FR3071037A1 - LUMINOUS MODULE FOR MOTOR VEHICLE - Google Patents

Abstract

A light module (1) for a vehicle comprises at least two organic light-emitting diodes (20) and a printed circuit board for at least partial control of the organic light-emitting diodes (20). Each organic electroluminescent diode (20) is connected to the printed circuit board via a flexible printed circuit (4) common to all organic light emitting diodes (20).

Description

The field of the present invention is that of light modules arranged in light devices, for lighting and / or signaling for motor vehicles, and the present invention relates more particularly to light modules which use at least one light-emitting diode organic.

Aesthetic and regulatory developments and the evolution of weight and space constraints of the components of a motor vehicle are making it increasingly sought after to produce light devices for lighting and / or signaling. of the vehicle, which combine extensive aesthetic possibilities with light power, long service life, small footprint, flexibility and ease of implementation. In this sense, the use of light modules comprising one or more light sources comprising one or more light-emitting diodes and, in particular, one or more organic light-emitting diodes, is a research and development path which opens up wide possibilities both in terms of optical performance in terms of design flexibility.

An organic light emitting diode conventionally comprises two electrodes between which is placed a set of organic layers which, under the effect of a voltage applied between the two electrodes, emit light. The assembly formed by the electrodes and the organic layers is generally sandwiched between two substrates of a translucent material. On a practical level, an organic light emitting diode for a light module arranged in a light device, for the lighting and / or signaling of a motor vehicle is conventionally composed of an emitting part formed by the organic layers, the electrodes and the aforementioned substrates, and a base on which the emitting part is fixed, for example by an adhesive, the assembly being connected to an electrical supply and control device by suitable connection means.

Organic light emitting diodes are increasingly used in the automotive field, both for lighting or signaling the vehicle itself and for aesthetic reasons, in particular for questions of visual and light signature of the vehicle. In this context, the present invention can in particular find an application in light devices intended for rear signaling of motor vehicles.

A light device comprises, in known manner, a housing closed by a glass, the housing and the closing glass together delimiting a reception volume of one or more light modules respectively comprising at least one light source. Each light module further includes a light source support which separates the reception volume into an optical volume, visible from outside the vehicle, in which the emitting parts of the light sources are located, and a technical volume in which are located. the elements for connecting the light sources to an electrical power supply and control device for these sources.

A drawback of the use of these organic light-emitting diodes lies in the multiplicity of electrical connections of these sources by means of wired connections. In fact, the emitting part of these organic light-emitting diodes is advantageously segmented and each of the segments requires a specific connection to the power supply and control device for these sources. A light module usually includes a plurality of light sources, which further increases the number of wires required, which poses problems of integration, reliability and assembly time for the electrical connection.

The present invention is part of this context and aims to propose a light module comprising organic light-emitting diodes whose electrical connection is simplified and made more reliable.

An object of the present invention thus relates to a light module for a vehicle, comprising at least two organic light-emitting diodes and a printed circuit board intended for driving, at least partially, organic light-emitting diodes. According to the invention, each organic light emitting diode is connected to the printed circuit board by means of a flexible printed circuit common to all the organic light emitting diodes.

In the remainder of the document, the organic light emitting diodes will be called indifferently "organic light emitting diodes" or "OLED diodes" according to the acronym for "Organic Light Emitting Diode".

It is understood that, according to the invention, a single flexible printed circuit makes it possible to connect all of the organic light-emitting diodes to the printed circuit board intended for the power supply and for controlling the latter. The term “printed circuit board” means a rigid plate, based on FR4 or SMI technology for example, and on which electrical circuits are engraved.

It is understood that the light module according to the invention comprises a plurality of connectors which allow connections to be made on the one hand between each of the OLED diodes and the flexible printed circuit, and on the other hand between this flexible printed circuit and the printed circuit, it being understood that the number of electrical connections is reduced here compared to wired connections of the prior art. In other words, the light module comprises at least three connectors, two of them making it possible to connect each of the OLED diodes to the flexible printed circuit and the third making it possible to connect this flexible printed circuit to the printed circuit board.

