EP0164774B1 - Circuit device for controlling the running voltage of high-pressure gas-discharge lamps - Google Patents

Abstract

1. A circuit arrangement for adjusting the operating voltage of high-pressure gas discharge lamps to a given nominal value comprising a controllable current limiter arranged in series with the lamp and an adjustment circuit controlling the latter, whose output signal is determined by the difference between a given desired value determining the nominal lamp operating voltage and an actual value dependent upon the instantaneous lamp operating voltage, characterized in that a heating element (5) is arranged parallel to the lamp (1), this element being in thermal contact with a temperature-dependent electrical element (6 and 10, respectively), which produces the actual voltage dependent upon the instantaneous lamp operating voltage.

Description

The invention relates to a circuit arrangement for regulating the operating voltage of high-pressure gas discharge lamps to a predetermined nominal value, consisting of a controllable current limiter connected upstream of the lamp and a control circuit controlling the latter, the output signal of which is determined by the difference between a predetermined nominal value which determines the nominal lamp lamp voltage and one of those current lamp voltage dependent actual value is determined.

When operating high pressure gas discharge lamps, problems arise due to fluctuations in the lamp lamp voltage, e.g. as a result of a change in the mains voltage and a change in the lamp voltage during the life of the lamp. This can overload the lamp and thus shorten its lifespan. In the case of high-pressure sodium discharge lamps with increased sodium pressure, there is also the undesirable effect that the color properties of the lamp also change with the lamp operating voltage. Differences in the lamp burning voltage do not only occur due to the aging phenomena already mentioned in the course of the service life, but can also be caused by manufacturing tolerances. The lamp lamp voltage often increases over the course of its life; however, there may also be a decrease in the operating voltage during this time, or a combination of both.

Regulating the lamp burning voltage to a predetermined nominal value should therefore also be understood to mean that the same value of the burning voltage is set for each lamp of one type, when operated with the above circuit arrangement. This is not synonymous with power stabilization, since different power consumption of the individual lamps may be necessary due to manufacturing tolerances to achieve the same lamp operating voltage. For the same reason, it is not possible to only stabilize the lamp current.

From EP-OS 0104687 a circuit arrangement mentioned at the outset is known, in which the operating voltage of high-pressure gas discharge lamps is regulated when their instantaneous operating voltage exceeds the desired nominal operating voltage by more than 10%. A complicated and complex control circuit is used for this. If the lamp lamp voltage is lowered, however, this is not readjusted. For the known circuit, only a maximum of 1.5% change in lamp power for regulating lamp lamp voltage is permitted per volt change in lamp lamp voltage, since otherwise instabilities occur in the lamp. However, such a small change in lamp power is not sufficient for all lamp types in order to be able to compensate for changes in lamp lamp voltage in a satisfactory manner.

The invention is therefore based on the object of providing a circuit arrangement for regulating the operating voltage of high-pressure gas discharge lamps, in particular sodium vapor high-pressure gas discharge lamps, which enables precise regulation of the lamp operating voltage to a predetermined nominal value without this resulting in instabilities during lamp operation. Both burning voltages above the nominal value and burning voltages below this nominal value should be regulated.

This object is achieved in a circuit arrangement of the type mentioned at the outset according to the invention in that a heating element is connected in parallel with the lamp and is in thermal contact with a temperature-dependent electrical component which generates the actual value voltage which is dependent on the lamp lamp voltage in question.

Depending on the lamp voltage, the heating element is more or less heated. The resistive losses of the heating element R P hang according to the equation P = U _L ² / R with the lamp burning voltage U _L together and thus are an appropriate size to the internal voltage stabilization. These losses are then converted into an electrically measurable and thus electronically trackable signal by heating a temperature-dependent electrical component.

With e.g. Sudden changes in the lamp current, caused by fluctuations in the mains voltage, the thermal time constant of the lamp, i.e. the time between the likewise sudden change in the operating voltage and the subsequent running through of the output value, depending on the lamp type, between several seconds and a few minutes. For stable control behavior, it is therefore advantageous if the thermal time constant of the unit consisting of the heating element and the temperature-dependent electrical component is in the order of magnitude of the thermal time constant of the lamp.

If voltage changes with such large time constants were to be controlled electronically, high-quality and expensive capacitors and operational amplifiers would be necessary for such control circuits in order to keep leakage currents as low as possible. For this reason, a control circuit is used in the circuit arrangement according to the invention, which does not have any electronic integrators, but whose necessary control time constant is achieved by the thermal inertia of the unit consisting of the heating element and the temperature-dependent electrical component.

