DE3401653A1 - Invertor circuit for operating gas-discharge lamps - Google Patents

Abstract

The invertor circuit for gas-discharge lamps (G) operates at high frequencies and with low-loss tuned circuits. In order to prevent the electrical variables (voltage-current) rising too rapidly and too high as a result of the low-loss tuned circuits when the gas-discharge lamp (G) is defective, a resistor (R1) and a controllable semiconductor valve (T1) are provided between the mains voltage lines (V+ - V-). The semiconductor valve (T1) is controlled by an electrical variable which increases if the lamp (G) is defective. A diode (D2) which is connected between the semiconductor valve (T1) and the resistor (R1) is electrically, effectively connected to the invertor (W) and switches the latter off as soon as the semiconductor valve (T1) has been activated by the rising electrical variable. <IMAGE>

Description

A «g

ti JM. SB

Patent holder: · Zumtobel Aktiengesellschaft

■ 6850 Dornbirn (Vorarlberg -> Austria)

Subject: Inverter circuit for operation

of gas discharge lamps

Legal file: X 1169

Claimed priority: Austria (AT); 1983 01 20

A 186/83

Inventor: Jagschitz Otto, Dipl.Ing.

. Götzis (Vorarlberg - Austria)

Publications that were considered to delimit the state of the art:

DE-OS 28 07 999
DE-OS 30 32 328

HE 8192/93

9 / sat / 12

The invention relates to an inverter circuit for operating gas discharge lamps with a high-frequency voltage and with an inverter that can be connected to two phases of a direct voltage source and has at least one switched Output, with at least one series resonant circuit formed from inductances and capacitances at this output and the gas discharge lamp or gas discharge lamps lying in series with the series resonant circuit on the other side is or are connected to a phase of the DC voltage source feeding the inverter, wherein in parallel at least one further capacitor is provided for the discharge path of the gas discharge lamps.

It is known, gas discharge lamps with high frequency Voltage, for example 20 kHz or more to operate. By operating gas discharge lamps with higher voltages Frequency can increase the light output of such a lamp and the components for operating the lamp also have lower power losses in this case and can therefore be built smaller than those used for the operation of fluorescent lamps with conventional mains frequency. In order to obtain the high voltages required for starting the gas discharge lamps, the aforementioned Circuits Series resonant circuits assigned to the gas discharge lamps, which increase the voltage extremely quickly leave until the gas discharge lamp starts. Gas discharge lamps with preheated electrodes can be used for this purpose or those with electrodes that have not been preheated can be used. The lamp starts in spite of some reasons If the starting voltage is not reached, the voltage here rises to values that can endanger the circuit. A fault that prevents the gas discharge lamp from starting can be, for example, that the lamp is leaking, i.e. has a so-called gas defect. Here and in the following, such a defect is referred to as a gas defect.

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by which the gas conditions in the glass bulb of the gas discharge lamp are disturbed in some way. These gas defects can have various causes.

The object and purpose of the invention is now to provide a circuit that switches off the inverter when due ein.solchen Gasdefektes on the lamp, the starting process after a predetermined time has elapsed has resulted in the desired success. The circuit should also be constructed so that as soon as the defective lamp is replaced is, the starting process starts by itself without the need to switch the network off or on. For extensive lighting systems, this is a considerable relief for the support staff. To solve this problem, the invention now proposes that between a phase of the DC voltage source and a electrode of a gas discharge lamp connected to the other phase and - viewed in the direction of the power flow - The gas discharge lamp is followed by a resistor in series with a controllable semiconductor valve, for example a thyristor is located, and the semiconductor valve of an increasing electrical size when the lamp is defective (Voltage, current, voltage drop) is controlled and the line connecting the resistor and the semiconductor valve is in operative connection with the inverter via a diode and switches off this inverter in the event of a current flow in the line. If the lamp does not start due to a gas defect, θο increases in the circuit due to the here The existing, usually low-loss oscillating circuits very quickly apply the voltage and thus the currents and the associated currents associated voltage drop θ across the circuit elements. These electrical quantities (voltage level, voltage rise, current and strength, Voltage drop) individually or in total, are used as a control signal for controlling the semiconductor valve used. To this end, another feature is sought

T-

of the invention, the control electrode (gate) of the semiconductor valve via a time delay element and via a electronic release device, for example a trigger connected to the series resonant circuit. This measure enables a simple circuit structure.

Without restricting the invention, three circuit examples are explained in more detail with reference to the drawing.