Advantageously, the use of a single flexible printed circuit to make the connection of all the OLED diodes with the printed circuit board makes it possible to considerably reduce the number of separate connection means to be integrated into the light module. This facilitates the assembly of the light module and ensures mounting reliability in the significant reduction in the number of operations. The light module according to the invention is of great interest for this purpose when the light module is equipped with a large number of OLED diodes.

According to a characteristic of the invention, a plurality of electrical circuits, of the copper track type, is etched on said flexible printed circuit common to all organic light-emitting diodes, said electrical circuits being configured so as to be grouped at one of their ends. in a first connection zone to the printed circuit board and so as to be distributed in second connection zones specific to each organic light-emitting diode. It is understood that there are as many second connection zones as the light module comprises organic light-emitting diodes.

According to a characteristic of the present invention, the light module comprises at least one connector of the CMS type.

Advantageously, each connector of the light module is a CMS type connector, that is to say that these connectors are secured to one of the components which they participate in connecting, namely the flexible printed circuit common to all the diodes, light emitting diodes or the printed circuit board, by soldering. In other words, these connectors are arranged on the surface of the aforementioned components, and do not have a through pin.

According to the invention, the light module comprises at least one ZIF type connector.

"ZIF type connector" means a "Zero Insertion Force" connector, from the English acronym. Advantageously, this type of connector comprises a male element and a female element respectively comprising pins to be made to cooperate in order to make the electrical connection, with the female element which comprises removable pins, capable of being placed in a withdrawal position in which the pins do not oppose the insertion of the male element and an active position in which the pins of the female element are pressed against the pins of the male element. Thus, the connector can be assembled without effort, or with little effort, thus limiting the risk of damage to the connector itself or to the component on which it is assembled, in this case the printed circuit board, the circuit flexible print or one of the organic light emitting diodes.

Alternatively, a LIF type connector can be chosen, corresponding to the acronym "Low Insertion Force", in which the electrical connection and the locking are carried out successively during the insertion of the flexible male element into the female element of the connector, without requiring a separate locking operation.

The connector (s) used according to the invention comprise a male element formed by a free end of a flexible printed circuit, where appropriate the flexible printed circuit common to all organic light-emitting diodes, and a female element made integral by soldering flexible printed circuit board, organic light emitting diodes or the printed circuit board.

According to different embodiments of the invention, such a female element of a CMS connector of the LIF or ZIF type can be made integral with the flexible printed circuit to cooperate with a male element arranged at the end of an additional flexible printed circuit fixed on the OLED diode, or else be made integral with the printed circuit board to cooperate with a male element arranged at the end of the flexible printed circuit common to all organic light emitting diodes.

It is understood that a light module according to the invention can comprise these variants cumulatively or alternatively.

According to a characteristic of the invention, part of the electronics for driving organic light-emitting diodes can be carried by the flexible printed circuit common to all organic light-emitting diodes. Advantageously, the electronic elements having an interest in being arranged close to the OLED diodes, such as for example, a device for protection against electromagnetic fields, a device for electrostatic protection, temperature sensors, or even a current regulator can thus be carried by the flexible printed circuit. Optionally, the OLED diode control electronics can be fully carried by the flexible printed circuit. In this situation, the rigid printed circuit board continues to supply electrical power to these OLED diodes - via the flexible printed circuit - and can also ensure the control of any other light sources which may be present elsewhere in the module. luminous.

According to features of the invention, the organic light emitting diodes extend in a series along a transverse axis and the flexible printed circuit common to all the organic light emitting diodes extends mainly along this transverse axis. All of the connectors connecting this flexible printed circuit to each of the organic light-emitting diodes can be arranged on the same edge of the flexible printed circuit.

Advantageously, each organic light-emitting diode comprises at least two distinct emission zones, each configured to emit at least one light ray.

