HU208778B - Operating circuit for a high-pressure sodium or metal-halogen lamp - Google Patents

Abstract

The series circuit of a high pressure gas discharge lamp 1 and an inductive filter 2 is connected to the output of a rectifier unit 3 having its input connected to an A.C. supply, and a ballast element is also connected to the rectifier 3. The ballast element may be a capacitor (6), (Fig. 3), in series with the input of rectifier, or a resistor 4 in series with the input or the output (Fig. 2) of the rectifier. The resistor 4 may be an incandescent filament arranged in a common envelope with the lamp 1. <IMAGE>

Description

The present invention relates to a circuit arrangement for operating a high pressure sodium or metal halide lamp comprising a mains voltage, a rectifier unit, a current limiting ballast, and the high pressure sodium or metal halide lamp itself.

The circuit arrangement of the present invention offers the possibility of widespread use of low power high pressure sodium or metal halide lamps by reducing the tendency of the lamps to go out.

It is known that high-pressure sodium or sodium hydroxide with a nominal current of less than 1A. metal halide lamp types are difficult to ignite, have high re-ignition voltage peaks, and tend to go out at 50-60 Hz power supply. Therefore, there is a recent development of solutions in which these lamps, especially miniature versions, are operated by either high frequency AC or rectifiers with high frequency pulses. Such connections are described e.g. U.S. Patent Nos. 4,170,746; and SU 496,700. High frequency or high frequency. For pulsed actuation, the frequency must be appropriately selected, on the one hand, because the lamp and its actuator can cause audible interference, and, on the other hand, harmful resonances can develop in the lamp body, which can cause malfunctions. Such a high-frequency actuator is rather complicated in design, which can also adversely affect operating safety. It is also expensive.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solution which, while simpler than previously, but to a greater extent than before, reduces the high pressure sodium and / or sodium. metal halide lamps have a tendency to extinguish, which further reduces lamp size and power beyond previous limits. The object may be achieved by connecting the high-pressure sodium or metal halide lamps and the series-connected inductive filter directly to the output terminals of the mains voltage rectifier, or by applying at most a low-voltage ballast between them. Direct connection means that the lamp has filtered the rectifiers current to a minimum, thus reducing the lamp's tendency to go out.

In fact, it has been found that while the use of a non-direct current in Hg discharge lamps does not interfere with the operation of the lamp, i.e. does not cause extinction, in high-pressure Na lamps and in some cases in halogen metal lamps, the uninterruptible direct current operation. In addition, it was surprisingly realized that using the capacitive filtering in parallel with the lamp did not achieve the desired purpose, that is, sleep-free operation.

Only the inductive filter connected in series with the lamp produced stable operation.

Accordingly, the present invention provides a circuit arrangement for operating a high pressure sodium or metal halide lamp comprising a mains voltage, a rectifier unit, a current limiting ballast, a high pressure sodium or metal halide lamp, and a rectangular connected. An ac or capacitive ballast can be connected to the AC input of the rectifier unit.

The present invention also provides a circuit arrangement for operating high pressure sodium or metal halide lamps comprising a mains voltage, rectifier unit, current limiting ballast, high pressure sodium or metal halide lamp, and a rectifier and connected.

Preferably, the ohmic ballast can be a filament, which is housed in a bulb common to the high pressure sodium or metal halide lamp.

In order to improve the filtering effect, it may be desirable to place a diode parallel to the high pressure sodium or metal halide lamp and the inductive filter connected thereto, which diode is polarized in relation to the output polarity of the rectifier unit. Without the rectifier diode, the ohmic ballast will degrade the filtering effect of the inductive filter. It is therefore advisable to insert this diode into the circuit.

It is advantageous to use an ohmic ballast for limiting the lamp current, especially if a mixed lamp (incandescent lamp + discharge lamp in a common lamp) is desired, which cannot be achieved with high pressure sodium lamp in AC power supply due to the strong tendency to extinguish. In this case, the ohmic ballast is the filament, which is placed in a common bulb with the high pressure sodium or metal halide lamp. The ohmic ballast may be on the AC input side of the rectifier unit or on the DC output side. In the latter case, i.e., when the high pressure sodium or metal halide lamp, the inductive filter and the ohmic ballast are connected in series, it is preferable for a better filtering effect to have a rectifier diode arranged in the high pressure sodium or metal halide lamp parallel to the filter, with polarity in the closing direction. It is advantageous to place the ohmic ballast on the output side of the rectifier unit because in the case of a mixed-light lamp, only three connection points are required at the lamp, while in the case of an AC input side, four.

The use of a filament as an ohmic ballast has the additional advantage that such a lamp is less prone to extinction because the filament itself has a current stabilizing effect, so that the lamp is less sensitive to fluctuations in the mains voltage.

For better efficiency, capacitive ballast can be used instead of ohmic ballast. The capacitive ballast can only be connected to the AC input of the rectifier unit.

HU 208 778 Β

In order to compensate for any changes in the electrodes of the high pressure sodium or metal halide lamp due to DC power supply, it is desirable to design the electrodes asymmetrically in advance so that the cathode has a higher emitting content than the anode. The anode may not contain any emitting material. In addition, it is desirable to make the anode larger than the tub.

