WO2008022929A1

WO2008022929A1 - Discharge lamp, particularly low-pressure discharge lamp

Info

Publication number: WO2008022929A1
Application number: PCT/EP2007/058277
Authority: WO
Inventors: Stephan Appel; Harald Denz; Armin Konrad
Original assignee: Osram Gesellschaft mit beschränkter Haftung
Priority date: 2006-08-24
Filing date: 2007-08-09
Publication date: 2008-02-28
Also published as: CN101506933A; KR20140139120A; CN101506933B; EP2054921B1; KR20090043595A; KR101632023B1; DE102006039637A1; EP2054921A1; HUE030022T2; KR101776826B1

Abstract

The invention relates to a discharge lamp, particularly a low-pressure discharge lamp, comprising a discharge vessel (2), two electrodes (3, 4) located at least in part inside the discharge vessel (2), and a first coating (9) which is disposed in at least some areas on an external face (23) of the discharge vessel (2) and is embodied at least as a spectral filter for the light generated in the discharge vessel (2). A second coating (10), which is configured as an antioxidant layer for the first coating (9), is embodied in at least some areas on the first coating (9).

Description

description

Discharge lamp, in particular low-pressure discharge lamp

Technical area

The invention relates to a discharge lamp, in particular a low-pressure discharge lamp, having a ^discharge vessel and two at least partially disposed in the discharge vessel electrodes as well as on an outer side of the discharge vessel at least partially disposed first coating which is formed at least as a spectral filter to the generated in the discharge vessel light.

State of the art

Discharge lamps, in particular fluorescent lamps, with exterior-side coatings are known. For relatively lightly loaded discharge lamps, ie lamps with a discharge current of approximately less than 20 mA, it is known to form outer coatings of plastic. These may be formed for example of polycarbonate or polyolefin or polyester, which also allow the function of a spectral filter, in particular a UV (ultraviol ^¬ lett) protection and other color effects. For these relatively lightly loaded discharge lamps called plastic coating also allows the function of a sufficient splinter protection, whereby the splintering of the discharge lamp and in particular the Entla ^¬ tion vessel, for example in a lamp burst, can be generally prevented. However, these monolayer coatings can only be applied to these relatively Ring loaded discharge lamps ensure their functionalities.

Moreover, it is known, in relatively highly loaded discharge lamps having discharge currents greater than 30 mA, to apply single-layer coatings on the outside, which comprise high-temperature-resistant plastics. However, this can not be used for a suffi ^¬-reaching pigmentation or coloring with a view to Spektralfilterfunktion so that the highly stressed ended lamp types so far can not be equipped with reliable splinter protection and simultaneous UV protection or color effect.

Presentation of the invention

It is therefore an object of the present invention to provide a discharge lamp, in particular to provide the discharge current concerning highly loaded discharge lamp whose outer coating meets multifunctional requirements.

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

A discharge lamp according to the invention is designed in particular as a low-pressure discharge lamp. The Entla ^{pressure discharge} lamp comprises a discharge vessel and two at least partially disposed in the discharge vessel electrodes. On an outer side of the discharge vessel, a first coating is at least partially arranged, which is formed at least as a spectral filter for the light generated in the discharge vessel. In addition, at least partially a on this first coating second coating formed, which second coating is formed at least as an oxidation protective layer for the first coating. Through this Schichtensys ^¬ tem multifunctional requirements of the discharge lamp can be done enough. In particular, can be prevented by the second coating, the oxidation of the first coating and the thermal resistance of the first coating can be significantly increased.

Preferably, the second coating is formed directly on the first coating. It can also be provided that at least one further layer is formed between the two coatings at least in regions. Likewise, it can be provided that both the first

Coating and / or the second coating are each formed as a multi-layer system.

The discharge lamp is advantageously used for Entla ^¬ dung currents greater than 20OmA formed. Particularly preferably, the discharge lamp is designed as a highly loaded discharge lamp, which is designed in particular for discharge currents greater than 300 mA. Even by these hochbe ^¬ loaded discharge lamps a layer system can thus be formed on the outer side, which fills at least both requirements of high thermal resistance as well at sufficient Spektralfilterfunktionalität ER. Even with such discharge lamps thus an outer coating can be colored or pigmented as desired and still withstand high thermal loads. In particular, the thermal stability of the first coating can thereby be significantly increased. Among a temperature resistance or a thermal resistance of a material is, inter alia -A-

understood that the materials essentially retain their elastic properties at a relatively high temperature influence and that the materials do not de- polymerise, do not oxidize and also do not embrittle.

