitors 2 and 3, energy is delivered from the capacitors 2, 3 to the smoothing capacitor 13. Otherwise, the capacitors 2, 3 pass through the rectifier 1 Energy taken from the supply network The two controllable switches 4 and 5 are known to be able to be switched on and off alternately, so that, depending on the adjustable switching frequency of the two switches 4 and 5, the DC voltage output by the rectifier 1 is converted into a high-frequency AC voltage and the gas discharge lamp 8 is supplied. If the frequency of the supplied AC voltage corresponds to the resonance frequency of the series resonance circuit consisting of the resonance inductance 6 and the resonance capacitor 7, the excess voltage at the resonance capacitor 7 can be used to ignite the gas discharge lamp by changing the frequency of the AC voltage, the operating point for the gas discharge lamp is set, and so these are dimmed However, the following problems occur in the circuit shown in FIG. 6: The second capacitor 3, which acts as a control capacitor, fulfills two functions with the rectifier 1, the return capacitor 2 and the optional choke 11 as a harmonic filter, which is intended to keep the harmonic radiation into the supply network as low as possible.However, this results in different or conflicting requirements for the dimensioning of the control capacitor 3, so that when it is dimensioned, there are either reductions in the co-determination of the resonance frequency or the harmonic filter effect must be made. This applies in particular during the preheating and ignition of the gas discharge lamp

Furthermore, Fig. 6 shows that a current I is fed in at the connection point between the two capacitors 2 and 3, which current can assume very different values from the start of the lamp to its operation, as a result of which the operating point of the entire circuit arrangement is shifted However, 8 can only work optimally on a single operating point dependent on the dimensioning of the capacitors 2 and 3 and the series resonance circuit 6 and 7 and the smoothing capacitor 13, i.e. the lamp burns satisfactorily only at this single operating point and the harmonic content reflected back into the supply network is determined within a certain range Limits kept in particular when igniting or preheating the lamp 8 flows through the resonance inductance 6 and the resonance capacitor 7, a strong resonance current I in the connection point between the two capacitors 2 and 3, so that the voltage across the capacitor 3 increases significantly above that value, be i that the previously described optimal working point is available

The present invention is therefore based on the object of specifying an electronic ballast in which the disadvantages described above are avoided

In particular, the present invention is based on the object of specifying an electronic ballast in which no compromises have to be made in the dimensioning of the second capacitor 3 and in which the current I fed in at the connection point between the capacitors 2 and 3 when igniting or preheating the gas discharge lamp 8 is kept as low as possible This object is achieved by an electronic ballast according to claim 1

The subclaims indicate advantageous embodiments of the present invention

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

1 shows a first exemplary embodiment of the present invention,

2a and 2b variants of the first exemplary embodiment for the control of two gas discharge lamps,

3 shows a second exemplary embodiment of the present invention,

4 shows a variant of the second exemplary embodiment for the control of two gas discharge lamps,

5 shows a third exemplary embodiment of the present invention, and

6 shows an exemplary embodiment of a known electronic ballast

1 shows a first exemplary embodiment of the present invention. The components already explained with reference to FIG. 6 are provided with the same reference numerals, so that a repeated description of these components can be dispensed with

It can be seen from FIG. 1 that, in contrast to the known circuit, the resonance capacitor 7 is no longer parallel to the gas discharge lamp 8, but is connected in series with one of two coupled windings 9, 10 of a transformer. In FIG. 1, these two windings 9 and 10 coupled in opposite directions It is pointed out, however, that the sense of coupling is irrelevant for the effect to be sought here. The left heating filament of the gas discharge lamp is connected to ground via the capacitor 3 in alternating current. The coil resistance of the left heating coil is connected by the transformer in parallel to the right winding 10 of the transformer, so that the resonance capacitor 7 is connected to the right heating coil of the gas discharge lamp 8 via the transformed coil resistance of the left heating coil.This means that the resonance capacitor 7 is above the lamp 8 and thus, as in the known case, the voltage increase at the resonance capacitor 7 for igniting the Gas discharge lamp 8 can be used, but when the lamp 8 is heated or ignited, the resonance current is not fed directly to the connection point between the two capacitors 2 and 3. In addition, it can be seen that in the circuit according to the invention shown in FIG. 1, the capacitor 3 no longer co-determines the resonance frequency of the series resonance circuit, so that it can only be dimensioned taking into account the harmonic reflection. Thus, according to the invention, the problems described in connection with the known circuit using FIG. 6 no longer occur.