It is understood that the independence of these emission zones from each other complicates the connections to be made, since each emission zone has its own connection. It is understood that the use of a single flexible printed circuit common to all the organic light-emitting diodes again makes it possible to simplify these connections and thus reduce the total size of the light module.

Optionally, the light module according to the invention may comprise at least one other light source, this at least one other light source being controlled, at least partially, by the printed circuit board of said light module. In other words, the printed circuit board, at least partially, the organic light emitting diodes as well as the at least one other light source.

The invention also relates to a light device for lighting and / or signaling a vehicle, comprising a housing in which is housed at least one light module according to the invention, the housing also housing at least one support for organic light emitting diodes of this light module, this at least one support comprising at least one member for positioning the flexible printed circuit.

Such a light device may in particular consist of a projector, a taillight or an interior lighting device. Advantageously, the segmentation of the OLED diodes into different emission zones makes it possible, as a function of ignition instructions sent to each emission zone independently of the others, to form various light beams. The light device according to the invention can, by way of example, be used both for a rear position signaling function and for a direction indicator function, it being understood that the optical function performed by this device light is not limitative of the invention.

Advantageously, the support for organic light-emitting diodes is fixed to the housing by reversible fixing means in order to facilitate its replacement as well as the replacement of the flexible printed circuit.

According to the invention, the at least one member for positioning the flexible printed circuit of the light module comprises at least one pin intended to be received in an orifice formed in the flexible printed circuit. Once the flexible printed circuit is correctly positioned, the pins allowing this positioning can be deformed in order to keep the flexible printed circuit in position. This deformation can be carried out hot or cold.

Advantageously, the support for the OLED diodes comprises a plurality of pins and the flexible printed circuit comprises a plurality of holes, each pin being intended to be received in one of these holes.

According to a characteristic of the present invention, at least one reinforcement piece is fixed to the flexible electronic circuit board common to organic light-emitting diodes. This at least one reinforcement piece allows the fixing of the corresponding element of the connector configured for the electrical connection of the corresponding organic light-emitting diode, and it comprises at least one recess intended to receive at least one of the pins arranged in projections of the support for OLED diodes. In other words, the at least one recess formed in this reinforcing piece is placed opposite at least one of the orifices formed in the flexible printed circuit, this recess and this orifice then being traversed by the same pin from the support OLED diodes.

Advantageously, the light device according to the invention comprises at least as many reinforcing parts as OLED diodes and therefore of connectors arranged between the diodes and the flexible printed circuit. These reinforcing parts are advantageously arranged between the flexible printed circuit and the support of organic light-emitting diodes, the connectors ensuring the connection between the flexible printed circuit and each of the OLED diodes being integral with this reinforcing part.

According to one aspect of the present invention, the support for organic light-emitting diodes comprises at least two hooks capable of holding, each, one of these organic light-emitting diodes. For example, these hooks can be made from material with the support of OLED diodes.

Other characteristics, details and advantages will emerge more clearly on reading the detailed description given below for information only in relation to the various embodiments illustrated in the following figures:

- Figure 1 is a schematic representation, front view, of an organic light emitting diode of a light module according to the present invention;

- Figure 2 is a perspective representation, viewed from the rear, of the organic light emitting diode shown schematically in Figure 1;

- Figure 3 is a perspective view of part of a light module according to the invention in which a printed circuit board has been removed to make visible the interconnection between each organic light emitting diode of the light module and a printed circuit flexible of this light module;

- Figure 4 is a rear perspective view of a light device for a motor vehicle from which a housing has been partially removed in order to make visible the light module present in this light device.

In particular, a rear face of a light module capable of fitting a light device 15 intended to be integrated into a motor vehicle has been made visible in FIG. 4, to perform a lighting function, interior or exterior, and / or a function signaling of the vehicle, for example to form a rear light of this vehicle. The light device 15 comprises a box 16, a rear part of which is not shown in order to make visible the various components of this light module 1 housed in this box 16. The box 16 is for example made of a synthetic material, and obtained by molding. The rear face of the light module is turned towards the inside of the vehicle, and the front face, here not visible, is turned towards the outside of the vehicle.

