EP0446462A2 - High-pressure discharge lamp - Google Patents

Abstract

In high-pressure discharge lamps, especially in halogen metal-vapour discharge lamps with a sodium or lithium additive in the filling, an undesired ion migration occurs which leads to a change in the filling constitution and reduces the lamp life. External electrical fields promote this ion migration. In order to screen their electrical fields, the power supply lines (12, 13) running in the immediate vicinity of the discharge vessel (4) are provided with an electrically insulating sleeve (14) which consists of a material having a high dielectric constant. …<IMAGE>…

Description

The invention relates to a high-pressure discharge lamp according to the preamble of protection claim 1.

GB-PS 1 233 955 discusses the problem that, in the case of high-pressure discharge lamps which have metal-containing filler additives, positive metal ions are generated in the discharge vessel during operation and can diffuse through the wall of the discharge vessel. If current-carrying parts run in the vicinity of the discharge vessel, their electrical fields greatly promote ion migration. In addition, photoelectrons are released from these electrical conductors by the UV radiation generated during the discharge, which drift towards the wall of the discharge vessel and also promote ion migration. The diffusion process leads to losses in the metal-containing additives and thus to a change in the filling composition, which manifests itself in an unstable burning behavior of the high-pressure discharge lamp.

This ion migration occurs in particular in high-pressure discharge lamps with a discharge vessel made of quartz glass and metal halide additives in the filling, in which metal ions with a small ion radius, such as sodium ions, are formed under discharge conditions. Diffuse during operation of the lamp, favored by external electrical fields, positively charged sodium ions through the wall of the discharge vessel, so that an excess of iodine remains in it. Due to the electronegative behavior of the excess iodine, there are also difficulties in the ignition of the high-pressure discharge lamp and an increase in the operating voltage.

In order to eliminate these problems, the use of a shielding electrode is proposed in GB-PS 1 223 955, whereby another problem arises here, namely that electrical breakdowns can occur between the shielding electrode and the current supply running parallel to it. In order to avoid this problem, it is therefore proposed in the high-pressure discharge lamp in GB-PS 1 223 955 to fill the outer bulb with an inert gas, which may have electronegative additives to reduce the mean free path of the photoelectrons.

This construction has three serious disadvantages: It has been shown that electrical breakdowns between the shielding wire and the power supply running in parallel cannot be prevented to the desired extent. In addition, the gas filling in the outer bulb significantly deteriorates the thermal insulation of the discharge vessel. Finally, the shielding wire is inevitably designed to be self-supporting, so that there is a risk that it will hit the power supply or the discharge vessel in the event of vibrations and the lamp will be damaged.

Furthermore, DE-OS 37 35 523 discloses a high-pressure discharge lamp with a base on one side and an outer bulb and a two-ended arrangement axially arranged therein Discharge vessel is known, the current supply leading to the base-free end of the discharge vessel has a casing made of an insulating material (eg glass). A shielding electrode is not provided here. This sheath does not shield the electrical field of this power supply from the ions in the gas discharge, so that here too the ion migration is reduced but is not prevented to the desired extent.

The invention has for its object to provide a high-pressure discharge lamp with reduced ion migration, which has a satisfactory ignition behavior and a sufficiently constant operating voltage over the service life.

This object is achieved by the characterizing features of claim 1. Particularly advantageous designs can be found in the dependent claims.

The following advantages are achieved with the invention: Because the sheaths consist of an electrically insulating material, preferably with high dielectric constants, the influence of the electrical fields of the shielding wire and the second power supply, which is favorable for the ion migration, occurs in the immediate vicinity of the discharge vessel are reduced.

The GB-PS 1 223 955 shows a wrong way in comparison, since it tries to solve the problems described above by a combination of different effects to solve, but which lead to serious disadvantages in lamp operation.

The sheaths of the shielding wire and the second power supply also prevent photoelectrons from negatively charging the discharge vessel wall, on the one hand by weakening the UV radiation, which contributes significantly to the photoeffect, and on the other hand, they are impermeable to photoelectrons, so that these are finally directed back onto the electrical conductor and from be dissipated. The present invention offers the particularly advantageous possibility of dispensing with a filling gas in the outer bulb, which would reduce the mean free path of the photoelectrons but would impair the thermal insulation of the discharge vessel. A common sheath for the shielding wire and the second power supply allows a space-saving spatial arrangement of these parts without electrical breakdowns occurring between them. In addition, this design of the sheathing ensures mechanical stabilization of the shielding wire. High-pressure discharge lamps according to the invention show a more stable burning behavior and a longer service life than conventional high-pressure discharge lamps. The discharge vessel can consist of quartz glass or a translucent ceramic.

The invention can be used particularly advantageously in the case of high-pressure discharge lamps which have fillings which, during operation, give rise to alkali ions, especially Na and / or Li ions.

Figur 1

zeigt eine Seitenansicht eines ersten Ausführungsbeispiels einer Hochdruck-Entladungslampe mit einer gemeinsamen Umhüllung für Abschirmdraht und zweiter Stromzuführung

Figur 2

ist ein Querschnitt durch die in Figur 1 dargestellte Umhüllung

Figuren 3a - 3c

zeigen jeweils einen Querschnitt durch die Umhüllungen von Abschirmdraht und zweiter Stromzuführung gemäß weiterer Ausführungsbeispiele.

The invention will now be described with reference to several particularly preferred exemplary embodiments.

