DE4202971A1 - High pressure discharge lamp for DC operation - has two axially opposite inward protruding electrodes with high MP carrier pins and electrode forming cathode has at least two coils partly surrounding carrier pin - Google Patents

Abstract

The first coil (17) in the region of the free end of the carrier pin (6) of the cathode, is designed in the shape of a winding extending along the axis (2) of the pin. This coil (17) is at least partly enclosed by a second coil (18) on its end aligned to the current lead in (10) of the bulb (1). The second coil (18) encircles an annular cavity (19) seen axially, connected at the end of the first coil, aligned to the bulb wall and its distance to this is restricted by a third coil (20). This coil is at least partly surrounded by the second coil. The coils on the carrier pin (6) end at a distance to the wall of the bulb (1), and the free end of the carrier pin is designed in the shape of a cone (21). USE/ADVANTAGE - Metallic vapour, e.g. Mercury HP discharge lamp. Gives high electrical output and designed to hold arc at tip of cathode and damage to glass is prevented. Gives higher working life.

Description

The invention relates to a high-pressure gas discharge lamp for direct current drifted into the two with a gas-tight piston made of quartz glass electrodes protrude axially opposite each other high-melting metal support pins each over foil-like Feedthroughs made of refractory metal with electrical outside conclusions are connected, wherein the electrode forming the cathode at least has two helix partially surrounding the carrier pin, one of which forms an inner or first helix that is electrically conductive to the carrier pin touches, while the second forms an outer spiral, which on the inner Helix adjacent to the carrier pin at a distance, with both helix from high-melting metal exist.

From DE-PS 29 51 967 is a high pressure metal vapor discharge lamp with a translucent flask made of silicon dioxide known to ionize contains bare filling, whereby two electrodes with leads of high melting point  zenden metal are connected, which are sealed in the piston; of which an electrode serves as a cathode, which has a hollow spiral from high has melting metal, which extends from the feed line and includes an open-wound lap on the turns of the coil, the Create spacers between the windings; the hollow spiral is there clamped to the end of the refractory metal supply line and at least part of the glued end of the coil together with the supply line in the molten silica embedded in the piston wall. The subject of The patent is directed to the cathode being rich in energy compensation to ensure that the hot spot on the cathode quickly Operating temperature reached during ignition and during operation does not exceed. The DC-powered High-pressure metal vapor discharge lamp can be improved so that at least the serving as the cathode, a fixed and simply constructed coil and this electrode is reliably and easily centered. The be Written application is particularly on a miniature metal halide lamp directed.

Such electrode configurations become problematic in the case of high-pressure discharge lamps, high electrical power, since the discharge arc in such lamps can migrate to the side area of the cathode coil and thus a Devitrification of the quartz glass wall and its subsequent destruction caused can be.

The invention has for its object a metal vapor high pressure lamp for to indicate high electrical power, due to good emission ratio nisse at the tip of the cathode and unfavorable emission conditions in the rear Part of the cathode the arc is always held on the tip of the cathode and Devitrification or crystallization of the piston area in the cathode compartment avoided will. Furthermore, such a high-performance high should have a long service life pressure lamp can be achieved.

The object is achieved by the characterizing features of claim 1.  

In a preferred embodiment, that is in the tip region of the carrier pin arranged first coil at least on its surface with Emit ter material. The free end of the carrier pin protrudes in one Length in the range of 1.0 to 1.5 mm from the end facing the inside of the piston the first, inner coil, the surface of the carrier pin at least in the area of the tip protruding from the helix, a smooth one Surface.

Further advantageous refinements can be found in the subclaims.

The application is particularly on a high pressure mercury lamp, in particular directed specifically for photochemical purposes, for example diving torches.

A major advantage is the fact that the first coil in the area its end facing the wall of the piston is surrounded by a second helix is what makes it a radial he from the carrier pin to the second coil stretching ring-shaped cavity as a thermal insulator that seen along the axis of the support pin in the direction of current feedthrough is limited by a third spiral, which is spaced up to immediately bar in front of the quartz glass wall of the piston, so that here is another thermal insulation of the coil arrangement against the wall of the piston there and thus devitrification can be avoided with a high degree of certainty. Due to the thermal insulation, the cathode reaches in the tip area the carrier pin much higher temperatures than in the wall of the Kol bens or areas directed to current, so that due to the there are relatively low temperatures in the side parts or power supply lines of the cathode are definitely avoided can be.

