DE102010014611A1 - Shining module for lamp, has current feed terminals and current dissipation terminals that are arranged facing each other - Google Patents

Abstract

The module (10) has current feed terminals that are formed adjacent to the side portions. The current dissipation terminals are arranged adjacent to the side portions. The current feed terminals and current dissipation terminals are arranged facing each other. An independent claim is included for lamp.

Description

The present invention relates to a lighting module and a luminaire with a plurality of lighting modules, preferably modules with light emitting diodes and / or modules with organic light emitting diodes.

On the basis of organic light-emitting diodes, so-called OLEDs (Organic Light Emitting Diodes), novel surface light elements can be realized. As a flat luminaire with a moderate luminance compared to an inorganic LED, the OLED is ideally suited for the production of flat, diffuse light sources. Especially in the professional lighting sector diffuse lighting is a new possibility for the realization of large-scale high-quality luminaires. In the future, organic light-emitting diodes, with their thin-film technology, can also enable the realization of flexible light sources, which permit completely new applications in the lighting of rooms.

Analogous to inorganic LEDs, OLEDs are current-driven components, i. H. the luminance of the OLED is correlated with the current flowing through the light-emitting active layer of the OLED. In order to realize an OLED emitting uniformly light over its surface, it is necessary to provide a homogeneous current density distribution over the surface of the OLED. However, this presents a particular challenge in the production of large-area light-emitting elements. Typically, an OLED has at least one transparent electrode, which is realized, for example, by means of a transparent conductive oxide (TCO) or by means of transparent metal layers. However, since the electrical conductivity of these transparent electrode materials is low, the homogeneity of the current density distribution is limited. When required homogeneity of the luminance of the maximum achievable luminous area size is limited.

A standard structure of an OLED has, for example, an organic layer between a transparent ITO electrode (ITO = indium tin oxide) and a metallic cathode. By applying a suitable voltage between these two electrodes, electromagnetic radiation is emitted within the organic layer, in particular light in the optically visible range or infrared radiation. The ITO electrode can be applied to glass with a thickness of about 100 nm. The organic layer may have a plurality of partial layers, for example up to seven partial layers and a thickness of 100 to 200 nm. The metallic cathode may, for example, have a thickness of 100 to 500 nm and consist of aluminum. Such a comparatively structured OLED can also be referred to as an OLED panel.

In the case of large-area light-emitting elements, the high-resistance resistance of the ITO layer now leads to an inhomogeneity of the current feed, since the contacts of the ITO layer are only possible at the edge of the light-emitting element. This limits the maximum size of a uniformly luminous OLED to approx. 50 × 50 mm ² .

In order to achieve luminous elements with a larger light emission area, metal reinforcements in the form of nets in particular can be introduced into the ITO layer. These metal reinforcements, which are also referred to as "metal grids" or "busbars", lower the effective sheet resistance according to their occupation density and thus allow the realization of larger diodes surfaces. However, due to the lack of transparency of these gains, they lower the effective luminous area. For this reason, metal reinforcements up to approx. 25% of the ITO area make sense at all. One possible improvement would be to increase the thickness of the reinforcement metal. However, this is not meaningful due to the structuring possibilities and the layer thicknesses of the organic layers. Furthermore, the metal-reinforced ITO layer is only contacted at the outer edges, which limits the maximum luminous element area despite the effective reduction in resistance.

In order to achieve luminous elements with a large light emission surface, large OLED surfaces can be subdivided into a plurality of smaller individual OLED surfaces, which are referred to below as OLED modules. Due to the smaller size of a single OLED surface, it is now relatively easier to realize this single OLED surface as uniformly luminous OLED. If these individual OLED areas (OLED modules) are combined to form a larger illuminated area, an electrical contacting system is required for efficient control.