Preferably, the first coating is substantially completely covered by the second coating. This full-coverage coating can completely protect the first coating from oxidation.

However, it can also be provided that the second coating is formed only in regions of the first and the second electrode on the outside of the discharge vessel on the first coating. As a result of this configuration, it is possible to arrange an at least two-layer system, in particular at the areas of the discharge lamp and in particular the discharge vessel, which become the hottest. Especially there, the thermal resistance of the first Be ^¬ coating by the second coating can then be substantially ER increased. To increase this thermal resistance of the first coating, the second coating may be formed of a corresponding material.

Preferably, the first and / or the second coating is formed as a splinter protection layer for the discharge lamp. As a result, the layer system can be formed with a multi-functionality which, in addition to the spectral filtering by at least the first coating and the oxidation protection, which is realized by the second coating, also ensures the splinter protection function. Preferably, the first coating of plastic, ^{¬ in} particular at least partially from polycarbonate, polyester, poly-methyl methacrylate or polyolefin formed. The ^¬ se materials enable a relatively light pigmentation and thereby a relatively simple and low-effort generating Spektralfilterfunktionen this coating. Spectral filter functions can also be designed with regard to the generation of saturated light colors, for example red, green, blue, yellow, of the discharge lamp. In particular, a sufficient UV filter function is given by this first coating.

The second coating can also contribute to the spectral filter functionality of the layer system.

The second coating is particularly advantageous zumin- least partially, in particular completely, forming of a synthetic material layer having low oxygen permeability ^¬ ^¬ out. In particular, the second coating is made of FEP (perfluoro (ethylene-propylene) plastic) formed at least in part ^¬. This material enables a particularly effective oxidation protection of the first coating arranged underneath and, moreover, enables extremely reliable splinter protection, in particular with a discharge lamp which is heavily loaded with regard to the discharge current.

Preferably, the first coating extends at least over the entire length of the outside of the Entladungsgefä ^¬ SLI.

The second coating has a layer thickness of preferably less than 10 mm, in particular less than 6 mm, in particular a layer thickness between 0.1 mm and 5 mm. Preferably, the discharge lamp comprises a tubular discharge vessel, at whose end regions in each case an electrode is arranged. Loading the second coating is preferably formed with a layer thickness which is substantially constant ra- dial formed circumferentially and moreover substantially in each case has in the longitudinal direction of the discharge vessel, this radial thickness ^¬.

The discharge vessel preferably has an outer diameter of less than 30 mm, in particular less than 25 mm.

Short description of the drawing (s)

An embodiment of the invention will be explained in more detail with reference to a schematic drawing. The single figure shows a schematic sectional view of a discharge lamp according to the invention.

Preferred embodiment of the invention

In Fig. 1, schematically, a Schnittdarstel ^¬ system is shown by a designed as fluorescent lamp 1 Never ^¬ derdruckentladungslampe. The fluorescent lamp 1 comprises a tubular discharge vessel 2, which may be, for example, a glass bulb. At opposite end portions 21 and 22 of the discharge vessel 2 are each an electrode 3 or 4 is disposed and fasten ^¬ Untitled on an associated base 5, respectively. 6 From the sockets 5 and 6 each extend two electrical contact pins 7a and 7b and 8a and 8b to the outside. On an outer side 23 of the discharge vessel 2, a first coating 9 is formed. This first coating 9 is in the embodiment of a plastic ^¬ material layer of polycarbonate, polyester, poly-methyl methacrylate or polyolefin. This first coating 9 has at least one spectral filter functionality for the light generated in the discharge vessel 2. In particular ^¬ sondere the first coating 9 is formed as a UV-protective layer.

The first coating 9 extends over the entire length L, which includes the length of the discharge vessel 2 and the adjoining pedestals 5 and 6.

It can also be provided that this first coating 5 and 6, he stretches ^¬ 9 at least in regions facing the rear sides, and thus to the contact pins as relational 7a and 7b, 8a and 8b sides of the base.

The first coating 9 is completely encircling in the radial direction of the tubular discharge vessel 2 and thus the outside 23 is arranged completely covering. In the exemplary embodiment, this first Beschich ^¬ device 9 is formed directly on this outer side 23 and the edges of the base 5 and 6.

In addition, the layer thickness dl of said first Be ^¬ coating 9 in the radial circulation almost constant trained det. In addition, the layer thickness d1 is also formed over the entire length L substantially equal to this layer thickness dl.