The light module 1 according to the invention comprises a plurality of light sources 2 arranged on the side of the front face and connected to a printed circuit board 3 via a flexible printed circuit 4. As can be seen on the FIG. 4, the printed circuit board 3 comprises a connection device 30, allowing the electrical supply of the light sources 2 via the printed circuit board 3. The electronics for controlling the light sources 2 are advantageously distributed over this printed circuit board 3 and / or on the flexible printed circuit 4.

The flexible printed circuit 4 can for example be manufactured using a technology which consists in using a plastic substrate on which electrical circuits 40 are screen printed. This flexible printed circuit is advantageously deformable, which facilitates its integration into the light module 1 and will be described more fully in the following document, in particular with reference to FIGS. 1 and 2.

According to the invention, the light sources 2 of the light module 1 consist of a plurality of organic light-emitting diodes 20, or OLED diodes, one of them being shown front view in Figure 1 and perspective view in the figure 2.

As illustrated, this OLED diode 20 includes a part 5 emitting light rays attached to a base 6 (visible in FIG. 2).

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The emitting part 5 is conventionally composed of a set of polymer layers sandwiched between an anode and a cathode, and it may have, taking into account the nature of the materials which compose it, a certain mechanical flexibility. These polymer layers have the property of emitting light rays when an electric current passes through them. According to different embodiments, the emitting part 5 of the OLED diode 20 can comprise one or more distinct emission zones.

According to the example illustrated in FIG. 1, the transmitting part 5 comprises two separate transmission zones 50, 51 and a connection zone 52. As can be seen, the transmitting part 5 thus comprises a central transmission zone 50 and a peripheral emission zone 51. These emission zones 50, 51 being distinct, they may or may not be activated independently of one another. Thus, depending on traffic conditions, or the desired aesthetic effects, an ignition instruction may be sent for the central emission zone 50, for the peripheral emission zone 51, or for these two emission zones 50, 51 simultaneously. According to an alternative embodiment of the present invention not illustrated here, this emitting part 5 may include more than two emission zones, thus offering all the more different lighting possibilities.

The connection area 52 makes it possible, in particular, to provide electrical power and control of the emission areas 50, 51. As shown, a connection member 8 is thus connected to this connection area

52.

As mentioned above, the transmitting part 5 is attached to the base 6. By "added" is meant the fact that the transmitting part 5 and the base 6 are produced independently of each other before d 'be joined together, for example by bonding. This base 6 comprises a front face on which is fixed the emitting part 5 and a rear face 61 on which is provided a fixing member 7 of the OLED diode 20 in the light module 1 according to the invention. It is understood that the terms “front” and “rear” here relate to an orientation of the OLED diode in the figures and in an example of application in a given light module but are not limiting of the orientation that can take such an OLED diode.

As illustrated, this fixing member 7 comprises a first branch 70 extending mainly along a first axis parallel to a main extension plane of the emitting part 5 of the OLED diode and a second branch 71 which extends in to it mainly along a second axis, perpendicular to the first axis, this fixing member 7 thus having a general shape of T. A free end of the first branch 70 comprises a device for holding in position 10 intended to cooperate with a support 11, particularly visible in Figures 3 and 4. This cooperation allows, at least partially, the maintenance in position of the OLED diode 20 in the light module according to the invention.

According to the invention, the connection member 8 is produced by an additional flexible printed circuit, distinct from the flexible printed circuit 4 common to each OLED diode previously described. This additional flexible printed circuit is thus connected, by a first end 80, to the connection zone 52 of the emitting part 5 of the OLED diode and it has, at a second end 81, a connection tab configured to form a male element. a connector

9. More precisely, the second end 81 is a free end of this additional flexible printed circuit and the shape of this second end is designed to form a tongue which can be inserted in the female part of the connector 9.