According to FIG. 1, the gas discharge lamp G is connected with its one electrode W. to phase 1 of a DC voltage source V ₊ - V-, which can be switched on and off via the switch S. The other electrode W ~ of the gas discharge lamp G is connected via a series oscillating circuit LK, which consists of the choke L and the capacitor K, to the switched output 5 of the electrical inverter W, which in turn is connected to the two phases 1 and 2 of the mentioned DC voltage source. The two electrodes YL and W ~ of the gas discharge lamp are connected in series via a further capacitor C-. The inverter W is designed for an operating frequency of 20 kHz, for example. The series oscillating circuit LK. Is dimensioned with as little loss as possible. Its resonance frequency can correspond to the operating frequency of the inverter W.

Between phase 2 of the DC voltage source V + - v- and the electrode Wp connected to the other phase 1 the gas discharge lamp G and - viewed in the direction of the power flow - the gas discharge lamp G is arranged downstream a resistor R ^ in series with a controllable semiconductor valve T ^, which is designed, for example, as a thyristor. The control electrode of the semiconductor valve T ^ is a Voltage divider Rg-R ^, a diode D ^, a time delay element O ^ -R ^ and one as an electrical release device D ^ acting trigger connected to the series oscillating circuit L-K.

_{The resistors R g} and Rr _{7 connected} directly upstream of the control electrode of the semiconductor valve T. that when a current flows in line 3, the inverter is switched off.

If now - provided that the gas discharge lamp G has a so-called gas defect - the switch S is closed and the inverter W is connected to the DC voltage source V + - V-, the voltage at the choke L and the capacitor K of the series resonant circuit rises very quickly and, since the gas discharge lamp 3a cannot start because of its gas defect, it reaches ever higher values.This rapidly rising alternating voltage is converted to capacitor O ^ via the voltage divider R ^ -R * and the diode D. and via the charging resistor R, - to the capacitor G ^ led, which thereby receives an increasing charging voltage until the voltage present at the capacitor Op reaches the trigger value of the trigger D ^, which then switches through and thus opens the semiconductor valve T ^. The current flowing through the now open semiconductor valve T ^ causes a voltage drop at the resistor R. This is fed to the inverter W via the diode 2 and the line 4 and switches it off as soon as a current flows in the connecting line 3. As a result, the oscillation in the series oscillating circuit LK breaks down, the resistor R ^ for the semiconductor valve T ,, which is expediently designed as a thyristor, provides the necessary holding current.

If the defective gas discharge lamp G is now removed, the holding current flowing through the resistor R ,, for the Semiconductor valve T ^ interrupted because this holding current yes

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also flows through the electrode W. of the gas discharge lamp, which is connected in series with the resistor R ^ and the semiconductor valve T ^. This current interruption then closes the semiconductor valve T ^, that is to say clears the thyristor, whereby the switch-off signal which has been fed to the inverter W via the line 4 * collapses. The inverter is thus ready to oscillate again. However, since the defective gas discharge lamp G has been removed and the electrodes W and W ₂ are missing in the circuit, this oscillation process can only start when a new gas discharge lamp G has been inserted, although the power switch S does not need to be actuated, which is how before is still closed.

In the exemplary embodiment shown, the resonance voltage rising in the resonant circuit LK was used to control the semiconductor valve T. It is also possible to use other electrical quantities for controlling the semiconductor valve Ty. to be used, for example, the increasing current in the event of a malfunction or the increased voltage drop on the circuit elements caused by the increased current. Depending on the choice of the control signal for the semiconductor valve T, the circuit lying within the dashed line 6 and its connection A on the lamp circuit are to be varied and modified.

The circuit described above can also be used when two or more gas discharge lamps G are connected to the inverter W. Such a circuit is shown, for example, in FIG. 2, parts having the same function having been given the same reference numbers, to which an index line has been added to distinguish them. For the second gas discharge lamp G ¹ , the additional switching components R ₂ 'and R ^ ¹ for the voltage divider as well as the diodes D ₁ ¹ and D ₂ ¹ and an additional semiconductor valve T ₁ ^{1 are} required. If there is a gas defect in a lamp G, as in

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Described in connection with FIG. 1, the circuit only starts again when all gas discharge lamps G and G ^{1 have been} removed from their socket and then put back into place. It is sufficient if the defective lamp is removed and replaced and the other lamp is removed from its socket and then reinserted. In the circuit according to FIG. 2, the gas discharge lamps G and 'G' are connected in parallel. Essentially, the circuit shown here in FIG. 2 is a duplication of that circuit which has been explained in FIG. '- ·

J shows a circuit in which two gas discharge lamps G and G ¹ are connected in series. The electrode W. «of the lamp G and the electrode Wp ^{1 of} the lamp G ¹ see above:; an additional transformer T ^ fed. Since it is not possible to identify which lamp is defective if the start attempt is unsuccessful, two possible cases can be considered here. If it is assumed that the problem lies with the lamp G and this activates the switch-off device and the lamp G 'would be replaced, the starting process is initiated, but the defective lamp G is still in the circuit is involved, the shut-off device will again come into operation. If the lamp G is now replaced and the lamp G ^{1 is turned out} and in again, the switching of the lamps can start again and successfully.