FIG. 2a shows a variant of the first exemplary embodiment according to the invention shown in FIG. 1 for two gas discharge lamps 8 and 16, the essential components correspondingly being duplicated. A further transformer with coupled windings 17 and 18 and a further load circuit with the second lamp 16 and a further resonance inductance and a further resonance capacitance 15 are thus provided for the second gas discharge lamp 16. The optional choke coil 11 has been omitted in FIG. 2a. In addition, however, a measuring resistor 19 is provided in series with the resonance capacitors 7 and 15 and the second switch 5. With the help of this resistor 19, both the Are current and the preheating current can be measured. The Are current determines the brightness of the lamp, so that a measurement of this current is of great importance for the monitoring and regulation of the lamp brightness. In the event that the lower switch 5 is closed, the resonance inductors 6 and 14 and the resonance capacitors 7 and 15 are at the same potential since they are connected to one another. Thus, after ignition of the lamps 8, 16, the Are current flows through the measuring resistor 1 during the time when the switch 5 is closed and can therefore be measured at this point in time via the voltage drop across the measuring resistor 19. Before ignition of the gas discharge lamps 8, 16, the preheating current flows when the switch 5 is open via the resonance capacitors 7, 15, the resonance inductors 6, 14 and the closed switch 4. The preheating current is of particular interest in the preheating phase, so that the circuit according to the invention both in the preheating phase and in the operating phase on one and the same component, namely the measuring resistor 19, the parameter of interest can be measured if the measuring time is correctly selected.

The measurability of the parameters of interest in each case via the resistor 19 can generally be transferred to all circuit variants in which the Resonance capacitor is freely accessible, ie in an analogous manner, for example, also to the circuit shown in FIG. 1, FIG. 26 or FIG. 5

2b shows a further variant of the exemplary embodiment shown in FIG. 1 for two gas discharge lamps, a separate transformer being dispensed with for the second gas discharge lamp 16 and instead this lamp being connected on the one hand to the second winding 10 of the transformer of the first lamp 8 and on the other hand to one own winding 17 is provided, which is coupled to the windings 9 and 10 of the transformer of the first gas discharge lamp 8. It is again pointed out that the type of coupling is irrelevant to the effect according to the invention. Furthermore, the two gas discharge lamps are preceded by a balancing element, which advantageously consists of a balancing transformer with coils 20 and 21 coupled in opposite directions. The balancing transformer is used to adjust the lamp currents of the two gas discharge lamps 8 and 16, so that both lamps burn evenly during operation.For this purpose, the two windings 20 and 21 of the balancing transformer are flowed through in opposite directions by the lamp currents of the two gas discharge lamps, so that the balancing transformer carries the lamp currents is magnetized in opposite directions

It should be pointed out that the second gas discharge lamp 16 shown in FIGS. 2a, b is also operated like the first gas discharge lamp 8, so that the advantageous effects of the invention described with reference to FIG. 1 also apply to the second gas discharge lamp 16

Fig. 3 shows a second embodiment of the invention, wherein a transformer with three coupled windings 9, 10 and 22 is used. This exemplary embodiment is particularly advantageous for radio interference suppression, since the gas discharge lamp 8 is set to ground via its left connection and the central transformer winding 22 This exemplary embodiment is advantageous for the measurability of voltages or currents at the individual circuit points, since these variables can be measured directly in this exemplary embodiment, while in the circuits of FIGS. 1 and 6 only these variables can be measured as difference values

According to FIG. 3, three transformer windings are provided in order to supply the connection point between the capacitors 2 and 3 with as little or no current as possible in the case of preheating and in the event of ignition Transfer windings 22, 10, which is caused by the current flowing through the resonance inductance 6 and through the middle and right-hand transmission windings 22, 10, since these have the same number of turns. After the gas discharge lamp 8 is ignited, the current flowing through the gas discharge lamp 8 is transferred to the left-hand transmission winding 9 transmitted and fed to the connection point between the two capacitors 2 and 3. Thus, the object according to the invention is achieved in that the lowest possible current is supplied to the connection point in preheating and ignition mode. In addition, it can be seen that the capacitor 3 does not determine the resonance frequency of the series resonance circuit and thus can only be dimensioned taking into account the avoidance of harmonic radiation into the supply network.

