DE102009051962A1 - Lamp - Google Patents

Abstract

The invention relates to a lamp (10) comprising a hollow body, which is applied to the inside of a dimensionally stable rotating surface or has a layer or layer arrangement in the rotating surface itself, with at least one light-emitting layer (12), for example an OLED layer, at least one first electrode layer (23) and at least one second electrode layer (13), furthermore means (15, 17) for contacting the electrode layers of the illuminant and means for gas-tight sealing of the hollow body. According to the invention, the means for contacting the electrode layers of the illuminant comprise a first contact plate (15) which fits into a cylindrical region (22) of the hollow body and extends over the cross section of this cylindrical region and contacts the first electrode layer (13) on its circumference and one in the axial direction Distance to the first contact plate arranged second contact plate (17), which also extends over the cross section of the cylindrical region of the hollow body and contacts the second electrode layer (23) on its circumference.

Description

The present invention relates to a luminous means, comprising a hollow body, which, applied to the inside of a dimensionally stable surface of revolution, or in the surface of revolution itself has a layer or layer arrangement with at least one light-emitting layer, at least one first electrode layer and at least one second electrode layer, wherein Means are provided for contacting the electrode layers of the luminous means and means for gas-tight sealing of the hollow body.

A light source of the aforementioned type is in the Japanese Abstract 2004207081 A described. The basic idea is to provide a light source, which is similar in its external shape (bulb shape) of a conventional light bulb and also in its base region of an incandescent lamp and thus compatible with a conventional lamp socket. As a light-emitting layer, however, an organic electroluminescent layer is to serve with a layer structure, as it is used in principle in the so-called OLEDs. Until now, OLEDs have only been known as flat planar illuminants, which as a result have a flat emission in only one direction. On the other hand, with an OLED illuminant as described in the Japanese publication, radiation in all spatial directions can be achieved and combined with the photometric advantages of the OLEDs (organic LEDs). However, technical difficulties arise in the production of a luminous means of the type described therein. The organic electroluminescent layer is to be deposited by vacuum deposition or sputtering or by immersion on the inside in the hollow body. Subsequently, the second metallic electrode on the organic electroluminescent layer will also be deposited by vacuum deposition. However, this is technically not feasible, since due to the large heat development in the hollow body in the deposition of the metallic electrode layer, the heat-sensitive organic layer would be impaired.

Another problem in the production of such a luminous means is the gas-tight sealing of the base region and the contacting of the two electrode layers, which as a rule have only a very small layer thickness. In Japanese writing, a kind of plug is inserted into the neck of the glass bulb, which is to seal in the glass and must be made of an insulating material, probably made of plastic. Through this plug through two pin-like contacts are passed, which contact at one end in each case one of the electrode layers of the layer arrangement on the glass body and which are in each case at the other end in contact with areas of the lamp cap. It is not apparent from the document, as it should be technically possible, on the one hand introduce the stopper gas-tight in the neck of the glass bulb and on the other hand to connect the pin-like contacts electrically conductive with the thin electrode layers in the interior of the glass bulb.

A similar prior art as the previously described document discloses EP 1 448 026 A1 , There, a mostly hemispherical glass body is provided on the inside with a layer sequence of two electrode layers and a light-emitting layer and sealed in its open base area by a kind of plate to the outside moisture-tight. The vitreous can also have a pear shape. Two conductive wires extend through the plate and are each conductively connected in the interior of the hollow body with one of the two electrode layers. The glass body and the plate can be connected to each other via a binder such as a synthetic resin. When the conductive wires extend through the plate, it must be made of an insulating material such as plastic. In this known solution, an effective industrial mass production of the described illuminant is hardly conceivable. On the one hand, the plate must be connected to the glass body permanently solid and gas-tight and on the other hand, the wire-shaped contacts with the glass body usually very thin layers must be electrically connected. This can not be realized at the same time. If, however, in the first step, the plate is gas-tightly connected to the glass body, the plate must be opened again for passing the contacts, so that then a new seal is necessary. In addition, then the precise contacting of the layers is difficult.