Known contact configurations relate to contacting techniques on the OLED panel itself, ie on the glass substrate or an OLED background film. External contacts are connected via spring contacts or similar electrical contacts with a distributor plate. Since the total current for anode and cathode is supplied or discharged via these contacts, the contact must be at least two-part. In a common standard form, two opposing edges are connected to the anode and two opposing edges normal to the edges to the anode are connected to the cathode. This leads to non-optimal terminals, since the connection resistance between the cathode and anode are different. Furthermore, such an arrangement of the contacts not reverse polarity protected. If the plate is rotated by 90 ° and brought into contact with the external contacts, this leads to a polarity reversal of the light panel.

A modification of such a contact configuration is to provide a contact on two opposite sides of a board, as in, for example, US Pat 7 of the EP-A 14367674 can be seen. Another known contact configuration leads all contacts to one side of a light panel, such as the 2 and 6 of the EP-A-1367674 can be seen.

When contacting several panels as OLED modules, the focus is on a simple contact. So revealed the US-B2-7271534 a simple segmented port configuration, which is not solvable. The DE-A1-10 2007 061 473 discloses a radiation-emitting device having a frame in which ridge structures are provided to define portions that are sized to enable the inclusion of radiation-emitting organic devices. Each edge enclosing a partial region has a conductive region on all sides, wherein the radiation-emitting organic components are contacted via these conductive regions. However, such systems do not allow any involvement of a control or bus system, nor is an indirect contacting of the OLED panels carried out.

There is thus a need for a way to contact individual OLED modules that are suitable for large-area light elements, and in particular to contact reverse polarity.

A further need exists for a lamp, in particular a large-area lamp, with corresponding modules.

According to the invention, this need is solved by a lighting module according to claim 1 and a luminaire according to claim 9.

• einem Modulkörper, der zumindest vier Seiten aufweist, von denen sich eine erste Seite und eine zweite Seite gegenüberliegen;
• einem ersten Stromzuleitungsanschluss, der benachbart zu der ersten Seite gebildet ist;
• einem zweiten Stromzuleitungsanschluss, der benachbart zu der zweiten Seite gebildet ist;
• einem ersten Stromableitungsanschluss, der benachbart zu der ersten Seite gebildet ist; und
• einem Stromableitungsanschluss, der benachbart zu der zweiten Seite gebildet ist, wobei sich der erste Stromzuleitungsanschluss und der zweite Stromableitungsabschluss gegenüberliegen und wobei sich der zweite Stromzuleitungsanschluss und der erste Stromableitungsanschluss gegenüberliegen.

Embodiments of the invention provide a lighting module having the following features:

• a module body having at least four sides, of which a first side and a second side are opposed to each other;
• a first power supply terminal formed adjacent to the first side;
• a second power supply terminal formed adjacent to the second side;
• a first current dissipation terminal formed adjacent to the first side; and
• a current-carrying terminal formed adjacent to the second side, facing the first power-supply terminal and the second current-carrying terminal, and facing the second power-supply terminal and the first current-discharging terminal.

A corresponding arrangement of power supply connections and current discharge connections thus makes it possible, according to the exemplary embodiment in the invention, to securely and effectively interconnect larger OLED areas by means of a reverse polarity-proof interconnection system. In other words, it is possible to connect a lighting module according to the invention, for example for implementing a large-area lighting body, irrespective of whether the lighting module is rotated by 180 ° in a plane that is parallel to a main surface thereof.

Embodiments of the invention include third and fourth power supply terminals and current drain terminals on third and fourth sides which are opposed to each other, so that, in turn, each of power supply terminals and power discharge terminals face each other. In such embodiments, a reverse polarity connection is possible, regardless of whether the light module is twisted in 900 steps.

In exemplary embodiments of the invention, the light-emitting module has a light-emitting diode and in particular an OLED, wherein the current supply terminals are anode terminals and the current discharge terminals are cathode terminals. A plurality of corresponding lighting modules, which have OLEDs, can be connected in order to implement large-area luminous bodies.

Embodiments of the present invention thus provide a luminaire having the following features:
a plurality of corresponding lighting modules; and
Connection structures which electrically connect a current discharge terminal of an upstream lighting module to a power supply terminal of a downstream lighting module, so that the lighting modules are connected in series.

The connection structures may be configured to provide a non-detachable connection or a detachable connection.

