EP2252133A2 - Switching assembly for operating a low pressure gas discharge lamp and method for same - Google Patents

Abstract

The arrangement (1) has a control device (9) controlling an inverter (6) and frequency of an alternating current-supply voltage. A transformer (23) preheats electrodes of a low-pressure gas discharge lamp (19) and has a primary winding (24) and secondary windings (25, 26). The winding (24) is connected in series with a resonant capacitor and to a reference potential of the control device. An electrical switch (27) is coupled in parallel with the winding (24), where the control device transfers the switch into an electrically conducting switching state after fulfilling a starting criterion. An independent claim is also included for a method for operating a low-pressure gas discharge lamp.

Description

The invention relates to a circuit arrangement for operating at least one low-pressure gas discharge lamp, having an input with a first and a second input terminal for applying a DC supply voltage, having an output having a first and a second output terminal pair for connecting the at least one low-pressure gas discharge lamp. with an inverter coupled to the first and second input terminals for providing an AC supply voltage from the DC supply voltage, with control means for driving the inverter and thereby controlling the frequency of the AC supply voltage, the controller being configured to initiate a preheat phase upon satisfaction of a predetermined preheat criterion in which the inverter is operated with a preheating frequency, and after fulfillment of a predetermined ignition criterion, the frequency of the AC supply voltage to a Z. with a resonant circuit having a resonant choke whose first terminal is coupled to the inverter and whose second terminal is coupled to a resonant pole, and a resonant capacitor coupled between the resonant pole and the reference potential of the controller, and a transformer to Preheating electrodes of the low-pressure gas discharge lamp, which has a primary winding, one with The first secondary winding coupled to the first output terminal pair and a second secondary winding coupled to the second output terminal pair. Moreover, the invention relates to a method for operating a low-pressure gas discharge lamp in such a circuit arrangement.

State of the art

The invention is based on a circuit arrangement, as described in the document EP 0 748 146 A1 is described. In this known circuit arrangement, an inverter provides an alternating supply voltage for a low-pressure gas discharge lamp (fluorescent lamp). A resonance choke is coupled to the inverter. A resonant capacitor is coupled in parallel with the low pressure gas discharge lamp. The inverter controls all operating functions of the gas discharge lamp. After commissioning of the circuit - this by applying a mains AC voltage to a coupled to the inverter power supply - the inverter is operated during a preheating for gentle ignition of the gas discharge lamp with such a frequency, not only above the idle resonance frequency of the resonant circuit (resonance choke and resonant capacitor), but is also above an ignition frequency. During this preheating phase, a preheating current flows over the electrodes of the gas discharge lamp. This current is intended to heat the electrodes to emission temperature. Since the frequency of the alternating supply voltage during the preheating phase is greater than the ignition frequency of the gas discharge lamp, premature ignition of the Gas discharge lamp prevents. In fact, above the resonant frequency of the resonant circuit, the amplitude of the voltage across the resonant capacitor is indirectly proportional to the frequency.

For the preheating of the electrodes of the gas discharge lamp, a transformer is used in the subject of the above document, the primary winding is connected via a coupling capacitor to the output of the inverter. On the other hand, the primary winding can be coupled to the reference potential via a semiconductor switch. There are provided in the transformer, two secondary windings, which are each coupled to an electrode of the gas discharge lamp. In this way, the electrodes can be preheated.

Accordingly, in the article according to document EP 0 748 146 A1 a semiconductor switch for the primary winding required, which must be designed for operation at high voltages. Also, a transformer is required, which is approximately operated as a voltage transformer. In addition, a clamp diode is required, via which the voltage at the preheat switch can be limited to the supply voltage of the inverter. A particular challenge is to provide such a reliable preheating of the electrodes, as described in the document EP 0 748 146 A1 ensuring that it is easier and cheaper to achieve.

The publication US 2006/0267519 A1 also describes a circuit arrangement for operating a low-pressure gas discharge lamp. This document is about the Problem, a person who carries the reference potential of the earth and touches the gas discharge lamp to protect against electric shock. This document goes to the way to connect the reference potential of the gas discharge lamp via a parallel circuit of a switch and a capacitor with the reference potential of the inverter. The switch is closed only when the gas discharge lamp has ignited properly. Otherwise, the switch remains open, so that the connection of the gas discharge lamp is largely decoupled from the reference potential of the inverter low frequency. The capacitor coupled in parallel with the switch is required to ensure this decoupling between the connection of the gas discharge lamp and the reference potential of the inverter.

