DE4416042A1 - Circuit arrangement for operating discharge lamps - Google Patents

Abstract

The invention relates to an integral circuit arrangement for operating discharge lamps (30) or halogen lamps (36). In order to generate the necessary square-wave voltage in the invertor (2) which is supplied from a DC voltage source and to whose output there are series-connected an inductance (31) and thereto the discharge lamp (30) with preheat circuit (32) or to which there is connected directly an isolation transformer (35) for a halogen lamp (36), no inductive transmitter elements (transformer elements) are used for supplying the active switching components of the invertor (2). Instead, a capacitor (8), together with the drive circuits (4, 5) which store the switch-on pulse, simultaneously assume three functions (control, protective function and energy transmission) and thereby create the precondition for an integral arrangement of the controlling elements which at the same time permit the invertor (2) to be influenced in terms of frequency and duty ratio in a simple way in terms of circuitry and permit a flexible and comfortable design of the function of the entire invertor (2). The aim of the invention is the creation of a highly integrable overall solution of electronic ballast devices for discharge lamps and halogen lamps, while maintaining high flexibility in the application. <IMAGE>

Description

The invention relates to a circuit arrangement for Operation of discharge lamps, especially low-pressure discharge Dung lamps or halogen lamps according to the preamble of Claim 1.

DE 40 09 267 A1 describes a ballast for gas discharge is known that an electrical circuit on points in the bridge converter by a DC voltage source fed via two input DC voltage terminals and at least two controllable power switching elements  having. At the exit of the bridge converter is the row switching an inductor and one in parallel with one Gas discharge lamp switched capacitor as a series circle provided. The control electrodes of the power switch elements are each with one from the DC voltage source le fed buffer circuit connected via coupling transformers are supplied with control signals that from a control scarf controlled by a control unit be given.

Parallel to the voltage supply of the buffer circuits two diodes connected in series are provided, their connection tion to one connection of a capacitor is closed, both for the delivery of the cargo for the Power switching elements as well as voltage rise limitation and reduction of switching losses in the Lei power switching elements is used.

In this circuit of a ballast for gas discharge The control pulses by means of coupling transfor. lamps mators from the control circuit to the control circuit for the Transfer control electrodes of the power switching elements. Due to the coupling transformers required, the known circuit on the one hand and on the other hand Manufacturing an integrated circuit unsuitable.

Since discharge lamps, especially low-pressure discharge lamps such as fluorescent and compact lamps as well as halogen lamps, are manufactured in large quantities and one reliable function of the lamps to a considerable extent depends on the electronic ballasts is one effective manufacturing technology for large quantities  and at the same time high reliability of the function of the electronic ballasts required. A high degree reliability combined with effective Manufacturing technology can be achieved through greater integration the electrical circuit of the electronic ballasts te can be achieved.

The object of the present invention is a circuit create an arrangement for operating discharge lamps, the ensure reliable operation of the discharge lamps constant, inexpensive to manufacture, by a small Excellent volume and for an integrated circuit suitable is.

This object is achieved by the features of Claim 1 solved.

The solution according to the invention enables the production of electronic ballasts for discharge lamps, the ensure very reliable operation, in bulk quantities are inexpensive to manufacture and stand out a small construction volume and a high degree of integration award.

The solution according to the invention is based on knowledge from that by avoiding expensive, relatively large volumes ger transmitter for transmitting the control pulses from a Control device on the control electrodes of the power switching elements to a control circuit with low Construction volume and high degree of integration, so that high Numbers can be produced at low cost can. This is done according to the features of claim 1  one through an energy transmission with the signal transmission gung and by a circuit measure, the ensures that even without using transformers for Impulse transmission the power switching elements always ge are conductive, so that no short circuit can occur and thus affect the reliability of the overall circuit is pregnant.

An advantageous embodiment of the invention Solution is characterized in that the control circuit against a pulse shaper connected to the capacitor Formation of the switch-on pulse at the end of the switch-off process the other circuit breaker, d. H. at the end of HL or falling edge of the output from the capacitor Current pulse, a memory for storing the Kon capacitor emitted switch-on pulses for the duration of the on control of the assigned circuit breaker and given if necessary, the output of the memory with the respective Circuit breakers connecting gate circuit that additionally connected to an output of a control logic is the input side with an output of the pulse shaper as well as the inverting output of the memory and the reset input via another output controls the memory.