The number of turns of the left transmission winding 9 can be designed independently of that of the other two windings 22 and 10, so that the current to be fed to the connection point between the capacitors 2 and 3 can be set in particular via this winding 9

In comparison to the circuits described above, an isolating capacitor 23 is additionally provided. In FIG. 6, the center point of the half bridge between the switches 4 and 5 before the gas discharge lamp 8 is ignited by the capacitors 7 and 3 and after the ignition only by the capacitor 3 in terms of AC current from ground 3, this is not the case in the circuit shown in FIG. 3 after the ignition, so that the isolating capacitor 23 is provided to avoid asymmetries on the half-bridge consisting of the switches 4, 5 and the smoothing capacitor 13

FIG. 4 shows a variant of the second exemplary embodiment for the operation of two gas discharge lamps 8 and 16. Accordingly, four transformer windings 9, 18, 22 and 10 are required in this case, the effect of the circuit according to the invention corresponding to the advantageous effect described with reference to FIG. 3 for each gas discharge lamp As already in FIG. 2b, a balancing transformer with windings 20, 21 coupled in opposite directions is also provided in FIG. 4 for balancing the lamp currents of the two lamps 8, 16

5 shows a third exemplary embodiment of the electronic ballast according to the invention. This exemplary embodiment is a further development of the exemplary embodiment shown in FIGS. 1 and 2, but in addition to the two coupled

Uebertragerwicklungen 9 and 10 a third coupled Uebertragerwick 22 provided In addition, the measuring resistor 19 is in turn present in series with the resonance capacitor 7 and the lower controllable switch 5, so that the resonance capacitor is connected to the left connection of the gas discharge lamp 8 via the resistor 19, which can be neglected in terms of its size, and the capacitor 3, and the resonance capacitor 7 As it were parallel to the gas discharge lamp 8, the gas discharge lamp 8 can thus also be ignited in the circuit shown in FIG. 5 by increasing the resonance at the resonance capacitor 7. For preheating, a certain voltage is generated via the resonance capacitor 7, which is also applied to the lamp 8 via ground The transformer receives this voltage, which drops across the resonance capacitor 7, with its primary winding 22 and converts it into a corresponding heating voltage on the two filaments

Through the primary winding 22 of the transformer, the current is transformed up from the primary winding 22 into the spiral windings 9 and 10, so that, conversely, the spiral resistances are transformed up into the primary winding 22 and a low alternating current occurs in the primary winding 22 due to the high resistance the heating or ignition phase only a very small current is fed to the connection point between the capacitors 2 and 3, which solves the task originally set

In FIG. 5, additional free-wheeling or overshoot diodes 24 and 25 are advantageously additionally provided, each of which bridges one of the two controllable switches 4 and 5, which are preferably MOS field effect transistors

Claims

Expectations

1. Electronic ballast for gas discharge lamps, with a rectifier (1) that can be connected to a supply voltage source, with a capacitor circuit arrangement connected to the rectifier, comprising at least one first capacitor (2) and at least one second capacitor (3), with one with the capacitor Circuit arrangement connected series circuit of a first controllable switch (4) and a second controllable switch (5), which can be switched alternately, and with one connected to the connection point of the first and second switches

Load circuit with a series resonance circuit consisting of a resonance inductance (6) and one

Resonance capacitor (7) and a gas discharge lamp (8) connected to it, characterized by a transformer with a first winding (9), which is connected to the connection point between the first and second capacitors (2, 3), and with a second winding

