WO2003069963A1 - Lamp sensor for a choke for operating a gas discharge lamp - Google Patents

Abstract

The invention relates to a choke for operating a gas discharge lamp (4), which comprises an inverter (1) that has two transistor switches (17 and 18) that are connected in series to a direct voltage source (Ubus) in a push-pull circuit. The inverter (1) is linked with a load circuit (3) via a coupling capacitor (2) to which a high-impedance resistor (12) is connected in parallel, said load circuit comprising the gas discharge lamp (4) and an acceptor circuit (22). A sensor circuit (6) is used to detect both a lamp malfunction and the voltage applied to the lamp (4). The sensor circuit (6) is provided with a voltage divider (7) that is connected in parallel to the lamp filaments (8, 9) and the resonance capacitor (5) on the side facing away from the coupling capacitor (2) of the lamp (4). A sensor signal (10) detects a lamp malfunction or determines the lamp voltage that is tapped in a center (11) of the voltage divider (7).

Description

 Lamp sensor for a ballast for operating a gas discharge lamp

The invention relates to a ballast for at least one gas discharge lamp.

Conventionally, in the case of high-quality ballasts for gas discharge lamps, the lamp electrodes are preheated before the ignition voltage is applied between them. It has been shown that the life of the lamps can be extended to a considerable extent by this measure.

As described, for example, in EP 0 594 880 A1, the gas discharge lamp is generally operated on a series resonant circuit, wherein the resonant circuit capacitor is generally parallel to the discharge path of the gas discharge lamp. The electrodes of the lamp are designed as heating coils, through which the current of the resonant circuit flows when the lamp is not lit. In the preheating operation, the frequency is changed relative to the resonance frequency of the series resonant circuit such that the voltage across the resonant capacitor and thus across the gas discharge lamp does not cause ignition of the gas discharge lamp. In this way, a substantially constant current flows through the lamp electrodes designed as helices, so that they are preheated. After the preheating phase, the frequency is set in the vicinity of the resonant frequency of the resonant circuit, whereby the voltage across the resonant capacitor is increased so that the gas discharge lamp finally ignites.

In addition to the main function of initiating, maintaining and switching off the gas discharge, the ballast should additionally have a function monitoring the status of the lamp in order to detect any malfunctions and to be able to initiate appropriate measures. These measures may include, for example, the shutdown of the high voltage part. A malfunction may occur, for example, if one of the two coils or both are defective, or if the lamp has been completely removed or not (correctly) inserted into the sockets of the lamp.

EP 0 707 439 A1 discloses a method in which, in the case of an electronic ballast for a gas discharge lamp, the voltage drop is measured via a resistor connected in series with the primary winding of a heating transformer and thus the heating current in order to detect whether there is a coil breakage , or no lamp was inserted into the socket in the lamp.

Another requirement for modern ballasts is the detection of the voltage applied across the discharge path of the gas discharge lamp.

FIG. 3 shows schematically a section of a ballast, on the one hand for detecting a lamp fault

(Spiral breakage, non-insertion or removal of the lamp, etc.) and on the other hand designed to detect the lamp voltage. 1 to 3, an inverter with its two alternately clocked switches (power transistors) 17 and 18 is designated schematically. At the node of the inverter 1, a load circuit 3 is connected, which has a series resonant circuit 22, consisting of a resonance inductor 16 (L _R ) and a resonant capacitor 5 (C _R ). Furthermore, an LD pelkondensator 2 {C _κ) is provided, which connects the load circuit 3 to the capacitive node of the inverter. 1 The discharge path of the lamp 4 is connected in parallel with the resonance capacitor 5.

Furthermore, the heating coils 8 and 9 of the gas discharge lamp 4 can be seen. In series with the lower heating coil 9, ie between the lamp 4 and the ground node, a measuring resistor 26 (j?) Is connected, through which the lamp current and the Helical current flows. By means of the voltage dropping across the measuring resistor 26 (R), a measuring signal 10a (S1) can be tapped which shows whether a heating current can flow through the filaments 8 and 9 in the unfired state of the lamp and thus if a lamp 4 with proper heating filaments 8 and 9 is inserted in the provided sockets.