This configuration of the solution according to the invention enables universal use of the control circuit corresponding execution of the internal control logic. Becomes an external control circuit with the control circuits connected so additional lamp parameters such as Lamp voltage, input current and supply voltage of the altern half-bridge, desired lamp power or differences  between the desired and actual light intensity take into account and the control frequency of the power scarf ter vary as a result of controlling the hold time of the Memory derived from fixed time elements or variably derived from for example the load current of the Lei just switched on switch or from other internal or external Sources.

The gate circuit is only required if internal or externally generated fade-outs or temporal pulse cursors corrections necessary for the control of the circuit breakers dig without affecting memory.

The control logic preferably controls the gate circuit in this way indicates that the assigned circuit breaker is only on switches when the pulse shaper ends the reloading pro detected the inductance.

Alternatively, the control logic controls the gate circuit so that the assigned circuit breaker only then switches on when the control logic ends the reloading process of the Inductance via in series with the circuit breakers switched resistors detected.

The reset pulse of the memory can be advantageous Further development of the invention optionally from a time pulse formed its initial state and the memory as monostable flip-flop or as a trigger impulse from the control logic and from the rise formed the load current of the controlled circuit breaker become.  

Alternatively, the reset pulse of the memory from the LH or rising edge of the over the capacitor carried impulse in the control logic or over an external control input of the control logic in order to be able to act directly on storage externally.

With individual control from the pulse shaper via the con So there is an easy way in control of the circuit breaker in any form to design an external circuit that has no additional Operating voltage supply required, but via the Capacitor receives the necessary energy supply.

The circuit can be used as a half bridge as well Full bridge can be built, for example, some Control circuits have preset storage times zen, while the other control circuits via a Pha comparison control can be reset from the outside. The depending on the design of the phase ver equal control with rigid or with variable phases able to work so that an external power control is possible.

Likewise, the arrangement of the half bridge to a full bridge ke be expanded, with each individual half-bridge branch is controlled by a common generator.

The capacitor also offers a protective function for the circuit breakers during the changeover phase, that he the induction current from the current-limiting Induc activity picks up and thus the Lei just switching off Relief switch relieved.

Based on the embodiment shown in the drawing should play the idea underlying the invention are explained in more detail. Show it:

Fig. 1 shows an inventive electronic Vorschaltge advises with an integrable arrangement of an inverter in the half-bridge arrangement;

FIG. 2 shows a detailed illustration of the control devices according to FIG. 1;

Fig. 3 shows a first embodiment of a pulse shaper;

FIG. 4 shows a second embodiment of the pulse shaper;

Fig. 5 is a single control of circuit breakers from an external pulse generator and

Fig. 6 shows an electronic ballast with an integrable arrangement of an inverter in full bridge arrangement.

Fig. 1 shows a circuit arrangement for an electronic ballast for operating discharge lamps, the components of which can be summarized in an integrated circuit. The circuit has a line filter and rectifier 1 , which can be connected to a supply voltage AC network of, for example, 230 volts at a frequency of 50 Hz.

The DC voltage output of the line filter and rectifier 1 feeds an inverter 2 in half-bridge arrangement, between the output and a capacitive voltage divider with the capacitors 33 , 34, the series circuit device of an inductor 31 , a gas discharge lamp 30 and a capacitor is connected. A preheating device 32 is connected in parallel with the electrodes of the gas discharge lamp 30 .

Alternatively, instead of the inductance 31 and the discharge lamp 30, an isolating transformer 35 , the primary winding of which is arranged in the connection of the inverter output to the capacitors 33 , 34 , and a halogen lamp 36 connected to the secondary winding of the isolating transformer 35 can be provided.

