DE102006024700A1 - Electronic lamp ballast with heating circuit - Google Patents

Abstract

The circuit has a filament transformer (HzTr) with the secondary winding (L s1,L s2) connected to a coil electrode (W 1,W 2). The circuit also has a primary winding (L p1,L p2) provided with voltage and magnetically coupled with the secondary winding. The multiple magnetically coupled coils are provided at the primary winding, which are alternative or combined activated, in order to provide different heating output (P h1,P h2). INDEENDENT CLAIMS are also included for the following: (1) an operating device for fluorescent lamps (2) a method for heating coil electrodes of fluorescent lamps (3) an electronic control unit.

Description

The The present invention relates to an electronic ballast (EVG) for the operation of one or more fluorescent lamps via a integrated heating circuit for heating coil electrodes at least a fluorescent lamp connected to the ECG.

An electronic lamp ballast for fluorescent lamps with heatable filament electrodes is, for example, in EP 1 176 851 A1 described. To supply the filament electrodes with heating energy is a heating transformer with core, which emits energy on the secondary side of the filament electrodes and the primary side draws its energy from the AC voltage provided by an inverter half-bridge circuit.

In DE 295 14 817 U1 discloses an electronic lamp ballast, which is suitable for operating at least one low-pressure discharge lamp. The electronic ballast described herein has a heating transformer which is supplied with alternating voltage on the primary side via an inverter half-bridge circuit and is connected on the secondary side to the filament electrodes of a low-pressure discharge lamp connected to the electronic ballast. The duty cycle of the rectangular current flowing through the primary winding of the heating transformer and provided by the inverter half-bridge circuit is modulated by a power transistor connected in series with the primary winding via a pulse width modulator, the frequency of the control signal provided for this purpose by the pulse width modulator being substantially less as the frequency of the AC voltage at the output of the inverter.

EP 0 748 146 A1 refers to a circuit arrangement comprising an electronic lamp ballast for preheating the filament electrodes of at least one AC-driven fluorescent lamp connected to the ECG. At the output of serving to power the lamp inverter half-bridge while a primary winding of a heating transformer and connected to the primary winding in series controllable semiconductor power switch comprehensive heating circuit is connected, which required for preheating the filaments heating energy through two separate secondary windings of the heating transformer in two transmits independent load circuits in which the respective helical electrodes are located.

Another electronic lamp ballast with an integrated heating circuit for preheating the filament electrodes of at least one AC - powered fluorescent lamp connected to the ECG is disclosed in US Pat EP 0 707 438 A2 disclosed. The heating circuit comprises a primary side connected to the output of an inverter half-bridge circuit heating transformer with two separate secondary windings, which is used to transfer a required for preheating the coil electrodes, provided by the inverter half-bridge heating energy in two independent load circuits in which the individual coil electrodes are located ,

DE 10 2004 009 995 A1 describes an electronic lamp ballast for AC operation of a fluorescent lamp comprising an input side connected to a DC voltage source inverter half-bridge, a connected to the inverter half-bridge load circuit in which the lamp filaments are located, as well as serving for heating the lamp filaments heating transformer consisting of a primary winding and two with the Primary winding inductively coupled secondary windings, which are each connected in series with the two lamp filaments. The supplied via the inverter with AC primary winding of the heating transformer is arranged in an intermediate circuit having an adjustable impedance. In dimming operation, the heating power transferred to the lamp filaments is adjusted by changing the impedance of this intermediate circuit.

Another electronic lamp ballast and an associated method for preheating and igniting a fluorescent lamp are in GB 2 337 644 disclosed. The circuit arrangement described herein comprises a heating circuit comprising a heating transformer with two separate secondary windings, by means of which the two filament electrodes of the lamp are supplied with heating energy independently of each other, and a first semiconductor power switch controlled by a timing element and connected in series with the primary winding of the heating transformer. can be switched with the between two tapping points serving to provide the heating secondary winding of a primary side to the output of a self-excited push-pull sine converter inductively coupled power transformer.

OBJECT OF THE PRESENT INVENTION

outgoing from the aforementioned prior art, is the present Invention of the task dedicated to provide a passable heating circuit.

