阅读说明：本技术 照明设备和照明系统 (Lighting device and lighting system ) 是由 U·卡波夫斯基 C·克莱宁 J·舒格 于 2020-02-03 设计创作，主要内容包括：照明设备,尤其用于机动车应用,包括多个照明元件,其中每个照明元件包括至少一个或多个发光二极管(LED)。照明设备包括第一连接器,用于将照明设备连接到照明驱动器。照明元件布置成一行,以便形成发光带。多个照明元件被划分成多于一个的组,每个组由至少一个或多个照明元件组成。一个组中的照明元件串联电气连接。这些组并联电气连接,以便单独地控制每个组。(A lighting device, in particular for automotive applications, comprises a plurality of lighting elements, wherein each lighting element comprises at least one or more Light Emitting Diodes (LEDs). The lighting device comprises a first connector for connecting the lighting device to the lighting driver. The lighting elements are arranged in a row so as to form a light emitting strip. The plurality of lighting elements is divided into more than one group, each group consisting of at least one or more lighting elements. The lighting elements in one group are electrically connected in series. The groups are electrically connected in parallel so that each group is controlled individually.)

1. Lighting device, in particular for automotive applications, comprising:

a plurality of lighting elements (10), wherein each lighting element (10) comprises at least one or more light emitting diodes (14), and

a first connector (18) for connecting the lighting device to a lighting driver,

wherein the lighting elements (10) are arranged in a row so as to form a light emitting strip,

wherein the plurality of lighting elements (10) is divided into more than one group (12), each group consisting of one or more lighting elements (10),

wherein the lighting elements (10) in one group (12) are electrically connected in series, and

wherein the groups (12) are electrically connected in parallel so as to control each group individually,

it is characterized in that the preparation method is characterized in that,

one lighting element (10) is directly connected to a preceding lighting element (10) and/or a following lighting element in the group by more than one electrical conductor (16).

2. The lighting device according to claim 1, wherein the number of wires (16) is between two and four, and the connector (18, 20, 36) is configured to connect each wire (16) to the lighting driver.

3. The lighting device according to any one of claims 1-2, wherein the lighting device is flexible in two directions and/or twistable along a longitudinal axis.

4. The lighting device according to any one of claims 1 to 3,

wherein the light emitting area of the lighting device has a width of less than 10 mm, preferably less than 6 mm, and even more preferably less than 4 mm, and/or

Wherein the width of the lighting device is less than 10 mm, preferably less than 8 mm, and even more preferably less than 6 mm, and/or

Wherein the height of the lighting device is less than 10 mm, preferably less than 8 mm, even more preferably less than 6 mm.

5. The lighting device according to any one of claims 1 to 4,

wherein the lighting element and the wire are at least partially surrounded by a polymer, and

wherein preferably the polymer comprises a first part which is transparent and arranged in front of the lighting element in the direction of light emission and a second part which is opaque.

6. The lighting device according to any one of claims 1 to 5, wherein the wires (16) between two sequential lighting elements (10) are separated from each other and/or arranged in parallel.

7. The lighting device as set forth in claim 6,

wherein the length of the wire (16) between two successive lighting elements (10) is greater than the distance between two corresponding lighting elements (10), and

wherein, in particular, the outer wires (16 a, 16 c) are longer than the inner wires (16 b) when available.

8. The lighting device according to any one of claims 1 to 7, wherein at least two groups consist of the same number of lighting elements (10), and preferably each group (12) consists of the same number of lighting elements (10).

9. The lighting device according to any one of claims 1 to 8,

wherein the second connector (20) is arranged for connecting at least one group (12) of lighting elements to a lighting driver, and

wherein the first connector (18) is arranged at a head end of the row and the second connector (20) is arranged at a tail end of the row.

10. The lighting device as set forth in claim 9,

wherein at least one further connector (36) is arranged along the row between the first connector (18) and the second connector (20) to connect at least one group (12) of lighting elements to a lighting driver,

wherein the further connector is arranged between two sequential groups (12) of lighting elements (10).