The inverter 2 has two circuit breakers 6 , 7 in the two bridge branches of the half-bridge arrangement, which are designed as field effect transistors in the exemplary embodiment shown in FIG. 1. Antiparallel to the load connections of the circuit breakers 6 , 7 are freewheel diodes 11 , 12 connected. The control electrodes of the power switches 6 , 7 are connected to the outputs of two control circuits 4 , 5 , which are connected via a third or fourth resistor 13 , 14 to a load terminal of the circuit breaker 6 , 7 , respectively.

The two the control circuits 4 , 5 and circuit breakers 6 , 7 containing bridge branches of the inverter 2 are constructed in the same way and form a connection point of the bridge diagonals with regard to their circuit output. The one control circuit 4 is connected on the one hand via a resistor 9 to the positive voltage connection of the rectifier output and on the other hand to the diagonals of the bridge, while the other control circuit 5 is connected via a resistor 10 to the diagonals of the bridge and on the other hand directly to the negative connection of the rectifier output. Both control circuits 4 , 5 are coupled to one another via a capacitor 8 .

A third and fourth resistor 13 , 14 are provided in series with the load path of the circuit breakers 6 , 7 , while diodes 11 , 12 are connected in parallel with the load connections of the circuit breakers 6 , 7 .

The operation of the circuit shown in Fig. 1 Darge of a ballast for Entladungslam pen will be explained in more detail.

The AC voltage U _N applied to the line filter and rectifier 1 is present at the output of the line filter and rectifier 1 as a smoothed DC voltage. This is converted into a square-wave voltage by means of the inverter 2, in that the controllable power switches 6 , 7 of the half-bridge arrangement of the inverter 2 are brought into the conductive state alternately. The alternately conductive state of the circuit breakers 6 , 7 is caused by the control pulses applied to the circuit breakers 6 , 7 th control pulses of the control circuits 4 , 5 , which alternately control the circuit breakers 6 , 7 .

Here, the drive circuits 4, 5 miteinan the connecting capacitor 8 respectively with the falling edge in relation to the drive circuits 4, 5 to a switching pulse dynamically, so that this pulse erschaltungen in the Ansteu 4, 5 for the required duty cycle of the BE taken breaker 6 transmits or 7 must be saved. This storage time can be limited by fixed timers or be derived from values such as the load current of the circuit breaker 6 or 7 just switched on or from other internal or external sources.

The mutual control of the circuit breakers 6 , 7 by means of the drive circuits 4 , 5 which are coupled together via the capacitor 8 ensures that not both circuit breakers 6 , 7 are simultaneously conductive and thus produce a short circuit which leads to the destruction or impairment of the function of the ballast would lead.

The pending at the output of the inverter 2 hochfrequen te AC voltage is the series circuit of inductivity 31 , discharge lamp 30 with a preheating circuit 32 connected in parallel. Before the discharge lamp is ignited, the drive frequency of the inverter 2 is above the resonance frequency of the series circuit, which is formed from the inductance 31 and the capacitor contained in the preheating circuit 32 . Then the drive frequency is gradually reduced and when the resonance frequency of the series circuit is reached, the voltage across the capacitor in the preheating circuit 32 of the discharge lamp 30 is so high that the discharge lamp 30 ignites. After ignition, the discharge lamp loads the series circuit and leads to a damping of the series circuit, so that the half bridge remains inductive.

In operation, an external control can be carried out so that the drive frequency of the discharge lamp 30 is changed according to the respective conditions such as lamp voltage, input current of the inverter half-bridge, supply voltage of the inverter half-bridge, desired lamp power or difference between the desired and actual light intensity. Such an external control can be made via the control input S according to FIG. 2, in which the individual components of the control circuits 4 , 5 according to FIG. 1 are shown.

The control circuits 4 , 5 have a pulse shaper 41 , which is connected on the input side to the capacitor 8 and is connected via the resistor 9 or 10 with high resistance to the DC voltage supply. A first output of the pulse shaper 41 is connected to the set input S of a memory 42 , which is also supplied via the resistors 9 and 10 , respectively. The output Q of the memory 42 is connected to an input of a gate circuit 43 , the output of which is connected to the control connection of the circuit breaker 6 or 7 .

