EP2052399B8

EP2052399B8 - Method for the production and insertion of an electrode frame comprising a lamp coil into a discharge vessel of a discharge lamp

Info

Publication number: EP2052399B8
Application number: EP07822213A
Authority: EP
Inventors: Klaus Pankratz
Original assignee: Osram GmbH
Current assignee: Osram GmbH
Priority date: 2006-11-08
Filing date: 2007-11-05
Publication date: 2012-02-22
Anticipated expiration: 2027-11-05
Also published as: WO2008055873A3; EP2052399B1; US20100035506A1; CN101517689A; EP2052399A2; DE102006052760A1; BRPI0720509A2; WO2008055873A2

Abstract

The invention relates to a method for producing and inserting an electrode frame (1') comprising a lamp coil (6) into a discharge vessel (7) of a discharge lamp. In said method, the following steps are carried out: a) two separate electrode holders (2', 3') are provided in the form of substantially elongate wires; b) an elongate brace (8) is fastened to the two spaced-apart electrode holders (2', 3'); c) the lamp coil (6) is mounted on forward end regions (21, 31) of the electrode holders (2', 3'); d) some sections of the electrode frame (1') produced in steps a) to c) are inserted into the discharge vessel (7).

Description

Method for manufacturing and inserting an electrode frame with a lamp filament into a discharge vessel of a discharge lamp

Technical area

The invention relates to a method for manufacturing and introducing an electrode frame with a lamp filament into a discharge vessel of a discharge lamp.

State of the art

From DE 10 2004 004 655 A1, a low-pressure discharge lamp is known, which has an electrode extending at least partially into a discharge vessel. The electrode comprises an electrode frame, which electrode frame comprises two current-carrying electrode holders made of Vakuvit wire. At the front ends of these two separate electrode holders a lamp coil is attached. This subarea is located inside the discharge lamp. Also within this discharge vessel is a glass bead, which connects the two electrode holders and holds them. In the area in which the glass bead is attached, the electrode holders are bent like a bottle neck.

In Fig. 1, such known from the prior art discharge lamp with a corresponding electrode frame is shown schematically. The electrode frame 1 comprises the two electrode holders 2 and 3, which are connected to a glass bead 5 in a tapered curved region 4 arranged within a discharge vessel 7. At the front ends of the electrode holder ments 2 and 3 extends transversely across a lamp filament 6. At a lower end region 71 of the discharge vessel 7, the outwardly guided electrode holders 2 and 3 are squeezed and fused into the material, so that the discharge vessel 7 is closed gas-tight at this end region 71. Between the glass bead 5 and the end region 71, a so-called wiping edge 72 is formed, which represents the lower limit of the phosphor coating of the discharge vessel 7.

The electrode frame 1 extends relatively far into the discharge vessel 7, whereby the discharge space is reduced. This results in a distance dl between the lamp filament 6 and the lower end portion 71 of about 20 mm. Furthermore, a distance d2 between the lamp filament 6 and the glass bead 5 is dimensioned at about 10 mm.

2, an enlarged view of the electrode frame 1 is shown. It can be seen that in the tapered region 4, in which the glass bead 5 is formed drop-like, the two electrode holders 2 and 3 are arranged very close to each other.

The known electrode frame 1 is produced on the so-called FSP (Fußspannmaschine) in several successive manufacturing steps. For this purpose, first the individual wires of the electrode holders 2 and 3 are directed, the wires are cut, the frame geometry is bent accordingly and thus the two electrode holders 2 and 3 are bent into their shown shapes, the glass bead 5 is placed, the electrode frame 1 is bent into its final shape , the glass bead 5 melted, the electrode holders 2 and 3 planed, bent at the front end portions of the electrode holders 2 and 3 hooks to then insert the lamp filament 6 there and can jam. In the following, a Spreizmaß the electrode holders 2 and 3 is then bent, the lamp filament 6 bepastet, bent a final final dimension and then then the electrode frame 1 inserted into a frame feed.