According to the present invention, this connector 9 is of the “CMS” type, and can advantageously be a connector of the “ZIF” or “LIF” type, corresponding, respectively, to the English acronyms “Zero Insertion Force” and “Low Insertion Force”. >>. The connector 9 is formed by a female element directly secured to the flexible printed circuit 4 common to each OLED diode 20 and a male element, of the flexible tab type previously described, formed at the end of the additional flexible printed circuit of each OLED diode.

We will now describe in more detail the light module 1 according to the invention which comprises a plurality of OLED diodes 20 as described above, as well as the light device 15 comprising such a light module 1 with reference to FIGS. 3 and 4.

FIG. 3 is a partial perspective view of the light module 1 according to the invention on which the printed circuit board has been removed in order to make visible the interconnection between each OLED diode 20 and the flexible printed circuit 4. The module light 1 here comprises four OLED diodes 20, all electrically connected to the printed circuit board - as illustrated in FIG. 4 - by a single flexible printed circuit 4 of the light module 1. It is understood that the light module described and illustrated here is only an exemplary embodiment and that the number of light sources chosen for these illustrations is not limitative of the number of light sources that can comprise such a light module.

Each emission zone 50, 51 of the emitting part 5 of each OLED diode 20 comprises at least three connections: a positive terminal, a negative terminal and a ground connection terminal. Thus, the more the number of emission zones increases, the more complex the electrical connection of each OLED diode to the printed circuit board of the light module. It will therefore be understood that the use of a single means of connection, in this case the flexible printed circuit, of all the OLED diodes 20 to the printed circuit board 3 makes it possible on the one hand to facilitate the assembly of the light module comprising these OLED diodes and on the other hand to reduce the total size of the light module 1 comprising these OLED diodes 20.

In other words, the plurality of wires conventionally allowing the electrical connection of all the emission zones of each of the OLED diodes are here advantageously replaced by a single flexible printed circuit 4 on which is engraved a plurality of electrical circuits 40, rendered visible in FIG. 3 in a schematic representation in which the aim has been to identify the position of the electrical circuits and their grouping according to the zones of the flexible printed circuit, without the arrangement on one and / or the other of the faces of the circuit flexible print is limiting of the invention.

In addition to allowing a reduction in the number of connections to be made, this flexible printed circuit allows a simplified assembly, in particular by its flexibility which facilitates its positioning in the light module.

The electrical circuits 40 etched on the flexible printed circuit 4 common to all the organic light-emitting diodes are configured so as to extend mainly in the main direction of elongation of the flexible printed circuit.

More particularly, the OLED diodes 20 are arranged in a series extending along a transverse axis, and the flexible printed circuit 4 extends mainly along this same axis in order to be able to distribute each of the diodes. And the electronic circuits extend mainly along this transverse axis, from one of their ends where they are grouped in a first connection area 41, in particular to form a tongue capable of being connected to a female connector element secured to the card of printed circuit 3. At their second end, the electronic circuits are distributed in second connection zones 42 specific to each organic light-emitting diode 20.

In the example illustrated in FIG. 3, each organic light-emitting diode 20 is controlled and supplied by means of seven electrical circuits. It is understood that the segmentation of the diodes may be different from what is illustrated in FIG. 1, and that the supply by seven electrical circuits is given here by way of nonlimiting example. It follows from this example that in the first connection area, twenty-one electronic circuits extend side by side to be connected to the printed circuit board. It is understood that according to the invention, the connection of the diodes once each connected to the flexible printed circuit is done in a single mounting operation.

It is advantageous that, as illustrated, the connection of the flexible printed circuit 4 to the printed circuit board 3 is made at a transverse end of the flexible printed circuit, in order to reduce the size of the light module in the direction of the thickness, that is to say in the longitudinal direction of emission of the light rays by the OLED diodes, perpendicular to the plane in which the printed circuit board is mainly inscribed.