A control logic 44 is on the input side with an output of the pulse shaper 41 and the negated output Q / of the memory 42 as well as to the connection of a load connection of the circuit breaker 6 or 7 with the resistance connected in series with the load path of the circuit breaker 6 or 7 was 13 or 14 connected. On the output side, the control logic 44 controls the reset input R of the memory 42 and a second input of the gate circuit 43 . The voltage supply to the control logic 44 also takes place via the resistor 9 or 10 .

In addition, the control circuits 4 , 5 have a support capacitor 45 and a Zener diode 46 , which are connected in parallel to one another to the voltage supply of the control logic 44 .

A possibly external control can be connected in the further input of the control logic 44 , which is shown in the circuit arrangement according to FIG. 2 by the arrow S.

In the operation of the control circuits 4 , 5 , the pulse former 41 derives a switch-on pulse for the memory 42 from the falling edge of the pulse transmitted via the capacitor 8 in the form that either at the end of the falling edge or on any, but constant Edge point with subsequent delay the memory 42 is set. When the gate circuit 43 is open, the circuit breaker 6 or 7 switches on immediately.

The gate circuit 43 shown in FIG. 2 is only necessary, however, if internally or externally generated fade-out conditions or temporal pulse corrections for the control of the circuit breakers 6 , 7 are necessary without influencing the memory 42 .

The memory 42 can optionally also be designed as an astable multivibrator, the switch-on time of which is always less than its switch-off time, which is then synchronized via the capacitor 8 .

Due to the freely selectable reset conditions of the memory 42 from the control logic 44 , the frequency and the duty ratio of the entire inverter 2 according to FIG. 1 can be realized from various conditions. So z. B. a fixed limit value by time constant, a variable limit value by time function-dependent or current-dependent from the circuit breakers 6 , 7 reset pulse via the resistors 13 , 14 in series to the load path of the circuit breaker 6 , 7 via the input of the control logic 44 , which to the A load connection of the circuit breakers 6 and 7 is connected to the resistors 13 and 14 , respectively.

The compensation of the slow brightness start of the discharge lamp of approx. 5 minutes is mentioned as a particularly suitable application for a variable limit value specification. In addition, an externally fed reset condition via the external control input of the control logic 44 for power control of the discharge lamp is possible if special starting properties of the discharge lamp in relation to the frequency and the duty cycle are required. The control logic 44 takes over all of the functions to be coordinated.

When the control circuits 4 , 5 according to FIG. 1 are interconnected, an oscillatory system is obtained which, once triggered, enables an optimal operating mode of the circuit breaker 6 , 7 . This initiation is given by the control logic 44 in the form that, depending on the flank position on the pulse shaper 41, the circuit breaker 6 or 7 concerned is activated during the switch-on phase.

In addition to the controlling function of the capacitor 8 for alternating control of the control circuits 4 and 5 , this is also used in the switchover phase to protect the circuit breakers 6 and 7 . It relieves the circuit breaker 6 or 7 that is just being switched off so that it absorbs the induction current from the current-limiting inductor 31 according to FIG. 1 and conducts it via the pulse shaper 41 to the supporting capacitor 45 of the control circuit 4 or 5 according to FIG secure supply. The resistors 9 , 10 are used for the minimum current supply to the control circuits 4 , 5 .

In FIGS. 3 and 4 are shown embodiments of the Impulsfor mers 41 according to Fig. 2, which will be able to realize the demands placed upon it triple function.

The circuit arrangement shown in FIG. 3 for an embodiment of a pulse shaper has two transistors 51 , 52 of different conductivity types, the bases of which are connected to the positive or negative pole + or - of the voltage supply and whose emitters and collectors are connected together, whereby the interconnected emitters are connected to the capacitor 8 . The interconnected collectors of the transistors 51 , 52 are connected to the connection of two diodes 53 , 54 connected in series, which are connected with their cathode or anode to the bases of the transistors 51 , 52 .