11. The lighting device according to any one of claims 1 to 10,

wherein each connector (18, 20, 36) comprises one or more terminals for at least one group (12),

wherein the terminals include one or more ground terminals (24) and/or one or more anode terminals (26, 28, 30, 32), and

wherein the number of terminals of each connector (18, 20, 36) is preferably equal to the number of wires.

12. The lighting device according to any one of claims 1 to 11,

wherein the lighting device emits light in only one direction, and

wherein the angle of the emitted light is preferably less than or equal to 180 °, more preferably less than 120 ° and most preferably less than 90 °.

13. The lighting device according to any one of claims 1 to 12, wherein each lighting element (10) comprises a printed circuit board (44).

14. The lighting device as defined in claim 13,

wherein the printed circuit board includes electrical connections, and

wherein preferably the printed circuit board is configured with crossing wires.

15. A lighting system comprising a lighting device according to any one of claims 1 to 14, and a lighting driver.

16. The lighting system of claim 15, comprising an error detection module,

wherein the error detection module is configured to detect errors in the lighting elements (10) and/or in the groups (12) of lighting elements (10).

17. The lighting system as set forth in claim 16,

wherein the error detection module is configured to detect the current and/or voltage through each group of lighting elements (10) individually, and

wherein an error is identified when a current and/or voltage through one of the groups (12) is detected to be less than or greater than a current threshold and/or a voltage threshold.

18. The lighting system according to claim 16 or 17,

wherein the error detection module is configured to detect the current and/or voltage through each group (12) of lighting elements (10) individually, and

wherein an error is detected from a deviation of said current and/or voltage through the first set (12) with respect to said current and/or voltage through the second set (12), wherein preferably said error is determined when said deviation exceeds a preset limit.

Technical Field

The present invention relates to a lighting device, in particular for automotive applications, and a lighting system comprising such a lighting device.

Background

In the automotive field, it is currently a trend to implement lighting devices that can be dynamically controlled. This means that it is no longer sufficient to be able to switch the lighting device on and off, but in addition the components of the lighting device have to be individually adjustable. For example, to produce dynamic lighting effects, individual components may be turned on and off or may be dimmed. The availability of Light Emitting Semiconductors (LEDs) has greatly enhanced the development of light emitting devices that can be dynamically controlled.

By addressing each LED by a separate electronic conductor, the LEDs can be controlled individually. However, this results in the need for numerous wires connected to the lighting driver in order to control each LED individually. This increases the necessary effort to manufacture and implement such a lighting device. Further, due to the numerous wires and complex wiring of the wires, the space constraints of the lighting device are easily exceeded, especially for automotive applications.

In order to avoid complicated wiring of the wires within the lighting device, it is possible to use flat ribbon cables instead. However, by using such a flat ribbon cable, the flexibility of the lighting device is limited because the flat ribbon cable is flexible only in one direction and is not flexible and bendable in the plane in which the wires of the flat ribbon cable are arranged. Typically, modern automotive lighting devices need to follow complex 3D shapes. Therefore, flat ribbon cables are not suitable for 3-dimensional applications.

Alternatively, it is well known to combine each LED with a control chip as an Integrated Circuit (IC) or microprocessor, wherein the control chips of the entire lighting device communicate via a bus. In US 2012/262076 a1, an LED based lighting device is disclosed. The light engine used in the lighting device may use a multilayer metal core printed circuit board and have a plurality of LED groups that are individually controllable by a control unit. However, implementing a control chip for each LED increases the cost of the lighting device. This is especially true in the automotive field where every IC or microprocessor must be tested and certified. This reduces the applicability of this solution and extends the necessary development and design cycles. Further, error detection is often required in the automotive field and needs to be implemented by additional circuitry, which increases the complexity even further.

Disclosure of Invention

It is an object of the invention to provide a lighting device and a lighting system that are flexible, dynamically controllable, less complex, and suitable for error detection.

The given object is achieved by a lighting device according to claim 1 and a lighting system according to claim 13.

The lighting device according to the invention is particularly suitable for automotive applications, in particular in automobiles, and comprises a plurality of lighting elements, wherein each lighting element comprises at least one or more Light Emitting Diodes (LEDs). Lighting elements are also known or referred to as inserts. Preferably, the lighting elements are identically constructed. The lighting element may comprise a Printed Circuit Board (PCB) carrying the LEDs. The LEDs may be mounted to the PCB by directly attaching the die, or the LEDs may be mounted to the PCB as Surface Mount Devices (SMDs), as through-hole technology (THT) components, or any other type of component. The PCB may include one LED or more than one LED.

