FR2502443A1 - Supply circuit for high pressure mercury vapour discharge lamp - uses small capacitor connected across ballast to lower extinguishing voltage threshold - Google Patents

Abstract

The connector is used for high pressure mercury vapour discharge lamps and has a supply circuit comprising a capacitor (C1) in parallel with the mains supply and a ballast choke (L1) in series with the tube, is characterised by having a second low value capacitor (C2) connected in parallel with the ballast. The second capacitor has a capacitance between 0.016pF and 0.020pF and for a 50Hz supply frequency its value is obtained from the relation L1C2 lies between 0.9 and 1.1 where L1 is the ballast inductance in Henries. The second capacitor lowers the extinguishing voltage threshold, allowing lower wattage running of the lamp.

Description

 The present invention relates to the supply of tubes or high-pressure discharge lamps, and in particular the supply of mercury vapor tubes.

 It is conventional to supply such tubes, from the AC mains, with a capacitor in parallel on the conductors of said network, followed, in series on the tube side, by an inductance-ballast. This capacitor and ballast assembly is often referred to as a power stage.

 High-pressure discharge tubes are currently widely used in the field of public lighting. The current trend towards energy saving is that lighting can be modulated. The easiest way to do this is to act on the AC supply voltage. Unfortunately, the high-pressure discharge tubes go out when the value of the supply voltage available at the moment when the lamp reboots decreases to a value approximately equal to the instantaneous maximum value of the arc voltage, or boot voltage. For mercury lamps, extinguishing occurs as soon as the power reduction reaches 23 to 28%.

 The present invention provides simple means, which substantially improve the situation and allow a power reduction of 50% without changing the existing standard plates.

 According to the invention, a capacitor is added across the inductance-ballast. It has indeed been noted that under certain conditions, it was then possible to substantially reduce the supply voltage of the plates below the instantaneous maximum value of the arc voltage without thereby causing the extinction of the voltage. lamp.

 It has thus been found that under certain conditions, the presence of this capacitor causes an increase in the voltage available for the lamp to be rebooted.

 It seems that this effect is due to the fact that the capacitor placed in parallel with the inductance-ballast tends to delay at each alternation the inversion of the voltage at the terminals of the lamp, and consequently, tends to increase the voltage available for the rebooting of this, since the ignition always occurs in the ascending part of the sinusoid representative of the supply voltage and the value of the voltage available at the terminals of the lamp is increased as a function of the delay which tends to be introduced by the discharge of the capacity.

As a general rule and in the field of usual powers, the capacity of the capacitor can be defined by the relation: 0.9 <L1C2 (1,1 (this relation being verified for a frequency of 50 Hz) "'ai" being the inductance of the ballast expressed in henry being the capacity expressed in microFarads.Although, if the value of the mains frequency is different from 50 Hz, the range indicated above is naturally modified as a consequence the impedance of an inductance s' writing Lw, and the impedance of a capacity 1 / Cw with ', = 2'v <F, where F is the frequency of the electrical network
According to another aspect of the invention, in the case of platinums for high-pressure mercury lamps, it is more directly possible to determine the capacity of said capacitor by the relation 0.016 P (C2 <0.020 P "C2" being the capacity expressed in microFarads "P" being the nominal power of the lamp expressed in watts.

Other features and advantages of the invention will appear on reading the detailed description which follows and with reference to the appended drawings, given to illustrate a non-limitative embodiment of a preferred embodiment of the present invention, and on which
- Figure 1 illustrates a conventional plate, directly feeding a discharge tube;
FIG. 1A illustrates waveforms recorded in the circuit of FIG.
- Figure 2 illustrates a plate feeding a discharge tube, a second capacitor being in parallel on the ballast.

In accordance with the present invention, FIGS. 2A and 2B illustrate waveforms taken from the circuit of FIG.
In FIGS. 1 and 2, the plate itself has, in parallel with the conductors supplying the supply voltage, a capacitor C1 whose value is for example 16 microFarads for a tube of nominal power of 250 Watts; then, in series on the tube side, an inductance-ballast, whose value is for example 260 MilliHenrys under the same conditions.