The subject matter of the invention is explained in more detail below with reference to FIGS. 1 to 6.

Fig. 1 shows a longitudinal section through a discharge lamp,

Fig. 2 shows a longitudinal section through the cathode of this lamp,

Fig. 3 shows a side view and a plan view through the power supply in the sealing region of the glass bulb,

Fig. 4 shows a sealing film of the current feedthrough with rounded ends or corners on one side.

Referring to FIG. 1, the discharge lamp includes an elongated lamp envelope 1 on, along its longitudinal axis 2, two projecting into the interior 3 of the electromagnet 4, 5 are arranged, the support pins 6, 7 each extending along the longitudinal axis 2. Electrode 4 represents the cathode, while Elektro de 5 shows the anode. The carrier pins 6 , 7 are each connected at their end facing away from the inner space 3 with sealing foils 8 , 9 , which form the sealed part of the current leadthrough 10 , 11 . On their outward-facing side, the sealing foils 8 , 9 are connected via external connecting pins 12 , 13 to the lamp power supply.

The interior 3 contains the amount of inert gas and mercury required for operation as a gas discharge lamp. While the anode 5 consists of the usual carrier pin 7 and a helix 14 located on the carrier pin, the cathode has a structured structure, as is explained in more detail with reference to FIG. 2.

Referring to FIG. 2, the connected via sealing foils 8, 8 'of the current feedthrough 10 support pin 6 projects from the sealing portion of the quartz glass bulb in the interior 3 of the here for the purpose of a better overview, not completely Darge set the lamp vessel 1. The carrier pin 6 of the cathode 4 has a Katho denkopf 15 , which consists of the free end of the carrier pin 6 , the first inner coil 17 and this partially including the second coil 18 be. The first coil 17 consists of a two-layer bifilar wound wire with a diameter of 0.4 mm made of thoriated tungsten. This first coil is also seen with emitter paste made of thorium oxide or yttrl oxide. The directly applied to the free end 16 of the carrier pin 6 first helix 17 is surrounded on its end facing the piston wall or current lead-through by the second helix 18 as the outer helix and thus hold ge, the second helix made of tungsten wire with 0.4 mm Diameter is available. The second coil 18 is on the end of the first coil 17 along the longitudinal axis 2 of the carrier pin 6 leads in the direction of current feedthrough 10 , an annular jacket-shaped cavity 19 adjoining the current leadthrough end of the first coil 17 , which is connected in the radial direction from the carrier pin 6 proceeding to the inner surface of the second coil 18, it stretches and is seen in the direction of the current lead-through 10 along the longitudinal axis 2 by a third coil 20 which surrounds the carrier pin 6 at its end directed towards the current lead-through. This third coil 20 is partially encompassed by the second coil 18 . The current lead-through end of the third filament 20 is arranged at a distance from the bulb wall of the lamp bulb 1 , the distance being in the range from 0.5 to 1 mm; the distance is preferably 0.8 mm. The third coil 20 is in electrical contact with the carrier pin 6 as well as with the second coil 18 , it has a diameter of 0.8 mm.

The free end 16 of the carrier pin is designed in the form of a cone 21 , the part of the carrier pin 6 protruding from the first helix 17 having a smooth surface.

With reference to FIG. 3 is a longitudinal and cross section of the support pin 6 of the cathode 4 illustrates the purpose of better overview omitting the representation of the coil, wherein the support pin 6 is provided on the directed towards the interior of the piston free end with the truncated cone 21 and on the end of the current feedthrough 10 has a thinned area 22 in which the contacting with the sealing film or the sealing films 8 , 8 'takes place. The section Z shown in cross section is shown on an enlarged scale for better illustration.

According to FIG. 4, the sealing film 8, 8 'in the connection region 25 pin to the support in its surface is itself wedge-shaped taper in order to increase the electric field strength, such as occurs, for example, ten at sharp Kan and thus such flashover. B. to prevent corners. Only in this connection area is the area usually bevelled in the case of molybdenum foils not thinly etched, as is also common for sealing purposes in the rest of the foil area.

The shaft of the support pin 6 according to FIGS. 1 to 3 is formed over its entire length on the surface of smooth, z. B. ground to avoid peaks and grooves, which also cause an increase in the electric field strength and thus sparkover.