In embodiments of the invention, current supply terminals and current discharge terminals extend differently far away from the respective associated edge, so that a current-carrying part of the contact always is outside the contact of the ground, so that a reverse polarity of the system is impossible.

In embodiments of the invention, the lighting modules further comprise one or more control bus terminals, which are respectively arranged adjacent to the first and the second side. These control bus connections can be designed in such a way that when the lighting module is rotated through 180 °, a bus is not connected. For this purpose, a control bus connection can extend further from the side adjacent to it in the direction of the side opposite to it, as a control bus connection which comes to lie at a position of this control bus connection when the lighting module rotates through 180 ° C. In embodiments of the invention, the lighting modules or a holder for the lighting modules may have a corresponding logic circuit to allow connection of the lighting modules to a control bus to allow the integration of a light control or sensor bus for professional control of large areas of light. For example, embodiments of the invention allow connection to known professional lighting controls, for example, in the form of a DALI bus (DALI = digital addressable lighting interface) or a DMX bus (DMX = digital multiplex).

Preferred embodiments of the present invention will be explained below with reference to the accompanying drawings. Show it:

1 schematically a series connection of a plurality of lighting modules;

2a and 2 B schematic representations to illustrate the construction of an embodiment of a lighting module;

3 schematically a bottom view of an embodiment of a lighting module;

4 schematically a bottom view of another embodiment of a lighting module;

5 schematically a representation of an embodiment of a lamp;

6 schematically a representation of an embodiment of a lamp;

7a and 7b schematic representations illustrating an embodiment of the invention with permanent contact; and

8a and 8b schematic representations to illustrate an embodiment with detachable contacting.

1 schematically shows a series connection of three lighting modules 10 , which may be formed for example by OLED panels. Each light module has an OLED with an anode terminal A, a cathode terminal K and an active area 12 on. The OLEDs may have a conventional structure as described above. The anode terminal A of the first lighting module and the cathode terminal K of the last lighting module are with corresponding potentials 14 and 16 connected so that the OLEDs are poled in the flow direction and thus emit light. The anode A of each OLED represents thereby a current supply connection and the cathode of each OLED represents a Stromableitungsanschluss. As in 1 is shown, in each case the cathode of an upstream OLED is connected to the anode of a downstream OLED, so that the OLEDs are connected in series.

The 2a and 2 B show schematically representations for illustrating a light module. It shows 2a a side view while 2 B a sectional view taken along a line bb of 2a shows.

As in the 2a and 2 B As shown, the light module may be an OLED panel 60 which may also be referred to as OLED plate or OLED film. The OLED panel has electrical contacts 62 . 62b on all four corners, with contacts 62 Anode contacts and contacts 62b Can represent cathode contacts. However, the arrangement of the anode contacts and cathode contacts on the OLED panel is insignificant and may differ from the arrangement described. The OLED panel 60 has planar electrodes (not shown) which allow a homogeneous current feed into an active region located therebetween. One of the flat electrodes is with the anode contacts 62 connected and one of the flat electrodes is connected to the cathode contacts 62b connected. The OLED panel 60 is about a glue 64 , which may be a thermally conductive adhesive, with a circuit board 66 mechanically connected. The board 66 provides an electrical connection between terminals 68 on one of the OLED panel 60 facing away from the main surface of the board 66 are arranged, and the anode contacts and cathode contacts 62 and 62b , More specifically, the connectors indicate 68 Anode or Stromzuleitungsanschlüsse on, with the anode contacts 62 are connected, and cathode or Stromableitungsanschlüsse connected to the cathode contacts 62b are connected. The anode terminals and cathode terminals of the light module can in the way be arranged on the side facing away from the OLED panel side, as herein with reference to the 3 . 4 . 7a . 7b . 8a and 8b is described. The board 66 thus provides a wiring between the contacts of the OLED panel and the anode terminals or cathode terminals arranged according to the invention. The inventive arrangement of the cathode and anode connections a user-friendly for a lighting manufacturer contacting, for example by means of spring contacts, allows. The arrangement of the cathode and anode connections can be standardized. At the same time, the current is switched to one or more contact points by means of the board 62 . 62b of the OLED panel, which are arranged on the OLED panel so that an optimal power supply is made possible. The contact points 62 and 62b The OLED panel can be individually adapted to the particular OLED panel used.

