DE3432266A1 - Electronic ballast for fluorescent lamps, and a method for its operation - Google Patents

Abstract

By means of signals from a monitoring device, which has a starting monitoring circuit (9) and an operation monitoring circuit (10) for the fluorescent lamps, as well as a temperature monitoring circuit (11) for the invertor, the control device (12, 13) which controls the invertor in terms of frequency can be brought to an initial position. The initial position is assumed when the monitoring device reports that no lamp can be operated, for example because there are no lamps or the temperature of the invertor is too high. The starting process for the lamps is initiated from the initial position in the event of second status reports from the monitoring device, which indicate that lamps have been replaced. If, in addition, only one of a plurality of lamps starts, the operation is started at the burning frequency. In consequence, the apparatus is always in a defined operating state, regular starting attempts for deactivated lamps are avoided and, when lamps are replaced, they start without further measures, for example replacement of a fuse or switching off the mains voltage. <IMAGE>

Description

Electronic ballast for fluorescent lamps and processes for its operation The invention relates to an electronic ballast with a controlled Inverter, for the operation of one or more fluorescent lamps as well as a Procedure for its operation.

Such ballasts are known e.g. from the German Offenlegungsschrift DE 31 12281 A1 and from European patent applications EP 0 059 064 A1 and 0 075 176 A2.

Electronic ballasts for discharge lamps operate in this Use of fluorescent lamps with frequencies preferably above 10 kHz. So that will around.

A 10% higher light output compared to 50 Hz operation. Furthermore, flicker-free start and operation are guaranteed. For economic For reasons, electronic ballasts are often used for simultaneous operation of designed two or more fluorescent lamps. The ignition voltage of the fluorescent lamps is mostly significantly above the burning voltage of the gas discharge. This excessive tension is generated with a series resonance circuit, operated near or at the resonance frequency. The resonance circuit current also flows through the cathodes of the fluorescent lamps, causes them to be heated and thus improves the ignitability of the lamp. The inductive Part of this circuit is used in the alternating current operation following the ignition as a current limit.

Is a fluorescent lamp no longer operational because of emission material has been removed from the cathodes or the fluorescent lamp is no longer gas-tight is, the cathode current inevitably rises to a significantly higher value, since the relevant series resonance circuit is undamped. This increase in current leads to without special measures after a short time to overload or destruction of the inverter.

Solutions known today are with fuses or thermal Overload protection or electronic peak current limitation with "fall back" properties equipped. This switches an electronic ballast, which at the same time switches several Fluorescent lamps inevitably also dump intact lamps. When changing the lamp it is no longer immediately apparent which fluorescent lamp is defective and which is de-energized. Furthermore, the devices do not start even after all lamps have been replaced more before the fuse replaces the thermal safety manually or reset after cooling down or the "fall back" electronics due to power failure e.g. reset on the light switch with reset information.

Delayed, automatically dropping overcurrent fuses cause periodically new start attempts; the fluorescent lamps thus work in the undesirable Flashing mode. This flashing mode, which is unpleasant for the eye, as well as the uncontrolled one onset of ignition of the fluorescent lamp when operating near or at the series resonance frequency cause early degradation of the cathode material and thus reduced lamp life.

The present invention is based on the object of a ballast to create, which the disadvantages mentioned not or only to a lesser extent having. This is achieved by a monitoring device, configured at least for detecting the lamp status and a control device for frequency control of the inverter, the control device by a first status message can be brought from the monitoring device into a starting position, if none Lamp can be operated and by a second status message to the control the lamp ignition process can be started.

Furthermore, a method for operating the ballast is shown, which is characterized by that when switching on the mains voltage the inverter through the control device from the start position with in the direction on the resonance frequency of the Lampserieresonanzkreis changing frequency and operated after ignition at least one lamp with its focal frequency is, with a first status message, which indicates that no lamp is operating the starting position can be assumed and with a second state Report again the operation with the intended ignition sequence we picked up the present Ballast avoids the disadvantages mentioned above by which leads to a status message, automatically without additional information and Handles can switch back to operation, i.e. after replacing a defective lamp it burns again without further ado, i.e. without switching the mains on / off.