The located at the free end of the support pin 6 cathode head 15 forms due to its good electron exit properties and the large upper surface of the interior 3 of the piston 1 ends of the first and second filaments 17 , 18 together with the end 16 of the support pin, the area in which the Arc attacks the cathode during ignition and stationary operation. The so-called cooling region of the cathode 4 in the form of the annular jacket-shaped cavity 19 adjoins the cathode head 15 ; this cavity forms a heat accumulation, so that heat flow from the area of the cathode head 15 is largely prevented and the high temperature ensures good arc discharge. On the other hand, the temperature of the cathode 4 is reduced in the region seen behind the cavity 19 in the direction of the current feedthrough, and the electron emission properties are reduced. This eliminates the risk of the arc jumping in the direction of the current lead-through during operation. The distance between the third filament 20 and the wall of the lamp bulb 1 in the region of the power supply also serves this purpose.

The discharge lamp according to the invention has an electrical connection power of 20 kW operated over a period of 30,000 hours, resulting in advantageously results in a very long service life.

Claims (13)

1.High-pressure gas discharge lamp for direct current operation with a gas-tight sealed bulb made of quartz glass, into which protrude two electrodes arranged axially opposite one another, the support pins of which consist of refractory metal and are each connected to external electrical connections via foil-type current leads made of refractory metal, the cathode forming electrode has at least two helix partially surrounding the carrier pin, one of which forms an inner or first helix which contacts the carrier pin in an electrically conductive manner, while the second forms an outer helix which adjoins the inner helix at a distance and surrounds the carrier pin, wherein Both coils consist of high-melting metal, characterized in that the first coil ( 17 ) in the region of the free end of the support pin ( 6 ) of the cathode is in the form of a winding extending along the axis ( 2 ) of the support pin, which w At least partially on its end directed towards the current feedthrough ( 10 ) of the piston ( 1 ) is enveloped by the second coil ( 18 ), the second coil ( 18 ) enclosing an annular jacket-shaped cavity ( 19 ) which extends in the direction of the axis ( 2 ) seen, adjoins the end of the first coil ( 17 ) directed towards the piston wall and is delimited towards the piston wall by a further or third coil ( 20 ) which is at least partially surrounded by the second coil, the coils on the carrier pin ( 6 ) end at a distance from the wall of the piston ( 1 ) and that the free end of the support pin ( 6 ) is not converted. 2. High-pressure gas discharge lamp according to claim 1, characterized in that Adjacent turns of the respective helix lie closely together touch. 3. High-pressure gas discharge lamp according to claim 1 or 2, characterized in that the first filament ( 17 ) has at least on its surface emitter material. 4. High-pressure gas discharge lamp according to one of claims 1 to 3, characterized in that between the wall of the bulb ( 1 ) facing the end of the third filament ( 20 ) and the wall a distance in the range of 0.5 to 1.0 mm is present. 5. High-pressure gas discharge lamp according to one of claims 1 to 4, characterized in that the free end of the support pin ( 6 ) in a length in the range of 1.0 to 1.5 mm from the towards the interior of the bulb ( 1 ) directed GE Front of the first coil protrudes. 6. High-pressure gas discharge lamp according to claim 5, characterized in that the carrier pin ( 6 ) has a smooth surface at least in the region of its end protruding from the first filament. 7. High-pressure gas discharge lamp according to claim 1, characterized in that the high-melting metal for carrier pin ( 6 ) and filament ( 17 , 18 , 20 ) consists essentially of tungsten. 8. High-pressure gas discharge lamp according to claim 7, characterized in that the high-melting metal is an alloy with 1.2 to 2 percent by weight Thorium, rest is tungsten.   9. High-pressure gas discharge lamp according to one of claims 1 to 8, characterized characterized in that the ratio of the diameters of the first and second Helix is in the range of 1: 2. 10. High-pressure gas discharge lamp according to one of claims 1 to 9, characterized in that a molybdenum foil ( 8 , 8 ') is provided as the current lead-through, which is formed in the area of its end facing the support pin ( 6 ) tapering in the conductor cross-section. 11. High-pressure gas discharge lamp according to claim 10, characterized in that the molybdenum foil ( 8 , 8 ') tapers in the region of its end facing the support pin ( 6 ) in a wedge shape. 12. High-pressure gas discharge lamp according to claim 10, characterized in that the molybdenum foil ( 8 , 8 ') tapers semicircularly in the region of its end facing the support pin ( 6 ). 13. High-pressure gas discharge lamp according to claim 10, characterized in that the molybdenum foil ( 8 , 8 ') tapers parabolically in the region of its end facing the support pin ( 6 ).