In addition, the flexible printed circuit 4 allowing the interconnection between the OLED diodes 20 and the printed circuit board can comprise all or part of the electronic control of these OLED diodes 20, thus freeing up space on the printed circuit 3. It is understood that this additional available space advantageously makes it possible to make other connections, that is to say to integrate more electronic components into the light module according to the invention. For example, this light module may include additional light sources, the OLED diodes 20 then being for example dedicated to signaling a turn and the additional light sources to brake signaling.

As illustrated in this FIG. 3, the OLED diodes 20 are assembled on a support 11. It is understood that this support 11 carries both these OLED diodes 20 and the flexible printed circuit 4 making it possible to connect these OLED diodes 20 to the card of the printed circuit 3 of the light module 1 as illustrated in FIG. 3. Thus, this support 11 carries the OLED diodes 20 on a first face 110 and the flexible printed circuit 4 on a second face 111.

To this end, the first face 110 has a series of hooks - not visible in these figures - intended to each receive one of the OLED diodes of the light module 1, and more exactly a lower part of the base 6 of these OLED diodes. These hooks also each have a shape complementary to the device for holding in position 10 formed on the first branches 70 of the fastening members 7 of the OLED diodes 20.

The second face 111 has meanwhile positioning members of the flexible printed circuit 4. According to the example illustrated, these positioning members are produced by pins 12 which emerge from this second face 111 and project from the latter , each of these pins 12 being dimensioned so as to be able to fit into an orifice formed in the flexible printed circuit, in order to allow correct positioning of this flexible printed circuit and therefore of the connector element to be connected with the element associated with each OLED diode.

As illustrated in FIG. 3, reinforcing pieces 13, advantageously a reinforcing piece 13 by OLED diode 20, are fixed on the flexible printed circuit, for example by gluing, and in particular on the edge of this card where are fixed the female connector elements. It should be noted that in the figure, these reinforcing pieces 13 are shown in dotted lines because they are in practice covered by the flexible printed circuit 4. In other words, the flexible printed circuit 4 is interposed between the reinforcing pieces 13 and the female connector elements 9. As shown, the reinforcement pieces 13 are arranged in a transverse series similar to the transverse series of connectors, all distributed on the same edge of the flexible printed circuit 4.

The reinforcement pieces 13 have at least two recesses, each of these recesses being intended to receive one of the pins 12 coming from the second face 111 of the support 11. It is understood from FIG. 3 that during assembly of the light module , the orifices formed in the flexible printed circuit 4 are placed opposite the recesses formed in the reinforcement pieces 13 and that these orifices and recesses are crossed, two by two, by one of the pins 12 coming from the support 11.

These pins 12 thus make it possible, firstly, to correctly position the flexible printed circuit 4, in particular via the reinforcement pieces 13 intended to support the connectors 9, and secondly, to secure the flexible printed circuit: these pins 12 can in fact be deformed, hot or cold, for example by rolling to prevent in particular the disengagement of the flexible printed circuit 4.

This support 11 further comprises a plurality of holes 14 allowing the latter to be fixed to the housing 16 of the light module, for example by means of screws 140 as illustrated in FIG. 4.

As previously mentioned, the light module 1, according to the example illustrated in the figures, comprises four OLED diodes 20, each connected, by means of a connector 9 which is specific to the flexible printed circuit 4. A fifth connector 90 is provided to make the connection between the flexible printed circuit 4 and the printed circuit board 3 carrying at least part of the electronics for driving the OLED diodes.

According to the example illustrated in FIGS. 3 and 4, the flexible printed circuit 4 comprises a free end 43 which forms a female element capable of being inserted in the male element of the connector 90 secured directly to the printed circuit board 3. As before, this connector 90 is a “CMS” type connector, that is to say that the male element is mounted on the surface of the printed circuit board.

In the example illustrated, the female elements of the connectors 9, 90, which constitute the most rigid part of the connectors, are carried respectively by the printed circuit board 3, as regards the connection between the printed circuit board and the flexible printed circuit, and by the flexible printed circuit 4 as regards the connection between the latter and the OLED diodes.