This object is achieved by the features of the independent claims. Embodiments that of the invention Understand basic ideas in an advantageous manner, are defined in the dependent claims.

SUMMARY PRESENTATION THE INVENTION

The Task is, for example, by a for heating coil electrodes provided by fluorescent lamps circuit according to claim 1, which a heating transformer whose secondary side has at least one Wendelelektrode is connected and the one with this secondary side magnetic coupled, supplied with voltage primary side has. It is the primary side to provide different, transmitted through the heating transformer Heating capacities designed.

By Measures from the primary side can Thus, the heating circuit in operation to different conditions with regard to the operating state, the dimming state, applied input voltages and / or different lamp types are adapted.

there can on the primary side several according to the invention magnetically coupled coils may be provided, which alternatively or combined are activatable. Also an embodiment in shape an autotransformer is possible.

alternative The present invention relates to a method for heating Helical electrodes of fluorescent lamps provided circuit, the one Has heating transformer whose secondary side with at least one Wendelelektrode is connected and the one with this secondary side magnetic coupled, supplied with voltage primary side has. There are on the primary side provided a plurality of magnetically coupled coils, the alternative or combined are activated to different heat outputs provide.

The primary of the heating transformer is in this case about the midpoint of an inverter half-bridge circuit with an AC voltage for operating a connected to the circuit Lamp supplied.

The The present invention further relates to a control device for fluorescent lamps, which is a circuit according to a having the two alternatives described above. The operating device can do this a control circuit which transmits the to the helical electrodes Heating power dependent from the operating and / or dimming state of a connected lamp. About that In addition, the operating device Also have a control circuit, the heating power depending on the type a connected lamp and / or dependent on the detection of a parameter adjusts the operating temperature the helical electrodes reproduces.

there can the operating device also for dimming one or more to an output terminal of the operating device be designed connected fluorescent lamps.

In addition, refers the invention relates to a method for heating helical electrodes of fluorescent lamps by means of a heating transformer whose secondary side is connected to at least one helical electrode and the one magnetically with this secondary side coupled, supplied with voltage primary side has. The method points doing the step of setting one of several heating power levels by selective activation of the primary side of the heating transformer on.

alternative the present invention is a method for heating helical electrodes of Dedicated to fluorescent lamps by means of a heating transformer whose secondary side is connected to at least one coil electrode and the one magnetic with this secondary side coupled, supplied with voltage primary side has. The procedure indicates the step of setting one of several heating power levels by selectively activating one or more magnetically coupled, the primary side of the heating transformer forming coils.

there can be provided that after setting the lowest heating power level a parameter is detected that reflects the spiral temperature. If the spiral temperature is still insufficient, a higher heat output level is inventively selected. The current heating power level can also depend on the Operating state and / or the dimming state to the aforementioned Circuit connected lamp can be selected or dependent on Type of connected lamp.

Further The present invention also relates to an electronic Control unit in support one of the methods described above is designed.

BRIEF DESCRIPTION OF THE DRAWINGS

Further Properties, advantages and expediencies of the present The invention will now be described with reference to the accompanying drawings. with reference to a detailed description of the embodiments present Invention explained. It shows

1 a schematic diagram of an electronic lamp ballast for operating a fluorescent lamp with a Heizstromregelkreis for controlling the heat required for preheating at least one of the two lamp filaments,

2 an electronic lamp ballast for AC operation of a fluorescent lamp according to a first embodiment of the present invention having a heating transformer for supplying heating energy to the filament electrodes of the lamp,

3 a current-time diagram showing the time course of the current flowing through one of the helical electrodes Vorheizstroms in the forward mode or in the blocking mode of the used for switching one of the two primary-side windings of the heating transformer controllable semiconductor power switch, and

4 shows a further embodiment of the invention.

DETAILED DESCRIPTION THE INVENTION

Hereinafter, the embodiments of the present invention will be described with reference to FIG 1 to 3 described in detail.

In 1 is a schematic diagram of an electronic lamp ballast for operating a fluorescent lamp LA shown, which has a heating circuit for at least one of the two lamp filaments W ₁ and W ₂ .