The glass bead is used to stabilize the Elektrodengestells 1 during handling between the individual processing steps to crushing of the end portion 71. Disadvantages of this embodiment with a glass bead are on the one hand to see that as a special material glass, for example OG131, with complex production is required. A current insulation to temperatures of about 600 ⁰ C must be guaranteed, which is not possible with conventional soft glasses. In addition, in the solution with a glass bead 5 no safe EOL (End of Life) behavior is guaranteed. During operation, situations may occur in which, despite a broken lamp filament 6 power supply to plastic parts and then melt them, since the glass bead 5 is conductive. In addition, pearl spots can occur in the burner positions. The known from the prior art production of such an electrode frame 1 and their introduction into the discharge vessel of a discharge lamp is relatively complex and also very expensive. In addition, undesired faults may occur during operation, which may lead to damage or destruction of parts of the discharge lamp. Presentation of the invention

It is therefore an object of the present invention to be able to simplify the production of such an electrode frame and the introduction of this into a discharge vessel and to be able to provide a more operationally robust electrode frame.

This object is achieved by a method having the features of claim 1.

In a method according to the invention for producing an electrode frame and for introducing such an electrode frame with a lamp filament into a discharge vessel of a discharge lamp, initially two separate electrode holders in the form of substantially elongated wires are provided. Furthermore, an elongated strut is attached to the two spaced apart electrode holders. At front end portions of the electrode holders, a lamp filament is mounted so that this lamp filament extends between the two electrode holders. The electrode frame produced in this embodiment is then introduced in regions into the discharge vessel, so that at least the lamp filament is arranged inside the discharge vessel. In particular, by attaching an elongated cross member, the stability criterion of the electrode holders and thus also of the entire electrode frame can be ensured. The stability is at least as great as when mounting a propfenartigen glass bead. In addition, it can be achieved that the electrode holders in the region of this stabilization elements are spaced further apart than in a configuration with a propfenartigen glass bead. Moreover, the elongate strut can be attached to the electrode holders much more easily and inexpensively, and is itself preferably made of materials which are much cheaper than expensive pearl glass, for example OG131.

Preferably, the electrode frame is introduced into the discharge vessel such that the elongated strut is positioned outside the discharge vessel. In addition to the guaranteed stability of the electrode frame, this arrangement can also be used to ensure accessibility to the transverse strut at any time. Even after the gas-tight fusing and in particular after squeezing the end region of the discharge vessel, into which the electrode frame extends into the discharge vessel, a handling of this elongate strut can be carried out.

The elongate strut is preferably completely separated from the electrode holders after the area-wise introduction of the electrode frame into the discharge vessel. This separation of the elongate strut preferably takes place after crushing of an end region of the discharge vessel for gastight sealing of the discharge vessel. The oblong strut thus serves for the stabilization during the production and introduction of the electrode frame into the discharge vessel and can be removed, in particular after squeezing, after the electrode frame has been mechanically stably arranged anyway. Preferably, the elongate strut is separated prior to pumping the discharge vessel. Pumping means evacuating and filling the discharge vessel with a filling material.

The elongate strut is preferably at least 12 mm, in particular at least 15 mm, in particular at least 20 mm, spaced from the lamp filament attached to the electrode holders. By this spaced arrangement, a substantial shortening of the entire electrode frame can be achieved.

Preferably, the elongated strut is welded to the electrode holders. In this case, a welding process proves to be particularly suitable in accordance with resistance welding. The mechanically stable connection of the electric rack can thereby be ensured during production and the primary introduction of the electrode frame into the discharge vessel.

The elongated strut preferably has a length between about 5 mm and 10 mm. In particular, the length of this cross member is about 7 mm. By means of this embodiment, it can be achieved that the electrode holders are spaced substantially further apart in the region of the attached elongate strut than is the case in the prior art with the formation of a prop-like glass bead. Short circuits between close to each other arranged electrode holders can be prevented.

Preferably, the elongate strut is formed as an electrically conductive element. In particular, it can be provided that the elongate strut is a wire, in particular Another is a vacuum wire. Particularly in embodiments in which the electrode holders are made of such a wire, in particular a Vakuvit wire, and the elongate strut may be formed of a corresponding material. As a result, costs can also be saved in the procurement of materials, since an already provided wire can also be used for the elongated strut.

Preferably, the elongate strut has a diameter of about 0.4 mm. This also corresponds to the preferred diameter of the electrode holders. Such a thickness of the elongate strut allows for reliable attachment to the electrode supports and also provides sufficient stability and position retention of the electrode supports during insertion and further securing of the electrode support to the discharge vessel.

In particular, if the elongated strut is to be separated from the electrode holders after the end region of the discharge vessel has been squeezed, such an electrically conductive element can be used. Since this elongate strut is then removed anyway before the actual operation of the discharge lamp, a possible current bridge, as would then arise through the oblong strut, can be prevented.

