NL9000202A - Circuit arrangement for low-pressure discharge lamp - adjusts amplitude averaged over modulation period of sinusoidal modulated high-frequency current - Google Patents

Abstract

Circuitry generates the high-frequency pulsatory current from a supply voltage. A modulator is provided for the sinusoidal amplitude modulation of the high-frequency pulsatory current with a modulation frequency f and a modulation depth M. Circuitry adjusts an amplitude A averaged over a modulation period of the sinusoidal modulated high-frequency pulsatory current. The circuit arrangement is also provided with circuitry V for effecting a change in the sinusoidal modulation.

Description

N.V. Philips' Incandescent lamp factories in Eindhoven.

"Switching device"

The invention relates to a switching device suitable for operating a low-pressure mercury discharge lamp with the aid of a high-frequency pulse-shaped current, comprising - switching means for generating a high-voltage pulse-shaped current from a supply voltage, - a modulator for substantially sinusoidal amplitude modulation of the high-frequency pulse-shaped current with a modulation frequency and a modulation depth M, and - switching means for adjusting an amplitude A of the substantially sinusoidally modulated high-frequency pulse-shaped current over a modulation period.

A switching device as described in the preamble is known from German Patent Application 2,335,589 laid open to public inspection.

Modulation depth M is understood to mean the ratio between the amplitude A'of the substantially sinusoidal modulation and the corresponding modulation period mean amplitude A of the high-frequency pulse-shaped current.

In the known switching device the luminous flux of the lamp can be adjusted by adjusting the amplitude A of the substantially sinusoidally modulated high-frequency pulse-shaped current.

With the lamp thus operated, striations in the lamp are effectively suppressed, even when the luminous flux of the lamp is relatively small.

However, changing the amplitude A does not only affect the luminous flux, but also the color point of the light emitted by the lamp, which is perceived as a nuisance in many applications.

The object of the invention is to provide a switching device with which the color point of the light emitted by the lamp is highly independent of the luminous flux of the lamp.

According to the invention, a switching device as described in the preamble is characterized in that the switching device is further provided with switching means for adjusting demodulation depth M.

It has been found that the color point of the light emitted by the lamp by adjusting both the depth of modulation and the amplitude A is substantially independent of the magnitude of the luminous flux.

A further advantage of the inventive measure is that the color point of the light emitted by the lamp at a selected luminous flux is adjustable over a wide range by adjusting the modulation depth H and the amplitude A.

In an advantageous embodiment of a switching device according to the invention, the switching device is provided with a circuit for adjusting the modulation frequency f of the substantially sinusoidally modulated high-frequency pulse-shaped current. This makes it possible to set the modulation frequency of the substantially sinusoidally modulated high-frequency pulse-shaped current in addition to the amplitude A and the modulation depth M at a selected magnitude of the luminous flux of the lamp. This increases the range over which the color point is adjustable at a selected magnitude of the luminous flux of the lamp.

The substantially sinusoidally modulated low-frequency pulse current can be both unipolar and bipolar. In the first case it is often desirable to commutate the current through the lamp at a low frequency.

A switching device according to the invention is suitable for operating low-pressure mercury discharge lamps of various types, such as, for example, compact low-pressure mercury discharge lamps, conventional tubular low-pressure mercury discharge lamps and electrode-free low-pressure mercury discharge lamps.

The invention will be explained in more detail with reference to a drawing of an exemplary embodiment.

In the drawing shows

Figure 1 shows a schematic representation of the construction of an embodiment of a switching device according to the invention and a lamp to be operated therewith;

Figure 2 shows the shape of a lamp current of a lamp operated on the switching device according to Figure 1, and

Figure 3 shows color points of the lamp operated with the switching device of figure 1, for different magnitudes of the luminous flux.

The structure of the switching device according to the invention shown in Figure 1 is as follows.

P and Q are terminals, suitable for connection to a power supply source. I forms a current source which generates a high-frequency pulse-shaped current from the supply voltage. An output of the current source I is connected to an input of modulatorII, which modulates almost sinusoidally with an modulation frequency f and a modulation depth M an amplitude of the high-frequency pulse-shaped current. An output of modulator II is connected to an input of switching device III, with which an average amplitude A of the substantially sinusoidally modulated current is adjustable over a modulation period. A low-pressure mercury discharge lamp IV is connected between an output of the switching device III and an earth terminal.