According to the invention, the lighting device comprises a first connector for connecting the lighting device to the lighting driver. The lighting driver may be built as an integrated component of the device or may be a separate entity. The first connector is used to control the lighting device and also to provide power for the lighting device.

According to the invention, the lighting elements are arranged in a row so as to form a light emitting strip or lighting strip. The lighting device has a length that exceeds a width of the lighting device. For example, the length of the lighting device may be more than 200 mm or more than 500 mm, while the width of the lighting element may be less than 10 mm or less than 6 mm, for example. By arranging a large number of lighting elements in a row, a long and very narrow lighting device can be achieved. The lighting device may be placed under or between other lighting devices of e.g. a car, such as headlights, auxiliary lights and may e.g. be used as a position light, daytime running light, welcome light, turn signal, stop light, or contour light.

According to the invention, the plurality of lighting elements is divided into more than one group, wherein each group consists of one or more lighting elements. The lighting elements in one group are electrically connected in series, wherein the groups are electrically connected in parallel, so that each group is controlled individually. To achieve dynamic illumination, the illumination driver may address individual groups of illumination elements. Furthermore, by dividing the lighting elements into groups, large currents through a plurality of lighting elements can be avoided. Further, by grouping the lighting elements, the complexity of the lighting device may be reduced while still providing a multifunctional lighting device (due to the group of individually controllable lighting elements).

According to the invention, each lighting element is directly electrically connected to the preceding and/or the following lighting element, except for the first and the last lighting element in the group, which are connected to the following and the preceding lighting element, respectively. The individual lighting elements are connected by more than one electrical conductor. The direct connection between sequential lighting elements may also comprise one or more physical connections for connecting the lighting elements in the structure of the lighting device. Such a physical connection may still be a wire, more particularly one or more electrical wires may also provide the physical connection and thus have a dual function. Thus, the lighting elements may be connected by more than one electrical conductor and may additionally be physically connected. If the lighting element is constructed as a circuit board, the wires may be electrically connected to or through the PCB and in electrical contact with the one or more LEDs of the particular lighting element.

In particular, the number of wires between two lighting elements is between 2 and 4, and the connector is configured to connect each wire to the lighting driver. Preferably, the number of wires between each lighting element is the same along the entire lighting device. Increasing the number of wires between each lighting element also increases the ability to control more groups of lighting elements. At the same time, the complexity of the lighting device increases and the necessary installation space also increases. Thus, with a maximum of 4 wires between each lighting element, a sufficient number of groups can be controlled, for example to provide dynamic lighting for automotive applications.

In particular, the lighting device is flexible or bendable in two directions. Preferably, the two directions are perpendicular to each other and to the longitudinal axis of the lighting device. The longitudinal axis of the lighting device is defined as the axis extending along the row or lighting element. The possible bend radius is preferably less than 100 mm, more preferably less than 50 mm and most preferably less than 25 mm. Additionally or alternatively, the lighting device may be twistable about the longitudinal axis. A 90 ° twist of the lighting device is possible within a length of 100 mm, more preferably within a length of 75 mm, and most preferably within a length of 50 mm. With this flexibility, the lighting device is suitable for a large number of applications and can be adapted to all kinds of shapes.

The lighting device may comprise a light emitting area having a width of less than 10 mm, preferably less than 6 mm, and even more preferably less than 4 mm. The light emitting area is the area through which light exits the device and the width is measured perpendicular to the longitudinal axis. Additionally or alternatively, the total width of the lighting device is less than 10 mm, preferably less than 8 mm, and even more preferably less than 6 mm. The width is measured perpendicular to the longitudinal axis. Thus, a small device suitable for all different kinds of applications is achieved. Additionally or alternatively, the height of the lighting device is less than 10 mm, preferably less than 8 mm, even more preferably less than 6 mm.