Object of the present invention in view of the prior art is to provide a lamp of the type mentioned, in which a technically feasible solution for contacting the inner electrode layers of the hollow body and the gas-tight encapsulation of the opening of the hollow body is given.

The solution to this problem provides a light source of the type mentioned above with the characterizing features of claim 1. Further advantageous features emerge from the dependent claims and the embodiments and examples described below. It is understood that the embodiments are not restrictive; Within the scope of the independent claims, a person skilled in the art can also make use of individual features of the following described feature combinations arrive at an object according to the present invention.

The present invention claims a luminous means in which the means for contacting the electrode layers of the luminous means comprise a first contact plate which fits over a cylindrical portion of the hollow body and which contacts the first electrode layer at its circumference and has a first contact surface axially spaced from the first contact plate arranged second contact plate, which also extends over the cross section of the cylindrical portion of the hollow body and contacts the second electrode layer at its periphery.

Thus, unlike the prior art described above, contact plates are used instead of contact pins. The first contact plate is dimensioned so that it can be fitted in the cross section of the cylindrical portion of the hollow body, so that over the entire circumference of the round contact plate results in an electrically conductive contact with one of the electrode layers of the light-emitting device. On the one hand, this geometry ensures reliable contacting of the electrode layer during the production of the luminous means. At the same time, it is also possible to close the opening to the cavity coated inside with the light-emitting layer via the contact plate and to protect the layers of the layer arrangement that are sensitive to oxygen and humidity in this way. This solution thus makes it possible in an elegant manner to simultaneously close the cavity during the production of the luminous means in one operation and to establish contact with the electrode layer on the inner surface of the hollow body. An additional plate for closing the cavity is no longer necessary.

The second contact plate can be arranged at an axial distance from the first contact plate, likewise extends over the cross section of the cylindrical region of the luminous means and contacts the second electrode layer on its outer circumference. For example, this makes it possible to design the luminous means such that the first contact plate makes contact with an inner electrode layer of the luminous means which terminates approximately in its region and the second contact plate makes contact with an outer electrode layer of the hollow body which extends beyond the inner electrode layer in the cylindrical region of the hollow body ,

According to the invention, either the first contact plate and / or the second contact plate should each close an opening of the hollow body corresponding to the cross section of the cylindrical region in a gastight manner. As a rule, this is already done by the first contact plate facing the hollow body. It is particularly preferred that the first contact plate and / or the second contact plate consists of a metallic material and is soldered at its periphery with the cylindrical portion of the hollow body. The hollow body is preferably made of glass, a glassy or ceramic material. Technically, it is possible by special methods to produce a solder joint between a material pair of, for example, glass / metal. For this purpose, not too high a temperature is necessary, so that the moderate heating in the region of the solder joint between the contact plate on its outer circumference and the glass material of the hollow body does not impair the function of the light-emitting layer in the interior of the hollow body. By such a solder joint, the contact is made and at the same time the interior of the hollow body effectively and permanently protected against the influence of oxygen and moisture from the surrounding atmosphere.

Within the scope of a preferred development of the present invention, it is provided that the light-emitting layer or the light-emitting region of the hollow body comprises an organic light-emitting diode (OLED) layer and / or nanoscale light-emitting structures, in particular quantum dots.

An exemplary constructive embodiment of the present invention provides that at least one contact pin, which is electrically conductively connected to the first contact plate, extends through the second contact plate approximately in the axial direction of the cylindrical region, wherein the passage region is electrically insulated from the second contact plate , The first contact plate can thus consistently close the cross section of the remaining opening of the hollow body. The second contact plate, which preferably extends approximately parallel to and at a distance from the first contact plate, also substantially closes the cross-section of the opening or extends over the entire cross-section of the cylindrical region, this being broken only by the contact pin of the first contact plate, resulting in only a relatively small opening. This small opening is unproblematic in the production, since the interior of the hollow body is already closed by the first contact plate.

