The invention relates to an arrangement in connection with a coupling device of a fluorescent lamp. Particularly, the arrangement of the invention enables the implementation of the condition monitoring of a fluorescent lamp and a lamp circuit in connection with electronic coupling devices.
Fluorescent lamps are generally used to achieve the good luminous efficiency produced thereby. In addition, the long operating life of fluorescent lamps and the various colour tones enable the use of the lamps in a plurality of different applications.
Burning fluorescent lamps requires a supply coupling to supply the required ignition voltage to the lamp circuit and the supply voltage required during use. If the supply coupling is formed without active monitoring of the lamp circuit, the problem that arises is that when the fluorescent lamp or the supply circuit gets damaged, it is impossible to automatically switch off the supply transformer, but it continues to supply the lamp circuit with power until manually switched off. When a broken lamp circuit is fixed, i.e. typically replaced with an undamaged fluorescent lamp, the supply transformer has to be switched on again manually.
Finnish publication 107580B discloses a supply coupling of a lamp circuit, wherein the above problem is rectified by adding a separate direct-current supply to the supply coupling, the direct-supply supplying direct current through the cathodes of the fluorescent lamp and the secondary of the supply transformer to a separate indicator circuit, which is arranged to indicate the direct current generated by the direct-current supply and thus the working condition of the fluorescent lamp. The purpose of the indicator circuit is to transfer information about the working condition of the fluorescent lamp to electronics controlling the supply of the fluorescent lamp and to stop the supply of voltage should the lamp or the lamp circuit be damaged.
However, the problem with the solution of the publication is that direct current causes a small direct-current component in the alternating current passing through the fluorescent tube. This direct-current component subjects the electrodes of the fluorescent tube to polarization, i.e. one electrode transforms into a cathode and the other into an anode. This tends to cause uneven wear of the electrodes, whereby active substance is oxidized on the anode and reduced on the cathode. Consequently, the operating life of the electrode acting as the anode shortens.
Furthermore, the prior art separate indicator circuit is located at the potential of the secondary of the supply transformer, whereby the voltage or current message produced by the indicator circuit has to be transferred to the potential of the electronics controlling the coupling device, i.e. the primary of the supply transformer.
The object of the present invention is to provide an arrangement in connection with a coupling device of a fluorescent lamp, avoiding the above drawbacks, and enable the generation of a signal indicative of the working condition of a fluorescent lamp without the electrodes polarizing direct to the potential of the electronics controlling the coupling device, which shortens the operating life of the fluorescent tube.
The invention is based on the idea of supplying alternating current through the cathodes of the fluorescent lamp and the secondary of the supply transformer, the alternating current being generated by using a signal transformer to whose primary an alternating voltage is supplied and whose secondary constitutes part of the current part wherein the cathodes of the fluorescent lamp and the secondary of the supply transformer are located. The arrangement of the invention provides a simple and inexpensive solution for transferring information about the working condition of a fluorescent lamp reliably directly to the electronics controlling the coupling device without separate galvanic separations and changes in potential levels. On the basis of this information, the coupling device is able to automatically switch the control of the fluorescent lamp off in connection with malfunction and on when the fluorescent lamp is again in working condition.
In the following, the invention will be described in more detail in connection with a preferred embodiment with reference to the accompanying drawings, in which
The figures show the arrangement according to the invention in connection with a coupling device of a fluorescent lamp. The coupling device comprises a supply transformer T1 whose secondary N12 is coupled in parallel with a fluorescent lamp L. Furthermore, in parallel with the fluorescent lamp L is coupled a capacitor C1, which serves to act as part of the resonance circuit together with the leakage inductance of the supply transformer during the ignition of the fluorescent lamp. Consequently, the supply transformer T1 and the capacitor C1 constitute part of a normal coupling device for operating a fluorescent lamp.
In the arrangement according to a preferred embodiment of the invention shown in
As mentioned above, the signal transformer T2 comprises a second primary coil T21b, which is arranged to generate a voltage proportional to the current of the secondary and thus act as an indicator circuit. By means of a transformer effect, the passage of current through the secondary coil N22 of the signal transformer, the cathodes F1, F2 of the fluorescent lamp and the secondary N12 of the supply transformer achieve a voltage in the second primary coil T21b, wherein this voltage is simply detectable.
When said current path is shut off through the cathodes of the fluorescent lamp, the current generated by the signal transformer is unable to run. Since no current runs in the secondary, the voltage of the second primary coil is low. Accordingly, this low voltage or its transforming to low enables reliable detection of the shut-off of the current path, and the supply of voltage to the lamp circuit can be stopped. Thus, the task of the second primary coil is not exact measurement of the current of the secondary coil, but more like the generation of ‘low’ or ‘high’ information, allowing the conclusion of the condition of the current path.
The figure further shows protective resistors R2 and R3, and a protective capacitor C2 coupled to the current path. The task of these components is to serve as low-pass filters for the high-frequency voltage generated by the supply transformer for the fluorescent lamp. As the figure shows, the first poles of the protective resistors R2, R3 are coupled directly to the cathodes F1, F2 of the fluorescent lamp, the protective capacitor C2 being coupled between the second poles of the protective resistors R2, R3. Accordingly, these protective components serve to protect the transfer of a high-frequency voltage from the fluorescent lamp towards the signal transformer.
The frequency of the voltage supplied to the signal transformer may be in the order of 10 to 30 kHz and can have almost any waveform, as long as the pulse ratio of the waveform is sufficiently even. Accordingly, voltage information about whether the current path through the secondary N12 of the supply transformer T1 and the cathodes of the fluorescent lamp is obtained from the second primary N21b of the signal transformer. The voltage information is obtained as a voltage level, i.e. the voltage of the second primary is high when the current path is shut off and low when the current path is intact. This ‘low’ and ‘high’ information can be transferred directly to the base of a semiconductor switch of the control electronics, for example, since the primary coils of the signal transformer may be located directly at the potential of the control electronics. In the solution according to the embodiment of the invention shown in
The arrangement of the invention can be used to produce reliable information about the condition of a lamp circuit directly to the potential of the electronics controlling the lamp circuit, allowing the control of the lamp circuit to be stopped in connection with malfunction. For example, when a damaged fluorescent tube is replaced, alternating current starts again to run on the current path, allowing the control electronics controlling the lamp to be automatically switched on.
It is obvious to a person skilled in the art that the basic idea of the invention can be implemented in a variety of ways. Consequently, the invention and its embodiments are not restricted to the above examples, but can vary within the scope of the claims.
Number | Date | Country | Kind |
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20031870 | Dec 2003 | FI | national |
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Number | Date | Country | |
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20050140301 A1 | Jun 2005 | US |