V and VI are a switching device for adjusting the modulation depth M and a switching device for adjusting the modulation frequency f, respectively. An output of the switching device V for adjusting the modulation depth M is connected to an input of modulator II and also an output of the switching device VI for adjusting the modulation frequency f is connected to a further input of modulator II.

The lamp current through the lamp IV as a function of time is shown in Figure 2. Dimension time is plotted along a horizontal axis and dimension current is plotted along a vertical axis. S is a substantially sinusoidally modulated high-frequency pulse-shaped current. A is an average amplitude of the high-frequency pulse-shaped current S over a modulation period. A 'is an amplitude of the substantially sinusoidal modulation of the high-frequency pulse-shaped current S. The modulation depth M is defined as A' / A. C is a period of near sinusoidal modulation. The period C is related to the modulation frequency f together according to the relationship C = 1 / f.

Figure 3 shows different color point settings and different magnitudes of the luminous flux and different modulation depths M.

Figure 3 shows part of the color triangle, in which four curves R, S, T and V indicate a variation of a color point of the lamp, being in this case a compact low-pressure mercury lamp, when the luminous flux of the lamp is changed at a constant demodulation depth . The modulation depth used was 0, 20, 50 and 100% for curves R, S, T and V. In points 1 to 8 of each curve, the luminous flux of the lamp was 600, 540, 480, 420, 360, 300 respectively , 240 and 180 lumens. A repetition frequency of the high-frequency pulse-shaped current was 50 kHz, and the modulation frequency f was 8 kHz.

The location of the curves in Figure 3 shows that, when changing the luminous flux of the lamp in addition to the amplitude A, the modulation depth M of the substantially sinusoidally modulated high-frequency pulse-shaped current with which the lamp is operated is set, the location of the color point is largely independent of the magnitude of the luminous flux.

For example, assuming the lamp operation indicated by point 1 of curve R, the luminous flux of the lamp with constant modulation depth is reduced from 600 lumens to 360 lumens by setting the amplitude A to a different value, the color point shifts to point 5 of curve R, which means a significant shift.

However, if, in addition to setting the amplitude A, the modulation depth M is changed from 0% to 100%, no measurable shift of the color point occurs: point 1 of curve R falls together with point 5 of curve V.

In addition, the scattered location of points with an identical luminous flux in Figure 3 illustrates that the color point of the light emitted by the lamp at a selected luminous flux is adjustable over a wide range by adjusting the modulation depth M and the amplitude A.

The rated power of the compact low-pressure mercury lamp used was 9 watts. The lamp vessel was tubular with an internal diameter of about 10 mm. Argon was charged into the lamp vessel with a filling pressure of 4 mBar (at 300 K) and an amount of mercury. A luminescent layer was applied to the wall of the lamp vessel, comprising a mixture of red luminescent Eu (3+) activated yttrium oxide and green luminescent Tb (3+) activated cerium magnesium aluminate. The results obtained in Table I and Table II were obtained with the same lamp.

Table I shows the variation of the color point of the lamp in case not only the amplitude A and the modulation depth H are set during the dimming of the lamp, but also the demodulation frequency f. The effective lamp current is shown in Table I as a measure of the amplitude A. It can be seen that in this way it is possible to make the color point of the light emitted by the lamp to a considerable extent independent of the luminous flux.

Table II illustrates for three different luminous flux sizes that it is possible, by setting the amplitude A, demodulation frequency f and the modulation depth M, for a given range of luminous flux to adjust the color point of the light emitted by the lamp over a wide range . Also in Table II the effective value of the lamp current as a measure of the amplitude A is indicated. The repetition frequency of the high-frequency pulse-shaped current S was 50 kHz.

TABLE I

TABLE II

f- i

Claims (2)

Switching device suitable for operating a low-pressure mercury discharge lamp by means of a high-frequency pulse-shaped current, comprising - switching means for generating a supply voltage of the high-frequency pulse-shaped current, - a modulator for the substantially sinusoidal amplitude modulation of the high-frequency pulse-shaped current with a modulation frequency and a modulation depth M, and - switching means for adjusting an amplitude A of the substantially sinusoidally modulated high-frequency pulse-shaped current over a modulation period average, characterized in that the switching device is further provided with - switching means for adjusting the modulation depth M. Switching device according to claim 1, characterized in that the switching device is provided with switching means for adjusting the modulation frequency f of the substantially sinusoidally modulated current.