From the contact plates then, for example, each contact pins go out, wherein the contact pin extending from the first contact plate, starting from a contactable from outside first contact element in a base region of the bulb and, for example, a second contact pin is provided with the second Contact plate is electrically conductively connected and extending from the side facing away from the hollow body of the second contact plate, starting from an externally contactable second contact element in a base region of the lamp out.

It is furthermore preferred that the first contact plate makes contact with an inner electrode layer of the luminous means which terminates approximately in its region, and the second contact plate makes contact with an outer electrode layer of the hollow body which extends beyond the inner electrode layer in the cylindrical region of the hollow body. Both electrode layers can thus end in each case on a circulating in the cylindrical portion of the hollow body circumference, so that a deposition of the layer in the production of the light source is technically easier than in a circumferentially asymmetrically deposited layer, as in the aforementioned state of Technique is used.

In the present application, the term "surface of revolution" is understood to mean the surface of a body of revolution in the sense of the mathematical definition that results from rotation of a generating line about an axis of rotation. Examples of such rotary bodies are sphere, cylinder, torus, ellipsoid, rotational bodies derived therefrom and those with more complex shapes. The light-emitting structures are arranged following the shape of this body of revolution and the light is emitted to the outside.

The surface of rotation is dimensionally stable and is therefore designed in its shape in the function of a carrier of the lamp. According to the invention, it is possible to use a support which is neutral for the photometric function and is coated, for example, with one or more functional layers. But you can also assign the carrier itself another essential for the bulb function. For example, the carrier itself can assume optical properties (light scattering, refraction of light, reflection, etc.) or be current-conducting and thus act, for example, as an electrode. The carrier may also be multilayer and have a more complex layer structure with multiple functions. It is possible either to provide the functional layers with these after the preparation of the support, but it is also possible, for example, to produce a support which already encloses the light-emitting structure or layer during production.

It is preferably provided that the illuminant emits visible light having a color rendering index (CRI value) of the wavelength-dependent intensity distribution to that of the sunlight of at least 80, preferably at least 90, particularly preferably at least 95.

Advantageously, the luminous means according to the invention has at least two, preferably 3-5, particularly preferably 4 successive series of excitation layers for the electrically excited light emission. The layer sequence is continuous and contacted with an anode layer, preferably an optically transparent ITO anode layer of indium oxide and tin oxide, beginning and finally with a cathode layer.

As a carrier is preferably used in a luminous means according to the invention a largely and / or completely closed hollow body, which may for example consist of glass, plastic, ceramic, metal, combinations of these materials or other suitable material. The support material may be partially translucent, but this is not absolutely necessary. For example, the carrier can also consist of an opaque metal or ceramic, in which case at least one further layer in which the light-emitting structures are located can be applied externally to the carrier, which is then at least partially transparent or translucent. In this case, the carrier thus has a pure carrier function. However, the carrier may also already contain the light-emitting structures. The carrier may for example also be or comprise a prismatic foil and thus assume optical properties. Such a prism sheet can for example also be applied to a non-transparent support. A plastic material such as a plastic film may already contain the light-emitting structures. The carrier may also consist of an electrically conductive material and thus assume the function of one of the electrodes, for example.

The support may for example also be a one-sided or even double-sided open rotation body, such as a pipe, an open cone, truncated cone (luminous lampshade) a partial sphere or the like. Such a rotation body, which is initially open on one side or on both sides, can be closed, for example, in a later step of the production process if it requires the function to protect, for example, the nanoscale light-emitting structures against external influences such as oxidation, moisture, etc. The rotationally symmetrical body may also have one or more open points, perforations or lattice structures, possibly only in partial areas.

In a luminous means according to the invention, the hollow body in its light-emitting region preferably consists of glass or a suitable plastic or the hollow body comprises at least one layer of glass or plastic, in particular a thermoplastic or also thermosetting plastic, for example, from at least one plastic processable by blow molding or thermoforming selected from the group consisting of acrylonitrile-butadiene-styrene (ABS), polyamide (PA), polylactate (PLA), polymethylmethacrylate (PMMA), polycarbonate (PC), polyethylene terephthalate ( PET), polyethylene (PE), polypropylene (PP), polystyrene (PS), polyether ketone (PEEK) and polyvinyl chloride (PVC) or the like.

