DE4014355A1 - Electronic operating circuit for discharge lamp - has short-circuit switch for auxiliary sec. winding of heating transformer - Google Patents

Abstract

The operating circuit has a DC operating voltage obtained from the network voltage (Un) via a wave filter (OW) and a rectifier (WR), the latter coupled via a DC/AC converter (WR) to a heating transformer (HTA) for the heating electrodes of the lamp (LL). The heating transformer (HTA) has a number of secondary heating windings HW1, HW2 HWi) and a further secondary winding (W2) which can be short-circuited via a controlled switch (5). The switch control input is coupled to a switching control (SE) allowing the switch(s) to be closed after the lamp ignition and to remain closed during the subsequent operation of the lamp (LL). ADVANTAGE - Ensures min. power loss.

Description

Technical field

The invention relates to an electronic ballast device for at least one equipped with heatable electrodes Fluorescent lamp with an inverter, the input side a DC operating voltage is supplied and the output via a heating transformer for the heated electrodes the at least one fluorescent lamp with a little load circuit containing a fluorescent lamp manure stands.

Underlying state of the art

For fluorescent lamps equipped with heatable electrodes must be used as heating coils when switching on designed electrodes are sufficiently preheated to the Fluorescent lamp with the available ignition voltage to be able to ignite. Once the fluorescent lamp has lit, there is no need to heat the electrodes further, since for this the one now flowing through the fluorescent lamp Current in turn the electrodes for maintaining the Keeps the lamp current sufficiently warm. So one means continuous heating of the electrodes of the fluorescent lamp even during operation energy losses that actually should be avoided.

The reference DE 33 12 572 A1 therefore proposed a heating winding in each circuit To provide switching element with threshold behavior, whose Threshold value is dimensioned so that the voltage threshold of such a switching element from the heating voltage to the Heating coils during the preheating phase of the fluorescent lamp  is exceeded as soon as the fluorescent lamp has ignited. This is possible if the load circuit is a working resonant circuit contains, the capacitor of the fluorescent lamp parallel ge is switched. As long as the lamp has not yet ignited the working oscillating circuit is not very dampened and ensures that high, also via the primary winding of the heating transformer flowing oscillating current for a correspondingly high heating voltage on the heating coils. Once the fluorescent lamp is lit. the working oscillating circuit is strongly damped and thus a corresponding drop in the heating voltage to the heater windings. As soon as the heating voltages on the heating windings Voltage threshold of the arranged in your circuit below the switching element, the electrodes heating switched off and the unwanted Losses during the life of the fluorescent tube under bound.

As practice shows, such threshold behavior is required switching elements have a very careful dimension tion in connection with the dimensioning of the ballast device and the fluorescent lamp types to be operated with it. Extensive independence of the shutdown function from the body and dimensioning of the ballast on the one hand and the fluorescent lamp or fluorescent lamp arrangement used on the other hand, when using such threshold behavior switching elements not possible. Also must be feared be that perfect performance depending on Signs of aging on the one hand of the fluorescent lamps and on the other hand, the switch exhibiting the threshold behavior elements cannot be guaranteed in the long run can.

Disclosure of the invention

The invention is based, for a ballast the task device of the type described in the introduction another solution for the interruption of the electrode heating of the fluorescent lamp in the Connection to their ignition to indicate the unwanted  Heating losses during the operation of the fluorescent lamp also reliably prevented in long-term operation and above also allows a circuit structure that largely regardless of the size and structure of the ballast on the one hand and type of fluorescent lamp used or Fluorescent lamp arrangement on the other hand.

This object is achieved according to the invention by the in patent claim 1 specified features solved.

The invention is based on the knowledge that the with its Primary winding in the connection path between the output of the Inverter and the load circuit arranged heating transformer in an extremely simple way by short-circuiting one additional secondary winding ineffective and thus the heating voltage for the electrodes to be heated of the at least one Fluorescent lamp can be switched off.

The heating transformer losses caused by the short circuit mators can be kept extremely low, provided according to claim 2 is ensured that the Heating transformer for a negligibly small spreader ductility is designed.

Advantageous embodiments of the object according to the Claim 1 are also in the further claims 3 to 6 specified.

Brief description of the drawing

Mean in the drawing

Fig. 1 shows an electronic ballast with a load circuit in the form of a block diagram,

Fig. 2 shows a first preferred embodiment of the load circuit according to Fig. 1,

Fig. 3 shows a second preferred Auführung of a load circuit according to Fig. 1,

Fig. 4 shows a third preferred embodiment of a load circuit according to Fig. 1,

Fig. 5 is a development of the ballast according to FIGS. 1 to 4 using a switchable in its switching frequency inverter.

