EP1193732A2 - Filament electrode for a fluorescent lamp and fluorescent lamp therewith - Google Patents

Abstract

A coated coil electrode for a low pressure discharge lamp has the coil (16) dip coated with an emitting material. To prevent coating of the connections (12) to each end of the coil the connections are at right angles to the coil axis, e.g. they can be taken off tangentially. This allows the processor to hold the leads vertically as the coil is dip coated. Any coating on the connections runs down onto the coil. The coil can be single wound, double wound or even triple wound, as required.

Description

Technical field

The invention is based on a filament electrode for a low-pressure discharge lamp, especially fluorescent lamp, according to the preamble of claim 1. It is in particular a spiral electrode, which comprises a coil body and two coil endings. there the two spiral ends each have a connection area which they can be conductively connected to a respective power supply section are.

State of the art

So far, a filament electrode has been used in a fluorescent lamp known, which is explained in more detail below with reference to FIG. 1. The in Fig. 1 shown coil electrode 10 has coil ends 12 that run along of the helical axis 14 of the helical body 16. Within one Fluorescent lamps are the filament ends 12 at their connection areas 18 with power supply sections 20 of the fluorescent lamp Welding or clamping connected. Deviating from the illustration In Fig. 1, spiral electrodes are also known, the spiral ends of which are parallel run to the helix axis of the helix body.

To make the filament electrode usable for a fluorescent lamp, the coil body must be pasted with an emitter that is is usually barium, strontium or calcium carbonate. After the pasting, the spiral electrode is formed. This is the conversion process of the on the spiral electrode applied emitter in a corresponding oxide (e.g. barium, Strontium or calcium oxide), which is responsible for charge carrier emission and is therefore required for the function of the fluorescent lamp. In the Pasting the coil electrode very often causes problems that result cause the emitter to be connected to the power supply sections arrives. In this case, proper formation cannot be carried out and the coil electrode must be connected to the Power supply sections are discarded. Especially with one Low pressure discharge lamp with a small inner bulb diameter and a correspondingly small spiral body can hardly be prevented that the emitter reaches the power supply sections.

Another disadvantage of the previously known coil electrode is that it is immediate After pasting, drops often form on the spiral ends uses a clean procedure for pasting and the subsequent formation prevented.

Presentation of the invention

It is therefore an object of the present invention to provide a spiral electrode to develop the preamble of claim 1 such that the above Problems listed when pasting the coil body largely be avoided.

This task is performed on a spiral electrode with the features of the generic term of claim 1 in that one between the two Connection areas of the two spiral ends formed link is outside the coil body. It is precisely in this case possible to dip the coil body into a paste of emitter, without the connection areas and thus the power supply sections come into contact with the emitter at the same time. By immersing the coil body can be wetted with a relatively large amount of emitter be essentially the life of a fluorescent lamp certainly.

A first advantageous development of the invention provides that the spiral body has a straight helical axis. Especially this one The shape of the helix axis ensures an even charge carrier emission of the coil body.

In a further advantageous embodiment of the invention, the Helix body at least one end section, which is connected to a helix adjacent and having an end section axis, the adjacent Helix end at least one helix end section between the Has end portion and the connection area, the at least a spiral end portion has a course that is at each point has a non-zero directional component that is perpendicular to the end portion axis is arranged. This embodiment of the invention is particularly advantageous if the at least one helical end section the entire area of the helix between the end section and occupies the connection area and when the coil body has a straight spiral axis or is only slightly curved. Then namely emitter, which is located on the at least one helical end section located, directed towards the coil body, and one The formation of drops on the spiral end can be avoided.

The at least one helical end section can be essentially vertical to the end section axis. Especially with a low pressure discharge lamp with a small inner piston diameter and one Spiral electrode, which has a spiral body with a straight spiral axis has, so the inner piston diameter completely for the Spiral body can be used.

A triple spiral electrode, in particular, can be used as the spiral electrode Double spiral electrode or a rod spiral electrode can be used.

The above task is also accomplished by using a low pressure discharge lamp solved at least one spiral electrode according to the invention.

The spiral electrode can be connected to the two connection areas two power supply sections by clamping or by welding be connected.

In a particularly advantageous development, the spiral electrode is either in a switched-on state of the low-pressure discharge lamp or in a switched-off state of the low-pressure discharge lamp voltage-free connected to the two power supply sections. By such stress-free fastening in one of the states is avoided, that forces act on the coil electrode in this state, which reduce their lifespan.

The spiral electrode according to the invention is particularly suitable for use in low pressure discharge lamps that have an inner bulb diameter of less than 8 mm, in particular of 6 mm.

Description of the drawings

Fig. 2

eine schematische Darstellung einer ersten Ausführungsform einer erfindungsgemäßen Wendelelektrode;

Fig. 3

eine schematische Darstellung einer zweiten Ausführungsform einer erfindungsgemäßen Wendelelektrode; und

Fig. 4

eine schematische Darstellung einer dritten Ausführungsform einer erfindungsgemäßen Wendelelektrode.