In the case of a luminous means according to the invention, the interior of the rotary hollow body is as a rule closed gas-tight and / or optionally filled with a protective medium, more preferably a non-oxidizing gas.

In the case of a luminous means according to the invention, for example, radiation-coupling, in particular scattering, structures can be provided on an outside radiation exit side in order to increase the proportion of the light emitted from the rotation body to the outside.

A luminous means according to the invention thus preferably comprises the following components: a carrier designed as a dimensionally stable rotation surface, light-emitting structures, and visible light arranged at least in regions to a light-outcoupling side of the carrier outcoupling structures. The light emitting structures may be in, on or on the carrier. The visible light generated in this way is then coupled out of the carrier by the light coupling-out structures and emitted, for example approximately in the direction of the surface normal to the curved surface of the carrier. That is usually the radiation of the decoupled light takes place at a light source with trained as a rotational body carrier to the outside.

The light-emitting structures can, for example, be applied on the inside to the surface of revolution serving as a support.

The light-outcoupling structure can be, for example, an optically outcoupling film. This can be selected, for example, from the group of films consisting of scattering film, prism film, horizontal lenticular film, vertical lenticular film, Fresnel lens film, prism grid film.

In the case of a luminous means according to the invention, light sources based on organic light-emitting diodes (OLEDs), for example, can also be provided on or in the support, forming a light-emitting layer which, for example, can already be applied in advance to the inside of the dimensionally stable surface of rotation serving as support or else the light emitting layer and / or an electrode layer is located in the substrate itself.

For the electrical excitation of the organic light-emitting structures, a low voltage can be used, wherein as a voltage source, for example, serves a controllable from 5 to 50 volts power source.

In a luminous means according to the invention, for example, at least one of the layers essential for the function can be applied to the inner surface of the hollow body serving as a carrier by a spraying process in which a spray head moves into the hollow body. Preferably, the application of at least one layer by "organic vapor phase deposition", wherein, for example, the substance transported in a Schleppgasatmosphere in the vapor phase in the interior of the hollow body and then deposited on the surface to be coated of the hollow body controlled by cooling.

In the case of a luminous means according to the invention, for example, substantially all of the available inner surface or only a defined partial surface of the carrier formed as a hollow body can be covered with a single-layer or multi-layer arrangement of the layers essential for the function of the organic light-emitting diode.

In the case of a luminous means according to the invention, at least one second electrode providing indirect contact and / or excitation radiation can be arranged, for example, at a distance from the inner surface of the hollow body in the cavity separately from at least one layer arrangement.

An illuminant according to the invention may, for example, also have a complex layer structure of more than three layers.

An illuminant according to the invention can have, for example, the outer basic shape of a conventional lamp, in particular an incandescent lamp, fluorescent tube, bulb lamp, ball lamp or candle lamp, so that it is compatible with a conventional illuminant and can be exchanged for it.

In a luminous means according to the invention, for example, the hollow body may have the shape of a ball or a ball shape derived from the spherical shape and molded neck area (in particular piston shape, candle shape, pear shape) and the aforementioned cylindrical area in which the contact plates are located in the Cross section (relative to the hollow body itself) tapered neck portion of the hollow body.

Alternatively, in a luminous means according to the invention, for example, the hollow body may have approximately the shape of a cylinder or a tubular shape and at one end may be provided a lamp base or at both ends in the frontal areas each a lamp base with contact means for external electrical contacting (in a version) wherein the aforesaid cylindrical portion in which at least one of the contact plates is located is a portion to be closed at one end or at both ends of the hollow body, and in which case the cylindrical portion may also have the same diameter as the hollow body itself ,

It is advantageous if, for example, arranging the light-emitting structures in an optically substantially transparent medium, which may, for example, up to 90% transparency, optionally also, for example, up to 99% transparency, and which serves as a support for these structures.