Also connected to the connection of the two diodes 53 , 54 is a first NAND element 55 , the output of which is connected to the input of a second NAND element 56 , the output of which is in turn connected to the input of the first NAND element 55 via a resistor 57 is. The connection of the two NAND elements 55 , 56 is connected via a resistor 58 to the connection of the two emitters of the transistors 51 , 52 . The NAND elements 55 , 56 in conjunction with the resistors 57 , 58 form a Schmitt trigger for delivering defined output pulses from the pulse former 41 .

The pulse shaper circuit arrangement shown in FIG. 3 is designed such that, on a rising edge of the input pulse via the capacitor 8, the memory 42 according to FIG. 2 can be reset in order to force the memory 42 to be switched off dynamically. This enables direct individual control of the circuit breakers 6 , 7 from an external generator 15 according to FIG. 5.

The schematically simplified circuit arrangement of an exemplary embodiment for another pulse shaper shown in FIG. 4 has a transistor 61 , the base of which is connected to the negative pole of the voltage source and the emitter of which is connected to the capacitor 8 . The collector of transistor 61 is connected via a resistor 63 to the positive pole of the voltage source and directly to an output of the pulse shaper, anode side being connected to the emitter of transistor 61 on the one hand and kathodensei to resistor 63 on the other hand, a diode 62 being connected. In parallel to the base-collector path of the transistor 61 , a further diode 64 with a cathode side according to the connection to the collector of the transistor 61 is provided.

In the circuit arrangement of FIG. 5, the external generator 15 is connected to an input of the first drive circuit 4 with the Steuerein gear via the capacitor 8 directly to the drive circuit 5 is connected. Furthermore, the external generator 15 is connected to the negative pole of the input DC voltage and to the resistor 10, which is connected to the half-bridge diagonal, ie to the inductor 31 . The external generator 15 can be used, among other things, to carry out a temperature-dependent correction of the control or generator frequency of the circuit breakers 6 , 7 .

The other construction of the circuit arrangement of FIG. 5 corresponds to the half-bridge arrangement of the inverter 2 according to Fig. 1. The power supply of the generator 15 and the drive circuits 4, 5 takes place in the Schaltungsanord voltage in FIG. 5 also via the capacitor 8.

The half-bridge arrangement of the inverter 2 shown in the circuit arrangements shown in FIG. 1 can also be a full bridge arrangement of FIG. 6 are constructed, wherein arranged in the bridge branches B1 and B2 driving circuits 4, possess 4 'permanently set storage times and in the other bridge arms B3 and B4 angeordne th control circuits 5 , 5 'are reset via a phase comparison control 20 from the outside. Depending on the design of the phase comparison controller 20, the two interconnected half bridges can operate with a rigid or with a variable phase position, so that external power control is possible. The full-bridge circuit of the inverter shown in FIG. 6 causes a doubling of the discharge lamp 30 applied to the series circuit of the inductance 31 output voltage compared to the half-bridge arrangement in accordance with Figs. 1 and 5.

Likewise, the circuit arrangement of the half-bridge circuit of the inverter according to FIG. 5 can be expanded to a full-bridge arrangement in which each individual half-bridge branch is controlled by a common generator 15 alternately.

Such full bridge circuits are then required if e.g. B. the operating voltage of a half-bridge circuit is too low to feed a discharge lamp, so that this kind of doubling of voltage is sufficient large reserve is achieved.

Claims (17)