More particularly, a female element of a connector 9 can be integral with the flexible printed circuit 4 to cooperate with a male element arranged at the end of the additional flexible printed circuit fixed on an organic light-emitting diode 20. And a female element of a connector 90 may be integral with the printed circuit board 3 to cooperate with a male element arranged at the end of the flexible printed circuit 4 common to all the organic light-emitting diodes 20. Of course, without departing from the context of the invention, the female and male elements connectors could be swapped.

It is understood from the above that the present invention provides a light module comprising a plurality of organic light emitting diodes whose electrical connection is made by a single flexible printed circuit, having a small footprint compared to a wired connection as we know it today.

The present invention cannot however be limited to the means and configurations described and illustrated here and it also extends to all equivalent means and configurations and to any technical combination operating such means. In particular, the shape, the arrangement of the organic light-emitting diodes and of the flexible printed circuit can be modified without harming the invention insofar as they fulfill the functionalities described in this document.

Claims (13)

î. Light module (1) for a vehicle, comprising at least two organic light-emitting diodes (20) and a printed circuit board (3) intended to drive, at least partially, organic light-emitting diodes (20), characterized in that each light-emitting diode organic (20) is connected to the printed circuit board (3) via a flexible printed circuit (4) common to all organic light emitting diodes (20). 2. light module (1) according to the preceding claim, comprising a plurality of electrical circuits (40) etched on the flexible printed circuit (4) common to all organic light emitting diodes, said electrical circuits (40) being configured so as to be grouped at one of their ends in a first connection zone (41) to the printed circuit board (3) and so as to be distributed in second connection zones (42) specific to each organic light-emitting diode (20). 3. Light module (1) according to one of the preceding claims, comprising at least one connector (9, 90) of the CMS type. 4. Light module (1) according to any one of the preceding claims, comprising at least one connector (9, 90) of ZIF or LIF type. 5. Light module (1) according to any one of claims 3 or 4, wherein a female element of a connector (9) is integral with the flexible printed circuit (4) to cooperate with a male element arranged at the end of an additional flexible printed circuit attached to an organic light emitting diode (20). 6. light module (1) according to any one of claims 3 to 5, wherein a female element of a connector (90) is integral with the printed circuit board (3) to cooperate with a male element arranged at the end of the flexible printed circuit (4) common to all the organic light-emitting diodes (20). 7. Light module (1) according to any one of the preceding claims, in which a part of the electronics for driving the organic light-emitting diodes (20) is carried by the flexible printed circuit (4) common to all the organic light-emitting diodes. (20). 8. Light module (1) according to any one of the preceding claims, in which, the organic light-emitting diodes (20) extending in a series along a transverse axis, the flexible printed circuit (4) extends mainly parallel to this transverse axis. 9. light module (1) according to the preceding claim, in combination with claim 3 or 4, wherein the set of connectors (9, 90) connecting this flexible printed circuit (4) to each of the organic light emitting diodes (20) is arranged on the same edge of the flexible printed circuit (4), parallel or substantially parallel to the transverse axis. 10. Light module (1) according to any one of the preceding claims, in which each organic light-emitting diode (20) comprises at least two distinct emission zones (50, 51), each configured to emit at least one light ray. not. Light module (1) according to any one of the preceding claims, comprising at least one other light source, this at least one other light source being controlled, at least partially, by the printed circuit board (3) of said light module (1 ). 12. Light device (15) for a vehicle, comprising a housing (16) in which is housed at least one light module (1) according to any one of the preceding claims, the housing (16) further accommodating at least one support. (11) organic light-emitting diodes (20) of this light module (1), this at least one support (11) comprising at least one member for positioning the flexible printed circuit (4). 13. Luminous device (15) according to the preceding claim, wherein the water 5 at least one member for positioning the flexible printed circuit (4) of the light module (1) comprises at least one pin (12) intended to be received in an orifice formed in the flexible printed circuit (4). 14. Lighting device (15) according to any one of claims 12 or 13, in which at least one reinforcement piece (13) is fixed to the printed circuit. 10 flexible (4) common to organic light emitting diodes (20).