On this first coating 9, a second coating 10 is formed immediately thereafter. The second Layer 10 is provided as an oxidation protection layer for the first coating 9. In the exemplary embodiment, the first coating 9 is covered over its entire area by the second coating 10. In addition to its functionality as an oxidation protection layer, the second coating 10 is furthermore also provided at least as a shatter protection layer. The second coating 10 is designed as FEP layer with low oxygen permeability and high splinter protection effect. This second coating 10 has a relatively high thermal resistance, which is higher than the basic thermal Be ^¬ permanence of the first coating. 9

In addition to the embodiment shown in the figure, it can also be provided that the second coating 10 only partially covers the first coating 9. Ins ^¬ particular it can be provided that the second Be ^¬ coating 10 is formed only in local areas A and B of the discharge lamp, and in particular the discharge vessel 2 from ^¬. In these regions of the discharge vessel 2 occur in comparison to other areas of the discharge vessel 2, the highest surface temperatures. Especially in these areas A and B, it is essential to increase the thermal resistance of the first coating 9 by the second coating 10. The dimensions of the regions A and B in the longitudinal direction are merely exemplary and can also be larger or smaller. In this embodiment, the second coating 10 thus represents two separate annular coatings which are formed radially circumferentially on the first coating 9. In this embodiment, no second coating 10 is then formed on the first coating 9 in the region between the regions A and B.

The layer thickness d2 of the second coating 10 is both radially circumferentially constant in the exemplary embodiment Wesentli ^¬ Chen, as formed in the longitudinal direction over the entire length L with this layer thickness d2.

It can also be provided that the layer thicknesses d 1 and d 2 vary in the direction of the longitudinal extent of the discharge lamp 1. For example, it may be provided that the layer thickness d2 is made thicker in a region near the electrodes 3 and 4, for example in the regions A and B, than in a region between these electrodes 3 and 4. This can also be achieved with the layer thickness d1 the first coating 9 may be provided.

The fluorescent lamp 1 is designed for operation with Entla ^¬ dung flow greater 200mA.

Claims

claims

1. discharge lamp, in particular ^low-pressure discharge ^lamp, having a discharge vessel (2) and two at ^¬ least partly in the discharge vessel (2), arrange ^¬ th electrodes (3, 4) and one at an outer side (23) of the discharge vessel (2) at least bereichswei ^¬ se arranged first coating (9), which is formed at least as a spectral filter for the discharge vessel (2) generated light, characterized in that at least in some areas a second coating (10) is formed on the first coating (9), wel ^¬ The second coating (10) is designed as an oxidation protection layer for the first coating (9).

2. Discharge lamp according to claim 1, characterized in that the second coating (10) is formed directly on the first coating (9).

3. Discharge lamp according to claim 1 or 2, characterized in that the first coating (9) is substantially completely covered by the second coating (10).

4. Discharge lamp according to claim 1 or 2, characterized in that the second coating (10) only in areas (A, B) of the first and the second electrode (3, 4) on the outer side (23) of the discharge vessel (2) the first coating (9) is formed.

5. Discharge lamp according to claim 1, characterized in that the first coating (9) is formed directly on the outer side (23).

6. Discharge lamp according to one of the preceding claims, characterized in that the second coating (10) is formed so that the thermal resistance of the first coating (9) is increased.

7. Discharge lamp according to one of the preceding claims, characterized in that the first (9) and / or the second coating (10) is formed as splinter protection layer for the discharge lamp (1).

8. Discharge lamp according to one of the preceding claims, characterized in that the first coating (9) made of plastic, in particular ^¬ at least partially made of polycarbonate, polyester, poly-methyl methacrylate or polyolefin is formed.

9. Discharge lamp according to one of the preceding claims, characterized in that the second coating (10) at least partially from

FEP is formed.

He stretches 10. Discharge lamp according to one of the preceding claims, characterized in that the first coating (9) over the entire countries ge the outer side (23) of the discharge vessel (2) ^¬.

11. Discharge lamp according to one of the preceding claims, characterized in that at least the first coating (9) is at least UV resistant.

12. Discharge lamp according to one of the preceding claims, characterized in that the second coating (10) has a layer thickness (d2) smaller than 10 mm, in particular less than 6 mm, insbesonde ^¬ re a layer thickness (d2) is between 0.1 mm and 5 mm, having .

13. discharge lamp according to any preceding che Ansprü- which is greater for discharge currents 200 mA, in particular ^¬ sondere greater 300mA formed.

14. Discharge lamp according to one of the preceding claims, characterized in that the discharge vessel (2) has an outer diameter of less than 30mm, in particular less than 25mm.