Best way to perform the invention

The electronic ballast shown in the block diagram advises an inverter WR, the input side of the Mains AC voltage Un through the series connection of a Harmonic filter OW and a rectifier arrangement GL as Operating DC voltage is supplied. The output side is the Inverter WR with a heating transformer arrangement HTA with the load circuit having at least one fluorescent tube LL LK connected.

The inverter WR consists, for example, as indicated in the block diagram according to FIG. 1, of a switch bridge arrangement with the switches S 1 , S 2 , which are controlled on the control input side by a saturation transmitter SÜ alternately in the rhythm of a switching frequency. In self-control, the switching frequency is determined by a working circuit associated with the load circuit LK. Self-excitation of the inverter WR takes place via the positive feedback realized by the saturation transformer SÜ.

The heating transformer arrangement HTA has the heating transformer HT, the primary winding W 1 of which lies in the connection path between the output of the inverter WR and the load circuit LK. For each of the electrodes HE to be sufficiently preheated in the preheating phase of the at least one fluorescent lamp LL, the heating transformer HT has a secondary heating winding HW 1 , HW 2 ,... HWi, which are firmly connected to the electrode HE assigned to them. This is indicated by the fact that each pair of connecting arrows of a heating winding HW 1 , HW 2 ,. . . HWi a pair of connecting arrows is assigned to an electrode HE on the side of the at least one fluorescent lamp LL in the load circuit LK.

As the heating transformer arrangement HTA also shows, the heating transformer HT has a further secondary winding W 2 with a center tap M, which is connected in parallel to the series circuit comprising two diodes D 1 and D 2 with opposite polarity. The controllable switch s, which is connected on the control input side to the control device SE, is arranged between the common connection point P of the two diodes D 1 and D 2 and the center tap M. When the switch s is closed, the further secondary winding W 2 is short-circuited via the diodes D 1 and D 2 and thus the heating voltages on the heating windings HW 1 , HW 2 ,. . . HWi also short-circuited or rendered ineffective.

The control device SE can be a timer in a simple manner be dependent on a control input side a switch-on process supplied via the inverter WR Voltage this voltage as a control signal after a pre time interval at the control input of the switch s passes on. This time interval is chosen so that in meanwhile, the preheatable electrodes HE at least a fluorescent lamp LL have been sufficiently preheated and lit the fluorescent lamp.

A typical embodiment for a load circuit LK with a working resonant circuit is shown in FIG. 2. The working resonant circuit consists of the inductance L and the capacitor C, which in turn is connected to the fluorescent lamp LL in parallel. Furthermore, the load circuit LK designed in this way also has a coupling capacitor CK in series with the parallel connection of the fluorescent lamp LL and the capacitor C.

If the fluorescent lamp LL is a rapid start lamp, then a constant voltage U 2 is applied to the fluorescent lamp LL via the electronic ballast when switched on and at the same time the electrodes HE are preheated via the heating transformer HT. Since the ignition voltage of the fluorescent lamp LL decreases as a function of increasing electrode temperature, the fluorescent lamp ignites automatically as soon as its ignition voltage has reached or falls below the constant voltage U 1 . In the load circuit LK shown in FIG. 3 for two fluorescent lamps LL 1 and LL 2 connected in series, each of which also has a capacitor C 1 or C 2 in parallel, use is made of an input-side stray field transmitter SFÜ to implement the high ignition voltage required here , by which the output voltage of the inverter is transformed up in the desired manner. The relatively large stray field inductance replaces the inductance L according to FIG. 2. The primary winding W 11 is a conventional coupling capacitor CK in series and the secondary winding W 21 is a capacitor C 3 connected in parallel.

Fig. 4 shows a load circuit LK corresponding to Fig. 2, which contains a fluorescent lamp, which is ignited after the sufficient preheating of its electrodes HE by excessive voltage with the aid of an ignition pulse generator ZG. The control device SE can, as is also indicated in Fig. 1 by the broken connection to the load circuit LK, in addition to the control of the switch s for the short circuit of the further secondary winding W 2 of the heating transformer HT of the heating transformer arrangement HTA also for the control of the ignition pulse generator ZG can also be used. For this purpose, the control device SE has a control signal generator TZ for the ignition pulse generator ZG and a control signal generator TA for the switch s. The input of the control device SE is assigned to the control signal generator TZ for the ignition pulse generator ZG, which in turn can be a time switching element already described in this connection. The control signal generator TZ in turn outputs the voltage occurring at its control input with a switch-on process with a sufficient time delay to the ignition generator ZG, which is thereby activated for the emission of the fluorescent lamp LL after sufficient preheating of its electrodes HE igniting ignition pulses of sufficiently high voltage. Then after the resulting ignition of the fluorescent lamp LL, the control signal generator TZ activates the control signal generator TA for the switch s, as a result of which the secondary winding W 2 of the heating transformer HT is short-circuited and thus the heating energy for the electrodes HE of the fluorescent lamp LL is switched off for the duration of the lamp operation becomes.