In a preferred embodiment, at least one inverter parameter is also used supervised. With this, e.g. the temperature of the power transistors of the inverter monitored, with the power level being exceeded directly the inverter can be locked. In a preferred embodiment is the focal frequency below the resonance frequency of the series resonance circuit. In order to a particularly energy-saving operation is possible, as it does not convert the light into light Power loss in the cathodes is minimized.

In the following, exemplary embodiments are described with reference to the figures. Show it: Fio. 1 shows a block circuit diagram of a ballast according to the invention for two lamps; 2 shows a current / frequency diagram; 3 shows a state diagram the control device.

In Figure 1 is the block diagram of a ballast with the both lamps 1 and 2 shown. The AC mains voltage is supplied by the rectifier 17 rectified and throughkden basically in a known manner built up Inverter converted into an alternating voltage with controllable frequency. The filter 16 reduces the feedback of high-frequency interference into the network. As a switch In the version shown, MosFet transistors are used for the inverter 20 used, which via a driver transformer 19 from a controlled oscillator 13 can be controlled. Between the driver transformer and the respective gates of the transistors 20 are elements 18 connected, which the switching times of the transistors with regard to slow switch-on edges and fast switch-off edges. This makes it possible to operate the inverter in multi-frequency operation with inductive and capacitive load and with the inverter frequency over the series resonance range the limiter choke 5 and the capacitor 4 to drive without the switching transistors to be damaged. In the example shown, there are two fluorescent lamps on the inverter 1 and 2 connected. The electrodes of the lamps are in series with the corresponding one Series resonance circuit consisting of limiting throttle 5 or 6 and capacitor 3 or 4 connected. To monitor the lamp operation, each limiting choke 5, 6 has a measuring winding 7.8 on. This allows the lamp status to be recorded, e.g. whether there is a lamp at all has been used, ignited or changed. To do this, the signals are off these measuring windings 7, 8 to two monitoring circuits shown as blocks 9 or 10 created. The first monitoring circuit 9 forms together with the sequence control 12 an ignition monitor for the lamps; the second monitoring circuit 10 can can be referred to as handling monitoring, as it determines whether a lamp has to be changed has taken place. The ignition monitor uses the signal from the measuring winding 7 or 8 determines whether the L / C series resonance circuit from the throttle at the ignition frequency fz Z 5 or 6 and the capacitor 3 or 4 without noticeable attenuation by the fluorescent lamp vibrates, which one does not lit lamp is the case or whether due to the resistance parallel to the capacitor 3 or 4, the ignited i.e. when the lamp is on there is attenuation. The corresponding message is sent by the sequence control is queried by the ignition monitoring 9 at the ignition frequency f.

The sequence control 12 determines the frequency of the oscillator 13 and thus the frequency of the inverter. This can after detection of the ignition the lamp burning frequency fig B to the desired value by the sequence control being controlled.

The second monitoring circuit 10 acts as a current threshold switch determines whether a certain minimum lamp current is flowing and can thus recognize whether a lamp is inserted, i.e. whether a lamp has been changed or not. Even this monitoring circuit is connected to the sequence control 12 in terms of signals. This monitoring circuit can also be used to detect the failure of a fluorescent lamp be designed at the operating frequency, since there is only a small current flows.

A temperature monitor is used as a further monitoring circuit 11 provided for the switching transistors of the inverter as well as voltage monitoring 15, which detects overvoltages and undervoltage in the AC mains voltage.

The sequence control is designed as a synchronous digital circuit and is clocked by the clock generator 14.

In this exemplary embodiment, it has four inputs for the status messages of said monitoring circuits and an output for controlling the oscillator 13th

The operation and other features of the device can be seen from FIG FIGS. 2 and 3 will be described.