The board can be used in addition to the wiring function for mechanical stabilization. Further, it may preferably be constructed of good thermally conductive material or have areas that pass heat well, in order to efficiently forward or dissipate the heat generated during operation of the OLED panel. Furthermore, logic circuits can be integrated into the board.

3 schematically shows a main surface of a module body 20 a light module 10 who is a first page 22 and a second page 24 which are opposite and parallel to each other. The module body 20 can, for example, through the board 66 be formed. In alternative embodiments, which do not have a circuit board, the module body may be formed by the OLED panel.

Next to the first page 22 a first cathode terminal K1 and a first anode terminal A1 are provided. Adjacent to the second page 24 a second cathode terminal K2 and a second anode terminal A2 are provided. In this context, "adjacent" should be understood to mean an arrangement in which the corresponding electrode connections are arranged at least closer to the adjacent side than on the opposite side. In embodiments of the invention, the terminals each extend from the adjacent edge toward the opposite side. Alternatively, however, the terminals could also be arranged at a distance from the edge.

As in 3 1, the first anode terminal A1 faces the second cathode terminal K2, and the first cathode terminal K1 is opposite the second anode terminal A2. Twisting the module body 20 by 180 °, the cathode terminal K2 comes to lie at the position of the cathode terminal K1 and the anode terminal A2 comes to rest at the position of the anode terminal A1. Thus, allows a port configuration, as in 3 is shown, a reverse polarity protected interconnection, as it is irrelevant whether the light module, starting from the in 3 shown state, rotated by 180 ° or not.

4 schematically shows a main surface of a module body 20 an alternative embodiment of the invention. In this embodiment, cathode terminals K3, K4 and anode terminals A3, A4 are also on a third side 26 and a fourth page 28 which are opposite, provided. The third cathode terminal K3 faces the fourth anode terminal A4, and the third anode terminal A3 faces the fourth cathode terminal K4. Upon a rotation of the in 4 90 ° each anode body and cathode connections come to lie at the same positions, so that here a polarity reversal can be achieved even with rotations of 90 °.

For the purposes of this disclosure, in the case of sides which are opposite each other and which are essentially parallel to one another, the term "opposite" in connection with the respective connections means that these are located on an imaginary line which is substantially perpendicular to the sides, to which the terminals are adjacent, face each other.

In general terms, therefore, the anode terminals are each arranged such that they come to lie at a same position (along the circumference of the lighting modules) at a rotation in a plane parallel to the main surfaces of the lighting modules by 180 ° or 90 °. The same applies to the cathode connections. Thus, a polarity-reversible contacting is possible, regardless of whether the lighting modules in the plane of the main surfaces thereof are rotated by 180 ° or 90 ° or not.

In 3 and 4 a module body with four sides was described. In alternative embodiments, the module body may also have more sides, for example 6 or 8 sides, with corresponding anode terminals and cathode terminals arranged on at least two opposite sides. Likewise, a variant with 3 sides is possible, in which the module body has a triangular base. In each case, an anode and a cathode connection are arranged on each side of the module body, so that upon rotation in a plane parallel to the main surface of the light module by 120 ° or 240 °, the anode and cathode terminals each come to rest at the same positions (along the circumference of the lighting modules). The opposite sides of the triangular module body are not parallel to each other in this case. It is also possible that the module body has a different basic shape than the OLED panel. For example, in an alternative embodiment, a round OLED panel may be arranged on a module body with a quadrangular basic shape.