However, it can also be provided that the elongate strut is formed of an electrically non-conductive material. For example, in this case also a stable plastic or the like may be provided. This, too, can be connected to the electrode be mounted holders, for example, a gluing, clinging or the like may be mentioned. It can also be provided that an electrically nonconductive element is formed with a corresponding temperature stability, so that it can also be provided that this elongate strut is arranged inside the discharge vessel when the electrode frame is introduced into the discharge vessel and a pinch of the End region, where the electrode frame is introduced, completed. In such a material design of the elongate strut, it can remain permanently attached during operation of the discharge lamp, since a current bridge does not arise in this regard.

Preferably, the elongate strut is formed with such a length that, after attaching the strut to the electrode mounts, the distance between the two electrode mounts in the region of the attached strut substantially the distance of the two Elektrodenhalte- ments at the front end portions where the lamp filament attached is, corresponds. A variety of bending and forming a tapered, bottle-like portion of the electrode holders, as required in the formation of a glass bead in the prior art, can be prevented thereby.

As a result of the embodiment and production according to the invention, it can also be achieved that the electrode frame must protrude less far into the discharge vessel than is the case in the prior art according to FIG. As a result, an extension of the discharge space in the discharge vessel can also be achieved, since in the case of such beaded loose electrode racks, the lamp filament can be lowered to a so-called wiping edge. Since a shorter electrode frame can thus also be achieved with the invention, the wire saved thereby can be used for an electrode holder, in particular for the elongate strut. Compared to the prior art, at most the same amount of wire is used, which already gives a cost-saving potential here.

In addition, the degree of use can be increased because no pearl bursting can occur. Furthermore, an increase in performance of the Fußspannmaschine can be achieved, since geometriebiegungen and a Perleneinschmelzen, as required in the art, omitted. In addition, since no power transmission takes place, as can occur, for example, in the case of the glass bead in the prior art, the discharge lamp is also EOL safe. Maintenance costs for bending tools and a melting torch for introducing the glass bead can also be saved.

Short description of the drawing (s)

An embodiment of the invention will be explained in more detail with reference to schematic drawings. Show it :

1 shows a discharge vessel of a discharge lamp with an electrode frame known from the prior art;

FIG. 2 is an enlarged view of the known electrode frame according to FIG. 1; FIG. 3 shows an instantaneous production phase of an electrode frame according to the invention when introduced into a discharge vessel of a discharge lamp; and

4 shows an enlarged view of an inventive electrode frame in a further production step.

Preferred embodiment of the invention

In the figures, identical or functionally identical elements are provided with the same reference numerals.

FIG. 3 shows a schematic representation of a production state of an electrode frame 1 ', which is introduced into a discharge vessel 7 of a discharge lamp. The basic structure of the electrode frame 1 'is made up of two electrode holders 2' and 3 ', one lamp filament 6' and one elongate strut 8. For this purpose, two separate pieces of wire are initially provided. In the exemplary embodiment, the electrode holders 2 'and 3' are made of a vacuum wire and have substantially the same length. In a further production step, an elongate strut 8 is then fastened between the electrode holders 2 'and 3' arranged substantially parallel to one another. The elongated strut 8 is also formed in the embodiment of Vakuvit wire and has a diameter of about 0.4 mm, which also corresponds to the diameter of the two electrode holders 2 'and 3'. The elongate strut 8 is introduced as a transverse strut between the two electrode holders 2 'and 3' and is attached to both electrode holders 2 'and 3'. attached by resistance welding. As can be seen both from the illustration in FIG. 3 and from the enlarged partial view according to FIG. 4, the elongated strut 8 is arranged offset back to front end areas 21 and 31 of the electrode holders 2 'and 3'. In the exemplary embodiment, the distance d4 between these front end portions 21 and 31 of the E- lektrodenhalterungen 2 'and 3' to the elongate strut 8 is about 15 mm.

As can be seen both from the illustration in FIG. 3 and from the illustration in FIG. 4, the two electrode holders 2 'and 3' extend substantially parallel over their entire length. Both electrode holders 2 'and 3' do not have a tapered region, as is required in the prior art according to FIGS. 1 and 2 in the region 4. The electrode holders 2 'and 3' thus have a substantially constant distance d3 over their entire length. This is in the exemplary embodiment about 7 mm and thus corresponds substantially to the length of the elongated strut 8.