With, for example, about 90% optical transparency, a medium, despite a certain loss rate, can already be considered as a carrier for illuminants, in which brightness and efficiency are the essential goals. With, for example, 99% transparency, lighting systems become accessible in which a given light mixture and intensity is radiated very precisely, which is particularly recommended for varied, daylight-proof illumination.

The present invention furthermore relates to a method for producing a luminous means of the aforementioned type having the features of claim 12.

This comprises, for example, the steps of first producing a hollow body made of glass, plastic, ceramic, metal, a combination of these materials or another suitable material, which is closed except for one or more relatively small openings in relation to the surface of the hollow body In the next step, the serving as a support inside of the hollow body is provided with one or more light-emitting layers and that finally the remaining (s) opening (s) of the hollow body is sealed gas-tight by means of at least one contact plate.

According to the invention, furthermore, at least one further layer is applied to the carrier on the inside and / or outside, which has light-scattering, light-deflecting, reflective or light-color-changing properties and overlaps at least with a partial area of the previously coated inner surface of the hollow body.

If, according to a preferred development, a film optically decoupling is provided, this film layer can be applied, for example, first as a lacquer, liquid prepolymer mixture or elastic film, preferably with an adhesion-promoting lower layer component having optically identical properties, by at least one of the measures selected from US Pat Group consisting of drying, thermal polymerization, photochemical polymerization, thermal curing connected to the substrate and finally formed on the exposed surface to one of the above types of film.

Such a film may, for example, be or will be provided at least in regions with certain wavelength ranges reflecting or wavelength-converting structures.

Furthermore, according to the invention, for example, at least one further layer can be applied at least in regions to the surface of the hollow body in front of an outer electrode layer which is opaque, reflective, directing light, changing the light color or light-scattering, or the outer electrode layer can be opaque at least in some areas Be light reflective or light scattering formed, or in the cavity may be arranged additional light-directing, light-scattering, light-reflecting or light-color changing elements.

In the production of a luminous means according to the invention, for example, at least one layer and / or the nanoscale, luminescent structures can be formed by thermolysis of gas-borne precursor compounds in a drag gas stream on a heated contact surface and subsequent passing of the gas containing the thermolysis products to create the layer structure in the light-emitting region of the rotating body on the cooled - preferably already provided in the same way with preparatory layers - support surface.

Hereinafter, the present invention will be explained in more detail by means of embodiments with reference to the accompanying drawings.

Showing:

1 a simplified schematic sectional view through a lighting means according to a first exemplary embodiment of the present invention;

2 an enlarged sectional view of a detail through the illuminant according to 1 ,

The following will be on 1 Reference is made and with reference to an exemplary embodiment of the present invention will be explained. In this example, the whole has the reference number 10 designated bulbs about the shape of a conventional light bulb. Thus, a trained as a hollow body rotational body is present, which is oval or ellipsoid in longitudinal section and tapers in a lower neck area in cross-section. This tapered portion is referred to in the present application as a cylindrical portion 22 referred to and is connected in one piece with the convex curved pear-shaped hollow body in the rule. The hollow body with the molded cylindrical area 22 For example, it can be formed from glass or plastic by known methods. To the cylindrical neck area 22 then closes a pedestal area 20 which, for example, can be designed like a conventional lamp base as a screw base, plug-in base or the like.

After the formation of the hollow body of this is coated by means of suitable methods on its inside with the necessary for the photometric function layers. For example, one can use a glass carrier 11 use the inside with a first transparent electrode layer 23 (see also 2 ) such as indium tin oxide (ITO) is coated. On the inside of the coated carrier 11 becomes a layer or layer arrangement 12 (with multiple layers), which contains the light-emitting material, for example OLED (organic LED layer). This coating is in turn a second electrode layer on the inside 13 which, in the case of the present embodiment, represents the innermost layer of the layer sequence. In order to increase the proportion of light emitted from the hollow body to the outside, the carrier has 11 on the outside a light decoupling layer 14 on. This light decoupling layer 14 For example, it may be a lens sheet or prism sheet that decouples the light from the glass or plastic support layer due to light scattering.