5 shows an embodiment of a lamp 40 , the four lighting modules 10 as they are in 3 are shown. The lamp 40 includes a carrier plate 42 on which the light modules 10 are arranged. On the carrier plate 42 are connection structures 44 provided, with each of which the cathode of an upstream lighting module is connected to the anode of a downstream lighting module. Furthermore, in 5 a connection structure 46 shown, via which the anode of the first lighting module can be connected to a corresponding potential, for example a positive supply voltage, while with 48 a connection structure is shown, via which the cathode of the last lighting module can be connected to a corresponding supply potential, for example ground. The connection structures 44 For example, on the carrier plate 40 be provided conductor tracks, which can not be connected to the corresponding terminals of the lighting modules in a detachable manner. For example, the lighting modules on the support plate 40 be glued on. Alternatively, the connection structures for a detachable connection, e.g. B. by spring contacts, be designed. At this point it should be noted that the carrier plate 40 and the connection structures arranged thereon 44 . 46 and 48 are shown transparent to recognize the underlying lighting modules can.

6 shows a schematic representation of an alternative embodiment, in which four lighting modules, as shown in 4 are shown on a support plate 50 are arranged, in turn, corresponding connection structures 44 . 46 and 48 having. While in 5 the lighting modules are arranged in a row, are in 6 the lighting modules arranged in two rows. It will be appreciated that embodiments of the invention thus enable interconnecting a plurality of lighting modules in various and varied ways to implement large area lighting fixtures. How out 5 can be seen, a reverse polarity protection is possible, regardless of whether the lighting modules are rotated by 180 ° or not. Out 6 It can be seen that a polarity-protected interconnection is possible, regardless of whether the lighting modules are rotated by 90 °, 180 ° or 270 °.

The 7a and 7b schematically show an alternative embodiment of lighting modules according to the invention. Here are in the 7a and 7b a first light module 70 and a second light module 72 shown the connection structures 90 are interconnected. The light modules each have an OLED panel 74 respectively. 76 and a board 78 respectively. 80 on. The contacts (not shown) of the OLED panel 74 and 76 are over the board 78 and 80 led to the back of the elements in order to realize a robust interconnection from there. More specifically, in this embodiment, on two opposite sides 22 and 24 of the module body 20 four contacts or connections attached. More precisely, the connections are on the respective board 78 respectively. 80 executed.

The to the side 22 Adjacent terminals include a power supply terminal 82 , a current drain connection 84 , and two control bus connections 86 and 88 , The to the side 24 Adjacent terminals include a power supply terminal 82 ' , a current drain connection 84 ' , and two control bus connections 86 ' and 88 ' ,

In the top view of 7a are the connection structures 90 congruent with the respectively arranged below terminals shown. It should be noted, however, that the connection structures 90 surface area larger or smaller than the terminals can be, as long as an electrical connection between the respective connection structure 90 and connection 82 to 88 respectively. 82 ' to 88 ' is delivered.

In operation is the power supply connection 82 connected to such a potential that it supplies a power supply, while the current dissipation terminal 84 ' associated with such a potential, z. B. ground or a power supply connection of a downstream module that it provides a current drain. About the tax bus connections 86 and 88 For example, a two-wire bus, for example a bus of a Dali bus system or a DMX bus system, can be contacted.

Corresponding connections are also on the corresponding opposite sides of the second light module 72 intended.

As in the 7a and 7b is shown schematically, the modules are via connection structures 90 connected with each other. More specifically, four connection structures are provided, which are the contacts 82 ' . 84 ' . 86 ' and 88 ' of the module 70 with the contacts 82 . 84 . 86 . 88 of the module 72 connect.

As in 7a can be seen, the configuration of the lighting modules is such that a power supply connection 84 respectively. 84 ' within each module one ground connection 82 ' respectively. 82 opposite. Furthermore, the configuration is designed so that when modules connect 70 and 72 the current drain connection 84 ' of the module 70 the power supply connection 82 of the other module 72 opposite. By connecting these connections, a simple series connection without crossing points is possible. Furthermore, there are the connection 82 ' of the module 70 and the connection 84 of the module 72 across and over a connection structure 90 connected. It should be noted, however, that this connection is not required to implement the described series connection.

By connecting the control bus connections 86 ' and 88 ' of the light module 70 with the tax bus connections 88 and 86 a simple forwarding of the tax bus can be achieved.