The lighting element and/or the wire may be at least partially or completely surrounded by the polymer. The polymer is preferably silicon which provides sufficient flexibility and photo-thermal stability. Preferably, the polymer comprises a first transparent part arranged in front of the lighting element in the direction of light emission. The transparent polymer forms a light emitting area through which light leaves the lighting device. The transparent polymer may define the light emission characteristics of the lighting device, such as the emission opening angle. Further, the polymer may comprise a second opaque polymer component. Preferably, the opaque polymer is white to reflect most of the light towards the light emitting region and increase the efficiency of the lighting device. Optionally, optical components (e.g. micro lenses, optical foils and/or collimators) may be placed on top of the lighting device for beam shaping.

The lighting device may (not necessarily) consist of only passive electrical components. No processor or Integrated Circuit (IC) or control chip is required.

The wires between two sequential lighting elements may be separated from each other so that there is no contact and so that there is no electrical connection between the wires. Alternatively or additionally, the wires are arranged in parallel between two sequential lighting elements. Preferably, the arrangement of the wires between each lighting element is identical along the entire row. Preferably, the conductors are arranged in a common plane. It is possible that the lighting device is bent perpendicularly to this plane in order to adapt the shape of the lighting device to the specific application. Even complex 3D shapes are possible.

In particular, the length of the wire between two consecutive lighting elements, and preferably between each lighting element, is greater than the distance between the two respective lighting elements. The larger length of the wires makes the bending of the lighting device even easier if the wires are arranged in one common plane. Further, the length of the wire may compensate for thermal expansion. Preferably, the outer wires between two sequential lighting elements, and more preferably between each lighting element, are longer than the possible inner wire(s) or the central wire(s).

In particular, the wires may have a meandering shape or an S-shape or a curved shape or a meandering form, so as to be more or less flexible during bending or thermal expansion to compensate for changes in the distance between the respective lighting elements.

In particular, at least two groups consist of the same number of lighting elements. This makes it possible for example for the lighting driver to compare the currents and/or voltages of the two groups; and if there is a deviation in current or power between the two identical sets, an error is detected. Preferably, each group consists of the same number of lighting elements, and even more preferably, the lighting elements of each group comprise the same number of LEDs. Thus, the current and voltage of each group can be compared with each other group in order to obtain a reliable error detection.

The lighting device may comprise a second connector to connect to the lighting driver, wherein the first connector is arranged at a head end of the row and the second connector is preferably (though not necessarily) arranged at an end of the row. A second connector connects the at least one group to the lighting driver. The second connector increases the number of addressable banks without increasing the complexity of the wiring of the wires. With two to four wires and/or two connectors, a sufficient number of groups can be individually addressed to provide dynamic illumination.

The lighting device may comprise at least one further connector arranged along the row between the first connector and the second connector for connecting at least one group of lighting elements to the lighting driver. The further connector is preferably arranged between two sequential groups of lighting elements. By introducing further connectors, the number of addressable groups can even be increased without substantially increasing the complexity of the wiring in the lighting device. Thus, with two to four wires, a greater number of groups can be individually addressed to provide dynamic illumination.

In particular, each connector comprises one or more terminals for at least one group. The terminals may include one or more ground terminals and/or one or more anode terminals. The number of terminals in the first connector and/or the number of terminals of the second connector is at least equal to the number of electrical wires of the lighting device. The anode terminal may be used to control each group individually. The groups of lighting devices are connected to and individually controlled by the lighting drivers by connectors and wires. It is possible that the first connector comprises a ground terminal and one or more anode terminals, while the second or third connector comprises only anode terminals. Alternatively, it is possible that the first connector comprises a ground terminal and one or more anode terminals, while the second connector also comprises a ground terminal and one or more anode terminals. Also, it is possible that one connector includes more than one ground terminal. Alternatively, the device may of course be used with a plurality of common anodes and switched ground terminals.

In particular, the lighting device emits light in a direction perpendicular to a longitudinal axis of the lighting device. The longitudinal axis of the lighting device is defined as the axis extending along the row or lighting element. Preferably, light is emitted into one half-space of the lighting device in only one direction.

In particular, the lighting device emits light in only one direction along the entire light emitting strip, wherein preferably the emission opening angle is equal to or smaller than 180 °. Thus, by means of the lighting device, light is emitted in only one half-space. Preferably, the opening angle is equal to or less than 120 ° and more preferably equal to or less than 90 °.