The invention will be explained in more detail below with the aid of several exemplary embodiments. Show it:

Fig. 2

a schematic representation of a first embodiment of a coil electrode according to the invention;

Fig. 3

a schematic representation of a second embodiment of a coil electrode according to the invention; and

Fig. 4

is a schematic representation of a third embodiment of a coil electrode according to the invention.

2 shows a first embodiment of a spiral electrode according to the invention 10 is shown schematically, the two spiral endings 12 and one Has helical body 16 with a straight helical axis 14. The spiral endings 12 are at connection areas 18 Welding or clamping connected to power supply sections 20. In order to wet the coil body 16 with the emitter 22, the entire Coil body 16 immersed in a paste of emitter 22, the emitter 22, as indicated in Fig. 2, adheres to the coil body. The connection areas 18 and thus also the power supply sections 20 remain free of emitter 22, so that a perfect formation can be carried out. Is also on the spiral ends 12 Emitter 22, this is gravity in the direction of the coil body 16 moves. A drop formation on the spiral ends 12 is excluded in this way. The spiral electrode 10 is like this connected to the power supply sections 20 that they at least in is stored in a voltage-free state in a non-current-carrying state.

3 shows a second embodiment of the spiral electrode according to the invention 10, which also has a helical body 16 with a straight Includes coil axis 14 and two coil ends 12. Indeed are the spiral endings 12 in this embodiment not as in the first embodiment arranged at right angles to the helix axis 14. But This course of the spiral ends 12 also leads to the spiral ends 12 located emitter 22 in the direction of the spiral body 16 flows. The greater the distance between the connection areas 18 and Helical axis 14, the less likely it is that the power supply sections will be wetted 20 when the emitter 22 by immersing the coil body 16 is applied in a paste of emitter 22. This too second embodiment is voltage-free with the power supply sections 20 connected by welding or clamping. tensions thus only occur when the coil electrode 10 is supplied with current becomes. However, the coil electrode 10 can also do so with the power supply sections 20 are connected so that they are only voltage-free is stored when it is supplied with electricity of a certain current becomes.

4 shows a third embodiment of the spiral electrode according to the invention 10 is shown schematically in a state in which it is connected is connected to the power supply sections 20, a curved coil body 16 has. This curved coil body 16 comprises two end sections 24 each with an end section axis 26. The each on one End section 24 adjacent spiral end 12 has a course that has a directional component at every point that is perpendicular to the respective one End section axis 26 is arranged. In this embodiment the Invention, the helix 16 is only slightly bent, so that the charge carrier emission can be done almost evenly. Also in this embodiment can the emitter 22 by a dipping process on the coil body 16 are applied, and located on the spiral ends 12 Emitter 22 can be directed to the coil body 16.

The spiral electrode according to the invention appears particularly suitable for installation in very small low-pressure discharge lamps, in particular are known as miniature fluorescent lamps (OSRAM FM / T2) because of these Fluorescent lamps the pasting with emitter a particularly large technical Represents problem that is solved by the invention.

The features of the individual embodiments can be combined.

Claims (9)

Filament electrode for a low-pressure discharge lamp, the filament electrode (10) having a filament body (16) and two filament ends (12), the two filament ends (12) each having a connecting region (18) at which they each conduct with a current supply section (20) are connectable, characterized in that a connecting path formed between the two connecting areas (18) of the two spiral ends (12) lies outside the spiral body (16). Spiral electrode according to claim 1, characterized in that the spiral body (16) has a straight spiral axis (14). Spiral electrode according to one of claims 1 or 2, characterized in that the spiral body (16) comprises at least one end section (24) which is adjacent to a spiral end (12) and has an end section axis (26), the adjacent spiral end (12) at least has a helical end section between the end section (24) and the connecting region (18), the at least one helical end section having a course which has a non-zero directional component at each point, which component is arranged perpendicular to the end section axis (26). Spiral electrode according to claim 3, characterized in that the at least one spiral end section extends substantially perpendicular to the end section axis (26). Spiral electrode according to one of claims 1 to 4, characterized in that the spiral electrode (10) is a triple spiral electrode or a double spiral electrode or a rod spiral electrode. Low-pressure discharge lamp with at least one filament electrode according to one of claims 1 to 5. Low-pressure discharge lamp according to Claim 6, characterized in that the filament electrode (10) is connected at the two connecting regions (18) to the two current supply sections (20) by clamping and / or by welding. Low-pressure discharge lamp according to one of claims 6 or 7, characterized in that the filament electrode (10) is connected to the two power supply sections (20) in a voltage-free manner either in a switched-on state of the low-pressure discharge lamp or in a switched-off state of the low-pressure discharge lamp. Low-pressure discharge lamp according to one of claims 6 to 8, characterized in that the low-pressure discharge lamp has an inner bulb diameter which is less than 8 mm, in particular 6 mm.

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