When applying the mains voltage and if its value is determined by the voltage monitoring 15 is recognized as permissible, the sequence controller 12 controls the inverter into the start position, i.e. with the start frequency f5, which is around 75 kHz. As can be seen from Fig. 2, the start frequency as so far selected that lies above the resonance frequency of the L / C series resonance circuit the current through the lamp electrodes and the lamp voltage are low. One Ignition of the lamp at the start frequency is therefore not possible. After a short Time span, which is selected here as about 10 ms, the frequency value is set to the Heating frequency fH lowered, which is about 43 kHz. Thereby finds a lamp-friendly Preheating of the electrodes takes place. This preheating should turn on before the ignition Electrode temperature value can be achieved, through which a maximum service life of the Lamp is guaranteed, i.e. that only so much of the electrode material evaporates should be considered absolutely necessary. As a rule, the electrodes should be done before ignition be hotter than 5000C. The heating frequency is maintained for about 0.4 s and then there is a further lowering of the frequency in the direction of the resonance frequency the value of the ignition frequency, at around 38 kHz. At the ignition frequency are current and Voltage in the series resonance circuit increased so that ignitable lamps start immediately. can. The duration of operation at the ignition frequency is also limited in time and amounts to about 1 s, with which it is selected in such a way that increased at the now start Heating current a still weak active lamp within a certain safety time can start.

Have ignited both lamps within this time, something from the monitoring circuit 9 and the sequence control 12 has been recognized, the inverter is from the sequence control is controlled to the focal frequency fig B of about 25 kHz. These is thus below the resonance frequency of the L / C series resonance circuit in the example described. The inverter frequency sweeps over the resonance after the lamps have been ignited frequency fR and goes in the direction of capacitive operation at fB. During lamp operation at f is that caused by the capacitor 3 resp.

B 4 flowing current is low, which means that the sat Power loss in the electrodes is minimized.

If only one of the lamps has ignited, the inverter is switched off the sequence control is also controlled to the burning frequency fB. Still the other one If the lamp is deactivated or has an open circuit, the other one will burn Lamp with nominal current, since the operating frequency is so far from the resonance frequency fR is away that in circles with deactivated lamps no impermissibly high Currents flow. At the same time, the operating voltage drops in deactivated lamps a value that complies with the safety regulations.

If the deactivated lamp is now replaced by another lamp, this corresponds to a lamp manipulation which is carried out by the handling monitoring circuit 10 is recognized. A status message of the circuit 10 is received from the sequence control recognized and causes it to go to the start position. The one described so far The sequence begins again with the starting frequency fs and leads to the ignition of the newly used Lamp, provided it is functional. The lamp that has been burning up to now will also be at the Replacing the deactivated lamp restarted.

If no lamp has ignited, which was recognized by ignition monitoring 9, the sequence control 9 goes to the start position. This is also done by means of a status message for excess temperature of the transistors. In the starting position, the Monitoring circuits and the sequence control of the lamp status at the start frequency f 5 queried. A second status message then shows that a lamp has been changed there is a new process for igniting the lamps, starting with the start frequency f 5 The power level is used to reduce the power loss in the start position of the inverter passively most of the time. Is the network switched on and none Lamp inserted or both lamps deactivated, which results in the start position, so tests the sequence control only cyclically about every 0.6 s the monitored circuits by the Inverter operated for about 10 ms with the start frequency f will. If a change in the lamp status is detected, this status message is triggered the sequence control starts the lamp at the start position, i.e. at the start frequency f to begin.

5 Figure 3 shows a state diagram for the sequence control. 0 means "Mains off", 1 means "Start" f5, 2 means "Heating" H '3 "Igniting" fZ, 4 "Burning" fB and 5 "standby" fS pulsed. It can be seen that the ballast is off every operating position 1-4 moves to start position 5, provided no lamp is operated can be, whereby a clearly defined and lamp-saving query mode is ensured in the event of a malfunction. If a change in status causes a second status message, the device starts again at startup, resulting in an automatic start of operation after remedying a fault, e.g.

replacing a defective lamp. It's just a lamp, too if several are functional, this is operated normally by the device and it takes place no unnecessary attempts to start the inoperative lamps. In Fig. 2 shows curve 1 shows the undamped resonance current.