In a circuit-type simple embodiment of the circuit arrangement according to the invention, the actual value voltage together with the setpoint voltage becomes a difference ver amplifier system supplied, the output signal controls the controllable current limiter.

The temperature-dependent component is preferably connected in series with a further electrical component and with a voltage source and the actual value voltage is tapped at the connection point of the two components. This arrangement is simple and inexpensive to implement.

In order to make the regulation of the lamp lamp voltage independent of a change in the ambient temperature, according to a further development according to the invention the setpoint voltage is controlled as a function of the ambient temperature. Changes in the ambient temperature can also be compensated for if the further electrical component connected in series with the temperature-dependent component acted upon by the heating element is also temperature-dependent.

The temperature-dependent component can be a temperature-dependent resistor (NTC or PTC resistor), a silicon temperature sensor or a Zener diode with a temperature-dependent Zener voltage. A temperature-dependent resistor is the cheapest and most insensitive to interference. Silicon temperature sensors have less variation in the temperature characteristics than temperature-dependent resistors. The Zener diodes mentioned are even more precise than silicon temperature sensors.

• Fig. 1 eine Schaltungsanordnung zur Regelung der Brennspannung einer Hochdruckentladungslampe mit einer den der Lampe vorgeschalteten Strombegrenzer steuernden Regelschaltung,
• Fig. 2 eine bei der Schaltungsanordnung nach Fig. 1 anwendbare Regelschaltung mit einem temperaturabhängigen Widerstand und
• Fig. 3 eine bei der Schaltungsanordnung nach Fig. 1 ebenfalls anwendbare Regelschaltung mit einer Zenerdiode mit temperaturabhängiger Zenerspannung.

Some embodiments according to the invention will now be described with reference to the drawing. Show it:

• 1 shows a circuit arrangement for regulating the operating voltage of a high-pressure discharge lamp with a control circuit which controls the current limiter upstream of the lamp,
• Fig. 2 is a control circuit applicable to the circuit arrangement of Fig. 1 with a temperature-dependent resistor and
• Fig. 3 is a control circuit also applicable to the circuit arrangement according to Fig. 1 with a zener diode with temperature-dependent Zener voltage.

In the circuit arrangement according to Fig. 1, A and B are input terminals for connection to an AC voltage network of e.g. 220V, 50 Hz. A series circuit consisting of a high-pressure discharge lamp 1 and a controllable current limiter 2 is connected to these input terminals. Parallel to the lamp 1, which is in particular a high-pressure sodium discharge lamp, there is a control circuit 3 which is supplied with the lamp lamp voltage at its first input C, D and a predetermined setpoint voltage voltage which determines the nominal lamp lamp voltage and is supplied from a DC voltage source 4 at another input F, G is produced. The control circuit 3 generates a voltage at its output H when the lamp lamp voltage averaged over time deviates from its nominal value. This output voltage is then fed to the controllable current limiter 2, which reduces the lamp power when the lamp lamp voltage is above its nominal value and increases when the lamp voltage is below its nominal value, so that the lamp lamp voltage is always returned to its nominal value.

Circuits with choke coils and triacs are suitable as controllable current limiters, e.g. in U.S. Patents 4162429, 3886405 and 4037148. Electronic switching power supplies, such as forward or flyback converters, can also be used.

The control circuit 3 shown in Fig. 2 will now be described. The lamp voltage at the first input C, D is fed to a heating element 5, which is connected in parallel to the lamp 1 and is in thermal contact with a temperature-dependent resistor 6, in this case an NTC resistor. Units of this type are commercially available under the name “indirectly heated thermistor” or can be produced in a simple manner from heating resistors and NTC resistors. This arrangement has the advantage of a galvanic separation between the heating resistor 5 connected to the lamp 1 and the NTC resistor 6, as a result of which the control circuit 3 can be set to any potential, which facilitates the activation of the current limiter 2.

The time constant T, with which the NTC resistor 6 reacts to changes in the lamp voltage applied to the heating resistor 5, can be set in a simple manner between a few seconds and a few minutes by changing the thermal coupling and thus be adapted to the thermal time constant of the lamp 1.