Preferably, the distance between each lighting element is identical in order to provide a uniform illumination. However, it is also possible to have different distances between at least two or more lighting elements to further adapt the illumination to a specific application.

In particular, the first connector may comprise one ground terminal and a first anode terminal and a second anode terminal, wherein three wires are used for connecting the lighting element. The plurality of lighting elements are divided into two groups, wherein a first group is controlled by the first anode terminal and a second group is controlled by the second anode terminal, and the first group and the second group are electrically connected to a common ground terminal. Thus, with three wires and one connector, two groups can be dynamically addressed by the illumination driver.

In particular, the first connector may comprise one ground terminal and a first and a second anode terminal, wherein the second connector comprises one ground terminal and a third and a fourth anode terminal. Each lighting element comprises one or more LEDs, wherein preferably each group has the same number of LEDs. Three wires are used to connect the lighting elements, wherein the plurality of lighting elements are divided into four groups, wherein a first group is controlled by the first anode terminal, a second group is controlled by the second anode terminal, a third group is controlled by the third anode terminal, and a fourth group is controlled by the fourth anode terminal. The first to fourth groups are electrically connected to the common ground terminal of the first connector and the second connector at the same time. Thus, with two connectors and three wires, it is possible to have four groups, which can be dynamically addressed by the lighting driver together with a through ground wire connecting the ground terminal of the first connector with the ground terminal of the second connector.

In particular, the first connector may comprise one ground terminal and a first and a second anode terminal, wherein the second connector comprises a third and a fourth and a fifth anode terminal. Each lighting element comprises one or more LEDs, wherein preferably each group has the same number of LEDs. Three wires are used to connect the lighting elements, wherein the plurality of lighting elements are divided into five groups, wherein a first group is controlled by the first anode terminal, a second group is controlled by the second anode terminal, a third group is controlled by the third anode terminal, a fourth group is controlled by the fourth anode terminal, and a fifth group is controlled by the fifth anode terminal. The first through fifth sets are electrically connected to a common ground terminal of the first connector. Thus, with two connectors and three wires, it is possible to have five groups, which can be dynamically addressed by the lighting driver.

In particular, the first connector may comprise a first and a second ground terminal and a first and a second anode terminal, wherein the second connector comprises a third and a fourth ground terminal and a third and a fourth anode terminal. Each lighting element comprises one or more LEDs, wherein preferably each group has the same number of LEDs. Four conductive wires are used to connect the lighting elements, wherein the plurality of lighting elements are divided into seven groups, wherein a first group is connected between the first anode terminal and the first ground terminal, a second group is connected between the second anode terminal and the first ground terminal, a third group is connected between the second anode terminal and the second ground terminal, a fourth group is connected between the third anode terminal and the second ground terminal, a fifth group is connected between the third anode terminal and the third ground terminal, a sixth group is connected between the fourth anode terminal and the third ground terminal, and a seventh group is connected between the fourth anode terminal and the fourth ground terminal. Thus, with two connectors and four wires, it is possible to have seven groups, which can be dynamically addressed by the illumination driver.

In particular, the first connector may comprise one ground terminal and a first and a second anode terminal, wherein the second connector comprises a third and a fourth anode terminal and further comprises a ground terminal. Each lighting element comprises one or more LEDs, wherein preferably each group has the same number of LEDs. Three wires are used to connect the lighting elements, wherein the plurality of lighting elements is divided into ten groups. A third connector is disposed between the fifth and sixth groups, wherein the third connector includes fifth and sixth anode terminals and seventh and eighth and ninth and tenth anode terminals. The first group is controlled by the first anode terminal, the second group is controlled by the second anode terminal, the third group is controlled by the third anode terminal, the fourth group is controlled by the fourth anode terminal, the fifth group is controlled by the fifth anode terminal, the sixth group is controlled by the sixth anode terminal, the seventh group is controlled by the seventh anode terminal, the eighth group is controlled by the eighth anode terminal, the ninth group is controlled by the ninth anode terminal, and the tenth group is controlled by the tenth anode terminal. The first to fifth groups are electrically connected to the common ground terminal of the first connector, and the sixth to tenth groups are electrically connected to the common ground terminal of the second connector. Thus, with three connectors and only three wires, it is possible to have ten groups, which can be dynamically addressed by the lighting driver.