For detecting the lamp voltage is also on the sides of the coupling capacitor 2 (C _κ) of the load circuit 3, a voltage divider te 7 connected in parallel to the gas discharge lamp. 4 This voltage divider 7 has two resistors 14 and 15 (R ₁ and R ₂ ), which are connected in series. Thus, at the circuit node 11 between the two resistors 14 and 15 a signal 10b (S2) can be tapped, which is representative of the voltage applied across the discharge path of the gas discharge lamp 4 voltage.

It should be noted that in such a circuit for the detection of the lamp voltage and for detecting a malfunction of the lamp 4 per a separately provided circuit must be provided. Accordingly, two signals Sl and S2 must be utilized.

In view of the above requirements for modern electronic ballasts, it is an object of the present invention to provide a technology that allows the detection of voltage applied to a gas discharge lamp in operation voltage and the detection of a lamp failure (missing lamp, etc.) in a simple manner.

In particular, a single signal should suffice for the detection of the lamp voltage as well as the detection of a malfunction of the lamp.

This object is achieved by the features of the independent claim. The dependent claims form continue the central idea of the invention in a particularly advantageous manner.

The invention thus provides a ballast for operating a gas discharge lamp. In this case, an inverter, which has two series-connected and connected to a DC voltage source, in push-pull transistor switch (ϊi or T ₂ ), which are connected via a coupling capacitor (C _κ ) with a load circuit. The load circuit, as already known from the prior art, the gas discharge lamp and a series resonant circuit. Finally, a sensor circuit is provided for the combined detection of a lamp failure and the voltage applied to the lamp based on a single measurement signal (S2). In this case, the sensor circuit has a voltage divider which, on the one hand, is connected to the "upper" potential-carrying filament of the lamp and, on the other hand, to ground.

The sensor circuit 6 makes it possible to tap a sensor signal (S2) to detect a lamp malfunction or to detect the lamp voltage. Thus, it is an advantage of the present invention that on the basis of a single sensor signal (S2) both a lamp failure and the lamp voltage can be evaluated.

With the coupling capacitor, a high-impedance resistor R _κ can be connected in parallel to form in a simple manner a DC branch.

The sensor circuit may be integrated in an ASIC.

The heating power can be capacitively or inductively coupled into at least one filament of the gas discharge lamp.

Furthermore, a method for detecting the lamp voltage and for detecting a lamp failure in a ballast for gas discharge lamps is provided according to the invention. In this case, the detection of the lamp voltage and the detection of a spiral breakage of the lamp based on a single measuring signal (S2). In particular during the preheating and ignition phase, the filament current is monitored and during normal operation the lamp current is monitored.

Further features, advantages and features will now be explained with reference to the figures of the accompanying drawings and to a detailed description of exemplary embodiments.

1 shows a first embodiment of the invention in a schematic way,

Fig. 2 shows a further embodiment of the invention, and

FIG. 3 shows a further basic possibility for detecting a lamp malfunction and for detecting the voltage applied to the discharge path of the lamp.

In Fig. 1, an embodiment of the present invention is shown schematically. As is known, the ballast according to the invention has an inverter 1 with two series-connected, connected to a DC voltage source U _bus and alternately clocked transistor switches 17 and 18 (2 and T ₂ ) on. The switching can be effected by a control unit 23, which can be realized as an integrated circuit (IC) and in particular in an ASIC. At the junction of the two switches 17 and 18, a load circuit 3 is connected, which has a series resonant circuit 22 and the lamp 4. The series resonant circuit 22 consists of a resonance inductor 16 (L _R ) and a resonant capacitor 5 (C _R ). The discharge path of the gas discharge lamp 4 between the two heating coils 8 and 9 is, as known, connected in parallel to the resonance capacitor 5 (C _R ). Parallel to the coupling capacitor 2 (C _κ ), a high-resistance resistor 12 (R _κ ) is connected, so that bypassing the coupling capacitor 2 (C _κ ) a low direct current I _DC through the upper heating coil 8 and a later explained in more detail Voltage divider 7 can flow.