The heating circuit in this case has a heating transformer HzTr 'whose secondary side L _s1 ', L _s2 ', with at least one helical electrode W ₁ , W _{2 is} connected. The heating transformer also has a primary side magnetically coupled to this secondary side L _s1 ', L _s2 ' (L _p1 ', L _p2 ').

The Heating circuit can finally also a Heizstromregelkreises HRK have.

in the forward path this Heizstromregelkreises HRK is at least one power actuator, which for adjusting the transmitted heat output by accessing the primary page the heating transformer is used.

The setting of the heating power transmitted by the heating transformer may, for example, in dependence on a manipulated variable StG, which is supplied by a data output Data OUT a digital control and regulating device (R & S module). In this case, the control and regulating device is supplied via a data input Data IN _{1 with} a measured value of a control variable RG (actual value) tapped via a load circuit of the electronic ballast, in which one of the two lamp filaments W ₁ or W ₂ is located. The measured value indirectly or directly reflects the spiral temperature.

This measured value can be, for example, a voltage U _M which is proportional to the filament current I _W2 flowing through one of the two lamp filaments (W ₂ ) and thus a statement about the temperature-dependent effective resistance R _W2 (θ) of the relevant lamp filament W. ₂ and their operating temperature θ _W2 supplies.

The control and regulating device controls the manipulated variable StG in this case as a function of the measured value of the controlled variable RG present at the data input Data IN ₁ and a command variable FG (setpoint value) for the heating power to be transmitted in heating operation to at least one of the two lamp filaments W ₁ and W ₂ P _H1 or P _H2 .

• – Betriebszustand der Lampe (bspw. Vorheizen oder Zuheizen während des Brennbetriebs),
• – Dimmzustand der Lampe (stärkeres Heizen bei Betrieb bei niedrigen Dimmwerten),
• – Höhe der anliegenden Eingangsspannung, und/oder
• – Lampentyp (ggf. automatische Lampentyperkennung bspw. Über den Wendelwiederstand oder andere elektr. Eigenschaften der Lampe).

The setpoint value may depend, for example, on the following parameters (non-exhaustive enumeration), which can each be detected directly or indirectly and fed to the control and regulation device:

• Operating state of the lamp (eg preheating or heating during the burning operation),
• - Dimming status of the lamp (higher heating when operating at low dimming values),
• - amount of applied input voltage, and / or
• - Lamp type (possibly automatic lamp type detection, for example, about the coil resistance or other electrical properties of the lamp).

In 2a a circuit implementation of an electronic lamp ballast for AC operation of a fluorescent lamp LA according to a first embodiment of the present invention is shown, which comprises a heating circuit with a Heizstromregelkreis HRK as described above with reference to 1 contains described.

This in 2 sketched electronic lamp ballast thereby has an inverter half-bridge circuit DC / AC, consisting of two mutually connected in series, driven alternately with a fixed or adjustable frequency semiconductor power switches T ₁ and T ₂ , which serves for supplying voltage to the lamp LA AC voltage U _WR provides. The frequency of this AC voltage can be controlled to adjust the lamp power.

The inverter half-bridge DC / AC becomes In this case, via a storage capacitor C _1, one of a radio interference filter TPF and power rectifier AC / DC smoothed and rectified mains AC voltage U _e1 supplied as an intermediate circuit voltage U _C1 . The output port of the inverter half-bridge DC / AC formed from the connection node between the two controllable semiconductor power switches T ₁ and T ₂ and the ground node of the electronic ballast is connected via a series resonant circuit consisting of a resonance inductor L and a resonance capacitor C ₂ and via an (optional) coupling capacitor C ₃ for decoupling the DC voltage component of the lamp LA supplied supply voltage U _WR connected, via which the individual coils W ₁ and W _{2 of} the gas discharge charge lamp LA are supplied with heating energy.

The intermediate circuit voltage U _C1 is thereby converted by an alternately performed switching on and off of the two semicon ter-circuit breaker T ₁ and T _{2 of} the inverter half-bridge DC / AC in a high-frequency AC voltage, which is delivered from the inverter to the series resonant circuit.