After welding the elongate strut 8 to the two electrode holders 2 'and 3', the wires are planarized. Subsequently, hooks are then bent at the front ends 21 and 31, and subsequently the lamp filament 6 is inserted into these bent hooks and clamped there. Then an expansion dimension of the electrode holders 2 'and 3' is bent and the lamp filament 6 is pasted. Then follows a bending of the final dimension of the electrode frame 1 'and an insertion of this in the rack feed. In this state of manufacture, the electrode frame 1 'is in its basic condition completed. Subsequently, this electrode frame 1 'is then introduced into the discharge vessel 7. For this purpose, the front region, to which the lamp filament 6 is fastened, is introduced into the discharge space at an end region 71 of the discharge vessel 7. This follows in the embodiment so far that the elongate strut 8 is still outside the discharge vessel 7.

The electrode frame 1 'is introduced into the discharge vessel 7 so far that a distance d5 between the lamp coil 6 and the lower edge region of the end region 71 is formed. This is in the exemplary embodiment about 10 mm and is thus substantially smaller, in particular by half smaller than the distance dl in the conventional embodiment according to FIG. 1. The electrode frame 1 'must therefore be introduced far less into the discharge vessel 7, whereby the discharge space can be increased in comparison to the prior art.

The distance d4 between the lamp filament 6 and the longitudinal borrowed strut 8 is, as already explained, in the exemplary embodiment about 15 mm. As can be seen, the electrode frame 1 'and thus also the lamp filament 6 extend at the front ends 21 and 31 of the electrode holders 2' and 3 'by a relatively small value beyond the wiping edge 72 into the discharge vessel 7.

Starting from this manufacturing state shown in FIG. 3, the end region 71 is then heated and squeezed in the following so that the electrode holders 2 'and 3' are fixed in position in this end region 71. are squeezed and this end 71 is closed gas-tight.

In the following, the elongated strut 8 is then separated from the electrode holders 2 'and 3', in which, for example, cutting is carried out with a corresponding cutting tool. After the separation of this elongate strut 8 then the pumping operation takes place in the discharge vessel 7, in which this is evacuated and appropriate filling material is introduced.

The enlarged representation of the electrode frame 1 'shown in FIG. 4 shows a production state after the actual parts assembly of the electrode frame 1' and before introduction into the discharge vessel 7.

Claims

claims

1. A method for manufacturing and inserting an electrode frame (I ¹ ) with a lamp filament (6) in a discharge vessel (7) of a discharge lamp, in which the following steps are carried out: a) providing two separate Elektrodenhalte- ments (2 ', 3' ) in the form of substantially elongated wires; b) attaching an elongate strut (8) to the two spaced apart held dungsgemanden electrode holders (2 ', 3'); c) attaching the lamp filament (6) to front Endbe ^¬ rich (21, 31) of the electrode holders (2 ',

3 '); d) area-wise introduction of the electrode frame (I ¹ ) manufactured in steps a) to c) into the discharge vessel (7).

2. The method according to claim 1, characterized in that the electrode frame (I ¹ ) is introduced into the discharge vessel (7), that the elongate strut (8) outside the discharge vessel (7) is positioned.

3. The method according to claim 1 or 2, characterized in that the elongated strut (8) after the regional introduction of the electrode frame (I ¹ ) in the Entla ^¬ tion vessel (7) from the electrode holders (2 ', 3') is separated.

4. The method according to claim 3, characterized in that the strut (8) after squeezing an end portion (71) of the discharge vessel (7) is separated.

5. The method according to claim 3 or 4, characterized in that the strut (8) before the pumping of the discharge vessel (7) is separated.

6. The method according to any one of the preceding claims, characterized in that the elongate strut (8) at least 12 mm, in particular at least 15 mm, in particular at least 20 mm, spaced from the lamp filament (6) to the electrode denhalterungen (2 ', 3 ') is attached.

7. The method according to any one of the preceding claims, characterized in that the elongate strut (8) to the electrode holders (2 ', 3') is welded, in particular by a resistance welding is attached thereto.

8. The method according to any one of the preceding claims, characterized in that the elongate strut (8) is electrically conductive.

9. The method according to claim 8, characterized in that the elongated strut (8) is a wire, in particular a Vakuvit wire.

10. The method according to any one of the preceding claims, characterized in that the elongate strut (8) has a length such that after attaching the strut (8) to the electrode holders (2 ', 3'), the distance (d3) between the two electrode holders (2 ', 3') in the region of the strut (8) substantially the distance (d3) of the two electrode holders (2 ', 3') at the front end regions (21, 31).