The arrangement of the connections shown a simple connection by simply contacting all the connections of both modules is possible without cross-over of lines are required.

As in 7a can be seen, the power line connection extends 82 further away from the page 22 off as the power drain close 84 , Furthermore, the control bus connection extends 88 further away from the page 22 away as the control bus terminal 86 , In the embodiment shown have the connections 82 and 88 the same length and connections 84 and 86 have the same length. The lengths of the connections 82 ' . 84 ' and 86 ' correspond to those of the connections 82 . 84 and 86 , However, the control bus connection points 88 ' a shorter length than the control bus connection 86 ' , The importance of this particular embodiment of the connections will be described below with reference to FIGS 8a and 8b discussed in more detail.

In the in the 7a and 7b In the embodiment shown, the connection structures are designed to provide a non-detachable connection between the lighting modules 70 and 72 to deliver. The connection structures 90 can be suitably arranged on a carrier plate which can be glued, for example, to the lighting modules in order to implement both a mechanical connection and the necessary electrical connections.

The different lengths of the terminals are particularly in the implementation of a releasable connection, as described below with reference to 8a and 8b is explained, advantageous. Alternatively, the terminals may each have an equal length, ie extend equidistant from the respective adjacent edge away.

The 8a and 8b show schematic representations to illustrate an embodiment of a reverse polarity protected circuit system with detachable contacting. In the top view of 8a is only the light module 72 shown while in the side view of 8b the light module 72 and a lower part of the light module 70 is shown.

The structure of the lighting modules 70 and 72 can correspond to the structure, as above with reference to the 7a and 7b was explained.

As in 8b is shown, is a Kontaktierungshaltersystem 90 intended to implement detachable connections. The contacting holder system 90 has a carrier plate 91 and contacts 92 . 92 ' on, which can be designed as spring contacts. The places where the contacts of the Kontaktierungshalter system 90 on the connections 82 to 88 and 82 ' to 88 ' meet the board are, for illustrative purposes in the plan view of 8a shown as black square dots.

contacts 92 are with respective contacts 92 ' connected by conductive connections (not shown) on the carrier plate to implement the necessary electrical connections between two lighting modules to connect the lighting modules in series. This can be done on or in the carrier plate 91 appropriate conductive structures may be provided. The carrier plate 91 may be formed as a single-layer or multi-layer wiring substrate.

For example, the contacts 92 ' that the light module 70 are shown opposite, with the contacts 92 that the light module 72 are shown opposite, connected to connect the corresponding terminals of the two lighting modules together. Thus, a series connection of the lighting modules is possible via the corresponding supply connections (power supply connections and current discharge connections), while integration into a control bus system is possible via the corresponding control bus connections.

In order to achieve a corresponding interconnection, the lighting modules are mechanically with coupled to the Kontaktierungshalterungssystem, so that the spring contacts the corresponding terminals 82 to 88 and 82 ' to 88 ' to meet. To illustrate this are the places where the contacts 92 respectively. 92 ' to hit the connectors of the board, in 8a represented by black square dots, one of which is denoted by the reference numeral 100 is designated. A detachable mechanical connection or holder between the lighting modules 70 . 72 and the Kontaktierungshaltersystem 90 can be done in any suitable manner, for example by suitable clamping devices, snap devices, screwing devices or the like. Such devices can in particular allow the replacement of individual lighting modules.

As 8a can be seen, is the position of the connections 82 to 88 and 82 ' to 88 ' as well as the contacts 92 and 92 ' designed so that when a rotation of the module by 180 ° no short circuit of the module can come about and in addition always the current-carrying part of the contact outside the current-draining part (ground) of the contact is, so that a reverse polarity of the system is impossible. This is achieved by the power supply connections 82 . 82 ' are longer than the current drain connections 84 . 84 ' and in that the contacts for the power supply terminals are offset further inwardly with respect to the respective side edge than the contacts for the current discharge terminations.