It is provided that at least one of the two lamp filaments W ₁ and W ₂ is preheated or additionally heated before and / or after the ignition of the lamp to a specific predeterminable operating temperature. For this purpose, the in 2a illustrated electronic lamp ballast via one or as shown two separate heating circuits HzK ₁ and HzK ₂ , via which the two helical electrodes W ₁ and W ₂ are heated to a desired operating temperature θ _W.

An on the primary side in the two respective heating circuits HzK ₁ and ₂ Hz integrated and fed via a further (optional) coupling capacitor C ₄ with the inverter output voltage U _WR heating transformer HzTr with a secondary winding or two galvanically separated secondary windings L _s1 and L _s2 serves to provide the in preheating required heating energy by inductive coupling. The secondary side is connected to the helical electrodes.

The primary side of this heating transformer according to the invention consists of at least two, for example. Via a common ferrite core magnetically coupled primary windings L _p1 and L _p2 , which are activated alternatively or additively. Depending on the activation, different heating power levels can thus be selected.

One of the primary windings L _p1 is, for example, selectively connectable to the other primary winding via a controllable semiconductor power switch T ₃ connected in series with a diode D ₃ acting as a half-wave rectifier. The power switch can be, for example, a field effect transistor controlled by a heating current control device of the R & S module, which can be switched to a low-resistance state by a corresponding activation of its gate electrode (switch-through operation), whereupon the relevant primary winding L _{p1 is} switched on.

Preferably the heating operation is started in particular during preheating with low heating power and increases the heating power, if a reading representing the coil temperature is insufficient Indicates spiral temperature.

As long as the _two flowing, detected through the voltage dropping at a measuring resistor R _M voltage U _M helix current I _W2 one of Heizstromregeleinrichtung predeterminable via a reference voltage U _ref2 by Wendel W, a certain heat resistance of the coil electrode W ₂ and θ a given filament temperature _W2 representing the threshold value is not falls below, the semiconductor power switch T _{3 is operated} in a high-impedance state (blocking operation). As a result, only the heating power P _H2 supplied via the primary winding L _{p2 is} transmitted to the two helical electrodes W ₁ and W ₂ .

If, however, the filament current I _W2 falls below this threshold value, the relevant primary winding L _{p1 of} the heating transformer HzTr is switched on via the forward-biased semiconductor power switch T ₃ (or switched over to this primary winding L _p1 if it transmits a higher heating power). Thus, the heating power P _H2 supplied to the helical electrodes W ₁ and W _{2 is} increased by the amount of the power P _H1 transmittable via this primary winding, or the higher heating power of the other primary winding is transmitted.

Thus, depending on the detected coil temperature θ _{W2, it is possible to} switch over between different, preferably discrete, heating output stages which are required, for example, in the preheating operation and / or in the dimming operation of the lamp LA.

As 2a can be seen, the traversed by a part of the helical current I _W2 measuring resistor R _{M is connected} at one end to the helical electrode W ₂ and at another end to the ground node. A to the measuring resistor R ₂ connected in parallel with series circuit of two oppositely poled Zener diodes D ₁ and D ₂ serves to limit the voltage dropping across the measuring resistor R ₂ measurement voltage U _M.

In 2 B is an electronic lamp ballast for AC operation of a fluorescent lamp according to a second embodiment of the present invention, which is opposite to in 2a differs in that instead of a heating transformer HzTr with two each via a common ferrite core magnetically coupled, galvanically isolated primary (L _p1 , L _p2 ) and secondary windings (L _s1 , L _s2 ) to provide heating energy to the helical electrodes W _first and W _{2 of} the lamp LA serving power transformer HzTr 'is used, the primary side consists of two parallel to each other, connected to the associated secondary side via output taps auto-transformer windings L _p1 ' and L _p2 ', each via a controllable semiconductor power switch T ₃ or T ₄ individually or in combination are switchable.

