EP0991107A1 - Discharge lamp and lighting device comprising a discharge lamp - Google Patents

Abstract

Discharge lamp has a transparent electroconductive layer (4) extending over the entire lamp vessel (1) enclosing the discharge space (3). An Independent claim is also included for a lighting system including the above discharge lamp. Preferred Features: The transparent conductive layer (4) is provided over the lamp vessel exterior and comprises a 300 nm thick ITO layer of less than 100 OMEGA /square surface resistivity.

Description

The invention relates to a discharge lamp according to the preamble of Claim 1 and a lighting system with a discharge lamp.

I. State of the art

Such a discharge lamp is for example in the American one Patent US 5,420,481. This patent describes a discharge lamp external electrodes applied to their discharge vessel that are designed as transparent ITO layers.

European patent EP 0 334 208 describes one in a reflector arranged discharge lamp, the discharge vessel of a cylindrical, glass thermal pitot tube is surrounded. The thermal pitot tube is included an ITO layer to approximate the color temperature of the lamp Lower 600 Kelvin.

The aforementioned discharge lamps have the disadvantage that their operation on an electronic control gear, which the lamp is usually equipped with medium-frequency supply voltage in the range of approximately 20 KHz feeds up to 100 kHz, can interfere with the reception of radio equipment.

II. Presentation of the invention

It is the object of the invention to provide a discharge lamp which avoids the disadvantages of the prior art.

This object is achieved by the characterizing features of claim 1 solved. Particularly advantageous versions of the Invention are described in the subclaims.

The discharge lamp according to the invention has at least one translucent one Lamp vessel which encloses the discharge space of the discharge lamp, a lamp and electrical connections for their power supply. According to the invention, the at least one lamp vessel has one translucent, electrically conductive layer on at least the discharge space of the lamp. Under the discharge space is here only the part of the interior that is effective for gas discharge in the lamp understood the at least one lamp vessel. The invention Coating therefore extends at least over those parts of the vessel at least one lamp vessel, which enclose the discharge plasma. By coating the at least one lamp vessel according to the invention is operated at a medium frequency when the discharge lamp is in operation AC voltage from the discharge plasma enclosed in the lamp vessel emitted medium-frequency electromagnetic radiation weakened by more than 50 decibels. A disturbance in the radio reception takes place therefore does not take place even if the discharge lamp according to the invention near the antenna of a radio receiver on an electronic Operating device is operated.

For technical reasons, it is translucent, electrically conductive Layer advantageously on the outer surface of the at least applied a lamp vessel. To a satisfactory electromagnetic To ensure compatibility of the discharge lamp according to the invention, is the specific surface resistance of the translucent, electrically conductive layer advantageously less than 100 ohms per Square.

The specific surface resistance of an electrically conductive layer is usually measured with the help of two flat electrodes, which are applied to the layer to be measured so that they are facing each other are arranged opposite one another. The distance between the two measuring electrodes is the same size as the width of the measuring electrodes, so that between the two Measuring electrodes a square section of the layer to be measured is arranged. A current is given to the layer via the measuring electrodes Current intensity and the voltage drop across the measuring electrodes determined by means of a galvanometer. The quotient from the measured Voltage drop and the current strength of the impressed current results the specific surface resistance of the layer to be measured. The specific one The surface resistance of the layer is independent of the size the square area of the layer. It just depends on that Quotients from the specific electrical resistance of the layer material and the layer thickness. The unit of surface resistivity is usually referred to as ohms per square.

The translucent, electrically conductive layer is advantageously as ITO layer, that is, formed as an indium tin oxide layer. In which particularly preferred embodiment of the invention a discharge lamp that is predominantly yellow, orange, or red Light emitted. The layer thickness of the translucent, electrically conductive Layer is therefore advantageously chosen so that the coated lamp vessel as far as possible in the wavelength range from 550 nm to 700 nm high transparency, that is, a transmission coefficient of greater than 0.8. The thickness of the translucent, electrically conductive layer on the one hand, it must be sufficiently large to have sufficient electrical power To ensure conductivity, but also sufficient be small in order to still have sufficient light transmission. According to the particularly preferred embodiment of the invention the discharge lamp is designed as a neon gas discharge lamp. That lamp mainly produces orange or red light. It can therefore advantageously as part of a lighting system in a motor vehicle, to generate the flashing light or the tail light and / or brake light, be used.