Further, the control bus connection 88 longer than the tax bus connection 88 ' ie the control bus connection 88 sticks out from the side 22 inside as the tax bus terminal 88 ' of the page 24 protrudes inwards. The places where the connections 88 and 88 ' associated contacts on the Kontaktierungshaltersystem to the terminals 88 and 88 ' meet, are in 8a with the reference numerals 96 and 96 ' designated. The corresponding contacts are on the Kontaktierungshaltersystem 90 arranged such that they have a different distance from the respective edge of the lighting module when the lighting module is mechanically coupled to the Kontaktierungshaltersystem in the correct orientation. However, if the light module is rotated by 180 °, at least the contact with the correct orientation contacts the connection 88 associated contact the shorter control bus connection 88 ' not so that a connection to the control bus does not take place. Such a procedure makes sense if specified polarities must be adhered to when connecting the control bus. If such given polarities are not met, for example when using a single-wire bus, the control bus terminal (s) can be designed to permit a connection of the control bus, irrespective of the orientation of the light-emitting module.

The contacting holder system 90 may have a plurality of corresponding contacts or contact points to interconnect a plurality of lighting modules according to the above embodiments. In particular, the contacting holder system can be designed to connect a plurality of lighting modules in series. In embodiments, the Kontaktierungshaltersystem can also be designed to allow the integration of a light control or sensor bus (generally Steuerbusses) for a professional control of large areas of light. In the implementation of a light control or sensor bus, either the individual lighting modules or the Kontaktierungshaltesystem may have corresponding logic circuits to allow control of the lighting modules, which is independent of the control of other lighting modules, such as switching on and off of individual modules or dimming of individual modules ,

In exemplary embodiments of the present invention, the lighting modules have a module body whose main surfaces are rectangular, in particular square. In alternative embodiments, the major surfaces may be polygonal, such as hexagonal or octagonal. Preferably, at least two sides lie opposite each other substantially parallel, so that a reverse polarity-proof connection can be achieved independently of at least two possible orientations of the module body.

Embodiments thus provide OLED surfaces, which are subdivided by means of smaller OLED modules, wherein the OLED module system can be set up releasably or non-detachably contacted. In embodiments, the OLED modules are designed interchangeably to allow replacement due to the limited life. Embodiments of the present invention enable a detachable connection to be constructed with reverse polarity protection. Large OLED areas can be realized, with the possibility of exchanging individual OLED modules. Embodiments of the present invention also offer the possibility of integrating not only the electrical contacting but also professional lighting controls, for example in the form of a two-wire bus (for example a Dali bus or DMX bus).

In the described embodiments of the invention, the respective terminals are arranged on an underside of the lighting module. In alternative embodiments, the terminals may also be disposed on side surfaces connecting the two main surfaces, if the corresponding contact points are also arranged mating a Kontaktierungshaltersystem, for example, on the side walls of respective recesses in the Kontaktierungshaltersystem. Here, main surfaces are to be understood as meaning the, generally parallel, surfaces of the module body which have the largest surface area.

Referring to the 7a . 7b and 8a . 8b Exemplary embodiments have been described in which control bus connections 86 . 88 . 86 ' and 88 ' between power supply connections 82 . 84 . 82 ' . 84 ' are arranged. In alternative embodiments, other arrangements are possible, for example, the power supply terminals 82 . 84 . 82 ' . 84 ' be juxtaposed adjacent to each other and the control bus terminals on one side or both sides thereof.

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

• EP 14367674A [0009]
• EP 1367674A [0009]
• US 7271534 B2 [0010]
• DE 102007061473 A1 [0010]

Claims (15)