The secondary side of the power transformer HzTr 'in turn consists of two in the two respective load circuits LK ₁ and LK ₂ integrated, to the lamp filaments W ₁ and W _{2 connected} in series autotransformer windings L _s1 ' and L _s2 ', so that for each of the two consisting of a pair of primary and a secondary-side autotransformer winding part transformer results in a predeterminable by the winding conditions of the individual autotransformer windings fixed voltage translation ratio. About a to the aforementioned parallel connection of the two switchable by the semiconductor power switches T ₃ and T ₄ primary side autotransformer windings L _p1 'and L _p2 ' of the power transformer HzTr 'in series further semiconductor power switch T ₅ , both heating circuits HzK ₁ and HzK ₂ are interrupted together, whereby the Heizspannungsversorgungen the two lamp filaments W ₁ and W ₂ are turned off simultaneously.

Optionally, in each of the two load circuits LK ₁ and LK ₂ , an adjustable capacitor C ₆ or C ₇ connected in series to the lamp filaments W ₁ or W ₂ and the individual secondary-side autotransformer windings L _s1 'and L _s2 ' can also be included be over which the impedances of the respective load circuits and thus the characteristics of the current flowing through the respective lamp filaments helical currents I _W1 or I _W2 can be changed.

In 3 a current-time diagram is shown, which shows the time course of the current flowing through helical electrode W ₁ preheating current I _H1 in forward mode or in blocking operation of the one of the two primary-side windings L _p1 and L _{p2 of} the heating transformer used HzTr controllable semiconductor power switch T ₃ shows. The winding ratios ü ₁ : 1 and ü ₂ : 1 of the transformer windings can be set so that when switching through T ₃ after the transient has subsided a preheating I _H1 sets, the peak value is for example almost twice as large as the peak value of the im Disabling operation of T ₃ pre-heating current I _H1 .

4 shows another embodiment of the present invention, in which a tap (center tap) is provided between the two ends of the inductance forming the primary side. Thus, a kind of Spartrafo is formed, in which a tapping point also extends to the provision of different Heizleitungsstufen.

The detection of the spiral temperature can indirectly, for example, on the primary side, namely on the in 4 apparent resistance R _mp done.

The switching between Heizleistungsstufen also takes place in the embodiment of 4 by appropriate control of the yellow voltage U _{G of} the power transistor M1.

All in all So it should be noted that the primary side according to the invention designed to is selectively two and preferably three or more different Provide power levels.

According to the invention Heizungsleistungsumschaltung relatively simple, since they by means of Combination of the MOSFET M1 with the diode D1 can be done so that the control preferred without driver block directly, for example can be done by a microcontroller.

• – Die Heizleistung kann unabhängig von der Busspannung und der Arbeitsfrequenz des Wechselrichters sein, wenn die Versorgung der Primärseite des Heiztransformators bspw. über eine Abgriff der Mittenpunktspannung des Wechselrichters erfolgt.
• – Diese ist natürlich insbesondere dann ein Vorteil, wenn der Wechselrichter mit konstanter Frequenz betrieben wird.
• – Das Umschalten der Primärseite des Heiztransformators ist verhältnismässig einfach im Vergleich z.B. zu einem hochfrequent getakteten Schalter auf der Primärseite.

Among other things, the following advantages can be achieved by the invention:

• - The heating power can be independent of the bus voltage and the operating frequency of the inverter when the supply of the primary side of the heating transformer, for example. Via a tap of the mid-point voltage of the inverter.
• - This is of course an advantage especially if the inverter is operated at a constant frequency.
• - The switching of the primary side of the heating transformer is relatively simple compared to eg a high-frequency clocked switch on the primary side.

Claims (15)