Figure 1

shows a side view of a first embodiment of a high-pressure discharge lamp with a common sheath for shielding wire and second power supply

Figure 2

is a cross section through the envelope shown in Figure 1

Figures 3a - 3c

each show a cross section through the sheaths of shielding wire and second power supply according to further embodiments.

FIG. 1 shows a 250 watt metal halide discharge lamp with an evacuated outer bulb 1, a base 2, a frame 3 for holding the discharge vessel 4 and a getter 5. The axially aligned discharge vessel 4 has a base near 6 and a base distal end 7 and electrodes 8, 9. Inside the discharge vessel 4 there is a filling which, in addition to an inert gas and mercury, also contains additions of NaJ, DyJ₃, HoJ₃, TmJ₃ and TlJ. The ends 6, 7 of the discharge vessel 4 have coatings 10 made of a heat-insulating material. A first power supply 11 leads to the end 6 near the base, which electrically contacts the electrode 8 with the voltage source via the lamp power supply 11a. A second power supply line 12 runs along the discharge vessel 4 and connects to the is connected to the base distal end 7 and ensures the voltage supply to the electrode 9 via the lamp power supply 12a. A shielding wire 13 with an inflection point 13b, an angled region 13a and an end 13c remote from the base is arranged parallel to the power supply 12. The angled region 13a and the first power supply 11 are connected to one another in an electrically conductive manner. Shielding wire 13 and power supply 12 are partially surrounded by an Al₂O₃ ceramic body 14. The one-piece, electrically insulating ceramic body 14 is continued in the second power supply 12 and the shielding wire 13 beyond its end 13c remote from the base. In addition, the ceramic body 14 is continued in the second power supply 12 beyond the break point 13b, in the direction of the base 2. Both measures serve to avoid electrical breakdowns due to the particularly high electrical field strength at the break point 13b and at the end 13c of the shielding wire 13 remote from the base. The ceramic body 14, which is fastened to the second power supply 12 by means of nickel strips 16, gives the shielding wire 13 mechanical stability. Figure 2 shows a cross section through the ceramic body 14 with two channels 15 in the longitudinal direction, which are designed here as bores. The diameter of ceramic body 14 in FIG. 2 is 4.2 mm or 2.2 mm and the channels 15 have a diameter of 1.2 mm.

In a second exemplary embodiment, the ceramic body 14, shown in FIG. 3a, consists of two separate tubes 17, 18, the tube 17, which surrounds the shielding wire 13, by means of two clips 19 Tube 18, which surrounds the second power supply 12, is mechanically fastened.

According to the third exemplary embodiment, the ceramic body 14, outlined in FIG. 3b, consists of two coaxially arranged tubes 20, 21 which are mechanically connected by means of webs 22. The second power supply line 12 or the shielding wire 13 run in the interior of the tube 20 or in the intermediate space 23. The shielding wire can be divided into several wires.

In a fourth embodiment, the Al₂O₃ ceramic body 14 '' '(Figure 3c) has a central channel 24 and five outer channels 25 which are arranged in a circle around this. The second power supply line 12 runs within channel 24, while in each of the channels 25 at most one wire of the shielding wire 13 runs. The wires of the shielding wire unite outside the ceramic body 14, in the vicinity of the break point 13b.

Claims (10)

High pressure discharge lamp with - a one-sided base outer bulb (1) - A discharge vessel (4) arranged inside the outer bulb (1) and having a base (6) near the base and an end (7) remote from the base - A filling of inert gas, mercury and metal-containing additives, in particular metal halides, within the discharge vessel (4) - A frame (3) which, in addition to a first (11) and a second power supply (12), which are connected to a base (6) or base (7) of the discharge vessel (4), also a shielding wire (13) has, which runs partially parallel to the second power supply (12) and is arranged electrically isolated from this and is at a different electrical potential than this second power supply (12) characterized in that the second power supply (12) and the shielding wire (13) have envelopes (14) made of an electrically insulating material. High-pressure discharge lamp according to Claim 1, characterized in that the shielding wire (13) is connected in an electrically conductive manner to the first power supply line (11) via an angled section (13a). High-pressure discharge lamp according to claim 1, characterized in that the envelopes (14) from one electrically insulating material with a high dielectric constant, in particular made of Al₂O₃ or Ba₂TiO₄. High-pressure discharge lamp according to Claim 1, characterized in that the envelopes (14) extend at least over the entire length of the parallel sections of the shielding wire (13) and the second power supply (12). High-pressure discharge lamp according to Claim 4, characterized in that the sheath (14) of the shielding wire (13) is extended at least beyond its end (13c) remote from the base. High-pressure discharge lamp according to Claims 2 and 4, characterized in that the sheath (14) of the second power supply line (12) extends beyond the kink point (13b) of the shielding wire (13) between its angled section and its section running parallel to the power supply line (12) is. High-pressure discharge lamp according to Claim 1, characterized in that the sheaths (14) of the shielding wire (13) and the second power supply (12) are mechanically connected to one another. High-pressure discharge lamp according to claim 7, characterized in that the envelopes (14) as a common envelope, consisting of a one-piece body with a channel (15, 24) for the second power supply (12) and at least one channel (15) for the Shield wire (13) are executed. High-pressure discharge lamp according to Claim 8, characterized in that the shielding wire (13) consists of a plurality of wires, each of which a channel (25) is assigned. High-pressure discharge lamp according to Claim 1, characterized in that the outer bulb (1) is evacuated.

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