Presentation of the invention

It is an object of the present invention, starting from the subject matter according to document EP 0 748 146 A1 to show a solution as a circuit arrangement of the type mentioned can be particularly favorable.

This object is achieved by a circuit arrangement with the features according to claim 1, as well as by a method having the features according to claim 7. Advantageous embodiments of the invention are the subject of the dependent claims.

Thus, the primary winding of the transformer is connected in series with the resonant capacitor and connected directly to the reference potential of the controller, and an electrical switch is coupled in parallel with the primary winding of the transformer. The electrical switch has a control terminal which is coupled to the control device. The control device is designed to convert after fulfillment of the ignition criterion the electrical switch in its electrically conductive switching state.

Thus, the effect of the invention is achieved in that the primary winding of the transformer coupled on the one hand with the resonant capacitor in series and on the other hand connected directly to the reference potential of the control device, as well as by bridging the primary winding during ignition of the low-pressure gas discharge lamp. In other words, a basic idea of the invention is to allow the current flowing via the resonance capacitor connected in parallel to the gas discharge lamp to flow during the preheating phase also via the primary winding - which is connected to the reference potential of the control device - and the primary winding after the preheating phase on the primary side with the reference potential short circuit the controller by means of the electric switch.

Compared to the article according to the publication EP 0 748 146 A1 the circuit arrangement according to the invention on the one hand has the advantage that it manages without an additional coupling capacitor for the primary winding of the transformer; the function of the coupling capacitor takes over here the resonant capacitor. On the other hand, the circuit arrangement according to the invention is also without a clamping diode, as used in the prior art; the primary winding is namely when igniting the Gas discharge lamp shorted by means of the electrical switch. Another advantage of the circuit arrangement according to the invention over the object according to document EP 0 748 146 A1 can be seen in the fact that a low-cost low-voltage switch (generally less than 100 volts) can be used for bridging the primary winding. In the prior art, on the other hand, the switch had to be designed to operate at high voltages as they drop across the primary winding (typically 600 volts).

Also with respect to the article according to document US 2006/0267519 A1 the circuit arrangement according to the invention offers advantages in terms of the number of components used and thus in terms of cost. In order to solve the technical problem specified in this document, a capacitor between the primary winding and the reference potential had to be used. The switch used there, with which the primary winding and the capacitor are bridged, must withstand high voltages, which is associated with additional costs compared to a low-voltage switch.

In the subject matter in the publication US 2006/0267519 A1 Furthermore, a coupling capacitor between the inverter and the resonant choke had to be switched due to the technical problem specified there. In contrast, in the circuit arrangement according to the invention the coupling capacitor can be coupled between the second terminal pair of the output and the reference potential of the control device (ie connected to the "low side" of the gas discharge lamp). In this way, the coupling capacitor can also be performed symmetrically, and the current load of a DC link capacitor coupled in parallel to the input and the voltage of the gas discharge lamp to ground can be reduced.

Not unnoticed should remain a further advantage of the circuit arrangement according to the invention, namely that a voltage drop across the primary winding can be detected by the control device. This is made possible by the fact that the primary winding of the transformer - in contrast to the subject matter according to document US 2006/0267519 A1 - Is directly coupled to the reference potential of the control device. The detection of the voltage drop across the primary winding makes it possible to draw conclusions about operating conditions prevailing at the secondary windings and thus at the output of the circuit arrangement. By evaluating this voltage, it is possible to detect such an operating state in which the terminals of a single terminal pair are short-circuited or else in which an open circuit occurs between these terminals, namely, for example, after unscrewing the gas discharge lamp or after burning through a coil. If, for example, an impermissible operating state is detected at the output of the circuit arrangement, the control device can switch off the inverter and thus the AC supply voltage.

It has proven to be particularly advantageous if the electrical switch is a bidirectionally blocking or conducting semiconductor switch. For example, the electrical switch may be a symmetric blocking MOSFET. Such MOSFETs, in which the parasitic diode is no longer present, are recently available in the market. With a MOSFET on the one hand significantly shorter switching times can be achieved than with a conventional relay; On the other hand, MOSFETs are cheaper.