Circuit for heating filament electrodes (W ₁ , W ₂ ) of fluorescent lamps (LA), comprising a heating transformer (HzTr ') whose secondary side (L _s1 ', L _s2 ') is provided with at least one filament electrode (W ₁ and / or W ₂ ) is connected and one with this secondary side (L _s1 ', L _s2 ') magnetically coupled, with voltage ( U _WR ) supplied primary side (L _p1 ', L _p2 '), wherein to the primary side (L _p1 ', L _p2 ') to provide of at least two different heating powers (P _H1 , P _H2 ) transmitted by the heating transformer (HzTr '). The circuit of claim 1, wherein the different ones Heating power over a semiconductor component of the primary side are available. A circuit according to claim 1 or 2, _wherein on the primary side (L _p1 ', L _p2 ') a plurality of magnetically coupled coils are provided, which are activated alternatively or in combination. Circuit for heating filament electrodes (W ₁ , W ₂ ) of fluorescent lamps (LA), comprising a heating transformer (HzTr) whose secondary side (L _s1 , L _s2 ) is connected to at least one filament electrode (W ₁ and / or W ₂ ) and which has a magnetically coupled to this secondary side (L _s1 , L _s2 ), supplied with voltage ( U _WR ) primary side (L _p1 , L _p2 ), wherein on the primary side (L _p1 , L _p2 ) a plurality of magnetically coupled coils are provided which can be activated alternatively or in combination to provide different heating powers (P _H1 , P _H2 , P _H1 + P _H2 ). Circuit according to one of the preceding claims, wherein the voltage supply of the primary side (L _p1 , L _p2 ) via the midpoint of an inverter half-bridge circuit (DC / AC) takes place, which provides an AC voltage ( U _WR ) for the operation of a connected lamp (LA). control gear for fluorescent lamps, comprising a circuit according to one of the preceding claims. Operating device according to claim 6, comprising a control circuit (R & S module), which sets the heating power (P _H1 , P _H2 , P _H1 + P _H2 ) depending on the operating and / or dimming state of a connected lamp (LA). Operating device according to claim 6 or 7, comprising a control circuit (R & S module), which sets the heating power (P _H1 , P _H2 , P _H1 + P _H2 ) depending on the type of a connected lamp (LA). Operating device according to claim 6 or 7, comprising a control circuit (R & S module), which sets the heating power (P _H1 , P _H2 , P _H1 + P _H2 ) depending on the detection of a parameter ( I _W1 , I _W2 ), the coil temperature (θ _W1 , θ _W2 ), the applied input voltage, the operating state and / or the lamp type reflects. Method for heating filament electrodes (W ₁ , W ₂ ) of fluorescent lamps (LA) by means of a heating transformer (HzTr ') whose secondary side (L _s1 ', L _s2 ') is provided with at least one filament electrode (W ₁ and / or W ₂ ) and having a magnetically coupled to this secondary side (L _s1 ', L _s2 '), supplied with voltage ( U _WR ) primary side (L _p1 ', L _p2 '), comprising the step of adjusting one of a plurality of Heizleistungsstufen (P _H1 , P _H2 , P _H1 + P _H2 ) of the primary side (L _p1 ', L _p2 ') of the heating transformer (HzTr '). Method for heating filament electrodes (W ₁ , W ₂ ) of fluorescent lamps (LA) by means of a heating transformer (HzTr) whose secondary side (L _s1 , L _s2 ) is connected to at least one filament electrode (W ₁ and / or W ₂ ) and _{comprising a} primary side (L _p1 , L _p2 ) magnetically coupled to said secondary side (L _s1 , L _s2 ) and supplied with voltage ( U _WR ), _comprising the step of adjusting one of a plurality of heating power stages (P _H1 , P _H2 , P _H1 + P _H2 ) by selectively activating one or more magnetically coupled coils forming the primary side (L _p1 , L _p2 ) of the heating transformer (HzTr). Method according to one of claims 10 or 11, comprising the following steps: - setting the lowest heating power level (P _H1 , P _H2 ), - detecting a parameter (I _W1 , I _W2 ) representing the spiral temperature (θ _W1 , θ _W2 ) , and - selecting a higher heating power level (P _H1 + P _H2 ), if the coil temperature (θ _W1 , θ _W2 ) is still insufficient. Method according to one of claims 10 to 12, wherein the current heating power level (P _H1 , P _H2 , P _H1 + P _H2 ) depending on the operating state, selected by the level of the applied input voltage, the lamp type and / or dimming state of the connected lamp (LA) becomes. Method according to one of claims 10 to 13, wherein the current heating power level (P _H1 , P _H2 , P _H1 + P _H2 ) depending on the type of the connected lamp (LA) is selected. Electronic control unit in support of a Method according to one of the claims 10 to 14 is designed.