A variant of the embodiment according to Fig. 4, Fig. 5. When a load circuit LK having a working resonant circuit corresponding to FIGS. 2 to 4 and a self-controlled inverter WR, the fluorescent lamp LL required after sufficient preheating of the electrodes HE Zündspan also voltage superelevation by a frequency switching of the switching frequency of the inverter WR can be brought about. The frequency switching of the inverter WR is brought about by a further secondary winding W 2 of the saturation transformer SÜ, which also expediently has a center tap M for its short circuit and which is connected in series with two oppositely polarized diodes D 3 and D 4 . This further secondary winding W 2 short-circuiting switch in the connection path between the center tap M and the common connection point P of the diodes D 3 and D 4 can be summarized with the switch s of the heating transformer arrangement HTA according to FIG. 1 to a changeover switch U together. In the rest position of the switch contact of the switch U, the further secondary winding W 2 of the säti supply transformer SÜ is short-circuited, so that during the heating phase before the switching frequency above the resonance frequency of the working circuit is also shifted to higher frequencies and thus the voltage applied to the fluorescent lamp is reduced compared to the resonance voltage is. As soon as the electrodes HE of the fluorescent lamp LL are sufficiently preheated, the control device SE activates the changeover switch U, as a result of which the further secondary winding W 2 of the heating transformer HT is short-circuited and at the same time the short circuit of the further secondary winding W 2 of the saturation transmitter SÜ is canceled. This then causes the heating of the electrodes HE of the fluorescent lamp LL to be switched off and the switching frequency of the inverter to shift in the direction of the resonant frequency of the working resonant circuit of the load circuit. The voltage increase on the fluorescent lamp LL which is brought about in this way will then reliably ignite it.

Claims (6)

1. Electronic ballast for at least one fluorescent lamp equipped with heatable electrodes with an inverter to which an operating DC voltage is supplied on the input side and which is connected on the output side via a heating transformer for the heatable electrodes of the at least one fluorescent lamp to a load circuit containing these at least one fluorescent lamp, characterized in that the heating transformer (HT) has, in addition to the secondary heating windings (HW 1 , HW 2 ,... HWi), a further secondary winding (W 2 ) which can be short-circuited via a controllable switch (s), and in that the switch (s) is switched on to a control device (SE) which closes the switch (s) after the ignition time of the at least one fluorescent lamp (LL, LL 1 / LL 2 ) or after its successful ignition and during the operation of the at least one when the switch is turned on Fluorescent tube (LL, LL 1 / LL 2 ) keeps closed. 2. Electronic ballast according to claim 1, characterized, that the heating transformer (HT) for a negligibly small Leakage inductance is designed. 3. Electronic ballast according to claim 1 or 2, characterized, that the heating transformer (HT) is a toroidal core transformer. 4. Electronic ballast, in which the at least one fluorescent lamp (LL, LL 1 / LL 2 ) in the load circuit (LK) a controllable ignition pulse generator (ZG) is switched on, according to one of the preceding claims, characterized in that the control device (SE) Control signal transmitter (TZ) for the ignition pulse generator (ZG) and a control signal transmitter (TA) for the switch (s), and that the control signal transmitter (TZ) for the ignition pulse generator (ZG) in dependence on a switch-on process taking into account a sufficient electrode preheating time of the at least one fluorescent lamp (LL, LL 1 / LL 2 ) the ignition pulse generator (ZG) and then the control signal generator (TA) for the switch (s) activated. 5. Electronic ballast, in which the load circuit has a resonant circuit consisting of the series connection of an inductor and a capacitor, the capacitor of which is connected to the fluorescent lamp in parallel and in which the inverter has a self-controlled switch bridge arrangement with a feedback of the output circuit to the control inputs of the switches Realizing saturation transformer is, according to one of the preceding claims, characterized in that the saturation transformer (SÜ) to increase the switching frequency of the inverter (WR) in the preheating phase of the least one fluorescent lamp (LL, LL 1 / LL 2 ) also one over controllable switch during this preheating phase short-circuited secondary winding (W 2 ) and that the switch in the circuit of the short-circuitable secondary winding (W 2 ) of the saturation transformer (SÜ) and the switch (s) in the circuit of the short-circuitable secondary wic cooling (W 2 ) of the heating transformer (HT) are combined to form a switch (U) controlled by the control device (SE). 6. Electronic ballast according to one of the preceding claims, characterized in that the short-circuitable secondary winding (W 2 ) of the Heiztransforma gate (HT) or the saturation transformer (SÜ) of the series connection of two oppositely polarized diodes (D 1 / D 2 , D 3 / D 4 ) is connected in parallel, has a center tap (M) and that the switch (s) or the associated switch contact of the switch (U) in the connection path between the center tap (M) and the common connection point (P) of the two diodes (D 1 / D 2 , D 3 / D 4 ) is arranged.