The lighting system according to the invention has a discharge lamp and an operating device for the discharge lamp, wherein the discharge lamp at least one enclosing the discharge space of the lamp Lamp vessel has that with a translucent, electrically conductive Layer is provided, wherein this layer is at least over the discharge space extends and to a predetermined electrical reference potential, which advantageously the circuit-internal ground potential of the operating device or the earth potential is connected. The aforementioned features of the lighting system according to the invention ensure its satisfactory electromagnetic compatibility because of the discharge plasma the discharge lamp emitted medium-frequency electromagnetic Radiation is weakened by more than 50 decibels. Advantageously the lighting system according to the invention additionally has a reflector on. In order to achieve a high degree of light reflection, the reflector has of the lighting system according to the invention advantageously a metallic or a metallized reflection surface. The reflector practices therefore also a shielding effect on that of the discharge plasma electromagnetic radiation generated in the discharge lamp. It has proven particularly advantageous to use the reflector and possibly Metallized parts of the luminaire housing to improve the shielding also to be connected to the specified electrical reference potential. This allows the layer thickness of the translucent, electrically conductive Layer on the reflector or the interior of the lamp facing Wall areas of the at least one lamp vessel advantageously run less than on those facing away from the reflector Wall areas of the at least one lamp vessel, and on this Way the light transmission of the wall areas facing the reflector increases and the efficiency of the lighting system according to the invention be improved. The at least one lamp vessel advantageously has one cylindrical vessel part and two angled in the direction of the reflector End up. This ensures that the dark ends of the Discharge lamp equipped with the electrical connections of the lamp are not visible. Alternatively, the dark ends of the Discharge lamp also in shadowed areas of the lighting device be relocated.

In the particularly preferred embodiment of the invention Lighting system is the layer thickness of the translucent, electrically conductive layer on the wall areas facing away from the reflector of the at least one lamp vessel 300 nm Wall areas a particularly high transparency for light with a wavelength from 600 nm. This lighting system is therefore advantageously suitable for use in a motor vehicle to generate the Tail light and / or the brake light.

III. Description of the preferred embodiment

Figur 1

einen Längsschnitt durch eine Entladungslampe gemäß des bevorzugten Ausführungsbeispiels der Erfindung in schematischer Darstellung

Figur 2

einen Querschnitt durch die Entladungslampe gemäß Figur 1 mit einem Reflektor in schematischer Darstellung

Figur 3

Transmissionskurven für das unbeschichtete und das beschichtete Lampengefäß

The invention is explained in more detail below on the basis of a preferred exemplary embodiment. Show it:

Figure 1

a longitudinal section through a discharge lamp according to the preferred embodiment of the invention in a schematic representation

Figure 2

a cross section through the discharge lamp of Figure 1 with a reflector in a schematic representation

Figure 3

Transmission curves for the uncoated and the coated lamp vessel

In the preferred embodiment of the invention shown in FIG. 1 it is a neon gas discharge lamp. That lamp has a tubular, glass discharge vessel 1 with two right angles, Ends angled in the same direction 1a. In each of the ends 1a Electrode system 2 of the neon gas discharge lamp melted down gas-tight. The current leads protruding from the melting area 1aa 2a form the electrical connections of the lamp. Between his angled The discharge vessel 1 has a circular cylindrical shape at the ends 1a. The outer diameter of the discharge vessel 1 is approximately 5 mm. The distance between the power leads 2a, which is approximately the length of the circular cylindrical discharge vessel part 1b corresponds to 308 mm. The angled ends 1a have a length of 36.2 mm.

The outer surface of the discharge vessel 1 is provided with a so-called ITO layer 4 - this is an indium tin oxide layer - which extends over the entire discharge space 3 of the neon gas discharge lamp as far as the melting areas 1aa of the electrodes 2. The discharge space 3 is defined here by the ends of the two electrodes 2 on the discharge side and the inner diameter of the discharge vessel 1. The ITO layer 4, measured using the four-point measurement method, has a specific surface resistance of 14 ohms per square. It consists of 90 percent by weight indium oxide In ₂ O ₃ and 10 percent by weight tin oxide SnO ₂ . The transmission curve 1 shows the light transmittance of the discharge vessel 1 with ITO layer 4 as a function of the wavelength, while the transmission curve 2 shows the light transmittance of the discharge vessel without ITO layer. The layer thickness of the ITO layer is coordinated in such a way that the transmission curve 1 has a transmission maximum at a wavelength of 600 nm, that is to say for red light which is emitted predominantly by the neon gas discharge lamp. The layer thickness of the ITO layer 4 is therefore approximately 300 nm. In the wavelength range from 550 nm to 700 nm, the transmission of the coated lamp vessel 1 is more than 80% of the light impinging on the inner wall of the discharge vessel 1, that is to say the transmission coefficient therein Wavelength range greater than 0.8. At the wavelength of 600 nm, a transmission coefficient of more than 0.85 is achieved.