Summarizing the advantages of the circuit arrangement according to the invention, it can be stated that in the circuit arrangement according to the invention the sodium or metal halide lamps have a low tendency to go out due to the low current wave. This makes it possible to design and use lamps with even lower wattage than usual. In addition, higher power types can be operated with less light waveguide, it is possible to create mixed-light sodium or metal halide lamps, where the ballast can be implemented in the form of a filament very easily, the wavelength of the inductive filter is minimized, no high frequency interference. In addition to all these advantages, the solution is significantly simpler and less expensive than high frequency.

The invention will now be described in more detail with reference to the drawings, with reference to exemplary embodiments.

Figure 1: An exemplary embodiment of the arrangement of the present invention wherein an ohmic ballast is provided on the AC input side of the rectifier unit.

Figure 2: An exemplary embodiment of the arrangement of the present invention wherein the rectifier unit is directly connected to the mains and the ohmic ballast is disposed on the output side of the rectifier unit between the high pressure sodium or metal halide lamp and the output side of the rectifier unit.

Figure 3: An exemplary embodiment of the arrangement of the present invention wherein a capacitive ballast is provided on the AC input side of the rectifier unit.

1 shows a circuit arrangement comprising 1 high pressure sodium lamp. The 220 V, 50 Hz mains voltage is connected to the input points c and d of a two-way rectifier unit, Graetz-switched, by inserting a 4 ohm ballast between points a and c. The 4 ohm ballast is implemented with a 220-230 V and 100 W rated incandescent lamp. The rectifier unit 3 is connected to the DC output terminals e and f of the high pressure sodium or metal halide lamp 1 and inductive filter 2 in series, i.e. one terminal to the DC output terminal (e) of the rectifier unit 3 and the other terminal to a high pressure connected. 2 inductive filters are scaled to 1.2 H inductance. The total power consumption of the circuit arrangement is 60 W.

In the embodiment of FIG. 2, rectifier units 3 inputs c and d are directly connected to points a and b of the 220 V, 50 Hz network. One terminal of the 4 ohm ballast made of a filament lamp is connected to this output point of the DC output side of the rectifier unit, while the other terminal is connected to the current lead 9 of the high pressure sodium or metal halide lamp 1. The current inlet h of the high pressure sodium or metal halide lamp 1 is connected to one end of an inductive filter 2 and the inductive filter 2 is connected to the output point f of the DC output of the rectifier unit. In this way, a 4 ohm ballast, 1 high pressure sodium or metal halide lamp and 2 inductive filters were connected in series in the DC circuit. To increase the filtering effect, 1 high-pressure sodium or metal halide lamp and 2 inductive filters are connected in parallel with 5 rectifying diodes. The rectifier diode 5 is installed so that it has a closing polarity relative to the polarity of the rectifier output point f of the rectifier unit. A 4 ohm ballast and 1 high pressure sodium or metal halide lamp are housed in a common outer bulb, similar to mixed-light lamps.

Fig. 3 illustrates a switching arrangement in which the current limitation is performed by a capacitive ballast 6 on the alternating current side of the rectifier unit, i.e. one terminal of the capacitive ballast 6 is connected to a point of the AC mains and the other terminal is connected to input c of the rectifier. The circuit is further identical to the arrangement of FIG. 6 capacitive ballasts to 5.6 pF and 2 inductive filters

Scaled to 1.2H. The power consumption of such a circuit arrangement is approx. 20-30 W depending on the size of the high pressure sodium or metal halide lamp.

In our examples, of course, either a separate igniter or an internal ignition aid (such as a Penning mixture) must be used.

Claims (5)

PATENT CLAIMS A circuit arrangement for operating a high-pressure sodium or metal halide lamp in which a current limiting element (a) is connected to one point of the AC mains, the other terminal of which is connected to an AC input (c) of a rectifier unit (3) is connected to the other AC input (d) of the rectifier unit (3) and the sodium or metal halide lamp (1) is connected to the output points (e, f) of the rectifier unit (3), characterized in that the high pressure sodium or metal halide lamp 1) it is connected to the output points (e, f) of the rectifier unit (3) through a series of inductive filters (2). Circuit arrangement according to claim 1, characterized in that an ohmic ballast (4) is inserted between one of the alternating current inputs (c) of the rectifier unit and one of the points (a) of the alternating current network. HU 208 778 Β A circuit arrangement according to claim 1, characterized in that a capacitive ballast (6) is inserted between one of the alternating current inputs (c) of the rectifier unit and one of the points (a) of the alternating current network. 4. Circuit arrangement for operating a high pressure sodium or metal halide lamp, in which the AC input points (a, b) of the rectifier unit (3) are connected to the ac power supply connection points, the DC output points (e, f) of the rectifier unit (3) are connected. - either two current inputs (g, h) of a metal halide lamp (1) with a series of ohmic ballasts (4), characterized in that one of the current (g) of the high pressure sodium or metal halide lamp (1) is connected through a series ohmic ballast (4). (3) is connected to one DC output point (e) and the other current input (h) of the high pressure sodium or metal halide lamp (1) is connected to the other DC output point (f) of the rectifier unit (2) via a series connected inductive filter (2); one of the current feeders (g) of a high pressure sodium or metal halide lamp (1) and a rectifier diode (5) is inserted between the DC output point (f) of the rectifier unit (3) and the polarity of the output point (f) of the rectifier unit in closing polarity. Circuit arrangement according to claim 2 or 4, characterized in that the ohmic ballast (4) is a filament which is housed in a bulb common to the high-pressure sodium or metal halide lamp (1).