DE2522649C3 - High pressure metal halide lamp - Google Patents

Description

The invention relates to a high-pressure metal vapor lamp with a base and a base attached to it Pair of leads that are sealed inserted into the piston and connected to the base, further with a discharge tube with sealed inserted electrodes and a filling of a vaporizable Metal and an inert ignition gas, with the discharge tube mounted inside the bulb, and with a capacitive ignition aid made of a metal part that lies against the wall of the discharge tube is electrically connected to an electrode.

The lamp of the aforementioned type described in DT-OS 21 10 555 has the task with a relatively short external auxiliary electrode and without one that complicates the lamp Bimetal switching element to generate a relatively low ignition voltage. This task is carried out according to the DT-OS 21 10 555 solved in that the entire auxiliary electrode is at a point 1 to 3 cm from the other main electrode is removed. This auxiliary electrode arrangement According to the DT-OS mentioned, it has the advantage that little light is intercepted by it and that the ignition voltage of the lamp is relatively low, but it is with regard to the Evaporation at operating temperatures higher than 500 ° C and arranged free from the discharge tube this does not allow an optimal reduction in the ignition voltage.

The DT-OS 22 61 233 is based on the task of providing a way to start an arc discharge in To make lamps such as high-pressure sodium vapor lamps available where the demands on the Ignition voltage are significantly reduced and the speed and reliability of the ignition process is increased to allow use with the cheap ballasts previously available, in particular existing sockets that are already equipped with ballasts for the high pressure mercury vapor lamps comparable performance, even at low temperatures and supply voltages, under the normal value can be used. According to DT-OS 22 61 233, this task is thereby achieved solved that an electrical conductor over a

ίο larger part of the length of the arc discharge space extends and is capacitively coupled to this and the connections from which the electrodes voltage is supplied, have a connection for this conductor. The conductor is preferably coiled Form placed around the discharge tube and supported in contact with this, over the largest part same or preferably over practically the entire length of the arc discharge space between the Electrodes. This arrangement may have the advantage of reducing the ignition voltage, but it allows because of the direct contact between the conductor and the discharge tube, they do not have high operating temperatures the lamp.

In contrast, the present invention was based on the object of not only applying the ignition voltage reduce, but also to allow a high operating temperature of the lamp.

This object is achieved in a lamp of the type mentioned in that the metal part from is made of a thermally deformable metal and has one end that tapers at room temperature the wall of the discharge tube rests in order to facilitate the ignition by capacitive effect, and that stands out from the discharge tube when it is heated during operation of the lamp.

This embodiment of the capacitive ignition aid allows both an effective reduction of the Ignition voltage by about 50% as well as a high operating temperature of the lamp without overheating the Ignition aid and the advantages listed below.

DT-OS 24 61 568 relates to a vapor discharge lamp with an ignition electrode that is attached to the outer wall of the discharge tube is attached in the vicinity of the one discharge electrode. To an escape from To avoid sodium ions from the discharge tube and thus its blackening, is after To ignite the lamp, a bimetal switch is opened in such a way that the ignition electrode with respect to the other Electrode by an element on which two electrodes are opposite and at a distance from each other attached, electrically floating or at free potential.

It is also known that easier ignition of a discharge lamp is achieved by the "Penning" effect which requires an ignition gas mixture that contains main components and minor components. Such Penning mixtures are commonly used in mercury vapor lamps, fluorescent lamps and

<< o Low pressure sodium lamps used. A suitable Penning mixture for a high pressure sodium lamp is a mixture of neon and 1% argon. With such an ignition filling, an ignition aid is then in the form an internal auxiliary ignition electrode, as used in high-

⁽ 's high-pressure mercury vapor lamps or a conductive strip applied to the outside of the lamp envelope by a paint process, such as was used for fluorescent lamps in

highly conducive to a further reduction in the ignition voltage. The closure parts or end caps, which are used in ceramic lamp envelopes, however, do not allow easy attachment of auxiliary ignition electrodes. The very high temperatures of such ceramic pistons can also Problems include when applying or attaching conductors on the outside.

These problems are also solved by the capacitive ignition aid according to the invention, which has a Heat deformable conductor complies, which in the cold state on the outside of the discharge tube is applied and is lifted off when hot.

In a preferred embodiment, the ignition aid comprises a pair of thermally activated deformable bimetallic arms whose ends enclose the discharge tube at room temperature and in this way produce a capacitive effect. After the lamp is ignited and at its normal The operating temperature has been heated up, the bimetallic arms pivot from the discharge tube to the Reduce impairment of the Lichi radiation and overheating of the wall of the discharge tube impede.

Embodiments of the invention are shown in the drawing and will be described in more detail below described. In detail shows:

1 shows a side view of a high-pressure sodium vapor lamp,

Fig.2a and 2b a plan view in section and a End view of the capacitive ignition aid in the closed position,

F i g. 3a and 3b corresponding views of the capacitive ignition aid in the open position and

4 shows a plan view of a structural modification the capacitive ignition aid.

Fig. I shows a high pressure sodium vapor lamp. The lamp has a load capacity of approx 150 watts and therefore has a relatively small dimension, which is particularly easy to ignite is desired. The lamp 1 comprises an outer bulb 2 made of glass, on whose neck part a standard screw base is appropriate. The outer bulb also contains an inverted piston stem 4, through which in the usual Way lead a pair of relatively strong leads 5 and 6, the outer ends of which with the threaded sleeve 7 and are connected to the center contact 8 of the base.