The neon gas discharge lamp described above is preferably a component a lighting system, in particular a motor vehicle rear light and serves to generate a tail light and / or a brake light. In addition to the neon gas discharge lamp, this rear light also includes an electronic control gear for the neon gas discharge lamp and one trough-shaped reflector 5, which between the angled ends 1 a Lamp is arranged. The circular cylindrical vessel part 1b of the discharge vessel 1 is arranged approximately in the optical axis of the reflector 5. The reflection surface 5a of the reflector 5 facing the lamp is metallic or metallized and with the internal circuit potential of the Control gear connected. The ITO layer 4 of the discharge vessel 1 is also connected to the internal circuit potential of the control gear. The lighting device also has a housing (not shown) on, the metallized parts also to the internal circuit potential are connected so that a star-shaped contact in a common ground point. On the reflector 5 facing Wall areas 10a of the discharge vessel 1 have the ITO layer 4 a smaller layer thickness than that facing away from the reflector 5 Wall regions 10b of the discharge vessel 1. The layer thickness of the ITO layer 4 is on the wall areas facing away from the reflector 5 10b has a value of approx. 300 nm while it is on the reflector 5 facing wall regions 10a measures approximately 100 nm.

The invention is not limited to the exemplary embodiment explained in more detail above. For example, ITO layer 4 does not have to cover the whole Extend discharge vessel 1. Those wall areas are sufficient of the discharge vessel 1, which the space between the discharge side Enclose ends of the two electrodes 2 to be provided with the ITO layer 4.

The invention can also be applied to other types of discharge lamps, for example on low-pressure discharge lamps or on high-pressure discharge lamps and on lighting systems with a high-pressure discharge lamp such as one with a high pressure discharge lamp equipped automotive headlights can be applied. In particular in this case it is a single-sided high-pressure discharge lamp, which is a discharge vessel enclosed by a glass outer bulb has, the outer bulb with a translucent, electrically conductive layer - preferably an ITO layer which extends over the entire discharge space of the lamp. The High-pressure discharge lamp is preferably part of a motor vehicle headlight and is operated on an electronic control gear. The translucent, electrically conductive layer on the outer bulb The high-pressure discharge lamp is connected to the internal ground potential connected to the control gear.

Instead of an ITO layer, it is also possible to use translucent, electrically conductive layers which consist of another material, for example of tin oxide SnO ₂ or of tin oxide SnO ₂ : F or SnO ₂ : Sb doped with fluorine or antimony.

Claims (16)

Discharge lamp with at least one translucent lamp vessel (1) which surrounds the discharge space (3) of the discharge lamp, a lamp and electrical connections (2a) for supplying voltage to the discharge lamp,
characterized in that the at least one lamp vessel (1) has a translucent, electrically conductive layer (4) which extends at least over the entire discharge space (3) of the discharge lamp. Discharge lamp according to claim 1, characterized in that the at least one lamp vessel (1) at least one sealed end (1a) with a melting area (1aa) for an electrode system (2) and that the translucent, electrically conductive Layer (4) extends to the melting area (1aa). Discharge lamp according to claim 1, characterized in that the translucent, electrically conductive layer (4) on the outer Surface of the at least one lamp vessel (1) is arranged. Discharge lamp according to claim 1, characterized in that the specific surface resistance of the layer (4) less than 100 ohms per square is. Discharge lamp according to claim 1, characterized in that the Layer (4) an ITO layer, that is, an indium tin oxide layer is. Discharge lamp according to claim 1, characterized in that the Lamp is a neon gas discharge lamp. Discharge lamp according to claim 6, characterized in that the Transmission coefficient of the at least one lamp vessel (1) in the wavelength range from 550 nm to 700 nm is greater than 0.8. Discharge lamp according to claim 1, characterized in that the Discharge lamp is a high-pressure discharge lamp. Discharge lamp according to claim 8, characterized in that the High-pressure discharge lamp enclosing the discharge vessel Has outer bulb and the translucent, electrically conductive Layer on the outer bulb of the high pressure discharge lamp is arranged. Lighting system with a discharge lamp according to one or several of claims 1 to 9 and an operating device for the discharge lamp. Lighting system according to claim 10, characterized in that the translucent, electrically conductive layer (4) to a predetermined electrical reference potential is connected. Lighting system according to claim 11, characterized in that the predetermined electrical reference potential is the internal circuit Ground potential of the control gear or the earth potential. Lighting system according to claim 10, characterized in that the lighting system has a reflector (5) with a metallic one or a metallized reflection surface (5a) and at least a lamp vessel (1) facing the reflector (5) wall areas (10a) and wall areas (10b) facing away from the reflector (5) has, the layer thickness of the translucent, electrically conductive Layer (4) on the wall areas facing the reflector (5) (10a) less than the layer thickness of the translucent, electrically conductive layer (4) on that facing away from the reflector (5) Wall areas (10b). Lighting system according to claims 11 and 13, characterized in that the reflector (5) to the predetermined electrical Reference potential is connected. Lighting system according to claim 13, characterized in that the layer thickness of the translucent, electrically conductive layer (4) on the wall areas (10b) facing away from the reflector (5) at least one lamp vessel is 300 nm. Use of a lighting system according to one or more of claims 10 to 15 in a motor vehicle.

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