1. Circuit arrangement for the operation of discharge lamps, in particular low-pressure discharge lamps or halogen lamps, with an inverter fed from a DC voltage source, at the output of which the series circuit of an inductor and the discharge lamp is connected and which has at least two circuit breakers, the control connections of which are each one Control circuit are connected, characterized in that the control circuits ( 4 , 5 ) are connected to one another via a control element ( 8 ) which transmits a switch-on pulse alternately to the first or second control circuit ( 4 , 5 ). 2. Circuit arrangement according to claim 1, characterized in that the control element consists of a capacitor ( 8 ) which alternately transmits a dynamic switch-on pulse alternately to the first or second drive circuit ( 4 , 5 ). 3. A circuit arrangement according to claim 1 or 2, characterized in that the control circuits ( 4 , 5 ) for the circuit breaker ( 6 , 7 ) are of the same design and that the control circuits ( 4 , 5 ) their operating voltage from the inductance ( 31 ) receive the circuit breaker ( 6 , 7 ) during the blocking phase. 4. Circuit arrangement according to at least one of the preceding claims, characterized in that the control circuits ( 4 , 5 ) have a memory ( 42 ) for storing the switch-on pulses emitted by the control element or capacitor ( 8 ) for the duration of the activation of the assigned circuit breaker ( 6 , 7 ). 5. Circuit arrangement according to claim 1 or 2, characterized in that the control circuits ( 4 , 5 ) with the capacitor ( 8 ) connected pulse shaper ( 41 ) to form the switch-on pulse at the end of the falling edge of the capacitor ( 8 ) output Included. 6. Circuit arrangement according to at least one of the preceding claims, characterized in that the control circuits ( 4 , 5 ) have a gate circuit ( 43 ) connecting the output of the memory ( 42 ) with the respective circuit breaker ( 6 , 7 ), which additionally with an output of a control logic ( 44 ) is connected, the control logic ( 44 ) being connected on the input side to an output of the pulse shaper ( 41 ) and the inverting output of the memory ( 42 ) and driving the reset input of the memory ( 42 ) via a further output . 7. Circuit arrangement according to at least one of the preceding claims, characterized in that the Impulsfor mer ( 41 ) forms the switch-on pulse for the memory ( 42 ) at the end of the HL edge of the capacitor ( 8 ) transmitted pulse. 8. Circuit arrangement according to at least one of the preceding claims, characterized in that the Impulsfor mer ( 41 ) at any point, preferably at the beginning of the falling edge, the via the capacitor ( 8 ) transmitted pulse over a defined time delay to the memory ( 42nd ) as a switch-on pulse. 9. Circuit arrangement according to claim 5 and 6, characterized in that the control logic ( 44 ) controls the gate circuit ( 43 ) so that the associated circuit breaker ( 6 , 7 ) only turns on when the pulse shaper ( 41 ) the end of the reloading process the inductance ( 31 ) is detected. 10. Circuit arrangement according to claim 5 and 6, characterized in that the control logic ( 44 ) controls the gate circuit ( 43 ) so that the associated circuit breaker ( 6 , 7 ) only turns on when the control logic ( 44 ) the end of the reloading process the inductance ( 31 ) via series resistors ( 13 , 14 ) connected in series with the circuit breakers ( 6 , 7 ). 11. Circuit arrangement according to at least one of the preceding claims, characterized in that the reset pulse of the memory ( 42 ) is formed from a time pulse of its initial state and the memory ( 42 ) is designed as a monostable flip-flop. 12. Circuit arrangement according to at least one of the preceding claims, characterized in that the reset pulse of the memory ( 42 ) is emitted as a trigger pulse by the control logic ( 44 ) and is formed from the increasing load current of the controlled circuit breaker ( 6 , 7 ). 13. Circuit arrangement according to at least one of the preceding claims, characterized in that the reset pulse of the memory ( 42 ) from the rising edge of the via the capacitor ( 8 ) and pulse shaper ( 41 ) transmitted pulse in the control logic ( 44 ) is formed. 14. Circuit arrangement according to at least one of the preceding claims, characterized in that the reset pulse of the memory ( 42 ) via an external control input of the control logic ( 44 ) is supplied. 15. Circuit arrangement according to at least one of the preceding claims, characterized in that the control logic ( 44 ) emits a start pulse when there is no vibration when the operating voltage is applied, for example when it is switched on, and a circuit breaker ( 6 ) depending on the edge position on the pulse shaper ( 41 ) or 7 ) is activated. 16. Circuit arrangement according to at least one of the preceding claims, characterized in that the inverter ( 2 ) from a full bridge arrangement with four circuit breakers ( 6 , 7 , 6 ', 7 ') and control circuits ( 4 , 5 , 4 ', 5 ' ) in the bridge branches (B1 to B4). 17. Circuit arrangement according to claim 16, characterized in that the reset inputs of the memory ( 42 ) for a phase control for power control of the discharge lamp ( 30 ) or the halogen lamp ( 36 ) are controllable.