As already stated, the circuit arrangement has the advantage that the voltage drop across the primary winding of the transformer can be measured, whereby operating conditions prevailing at the output can be detected. In an embodiment, it is provided that the control device is coupled to a detection pole arranged between the winding and the resonance capacitor and designed to detect the voltage dropping across the primary winding. The following relationship is exploited: If the impedance of a circuit having the secondary winding changes, the effective impedance at the primary winding of the transformer also changes. The change in the impedance on the secondary side can therefore be detected directly by the evaluation of the voltage at the primary winding. If the voltage drop across the primary winding lies in an impermissible value range, then the control device can switch off the alternating supply voltage. This can be done, for example, in such a scenario: An operator turns on a power switch to turn on the gas discharge lamp. From the AC voltage of the supply network, a power supply provides a DC supply voltage for the circuit arrangement. Even before the preheating phase is initiated - in which the electrodes of the gas discharge lamp are preheated - the control device controls the inverter in such a way that very small currents flow via the primary winding. The control device now checks whether the voltage drop across the primary winding is within a permissible value range, that is, whether the gas discharge lamp is properly connected to the output and the lamp electrodes are in order or not. If the control device recognizes, for example, that no gas discharge lamp is connected to the circuit arrangement, the control device switches off the inverter.

In one embodiment, it is provided that the control device is designed to control the inverter before initiating the preheating phase and to detect the voltage dropping across the primary winding during this activation, wherein the preheating criterion includes that this voltage lies within a predetermined value range. Thus, the preheating is initiated by the controller only if the gas discharge lamp is properly connected to the circuit. It is thus prevented that the preheating is initiated, for example, when no gas discharge lamp is connected, and that an operator with a high voltage in contact. Thus, the circuit arrangement also does not require the high-voltage resistors, coupling capacitors or diodes otherwise used to detect the presence of the lamp electrodes on the secondary windings of the preheating transformer.

The control device can also detect the voltage dropping across the primary winding during the preheating phase. Then the ignition criterion includes that this voltage is within a predetermined value range. The control device can therefore also during the preheating an inadmissible Recognize operating state at the output of the circuit arrangement and optionally interrupt the preheat phase. This can be the case, for example, if during the preheating phase the gas discharge lamp is unscrewed or a filament of the lamp burns out. This embodiment may, for example, be implemented in such a manner: An operator turns on a power switch, thereby providing a DC supply voltage at the input of the circuitry. The control device initiates the preheating phase, namely with appropriate control of the inverter. During this preheat phase, the controller monitors the voltage drop across the primary winding. At the beginning of the preheat phase, this voltage is within the specified permissible value range, so that the preheat phase is continued. During the preheating phase, a filament of the gas discharge lamp burns through, and there is an idle between the terminals of the corresponding terminal pair. This idling recognizes the control device, namely the fact that the voltage at the primary winding is outside the predetermined permissible value range. Immediately after detecting the idle, the controller turns off the inverter.

Additionally or alternatively, the ignition criterion may include that after initiation of the preheat phase, a predetermined time interval has elapsed. It is then ensured that the electrodes of the gas discharge lamp are preheated for the predetermined time interval and the gas discharge lamp is gently ignited.

A method according to the invention is for operating at least one low-pressure gas discharge lamp on a circuit arrangement designed the genus mentioned above. In the method, during the preheat phase, an electrical current flowing across the resonant capacitor is also conducted across the primary winding of the transformer, the primary winding being directly coupled to the reference potential of the controller. When the ignition criterion has been met, an electrical switch is closed and the primary winding is thereby bridged.

The preferred embodiments presented with reference to the circuit arrangement according to the invention and their advantages apply correspondingly to the method according to the invention.

Further features of the invention will become apparent from the claims, the figure and the description of the figures. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the figure description and / or shown alone in the figure can be used not only in the respectively specified combination, but also in other combinations or in isolation, without the scope of To leave invention.

Short description of the drawing

The invention will now be explained in more detail by means of a preferred embodiment and with reference to the drawing, wherein the single figure illustrates in diagrammatic representation a circuit arrangement according to an embodiment of the invention.