Light module ( 10 ) having the following features: a module body ( 20 ), which has at least four pages ( 22 . 24 . 26 . 28 ), of which a first page ( 22 ) and a second page ( 24 ) are opposite; a first power supply terminal (A ₁ ; 82 ), which is adjacent to the first page ( 22 ) is formed; a second power supply terminal (A ₂ ; 82 ' ), which is adjacent to the second page ( 24 ) is formed; a first current dissipation terminal (K ₁ ; 84 ), which is adjacent to the first page ( 22 ) is formed; and a second current dissipation terminal (K ₂ ; 84 ' ) formed adjacent to the second side; wherein the first power supply terminal (A ₁ ; 82 ) and the second current dissipation terminal (K ₂ ; 84 ' ) and wherein the second power supply terminal (A ₂ ; 82 ' ) and the first current dissipation terminal (K ₁ ; 84 ) are opposite. Illuminating module according to Claim 1, in which the module body ( 20 ) a third and fourth page ( 26 . 28 ), which are facing each other, further comprising: a third power supply terminal (A ₃ ) adjacent to the third side (A ₃ ) 26 ) is formed; a fourth power supply terminal (A ₄ ) adjacent to the fourth side (A ₄ ) 28 ) is formed; a third current discharge terminal (K ₃ ) adjacent to the third side ( 26 ) is formed; and a fourth current discharge terminal (K ₄ ) adjacent to the fourth side ( 28 ), wherein the third current discharge terminal (A ₃ ) and the fourth current discharge terminal (A ₄ ) face each other, and wherein the fourth current supply terminal (A ₄ ) and the third discharge terminal (K ₄ ) face each other. A light module according to any one of claims 1 or 2, comprising a light emitting diode, wherein the power supply terminals are anode terminals and the current discharge terminals are cathode terminals. Illuminating module according to claim 3, comprising: an organic light-emitting diode ( 60 with an active region between a first conductive layer and a second conductive layer; and a board ( 66 ) on which the cathode terminals and the anode terminals are formed, wherein the cathode terminals are electrically connected to the first conductive layer and the anode terminals to the second conductive layer. Lighting module according to one of claims 1 to 4, further comprising the following features: at least one control bus terminal ( 86 . 88 ), which is adjacent to the first page ( 22 ), and at least one second control terminal ( 86 ' . 88 ' ) disposed adjacent to the second side opposite the first control bus terminal. Illuminating module according to claim 5, comprising two control bus terminals ( 86 . 88 ), which are adjacent to the first page ( 22 ), the two control bus terminals ( 86 ' . 88 ' ) disposed adjacent to the second side. Illuminating module according to one of Claims 5 or 6, in which at least one control bus connection ( 88 ) further from the side adjacent to it ( 22 ) towards the opposite side ( 24 ) extends as a control bus terminal ( 88 ' ), which is at a rotation of the light module by 180 ° at the position of this control bus terminal ( 88 ) comes to rest. A lighting module according to any one of claims 5 to 7, comprising logic configured to control the lighting module independently of the other lighting modules based on control signals. Lighting module according to one of claims 1 to 8, wherein the power supply terminals (A ₁ to A ₄ ; 82 . 82 ' ) and the current discharge terminals (K ₁ to K ₄ ; 84 . 84 ' ) on a main surface of the module body ( 20 ) are formed. A lighting module according to claim 9, wherein the first and second current supply terminals (A ₁ , A ₂ ; 82 . 82 ' ) from the adjacent side ( 22 . 24 ) extend differently far toward the opposite side than the first and second current dissipation sections (K ₁ , K ₂ ; 84 . 84 ' ) extend from the respective adjacent side to the opposite side. Luminaire with the following features: a plurality of light modules ( 10 ) according to any one of claims 1 to 10; and connection structures ( 44 ; 90 ; 92 . 92 ' ), which electrically connect a current discharge terminal of an upstream lighting module to a power supply terminal of a downstream lighting module, so that the lighting modules are connected in series. Luminaire according to Claim 11, in which the connecting structures ( 90 ) are designed to provide a non-detachable connection. Luminaire according to Claim 12, in which the connecting structures ( 92 . 92 ' ) are designed to provide a detachable connection. Luminaire according to Claim 13, in which the connecting structures have spring contacts ( 92 . 92 ' ) exhibit. Luminaire according to one of claims 11 to 14 with a connection structure holding device having connection structures for a plurality of lighting modules and which is designed for mechanical coupling with the plurality of lighting modules, so that they are connected in series by the connecting structures.

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