As can be seen in FIG. 1, according to the invention a voltage divider 7 with the resistors 14 and 15 (i _× or R ₂ ) is connected in parallel with the parallel connection of the gas discharge lamp 4 and the resonance capacitor 5 (C _R ). More specifically, the voltage divider 7 is provided on the side facing away from the coupling capacitor 2 [C _κ ) side of the lamp 4 and thus, viewed from the inverter 1, the upper heating coil 8 downstream. As already mentioned, as a result of the high-resistance parallel resistor 12, a direct current I _{ΏC flows} through the resistors 14 and 15 (R _x or R ₂ ) of the voltage divider 7. At the circuit node 11 between the two resistors 14 and 15 of the voltage divider 7 becomes Measuring signal 10b (sensor signal S2) tapped, which after an analog-to-digital conversion of a (digital) evaluation circuit 13 can be supplied. This evaluation circuit 13 can also be implemented as an integrated circuit. The voltage divider 7 together with the signal tap 11 thus represents a sensor circuit 6 for detecting a lamp failure as well as for detecting the lamp voltage.

The function of the circuit according to the invention will now be explained. The evaluation circuit 13 can detect the following luminous states depending on the value of the sensor signal 10b (S2):

If no lamp 4 is inserted into the sockets of the lamp or if the upper heating coil 8 of the gas discharge lamp 4 is broken, no direct current I _DC can flow through this heating coil 8 and thus through the voltage divider 7. Accordingly, no DC voltage drops at the voltage divider 7 in this case. In the non-ignited state, therefore, there is only one in the event of a lamp failure AC voltage according to the vibration behavior of the series resonant circuit 22 to the voltage divider 7 at. As already stated, this can be detected by the evaluation circuit 13 on the basis of the sensor signal 10b (S2). Under certain circumstances, measures may have to be taken immediately in this case of the lamp failure, since, for example, very high voltages can occur at the output of the inverter 1 without the use of a lamp 4. A measure, which is then caused by the evaluation circuit 13, can accordingly consist of a system shutdown or at least shutdown of the inverter 1.

In the event that a lamp 4, in which at least the upper heating coil 8 is working properly, is inserted into the designated sockets of the luminaire, a direct current I _{DC can} flow through this upper heating coil 8 and thus also through the voltage divider 7. On the basis of the sensor signal 10b (S2), the evaluation circuit 13 in this case will detect an AC voltage shifted by a DC voltage drop at the voltage charge 7.

The voltage drop across the lamp 4 AC voltage is thus measured in each case. Depending on whether or not a lamp 4 with proper upper heating coil 8 is inserted, this alternating voltage is possibly shifted by the DC voltage dropping across the voltage divider.

It should be pointed out that the high-resistance resistor 12 (R _K ) in the parallel branch of the coupling capacitor 2 [C _K ] furthermore has the advantage of having the so-called "whale", ie alternately bright and dark sections in the gas discharge lamp 4, can at least greatly reduce by providing a certain DC component.

Fig. 2 shows another embodiment of the present invention. In this embodiment, the coupling of the heating power into the heating coils 8 and 9 takes place inductively via the two coils 19 and 20 (Lhi or _h2 ) of a transformer. gers. While a capacitive coupling of the heating power is usually preferred for non-dimmed devices, the dimmed devices, the inductive form of Heizkraftseinkopplung is preferred.

In this drawing is also shown schematically that the primary winding 21 (Lh ₃ ) of a separate transformer can be used as a primary winding for the inductive heating power transmission. Alternatively, it is possible to use the resonance inductance 16 (L _R ) as a primary winding for the inductive coupling of the heating power into the heating coils 8 and 9 of the gas discharge lamp 4.