Preferred embodiment of the invention

A circuit arrangement 1 shown in the figure comprises an input 2 with a first and a second input terminal 3, 4. At the input 2, a DC supply voltage U _{G can be} provided, namely by means of a power supply from an AC voltage of a supply network. Parallel to the input 2, an intermediate circuit capacitor 5 is connected, to which the DC supply voltage U _G is applied.

Parallel to the input 2 and to the intermediate circuit capacitor 5, an inverter 6 including a first electrical switch 7 and a second electrical switch 8 is connected. The inverter 6 serves to provide an AC supply voltage U _V , which usually has such a frequency, which is significantly greater than the frequency of the mains voltage.

For controlling the inverter 6, a control device 9 is provided, which can set the frequency of the AC supply voltage U _V , namely with appropriate control of the inverter 6. The controller 9 is located at a first reference potential 10, which is also connected to the second input terminal 4 and thus also represents a reference potential of the inverter 6.

The AC supply voltage U _V is provided between a pole 11, which is arranged between the first and the second switch 7, 8, and the first reference potential 10.

The circuit arrangement 10 comprises a resonance circuit 12, which has a resonance choke 13 and a resonance capacitor 14. The resonant choke 13 is connected on the one hand to the pole 11 - ie to the inverter 6 - and on the other hand to a resonant pole 15. The resonant capacitor 14 is coupled between the resonant pole 15 and the first reference potential 10.

The circuit arrangement 1 comprises an output 16, which has a first and a second output connection pair 17, 18. The first output terminal pair 17 comprises a first and a second terminal 17a, 17b, wherein the second output terminal pair 18 also has two terminals 18a, 18b. At the output 16, a low-pressure gas discharge lamp 19 is connected, which is operated with the circuit arrangement 1.

The first terminal 18a of the second output terminal pair 18 is connected on the one hand via a first coupling capacitor 20 to the first reference potential 10, that is, by means of the first coupling capacitor 20 of the first reference potential 10 is electrically decoupled. On the other hand, the first terminal 18a of the second output terminal pair 18 is connected to the first input terminal 3 via a second coupling capacitor 21. The first terminal 18a of the second output terminal pair 18 represents a second reference potential 22 (ie, so-called "low side" of the gas discharge lamp 19). The two coupling capacitors 20, 21 ensure that over the gas discharge lamp 19 no direct currents can flow. Such direct currents could lead to an apparent inhomogeneity of the light emitted by the gas discharge lamp 19 (cataphoresis). In addition, by the symmetrical Arrangement of the coupling capacitors 20, 21 achieves the advantage that the current load of the intermediate circuit capacitor 5 is the lowest.

In order to ensure a gentle ignition of the gas discharge lamp 19, the electrodes of the lamp 19 must first be preheated. For this purpose, the circuit arrangement 1 comprises a transformer 23 having a primary winding 24, a first secondary winding 25 and a second secondary winding 26. The primary winding 24 is connected in series with the resonance capacitor 14 and, on the other hand, directly connected to the first reference potential 10. The first secondary winding 25 is connected on the one hand to the first terminal 17a and on the other hand to the second terminal 17b of the first output terminal pair 17. The second secondary winding 26 is connected on the one hand to the first terminal 18a and on the other hand to the second terminal 18b of the second output terminal pair 18.

Parallel to the first primary winding 24 of the transformer 23, an electrical switch 27 is connected, whose control terminal is coupled to the control device 9. Thus, this switch 27 is switchable by the control device 9 between an electrically conductive switching state, in which the primary winding 24 is bridged, and a blocking switching state. The electrical switch 27 may, for example, be a MOSFET, in particular such a MOSFET, which does not have a parasitic diode and is therefore designed symmetrically.