Further, the invention relates to a lighting system comprising a lighting driver and a lighting device as described before.

In particular, the lighting device comprises an error detection module, wherein the error detection module is configured to detect a faulty lighting element and/or a group comprising at least one faulty lighting element.

In particular, the error detection module is configured to detect the current through each group of lighting elements individually, preferably by the anode terminal of one connector, wherein an error is identified when the detected current through one group is smaller or larger than a current threshold. In case an LED in the lighting element is defective, no more current flows through the defective LED, which can be detected by the error detection module. Of course, the voltage, rather than the current, of each group of lighting elements may be detected by an error detection module, wherein an error is detected when the voltage across one group is detected to be greater than or less than a voltage threshold. In case the LED is defective, no more current will flow through the LED and the voltage will increase substantially, which can be detected as an error by the error detection module. In case of a short defect of the LED, the voltage drop can be measured.

In particular, the error detection module is configured to detect the current through each group of lighting elements individually, wherein an error is detected when a deviation of the current through the first group from the current through the second group is detected. Thus, preferably, the first and second groups consist of the same number of lighting elements. Preferably, an error is detected if the deviation exceeds a preset limit.

Drawings

Non-limiting and non-exhaustive embodiments of the present disclosure are described with reference to the following figures, wherein like or similar elements are designated by identical reference numerals.

Figure 1 is a schematic drawing of a lighting device according to the invention,

figure 2 is a circuit diagram of an embodiment of the invention,

figure 3 is a circuit diagram of another embodiment of the present invention,

figure 4 is a circuit diagram of another embodiment of the present invention,

FIG. 5 is a cross-section of a lighting device, an

Fig. 6 is a detailed view of the lighting element.

Detailed Description

In the following description, for purposes of explanation and not limitation, specific details are set forth such as particular architectures, interfaces, techniques, etc. in order to provide a thorough understanding of the present inventive concepts. However, it will be apparent to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In a similar manner, the text of this description is directed to example embodiments as illustrated in the figures, and is not intended to limit the claimed invention beyond the limits explicitly included in the claims. For the purposes of brevity and clarity, detailed descriptions of well-known apparatus, circuits and methodology have been omitted so as not to obscure the description of the present invention with unnecessary detail.

Fig. 1 illustrates an implementation of a lighting device according to the invention. The lighting device comprises a plurality of lighting elements 10, wherein in the example of fig. 1 the lighting device comprises ten lighting elements 10. Therein, the lighting elements 10 are divided into five groups 12, wherein each group consists of two lighting elements 10. Of course, the lighting device may have less than ten lighting elements 10 or more than ten lighting elements 10. Additionally, each group may also be composed of one or more lighting elements 10. In the example of fig. 1, each lighting element comprises a Light Emitting Diode (LED) 14. Each lighting element 10 may also comprise more than one LED 14. In particular, each lighting element 10 does not necessarily have the same number of LEDs 14. However, it is preferred that each lighting element 10 has the same number of LEDs 14, and it is further preferred that each group 12 comprises the same number of lighting elements 10 as depicted in fig. 1. Therefore, preferably, each group has the same number of LEDs.

All LEDs 14 are oriented in the same direction. Thus, along the entire lighting device, light is emitted in only one half-space. Wherein the lighting device may emit light only with an emission opening angle equal to or smaller than 180 °, and more preferably equal to or smaller than 120 °, or equal to or smaller than 90 °. To further improve the emission characteristics, a reflective element may be arranged on a plane parallel to the common plane of the LEDs (corresponding to the image plane of fig. 1) so as to reflect all light into the desired half-space. Further, the width of the lighting device is less than 10 mm and preferably less than 6 mm. Therefore, a very narrow and long light emitting band can be constructed, thereby providing high-efficiency illumination.