If, however, the lamp G ^{1 is} defective, it is sufficient to replace this lamp in order to start the starting process automatically and successfully without pressing the power switch S.

Depending on the dimensioning of the circuit, the components. R ¹ , D ^ and C ^ can be saved. The trigger D ^ can be used with

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Direct current or alternating current can be supplied.

To control the semiconductor valves, other disturbance variables (voltage drop) can also be used in the circuits according to FIGS. 2 and 3, as has been explained in connection with Hg The circuitry visible in the dashed line 6 can be modified and varied, as is the connection of this circuit to the circuit of the lamp itself. The switching elements C _x . -R ^ serve as a time delay element. Thanks to the circuit according to the invention, the starting ^{process is initiated automatically after the defective gas discharge lamp G or G 1 has been replaced} , without the need to operate the power switch S once it is closed, which is very important for the monitoring staff of the lighting system, especially if it is of considerable size Represents work relief.

Claims (7)

Patent claims: ρ] Inverter circuit for the operation of "gas discharge lamps with a high-frequency voltage and with an inverter which can be connected to two phases of an equilibrium voltage source and has at least one switched output, with at least one series resonant circuit formed from inductances and capacitances at this output and the gas discharge lamp in series with the series resonant circuit or gas discharge lamps is or are connected on the other side to a phase of the DC voltage source feeding the inverter, at least one further capacitor being provided parallel to the discharge path of the gas discharge lamps, characterized in that between one phase (2) of the DC voltage source and one on the other phase ( 1) connected electrode (W ,,) of a gas discharge lamp (G, g ¹ ) and - seen in the direction of the power flow - the gas discharge lamp (G, G ¹ ) downstream of a resistor (R ,,, R _-1 ¹ ) in series with a controllable semi-conductor terventil (T ^, T. '), for example a thyristor, and the semiconductor valve (T ^, T ^') is controlled by an increasing electrical quantity (voltage, current, voltage drop) when the lamp is defective and which increases the resistance (R. , R ') and the line (3, 3') connecting the semiconductor valve (T ^, T ^ ') via a diode (D ₂ , D ₂ ') with the inverter (W) and this inverter (W) in the In the event of a current flow in the line (3, 3 ¹ ) switches off (Fig. 1-3). 2. Inverter circuit according to claim .1, characterized in that that the control electrode (gate) has a time delay element (Cj-R ^) and an electronic output HE 8192/93 9 / sa / i2 release device (D *), for example a trigger with the series resonant circuit (LK; L ¹ -K ¹ ) is connected. 3. Inverter circuit, in which the inverter has a plurality of parallel, switched outputs, at which mutually parallel gas discharge lamps are arranged, according to claim 1, characterized in that each gas discharge lamp (G, G ') is a series circuit of a resistor (R ^, R ^ ') and a controllable semiconductor valve ( ¹ Sy, ¹ H. ') is assigned and the control electrodes of all semiconductor valves (T ^ , T ^ ¹ ) are connected to one another and this common line (4-) connecting the control electrodes is via a single line electronic release device (D ₇ ) and via a single time delay element (C.-R ^) is connected to the oscillating circuits (LK; L ¹ -K ^{1 ) assigned to the individual gas discharge lamps (G, G 1} ) (Fig. 2) · 4. Inverter circuit according to one of claims Ί to 3, characterized in that each switched output of the inverter (W) has one between the series resonant circuits (LK; L ¹ -K ¹ ) of the same and the time delay element (C ^ -R ^ ) lying voltage divider (R ₂ -Rv; R ₂ '-R ₅ ¹ ) is switched on (Fig. 2). 5. Inverter circuit according to claim 4, characterized in that that each voltage divider has a rectifier diode (D ^ j, D ^ '), which the time delay element (C ^ -R ^) is connected upstream (Fig. 2). 6. Inverter circuit according to claim 4, characterized in that the voltage divider (R ₂ -R ,; R ₂ '-R, ¹ ) between inductance (L, L ¹ ) and capacitance (K, K') of the series resonant circuit is connected. 7. Inverter circuit with several gas discharge lamps connected in series according to claim 1, 2 or 6, characterized in that the series circuit of resistor (1) and semiconductor valve (T-) is connected to the phase (1) of the DC voltage source
Electrode of the last lamp in the series circuit
(L ') (Fig. 3). 831230