It should also be noted that, in connection with the present invention, any type of coupling of the heating power into the heating coils 8 and 9 can be used.

LIST OF REFERENCE NUMBERS

No, component or signal

Inverter implemented as two series-connected normally-off n-channel MOSFETs T _x and T ₂

Coupling capacitor C _κ in the series resonant circuit 22nd

Load circuit, consisting of a series resonant circuit 22 and a gas discharge lamp. 4

Gas discharge lamp in the load circuit 3

Resonant capacitor C _{R of} the series resonant circuit 22nd

Sensor circuit (realized as a voltage divider 7 with the resistors Ri and R ₂ ) for detecting a disturbance of the gas discharge lamp 4 and for detecting a voltage drop across the gas discharge lamp. 4

Voltage divider, used as the sensor circuit 6 first (upper) heating coil of the gas discharge lamp 4 second (lower) heating coil of the gas discharge lamp. 4

10a voltage drop across the measuring resistor 26 (sensor signal S1)

10b output voltage of the sensor circuit 6 (sensor signal S2)

11 circuit nodes in the middle of the voltage divider 7 _

12 high resistance R _κ in the parallel branch of the coupling capacitor C _κ

13 evaluation circuit for evaluating the sensor signal 10

14 first (upper) resistor JI of the voltage divider 7th

15 second (lower) resistor R _{2 of} the voltage divider 7th

16 resonance inductance L _{R of} the series resonant circuit 22

17 first clocked transistor switch (implemented as a self-blocking n-channel MQSFET T) second clocked transistor switch (realized as a self-blocking n-channel MOSFET T ₂ )

19 inductance L _hl (realized as a primary winding of a heating transformer Tr _x ) for inductive coupling of the heating power in the first (upper) heating coil 8 of the gas discharge lamp. 4

20 inductance L _h (realized as a primary winding of a heating transformer Tr ₂ ) for inductive coupling of

Claims

Expectations

1. Ballast for operating a gas discharge lamp, comprising:

- An inverter (1) which has two series-connected switches (17 and 18) connected to a direct voltage source (U _bus ) and connected in push-pull mode and is connected by means of a coupling capacitor (2) to a load circuit (3) which connects the gas discharge lamp (4) and a series resonant circuit (22), and

- A sensor circuit (6) for combined detection of a lamp fault and the voltage applied to the lamp (4), the sensor circuit (6) having a voltage divider (7) which is connected on the one hand to the upper, potential-carrying filament of the lamp and on the other hand to ground and a sensor signal (10b) for detecting a lamp fault or for detecting the lamp voltage is tapped at a center point (11) of the voltage divider (7).

2. Ballast according to claim 1, characterized in that a high-impedance resistor (12) is connected in parallel to the coupling capacitor (2).

3. Ballast according to one of the preceding claims, characterized in "that the sensor circuit (6) is integrated in an ASIC.

4. Ballast according to one of the preceding claims, characterized in that the heating power is capacitively coupled into the filaments (8, 9) of the gas discharge lamp (4).

5. Ballast according to one of the preceding claims, characterized in that the heating power is inductively coupled into the filaments (8, 9) of the gas discharge lamp (4).

6. Ballast according to one of the preceding claims, characterized in that the sensor signal (10b) A / D-converted and an evaluation circuit (13) is supplied.

7. A method for detecting the lamp voltage and for detecting a lamp fault in a ballast for gas discharge lamps (4), characterized in that the detection of the lamp voltage and the detection of a filament break in the gas discharge lamp (4) is carried out using a single measurement signal (10b).

8. The method according to claim 7, characterized in that the measurement signal (10b) is derived at a voltage divider (7).

9. The method according to claim 7 or 8, characterized in that the filament current is monitored during the preheating and ignition phase and the lamp current during normal operation.