The discharge tube 9 is arranged centrally in the interior of the outer bulb 2 and comprises a elongated piece of a tube made of polycrystalline aluminum oxide. At the ends of the tube are using a glass-like sealing compound sealed end closures attached, which are made of metal caps JO and 11 Niobium is made up of approximately the same coefficient of thermal expansion as the ceramic material Aluniiniumoxide possesses. Through the end cap 10 is a Metal tube 12 sealed out, which during the manufacture of the lamp as a suction and filling tube serves. The suction tube is closed at its outer end and serves as a storage container in which excess sodium amalgam condenses during lamp operation. The lamp shown is intended for operation with the base at the bottom. The electrode 13 inside the lamp is on attached to the inwardly protruding part of the suction tube 12. The other electrode 15 is from a unused suction tube 14, which is guided through the metallic end cap 11, is held.

The suction pipe 12 is connected to the supply line 6 by a connecting part 16 and a short holding rod 17 connected, whereby the circuit connection from a base connection to the electrode 13 is made The suction tube 14 that is not in use extends through a ring holder 18 which is attached to a holding rod 19 is attached, which causes a fixation against lateral movement and at the same time an axial expansion of the discharge tube. A flexible metal band 20 connects the unused suction tube 14 with the holding rod 19. This is welded to the supply line 5 and thereby becomes the continuous Circuit connection established from the other base connection to the electrode 15 That turned away from the base The end of the holding rod 19 is connected to a chamber 22 which engages with an inverted part (Nipple) 21 is at the dome-side end of the piston 2.

It has been found that a lamp according to

Representation in Fig. 1 with an ignition gas made of neon 1% argon has an ignition voltage of around 300 volts effectively if there is no capacitive ignition aid A capacitive Zündhiife 23 consists of a forked strip of bimetal, which is around the Support rod 19 is coiled and spot welded on opposite sides at 24 and 25 of the ends of the bimetal are curved at 26 and 27 to form a tight enclosure around the discharge tube 9 in order to this way to get a good capacitive coupling to the same. The bimetal strip consists of a commercially available material in which the low expansion part is a nickel-iron alloy and the large expansion part is a nickel-chromium-steel alloy. A dimensioning of the Bimetal strip material with a thickness of about

U 0.13 mm and a width of about 3.8 mm is for this suitable. The F i g. 2a and 2b show the ignition aid in the rest position at room temperature, with the bimetallic arms include the discharge tube. The F i g. 3a and 3b show the ignition aid in the open state Operating temperature, in which case the arms are swung out and lifted off the discharge tube, as indicated at 26 'and 27'.

The ignition aid shown reduces the ignition voltage from around 300 volts to less than 180 volts. The ignition aid is at the potential of the electrode 15 and possibly works by that it acts as a capacitor in combination with the closer electrode 13. A charging current flows from the ignition aid through the wall of the discharge tube to the closer electrode and thereby supports the ignition of the lamp. The size of the charging current depends on the area the ignition aid, which is in close proximity to the wall of the discharge tube, and therefore it is required that the bimetallic strip has a noticeable width and the discharge tube tightly fitting includes.

When the arms of the ignition aid lift off the discharge tube, the blockage of the

ho light is reduced to a small fraction of the value that occurs with hugging arms, and it In this case, of course, harmful overheating of the bimetal material is also avoided. Farther a reaction between the ignition aid and the

<> ■ ·. Wall of the discharge tube avoided. Also will avoiding the thermal etching of the wall of the discharge tube that can occur when the at the Ignition aid reflected energy the temperature of the

Discharge tube raises so much that an increased evaporation of the ceramic material is caused. Overheating of the discharge tube wall can also occur as a result of the discharge being deflected in Direction of the wall due to the capacitive effect of the ignition aid. However, this phenomenon will also avoided when the arms pivot away from the discharge tube.

The F i g. Figure 4 shows another capacitive ignition aid 30. It comprises a forked and inwardly curved one Strip of bimetal, which is wrapped around the support rod 19 and on opposite sides at 31 and 32 on the same is spot welded. The arms of the strip are bent back on themselves at 33,34 and directed at the pipe 9. The ends are curved at 35, 36 so that they fit snugly on the discharge tube create and thereby a good capacitive coupling to the same is achieved. This structure allows one stronger cranking of the ends 35,36 than the structure according to FIGS. 2 and 3. Furthermore, thicker bimetal strip material be used, for example a material with a thickness of about 0.25 mm, the one less deflection for a given temperature change than the thinner material with a thickness of about 0.13 mm, as shown in the arrangement according to FIG. 2 and 3 was used.

Above, the capacitive ignition aid with a working plane transverse to the axis of the discharge tube; shown. However, this is not absolutely necessary and the arms can also be arranged so that they move in a plane containing the axis of the discharge tube, or below any other hints! to lie at the same.

1 sheet of drawings

Claims (2)

Patent claims: 1. High pressure metal halide lamp with a Outer bulb, a base attached to it and a pair of supply lines that are sealed into the Piston inserted and connected to the base, further sealed with a discharge tube introduced electrodes and a filling made of a vaporizable metal and an inert Ignition gas with the discharge tube mounted inside the bulb and with one on the wall of the Discharge tube adjacent capacitive ignition aid made of a metal part that is electrically connected to a Electrode is connected, characterized that the metal part (23) is made of thermally deformable metal and one end has, which rests against the wall of the discharge tube (9) at room temperature in order to ignite to facilitate capacitive action, and that when the lamp (1) is heated during operation of the Discharge tube (9) lifts off. 2. High-pressure metal vapor lamp according to claim I, characterized in that the ignition aid (23,30) a pair of arms made from a bimetal strip comprises, which are attached to the holding rod (19) of the discharge tube (9), the ends of the arms (26, 27, 35, 36) encompass the discharge tube (9) at room temperature and im heated state are swiveled away from the same.