According to the arrangement of FIG. 1, the plate is connected directly to the terminals of the discharge tube TD. This arrangement works well with the ordinary power supply voltage, whose effective value is 220 volts, which corresponds substantially to a peak value of 310 volts. Figure 1A shows the sinusoidale power supply voltage, denoted by the reference UA.On the same graph is carried the voltage across the lamp
TD, rated VA1. The operation of the tube is the following at each alternation, as soon as the voltage UA reaches a sufficient value, the tube begins to drive, and the voltage VA1 at its terminals goes up very rapidly to a value which is here of the order 160 V, then it drops quickly to 140 V and then slowly decreases to 90 V to reverse quickly to the next alternation of the voltage UA when it reaches a sufficient amplitude in the opposite direction. This FIG. 1A thus illustrates the operation of the conventional discharge, with a conventional stage, for an effective supply voltage of -220 Volts. If the supply voltage is progressively reduced, the lamp goes out when this last reaches an effective value of about 185 V; it would be necessary to reach 165 V (peak value of 234 V) to obtain a power reduction of 50% of the platinum supply.

 It appears that the supply voltage, instantaneous value, no longer takes, relative to the arc voltage of the tube, a sufficient value to ensure correct rebooting of the latter after each alternation.

In the assembly of FIG. 2, a second capacitor C2 whose value is, for example, 4.5 microFarads, for a high-pressure mercury lamp of a power, is added in parallel with the platinum inductor-ballast. nominal value of 250 W. Figure 2A illustrates the operation of the circuit of Figure 2, at the rated supply voltage, which is 220 volts rms, for 310 volts peak value. It appears in FIG. 2A that the presence of the capacitor slightly raises the resetting voltage of the tube at each alternation up to a value of approximately 190 volts (curve
VA2 of Figure 2A).

 The applicant has performed tests with the circuit of FIG. 2, by lowering the supply voltage to 170 volts rms or 240 volts rms. It is then observed that the voltage at the terminals of the lamp VD2 (FIG. 2B) reaches, at the moment of ignition of the lamp, a value of 250 volts. This value allows a convenient and stable operation of the tubes, even with such a reduced supply voltage.

 It is, moreover, important to note that with a capacitance of the capacitor C2 responding to the above-mentioned range, and preferably of a value of 4.5 F, in the case of a high pressure vapor lamp of mercury with a nominal power of 250 Watts, the power absorbed is practically not modified, only the current absorbed by the power stage is slightly increased. The increase observed is approximately equal to 0.1 Ampere in the case of the high-pressure mercury lamp with a nominal power of 250 W.

 Of course, the example which has just been described is capable of numerous variants, taking into account the values of the components of the plate itself (L1, C1), as well as the power of the mercury vapor tubes which is used , and other parameters that come into play.

 The Applicant currently prefers the following combinations which mainly account for the nominal power of mercury vapor tubes, and are given in order of rated power, capacity of capacitor C2: 125 Watts 2 MicroFarads 250 Watts 4.5 MicroFarads 400 Watts 6 , 5 Microfarads.

 Of course, the present invention is not limited to the embodiment described and extends to any variant within his mind.

Claims (3)

 1. Power supply assembly for a high-pressure discharge tube, in particular for a mercury vapor tube, of the type comprising a supply stage which comprises in parallel on the conductors of the electrical network a capacitor, then, in series on the tube side, a inductance-ballast, characterized in that it comprises, in parallel on the inductance-ballast (L1), a second capacitor (C2), of low value.  2. Assembly according to claim 1, characterized in that the capacitance of the second capacitor (C2) expressed in microFarads is defined by the relation 0.016 P4C240.020 P where P is the nominal power of the tube expressed in Watts.  3. Assembly according to claim 1, characterized in that the capacity of the second capacitor (C2) expressed in microFarads is defined at a frequency of 50 Hz by the relation 0.9 4'a1c2 i, i where "L1" is the impedance of the ballast expressed in Henry.