The control device 9 is arranged with a between the resonance capacitor 14 and the primary winding 24 Pol 28 coupled, namely via a high-impedance resistor 29. The resistance of the ohmic resistance 29 may be, for example, 1 MΩ. Due to the connection to the pole 28, the control device 9 can detect a voltage drop across the primary winding 24. The control device 9 can evaluate this voltage and, by means of this evaluation, refer back to the operating states prevailing at the output 16. If the impedance at the output 19 changes, be it at the first and / or the second output terminal pair 17 or 18, the voltage drop across the primary winding 24 also changes. By evaluating this change, the control device 9 can thus recognize that, for example, a filament of the lamp 19 has burnt out or whether there is a short circuit between the terminals 17a, 17b or 18a, 18b. If the voltage across the primary winding 24 lies in an impermissible value range during a preheating phase of the electrodes of the lamp 19, then the control device 9 can switch off the inverter 6 and thus the supply alternating voltage U _V.

The mode of operation of the circuit arrangement 1 will be explained in more detail below:

First, the DC supply voltage U _{G is} provided, for example by closing a power switch by an operator. If the DC supply voltage U _G at the input 2, so is the control device 9 in operation; it can generate the AC supply voltage U _V for the gas discharge lamp 19 by driving the inverter 6. Before a preheating phase is initiated, the control device 9 controls the inverter 6 in such a way that via the primary winding 24 very small currents flow. This can be achieved in that the control device 9 adjusts such a frequency of the alternating supply voltage U _V , which is significantly higher than a preheating frequency and an ignition frequency. During the control, the control device 9 checks whether the voltage drop across the primary winding 24 is within a predetermined value range or not. If this can be confirmed, it means that the gas discharge lamp 19 is properly connected to the output 16. If the voltage at the primary winding 24 is in an impermissible value range, the control device 9 switches off the inverter 6, and there is no voltage at the output 16.

If a predetermined preheating criterion is met, the control device 9 initiates the preheating phase. In this preheating phase, the electrodes of the gas discharge lamp 19 are heated, namely to a temperature which ensures a gentle start of the gas discharge lamp 19. The preheating criterion includes that, on the one hand, the DC operating voltage U _{G is provided} at the input 2 and, on the other hand, that the voltage across the primary winding 28 - during the control of the inverter 6 (small currents across the primary winding 25) - is within the predetermined value range.

Is the Vorheizkriterium met, 9 by the frequency of the AC supply voltage U _V is set to a preheating directs the control device controls the preheating phase a. During this preheating phase, the alternating supply voltage U _V is thus adjusted so that the gas discharge lamp 29 is not yet ignited. During the preheating phase flow through the output terminal pairs 17, 18 and thus via the electrodes of the gas discharge lamp 19 currents that are generated by the transformer 23. These currents heat the electrodes of the lamp 19.

Even during the preheating phase, the control device 9 checks whether the voltage across the primary winding 25 is within a predetermined value range. After the fulfillment of a predetermined ignition criterion, the control device 9 ends the preheating phase and lowers the frequency of the alternating supply voltage U _V so that the gas discharge lamp 19 ignites. When the lamps 19 are ignited, that is to say when the ignition criterion has been met, the control device 9 closes the electrical switch 27 so that it bridges the primary winding 24.

The ignition criterion includes that the voltage detected at the primary winding 24 during the preheating phase is within the predetermined value range and a predetermined time interval has elapsed after the preheating phase has been initiated, that is, the preheating phase has continued for a predetermined time. In this way it is achieved that the electrodes of the gas discharge lamp 19 are heated to the desired temperature and the lamp 19 can be gently ignited.

Overall, therefore, a circuit arrangement 1 is provided which can be produced more cost-effectively compared to the prior art. Namely, the circuit arrangement 1 does not require costly components, such as without a high-voltage switch, without a diode and without an additional coupling capacitor for the primary winding 24, as described in the subject matter of the publication EP 0 748 146 A1 be used. Namely, the resonance capacitor 14 also performs the function of a coupling capacitor for the primary winding 24.

Furthermore, it can be ascertained via the described manner on the primary side of the preheating transformer whether the electrodes of the discharge lamp are present or the lamp is properly connected. Thus, an additional saving of otherwise used high-voltage resistors and coupling capacitors or diodes to the secondary windings of the preheating transformer is possible.