The lighting elements 10 are arranged in a row, wherein each lighting element 10 is directly connected to a preceding lighting element 10 and/or a succeeding lighting element 10 by means of wires 16a-16 c. Thus, the lighting device in fig. 1 comprises three wires between each lighting element. In the example of fig. 1, the number of wires 16 between each lighting element 10 is identical. However, it is also possible to have an unequal number of wires between at least two or more lighting elements 10. The lighting elements 10 are electrically connected to each other by wires and the same electrical wires also provide the physical connection of the lighting elements. However, the physical connections need not be the same as the electrical connections within the scope of the invention. In the embodiment of fig. 1, the first lighting element 10a is directly electrically and physically connected to the second lighting element 10b by wires 16a-16 c.

At the head end of the row of lighting elements 10, a first connector 18 is connected to the row of lighting elements 10 via wires 16a-16 c. Additionally, at the end of the row of lighting elements 10, a second connector 20 is also connected to the row of lighting elements 10 by wires 16a-16 c. The first and second connectors each comprise three terminal pins 22, wherein the number of terminal pins of the connectors 18, 20 is equal to the number of wires of the lighting device. Thus, by using two connectors 18, 20 and three wires 16a-16c, the five groups 12 can be individually controlled by a lighting driver (not shown) to which the lighting device in fig. 1 is connected via the first connector 18 and the second connector 20. Thus, using only three wires between each lighting element 10, a sufficient number of groups can be dynamically controlled, while the complexity of the wiring for each individual group is low.

As shown in fig. 1, the distance a between each lighting element 10 is less than the length of each wire 16a-16 c. In the example of fig. 1, the distance a between each lighting element 10 is equal. However, it is also possible to have at least two or more distances between the respective lighting elements 10 that differ from each other. The wire has a bent or meandering shape in order to provide an excess length. By this excess length, a bending of the lighting device is possible and further thermal expansion of the lighting device can be compensated. Additionally, the outer leads 16a, 16c include a longer length than the inner or center lead 16 b. Thus, the lighting device may be bent in a plane in which the wires 16a to 16c are also arranged in a plane corresponding to the image plane of fig. 1. Thus, the lighting device may be adapted to any 3D shape of the application. In particular, since a specific configuration of a 90 ° twist of the lighting device is possible within a short length, sufficient flexibility to adapt to all different kinds of applications (i.e. shapes) is provided. Further, the bending radius is preferably less than 100 mm, more preferably less than 50 mm and most preferably less than 25 mm.

Fig. 2 shows a circuit diagram of a lighting device comprising five groups 12 according to fig. 1, wherein in the example of fig. 2 each group 12 comprises seven LEDs 14. Wherein each LED 14 may be arranged on a separate lighting element 10, or more than one LED 14 may be arranged on a single lighting element 10 in one group 12, up to the case where all seven LEDs 14 are arranged on a single lighting element 10. Further, the lighting device of fig. 2 has a first connector 18 and a second connector 20. Three parallel wires 16a, 16b and 16c start from a first connector 18 and are arranged in parallel along the entire length of the lighting device, which is also connected to a second connector 20. The LEDs 14 are arranged along a row so as to define a light emitting or illumination band.

The first connector 18 includes a ground terminal 24, and first and second anode terminals 26 and 28. The second connector 20 includes a third anode terminal 30, a fourth anode terminal 32, and a fifth anode terminal 34. Wherein a first group of LEDs is controlled by means of the first anode terminal 26. The first group 12 of LEDs 14 is controlled with a first anode terminal 26, wherein the first group 12 of LEDs 14 is connected to the ground terminal 24 of the first connector 18. With each further anode terminal of the first connector 18 or the second connector 20, the first group 12 of LEDs 14 may be addressed directly by an illumination driver, which is connected to the lighting device via the first connector 18 and the second connector 20. Thus, through the anode terminals of the first and second connectors 18, 20, five groups 12 of LEDs 14 may be individually addressed in order to provide dynamic illumination. This is achieved by using only three parallel wires along the entire length of the lighting device, thereby preserving the ability of the lighting device to be bent in all directions and providing low complexity of wire routing within the lighting device.

Fig. 3 shows another example of a circuit diagram of the present invention. Each group 12 consists of only a single LED 14, of which seven groups 12 are present in fig. 3. However, each group 12 may also include more than one LED 14. Further, it is possible to provide a smaller number of groups 12.