In 1 one recognizes further that the hollow body in the cylindrical area 22 , (which could also be referred to as a neck area), has a remaining cross-section, for example, round opening. To the inside of the carrier applied OLED layer 12 To protect against moisture and oxygen, this opening in the neck region of the hollow body is gas-tight, that is sealed. Previously, a protective gas can be filled in the interior of the hollow body. The closing of the opening is done by means of a first contact plate 15 , which is fittingly inserted into the opening in the neck region of the hollow body. This first contact plate 15 For example, consists of metal and is soldered after insertion at its outer periphery all around with the glass body of the hollow body. By this solder joint is a gas-tight connection at the periphery of the contact plate 15 achieved between the material pair metal / glass. At the same time contacts the metallic contact plate 15 at its outer periphery, the inner electrode layer 13 (Cathode layer), which extends into the neck region of the hollow body and approximately at the level of the contact plate 15 can end.

How to continue in 1 is at a distance and approximately parallel to the first contact plate 15 a second metallic contact plate 17 arranged, which is also inserted into the round opening in the neck region of the hollow body and further away from the center of the pear-shaped cavity of the hollow body is arranged, corresponding to the distance to the first contact plate 15 , This second contact plate 17 contacted on its outer periphery, the outer electrode layer 23 (see also 2 ) (Anode layer of ITO), which can be seen in the neck region of the hollow body over the inner electrode layer 13 extends beyond.

From the first contact plate 15 starting approximately at right angles extends approximately in the axial direction with respect to the cylindrical portion 22 a first contact pin up to the contact element 21 in the base area of the bulb, this contact pin 16 an electrically conductive connection between the first contact plate 15 and the contact element 21 at the end of the base area 20 manufactures. This first contact pin 16 is through the second contact plate 17 passed through, wherein in the implementation of an electrical insulation against the second contact plate 17 is provided. From the second contact plate 17 from extending to the cavity side facing away also a contact pin 18 , which is a second contact element 19 in the base area 20 the bulb contacted. As with a conventional bulb, the two contact elements 19 and 21 outwardly make the electrical contact to a lamp socket, in which the socket area 20 the illuminant of the invention 10 is screwed.

2 shows an enlarged detail of the wall of the hollow body from which one can see the layer sequence even more clearly. It is a carrier layer 11 For example, made of glass, on the outside of the light-coupling layer 14 located. Inside is the carrier layer 11 with the first electrode layer 23 (For example, anodic layer of ITO) coated. This is followed inward by the OLED layer 12 which can itself have a multi-layered structure. Finally, the second electrode layer closes inwards as the innermost layer 13 (Cathode layer) on. The light is emitted as in 2 indicated by the carrier, which is largely transparent in the example 11 through the light coupling layer 14 to the outside, approximately in the direction of the surface normal of the curved surface of the hollow body of the lamp 10 ,

The example describes by way of example a luminous means according to the invention 10 with a comparatively simple structure. Of course, the layer structure of the rotating body can be significantly more complex in both embodiments. For example, in addition to the layers mentioned, p-doped hole-line layers (HTL), n-doped electron-conducting layers (ETL), high-energy radiation-reflecting layers for protecting the light-emitting layer against UV radiation or layers with other optical functions, in particular light-scattering, light-directing, reflective Layers or layers with the light color changing properties can be provided. Furthermore, it is also possible for there to be a plurality of layers with luminescent nanoscale structures which overlap over the surface of the rotation body or even in regions.