The NTC resistor 6 is connected in series with an ohmic resistor 7 and a DC voltage source of, for example, 10 V and thus forms a voltage divider, at the connection point 8 of the two resistors 6 and 7 a voltage dependent on the actual value of the lamp lamp voltage is tapped off. This actual value voltage is then fed to the first input E, of a differential amplifier 9, while a nominal value determining the nominal lamp lamp voltage, which comes from the DC voltage source 4, is applied to its second input E2. The differential amplifier 9 need not be a single amplifier, but can also consist of a suitable combination of several amplifiers. If the lamp voltage exceeds its nominal value, there is a greater heating of the heating resistor 5 and thus of the NTC resistor 6 thermally coupled to it. As a result, its resistance decreases with the time constant T, as a result of which the voltage at the input E, the differential amplifier 9, the nominal Lamp fuel setpoint. This then leads to a change in the output voltage at the output H of the differential amplifier 9, which likewise takes place with the time constant T. This output voltage controls the current limiter 2, which in turn causes a change in power that reduces the overvoltage of the lamp 1. An analogous procedure with reversed sign results if the lamp voltage falls below its nominal value. The control circuit 3 behaves practically like an integral controller.

A disadvantage of the control circuit shown in FIG. 1 is that the voltage divider consisting of the NTC resistor 6 and the ohmic resistor 7 changes even with fluctuations in the ambient temperature, which occurs in particular in the case of ballasts integrated in a lamp base. This disadvantage can be avoided, however, if an NTC resistor whose temperature characteristic matches that of the NTC resistor 6 is also used instead of the ohmic resistor 7. If one then arranges the second NTC resistor (7) far enough from the heating resistor 5, the voltage divider ratio remains constant with changes in the ambient temperature.

Instead of the NTC resistor 6, a silicon temperature sensor (e.g. KTY 83 from Valvo) can also be used. Such silicon temperature sensors generally have less variation in temperature characteristics than NTC resistors. Since silicon temperature sensors have a positive temperature coefficient, the inputs E, and E2 of the differential amplifier would have to be exchanged in this case.

3, a series connection of an ohmic resistor 7 and a Zener diode 10 with a temperature-dependent Zener voltage is provided (e.g. TBD0135 from Thomson CSF). When the lamp voltage rises, the heating resistor 5 increases the heating of the zener diode 10, causing its zener voltage to rise. Analogously to the circuit with NTC resistors (FIG. 2), this leads to an increase in the voltage at input E, of differential amplifier 9. Furthermore, in this control circuit a setpoint voltage supplied to input E2 of the differential amplifier is provided, which depends on the ambient temperature. For this purpose, a further series circuit comprising a Zener diode 11 with a temperature-dependent Zener voltage, an ohmic resistor 12 and a DC voltage source is provided. At the connection point between the Zener diode 11 and the resistor 12, a setpoint voltage dependent on the ambient temperature is tapped. This means that when the ambient temperature changes, the voltages at the inputs E, and E2 of the differential amplifier 9 change in approximately the same way. Thus, the output signal generated at output H is almost independent of the ambient temperature, so that the regulated lamp voltage is not influenced by the ambient temperature.

Claims (9)

1. A circuit arrangement for adjusting the operating voltage of high-pressure gas discharge lamps to a given nominal value comprising a controllable current limiter arranged in series with the lamp and an adjustment circuit controlling the latter, whose output signal is determined by the difference between a given desired value determining the nominal lamp operating voltage and an actual value dependent upon the instantaneous lamp operating voltage, characterized in that a heating element (5) is arranged parallel to the lamp (1), this element being in thermal contact with a temperature-dependent electrical element (6 and 10, respectively), which produces the actual voltage dependent upon the instantaneous lamp operating voltage.

2. A circuit arrangement as claimed in Claim 1, characterized in that the thermal time constant of the unit comprising the heat element (5) and the temperature-dependent electrical element (6; 10) is of the order of the thermal time constant of the lamp (1).

3. A circuit arrangement as claimed in Claim 1 or 2, characterized in that the actual voltage is supplied together with the desired voltage to a differential amplifier (9), whose output signal controls the controllable current limiter (2).

4. A circuit arrangement as claimed in Claims 1 to 3, characterized in that the temperature-dependent element (6; 10) is connected in series with a further electrical element (7) and with a voltage source and the actual voltage is derived at the junction (8) of the two elements.

5. A circuit arrangement as claimed in any one of Claims 1 to 4, characterized in that the desired voltage is controlled in dependence upon the ambient temperature.

6. A circuit arrangement as claimed in Claim 4, characterized in that the further electrical element is also temperature-dependent.

7. A circuit arrangement as claimed in Claims 1 to 6, characterized in that the temperature-dependent element is a temperature-dependent resistor (6).

8. A circuit arrangement as claimed in Claims 1 to 6, characterized in that the temperature-dependent element is a silicon temperature sensor.

9. A circuit arrangement as claimed in Claims 1 to 6, characterized in that the temperature-dependent element is a Zener diode (10) having a temperature-dependent Zener voltage.

Images