The first connector 18 includes a first ground terminal, and a second ground terminal and a first anode terminal, and a second anode terminal. The second connector 20 includes third and fourth ground terminals, and third and fourth anode terminals. Thus, the first connector 18 and the first connector 20 are connected to the lighting element 10 of the lighting device by four wires, which are arranged in parallel along the entire length of the lighting device. Thus, by connecting the lighting devices to the lighting driver through the terminals of the first connector 18 and the first connector 20, each group 12 can be controlled individually in order to provide dynamic lighting.

Fig. 4 shows a further embodiment of the invention, wherein each group 12 illustratively has two LEDs 14, which two LEDs 14 may be arranged on different lighting elements 10 or on the same lighting element 10. However, further LEDs 14 and/or further lighting elements 10 may be introduced in each group 12.

The lighting device of fig. 4 shows a first connector identical to the connector of fig. 2. Further, the lighting device comprises a second connector 20 identical to the second connector 20 of fig. 2. Thus, three parallel wires along the lighting device are also foreseen in the embodiment of fig. 4. Additionally, however, a third connector 36 is disposed between the first connector 18 and the first connector 20. In particular, the third connector 36 is arranged between the fifth and sixth group 12 of lighting devices. The third connector has six anode terminals connected to the lighting driver to individually control the groups 12 of LEDs 14 in order to achieve dynamic lighting.

Fig. 5 shows a cross section of the lighting device. The LEDs 14 are arranged on top of the insert or lighting element 10. In the example of fig. 5, the lighting elements 10 are connected by three wires 16a, 16b, 16 c. The light emitting side of the LED 14 is connected to the light emitting surface 40 of the lighting device by a transparent polymer 38. The wires 16a, 16b, 16c, the lighting element 10, the LED 14 and the transparent polymer 38 are surrounded by an opaque polymer 42. The opaque polymer 42 serves as a protective cover for the lighting device while still providing sufficient flexibility. Additionally, the opaque polymer 42 may be a white polymer that reflects any light exiting the transparent polymer 38 back to the light emitting surface 40, thereby increasing the efficiency of the lighting device. Of course, the opaque polymer 42 may alternatively have any other color that is suitable for the particular application.

Fig. 6 shows a detailed view of the insert or lighting element 10. The lighting element 10 comprises a Printed Circuit Board (PCB) 44, wherein the LEDs 14 are arranged on one upper side of the PCB 44. The PCB 44 is connected to the previous lighting element 10 or connector in the row by a first set of three wires 15a, 15b, 15c, which are placed in parallel and connected to the PCB 44 at a first position (upper position in fig. 6), a second position (middle position in fig. 6) and a third position (lower position in fig. 6), respectively. However, in other embodiments, more or fewer wires may be implemented. In addition, the lighting element 10 is connected to a following lighting element 10 or connector by a second set of three wires 17a, 17b, 17c, which are also placed in parallel and connected to the PCB 44 on opposite sides of the first set, wherein these wires are also connected to the PCB 44 at positions corresponding to the first, second and third positions. Wherein the dashed lines in fig. 6 indicate the electrical wiring provided by the PCB 44 of the lighting element 10. In the example of fig. 6, the first anode connections 15a, 17a pass through the PCB 44, wherein on both sides of the PCB 44 the first anode connections 15a, 17a are connected to the PCB 44 at a first location. However, the second anode connections 15b, 17c may be connected at different locations on both sides of the PCB 44. Further, the ground connection 15c may be connected to the PCB at one location on the first side and then connected to the LED through the circuitry of the PCB 44. The anode connection 17b may be connected to the PCB 44, and then to the LED 14, at the same or a different location than the ground connection 15c, possibly on the same or opposite side. Thus, the LED 14 is connected to the anode connection 17b through the circuitry of the PCB 44 and also to the ground connection 15c in order to supply power to the LED 14. Thus, more complex wiring of wires, such as crossed wires, can be implemented by the PCB 44 of the lighting element 10, thereby enabling parallel wires to be maintained between each lighting element. Thus, a high degree of freedom regarding the wiring along the wires of the lighting device is provided.