On this curve the operating point moves from f to to f During ignition, the operating point jumps to curve 2, which shows the current when the lamp is lit and is shifted towards fig B. If there is no ignition, is driven back from fz Z to fs until a second one arrives Status message (lamp change) driven again on curve 1 to the ignition frequency will.

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Claims (13)

Claims Electronic ballast with controlled inverter, for the operation of one or more fluorescent lamps, characterized by a Monitoring device designed at least to detect the lamp status and a control device for frequency control of the inverter, wherein the Control device by a first status message from the monitoring device can be brought into a start position if no lamp can be operated and can be started by a second status message for controlling the lamp ignition process. 2. Electronic ballast according to claim 1, characterized in that that the monitoring device for detecting the lamp status and at least of an inverter operating parameter is configured, wherein when exceeded a first status message is issued for this parameter. 3. 'electronic ballast according to one of claims 1 or 2, characterized in that the monitoring device for detecting impermissible Mains voltage values is designed. 4. Electronic ballast according to one of the preceding claims, characterized in that the monitoring device is an ignition monitoring circuit (9), for issuing a first status message. 5. Electronic ballast according to one of the preceding claims, characterized in that the monitoring device is a handling monitoring circuit (10) for issuing a second status message. 6. Electronic ballast according to one of the preceding claims, characterized in that the control device is a sequence control circuit (12) and an oscillator (13) controllable by this. 7. Electronic ballast according to one of the preceding claims, characterized in that the power switch (20) of the inverter through the control circuit can be controlled with switching edges that are finitely steeply defined. 8. Procedure for operating the electronic ballast according to Claim 1, characterized in that when the mains voltage is switched on, the inverter by the control device from the start position towards the resonance frequency of the lamp series resonance circuit changing frequency and after ignition at least one lamp is operated with its focal frequency, with a first Status message, which indicates that no lamp can be operated, the start position is taken and with a second state medication the operation again intended ignition sequence is recorded. 9. The method of operation according to claim 8, characterized in that that the inverter by the control device from the start position with a Start frequency (f), which is above the resonance frequency (f) of the lamp resonance circuit and the lamp cannot be ignited after a first preselected one Time span (Ts) at a lower heating frequency (H which heats the lamp cathodes and lamp ignition not yet enabled, and after a preselected second period of time (TH) at a lower ignition frequency (fz), during a third Period of time (TZ) is operated, which enables the ignition of functional fluorescent lamps, whereby it is determined by the monitoring device whether at least one lamp has ignited, whereupon the control device denotes when at least one lamp is ignited Inverter with the burning frequency (fB) and no lamp in start position when ignited operates. 10. The method of operation according to any one of claims 8 or 9, characterized characterized in that the focal frequency is below the resonance frequency (fR)) of the Lampserieresonanzkreises, whereby the cathode power loss is minimized will. 11. Method of operation according to one of the preceding claims, characterized by the fact that the frequency range is passed through continuously, whereby when passing over the resonance range of the lamp series resonance circuit from the power switching elements of the inverter are inductive to capacitive operation can be controlled with current-limiting, finitely steep switching edges. 12. Method of operation according to one of the preceding claims, characterized in that the inverter is deactivated in the standby position and is only operated periodically at the start frequency to detect changes in state by the monitoring device. 13. Method of operation according to one of the preceding claims, characterized in that the focal frequency (fB) so far from the resonance frequency (kr) is removed that in circles with deactivated lamps no impermissibly high Currents flow and thus no excessively high power losses occur, which means the remaining functional lamps burn with nominal current. Electronic Ballast for fluorescent lamps and procedures for their operation