LIST OF REFERENCE NUMBERS

10

Lamp

11

backing

12

Light-emitting layer

13

cathode layer

14

Light decoupling layer

15

first contact plate

16

pin

17

second contact plate

18

second contact pin

19

first contact element in the socket area

20

Sockelbreich

21

second contact element

22

cylindrical area (neck area)

23

anode layer

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2004207081 A [0002]
• EP 1448026 A1 [0004]

Claims (13)

Illuminant, comprising a hollow body which, applied to the inside of a dimensionally stable surface of revolution, or in the surface of revolution itself has a layer or layer arrangement comprising at least one light-emitting layer, at least one first electrode layer and at least one second electrode layer, further comprising means for contacting the electrode layers are provided of the luminous means, and means for gas-tight sealing of the hollow body, characterized in that the means for contacting the electrode layers of the luminous means a (in a cylindrical region 22 ) of the hollow body fitted over the cross section of this cylindrical portion extending first contact plate ( 15 ) having at their periphery the first electrode layer ( 13 ) and arranged at an axial distance from the first contact plate second contact plate ( 17 ), which also extends over the cross section of the cylindrical portion of the hollow body and at its periphery the second electrode layer ( 23 ) contacted. Illuminant according to claim 1, characterized in that the first contact plate ( 15 ) and / or the second contact plate ( 17 ) each one the cross section of the cylindrical portion ( 22 ) Closing gas-tight opening of the hollow body. Illuminant according to one of the preceding claims, characterized in that the first contact plate ( 15 ) and / or the second contact plate ( 17 ) consists of a metallic material and at its periphery with the cylindrical portion ( 22 ) is soldered to the hollow body. Illuminant according to one of the preceding claims, characterized in that at least the cylindrical region ( 22 ) of the hollow body made of glass, a glassy or a ceramic material. Illuminant according to one of the preceding claims, characterized in that the hollow body has a piston shape, candle shape or pear shape and the cylindrical region ( 22 ) is a neck region of the hollow body that is tapered in cross-section. Illuminant according to one of claims 1 to 4, characterized in that the hollow body has a substantially cylindrical shape or tubular shape and the cylindrical portion is a region to be closed at one end or at both ends of the hollow body. Illuminant according to one of the preceding claims, characterized in that the light-emitting layer ( 12 ) of the hollow body comprises an organic light-emitting diode (OLED) layer and / or nanoscale light-emitting structures, in particular quantum dots. Illuminant according to one of claims 1 to 7, characterized in that at least one contact pin ( 16 ) connected to the first contact plate ( 15 ) is electrically conductively connected through the second contact plate ( 17 ) approximately in the axial direction of the cylindrical region (FIG. 22 ), wherein the passage region is electrically insulated from the second contact plate. Illuminant according to one of claims 1 to 8, characterized in that the contact pin ( 16 ) from the first contact plate ( 15 ) starting from a first contact element ( 21 ) in a base area ( 20 ) of the illuminant ( 10 ) extends. Illuminant according to one of claims 1 to 8, characterized in that at least one second contact pin ( 18 ) provided with the second contact plate ( 17 ) is electrically conductively connected and extending from the side facing away from the hollow body of the second contact plate, starting from a contactable second contact element ( 19 ) in a base area ( 20 ) of the bulb extends. Illuminant according to one of the preceding claims, characterized in that the first contact plate ( 15 ) an inner electrode layer ending approximately in its region ( 13 ) of the lamp contacted and the second contact plate ( 17 ) in the cylindrical region ( 22 ) of the hollow body via the inner electrode layer ( 13 ) extending outer electrode layer ( 23 ) of the hollow body contacted. Method for producing a luminous means, in particular according to one of the preceding claims, comprising the steps of first producing a hollow body made of glass, plastic, ceramic, metal, a combination of these materials or another suitable material, with the exception of one or more in proportion To the surface of the hollow body relatively small openings is closed, that in the next step as the carrier ( 11 ) serving inside of the hollow body with one or more light-emitting layers ( 12 . 13 . 23 ) and that finally the remaining opening (s) of the hollow body by means of at least one contact plate ( 15 . 17 ) is sealed gas-tight. Method according to the preceding claim, characterized in that the hollow body at least in the region of its opening made of glass, a vitreous or ceramic material and at least one metallic contact plate ( 15 . 17 ) is soldered at its periphery to the inner circumference of the hollow body in the region of the opening.

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