Claims (7)

Circuit arrangement (1) for operating at least one low-pressure gas discharge lamp (19), with - An input (2) having a first and a second input terminal (3, 4) for applying a DC supply voltage (U _G ), - An output (16) having a first and a second output terminal pair (17, 18) for connecting the at least one low-pressure gas discharge lamp (19), an inverter (6) coupled to the first and second input terminals (3, 4) for providing an alternating supply voltage (U _V ) from the DC supply voltage (U _G ), a control device (9) for controlling the inverter (6) and thereby controlling the frequency of the alternating supply voltage (U _V ), the control device (9) being designed to initiate a preheating phase after fulfillment of a predetermined preheating criterion, in which the inverter ( 6) is operated at a preheating frequency, and after the fulfillment of a predetermined ignition criterion, the frequency of the supply alternating voltage (U _V ) is set to an ignition frequency, a resonant circuit (12) having a resonant choke (13) whose first terminal is coupled to the inverter (6) and whose second terminal is coupled to a resonant pole (15), and a resonant capacitor (14) connected between the resonant pole (13) 15) and the reference potential (10) of the control device (9) is coupled, and - A transformer (23) for preheating electrodes of the low-pressure gas discharge lamp (19), which a primary winding (24) coupled to the first output terminal pair (17) first secondary winding (25) and a second output terminal pair (18) coupled to the second Includes secondary winding (26), characterized in that
the primary winding (24) of the transformer (23) is connected in series with the resonant capacitor (14) and directly connected to the reference potential (10) of the control device (9), and an electrical switch (27) is connected in parallel to the primary winding (24) of the transformer (23) is coupled, which has a control terminal which is coupled to the control device (9), wherein the control device (9) is further adapted to fulfill after fulfillment of the ignition criterion the electrical switch (27) in its electrically conductive switching state. Circuit arrangement (1) according to claim 1, characterized in that the electrical switch (27) is a bidirectionally blocking or conducting semiconductor switch, in particular a bidirectionally blocking or conducting MOSFET. Circuit arrangement (1) according to Claim 1 or 2, characterized in that the control device (9) is coupled to a detection pole (28) arranged between the primary winding (24) and the resonance capacitor (14) and for detecting a drop across the primary winding (24) Voltage is formed. Circuit arrangement (1) according to Claim 3, characterized in that the control device (9) is designed to control the inverter (6) before initiating the preheating phase and to detect the voltage dropping across the primary winding (24) during this activation, wherein the Preheating criterion includes that this voltage is within a predetermined range of values. Circuit arrangement (1) according to Claim 3 or 4, characterized in that the control device (9) is designed to detect the voltage drop across the primary winding (24) during the preheating phase, wherein the ignition criterion includes that voltage in a predetermined value range lies. Circuit arrangement (1) according to one of the preceding claims, characterized in that the ignition criterion includes that after initiation of the preheating a predetermined time interval has expired. Method for operating at least one low-pressure gas discharge lamp (19) on a circuit arrangement (1) having an input (2) with a first and a second input terminal (3, 4) for applying a DC supply voltage (U _G ) to an output (16) with a first and a second output connection pair (17, 18) for connecting the at least one low-pressure gas discharge lamp (19) to an inverter (6) coupled to the first and the second input connection (3, 4) for providing an alternating supply voltage (UV). from the DC supply voltage (U _G ), with a control device (9) which drives the inverter (6) and which, after the fulfillment of a predetermined preheat criterion, initiates a preheat phase in which the inverter (6) is operated at a preheat frequency and, after satisfying a predetermined firing criterion, the frequency of the supply ac voltage (U _V ) to a firing frequency, comprising a resonant circuit (12) having a resonant choke (13) whose first terminal is coupled to the inverter (6) and whose second terminal is coupled to a resonant pole (15) and to a resonant capacitor (14), which is coupled between the resonance pole (15) and the reference potential (10) of the control device (9), and a transformer (23) for preheating electrodes of the low-pressure gas discharge lamp (19), which has a primary winding (24), one with the first output terminal pair (17, 18) coupled first secondary winding (25, 26) and a second output terminal pair (17, 18) coupled to the second Secondary winding (25, 26), characterized by the following steps: during the preheating phase: conducting an electric current which flows through the resonance capacitor (14), also via the primary winding (24) of the transformer (23) coupled in series with the resonance capacitor (14), the primary winding (24) being connected to the reference potential (10) is directly connected to the control device (9), and - After fulfillment of the ignition criterion: transferring an electrical switch (27) in its electrically conductive switching state and thereby bridging the primary winding (24).

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