(10), which is connected to the resonance capacitor (7)

2. Electronic ballast according to claim 1, characterized in that the first winding (9) of the transformer is also connected to a filament of the gas discharge lamp (8) and the second winding (10) of the transformer to the other filament of the gas discharge lamp. (Fig. 1)

3. Electronic ballast according to claim 1 or 2, characterized by a between the connection point of the first and second capacitor (2, 3) and the connection point of the first and second switch (4, 5) connected further load circuit with a further series resonance circuit from a further resonance inductance (14) and a further resonance capacitor (15) and a further gas discharge lamp (16) connected to it, and a further transformer with a first winding (17) which is connected to the connection point between the first and second capacitors (2, 3), and with a second winding (18) which is connected to the further resonance capacitor (15) (Fig. 2a)

4. Electronic ballast according to claim 1 or 2, characterized in that a further load circuit is connected between the connection point of the first and second capacitor (2, 3) and the connection point of the first and second switch (4, 5), which comprises a further gas discharge lamp (16) connected to the series resonance circuit (6, 7) , and that the transformer comprises a third winding (17) which is connected to the connection point between the first and second capacitor (2, 3) and a filament of the further gas discharge lamp (16) (Fig. 2b)

5. Electronic ballast according to claim 1 or 2, characterized in that the transformer comprises a third winding (22) which is connected in parallel to the discharge path of the gas discharge lamp (8) (Fig. 5)

6 Electronic ballast according to one of the preceding claims, characterized in that the resonance capacitor (7) or the resonance capacitors (7, 15) with the second switch (5) and a measuring resistor (19) is or are connected

7 electronic ballast according to claim 6, characterized in that the measuring resistor (19) directly the Are current and the preheating current depending on the switching state, the switches 4, 5 can be measured

8. Electronic ballast according to claim 1, characterized in that the transformer comprises a third winding (22), the one filament of the gas discharge lamp (8) via the series circuit from the second winding (10) with the resonance capacitor (7) with the other Coil is connected, and wherein the third winding (22) is connected to the one coil of the gas discharge lamp (8) (Fig. 3)

9 electronic ballast according to claim 8, characterized in that the second and third windings (10, 22) have the same number of turns

10 electronic ballast according to claim 8 or 9, characterized in that with the resonance inductance (6) of the load circuit, a further load circuit with a further resonance capacitor (15) and a further gas discharge lamp (16) connected thereto, and that the transformer has a fourth winding (18), one filament of the further gas discharge lamp (16) being connected to the other filament of the further gas discharge lamp (16) via a series circuit comprising the fourth winding (18) with the further resonance capacitor (15), and the third winding (22) with which a filament of the two gas discharge lamps (8, 16) is connected (FIG. 4)

1 1. Electronic ballast according to one of claims 3, 4 or 10, characterized in that the two gas discharge lamps (8, 16) is assigned a symmetrizing element (20, 21) which can be magnetized in opposite directions by the lamp currents of the two gas discharge lamps

12 Electronic ballast according to claim 1 1, characterized in that the balancing element is a balun, whose oppositely acting windings (20, 21) at one end to one another and at the other end to the one filament of the corresponding gas discharge lamp (8, 16) are

13 Electronic ballast according to one of the preceding claims, characterized in that the first and second controllable switches (4, 5) is a MOS field effect transistor

14. Electronic ballast according to one of the preceding claims, characterized in that a choke coil (11) is connected between the rectifier (1) and the first capacitor (2).

15 Electronic ballast according to one of the preceding claims, characterized in that a diode (12) is connected between the first capacitor (2) and the first switch (4)

16. Electronic ballast according to one of the preceding claims, characterized in that a smoothing capacitor (13) is connected in parallel with the series circuit of the first switch (4) with the second switch (5).

17. Electronic ballast according to one of the preceding claims, characterized in that in each case a return diode (24, 25) is connected in parallel to the first and second switches (4, 5).

18. Electronic ballast according to one of the preceding claims, characterized in that a separating capacitor (23) is connected to the resonance inductor (6) or the resonance inductors (6, 14).