EP2869670A1 - Light or light assembly - Google Patents

Abstract

Luminaire or lighting arrangement (1) with a plurality of lighting modules or lighting segments (2, 12), wherein the lighting modules (2, 12) are thermally coupled to each other and each having a temperature sensor (3) and wherein the lamp (1) is adapted to Position of each light module (2, 12) within the luminaire (1) and to assign an address to each luminous module (2, 12) depending on the position, whereby the position of the luminous modules (2, 12) is determined by the luminaire (1) in each case the temperature in the lighting modules (2, 12) is determined with the aid of the temperature sensor (3) and with the aid of this information the position of the respective lighting module (2, 12) within the lamp (1) is determined.

Description

The present invention relates to a lamp or lighting arrangement with a plurality of lighting modules or lighting segments, wherein the lighting modules are thermally coupled to each other and each having a temperature sensor and wherein the lamp is adapted to determine the position of each lighting module within the lamp and each lighting module in dependence assign an address to the position.

Such lights can, for example, be elongated, wherein the lighting modules are then arranged linearly or one behind the other. The light-emitting modules are controllable modules, for example LED modules, which can be controlled or set individually or independently of each other, wherein the light modules are usually connected to a parallel bus. For this purpose, it is necessary that each light module can be individually addressed or contacted, for example by a central control device, which is also connected to the bus, and accordingly each light module must have an address. In order to allow a reasonable light output of the entire lamp, it is also necessary that the position of the individual lighting modules is known in relation to their address.

The address assignment to the lighting modules can, for example, be made before the installation of the lighting modules or even during the production of the lighting modules. By doing so, however, the problem arises that each light module must be installed exactly at the position within the lamp, which was previously determined by the address, otherwise the corresponding address of the light module is assigned to a wrong position in the lamp.

Another option for addressing the lighting modules in the luminaire is that each luminaire module is assigned an address manually after the installation of all the luminaire modules in the luminaire. This can, for example. At an elongated light to a light module at the edge of the lamp the address 001 be assigned and then the other light modules of the light in sequence with ascending addresses 002, 003, etc. are provided, whereby a central control device automatically the position of the corresponding light module known due to the address is. In the case of manual addressing, however, there is the problem on the one hand that this procedure involves considerable effort during or after the installation and, on the other hand, that manual errors can also lead to operator errors, which in turn lead to incorrect activation of the Lead light modules.

Alternatively, however, it could also be provided that the lighting modules are cabled in series within the luminaire and thus corresponding addressing or position detection results automatically. In this case, however, there is the problem that, in the event of a fault, additional bridging measures, for example a relay for bridging a defective board, are required.

The present invention is based on the object to develop a lamp with an alternative addressing of the lighting modules, in which a simple and error-free addressing of the lighting modules is possible and even in the event of an error, no appropriate bridging measures are required.

The object is achieved by a luminaire or lighting arrangement according to claim 1. Advantageous developments of the invention are the subject of the dependent claims.

In the case of the above-described lighting modules or lighting segments, which can be embodied, for example, as LED modules, it is frequently provided that these modules have a temperature sensor which serves to detect an over-temperature condition within the lighting module and, if necessary, to switch off the lighting module To avoid damage. In the present invention, this temperature sensor is now also used for determining the position of the lighting modules within the luminaire.

The luminaire modules are therefore thermally coupled to one another and each have a temperature sensor, and wherein the luminaire is designed to determine the position of each luminous module within the luminaire and each luminous module in Dependence of the position to assign an address. In order to determine the position of the lighting modules through the luminaire, the temperature in the luminous modules is in each case determined with the aid of the temperature sensor and with the aid of this information the position of the respective luminous module within the luminaire is determined.

In the case of the luminaire according to the invention, the temperature values determined by the temperature sensors are thus used not only to avoid damage in the event of an overtemperature, but additionally also to determine the position of each luminous module within the luminaire, whereby it is then possible for each luminous module by the exact position determination a corresponding address will be assigned.

Advantageously, it can be provided that the luminaire has a central control device for determining the position of the luminous modules and for assigning addresses, or that one luminous module or a plurality of luminous modules is / are designed to determine the position of the luminous modules and assign an address to each luminous module.

In order to determine the position of the lighting modules, the luminaire preferably determines the temperature values for all luminous modules of the luminaire and determines the position of each luminous module on the basis of the resulting temperature profile or the different high temperature values. It can be provided that the lamp shuts off all lighting modules before determining the position of the lighting modules.

Advantageously, the luminaire does not determine the position of the luminous modules until the temperature values of the luminous modules measured by the temperature sensors are below a threshold value.

In order to determine the position of the lighting modules, it is then also possible for the light to switch on a light module arranged at the edge of the light, wherein prior to switching on the light module arranged at the edge of the light, it has been known or determined which light module is on the edge the lamp is arranged. This determination can be made by a device, for example. A jumper, wherein at least one of the lighting modules can have such a device. Alternatively, it can also be provided that one lighting module has poorer thermal properties than the others and is arranged on the edge of the luminaire or in the vicinity of other heat sources, such as electronic ballasts. In this case, it may then be provided that the luminaire switches on all the luminous modules simultaneously before determining the position of the luminous modules and before switching off all the luminous modules and determines the luminous module with the highest measured temperature value as the luminous module arranged at the edge of the luminaire.

As soon as a lighting module arranged at the edge of the luminaire is known and is switched on, it is further advantageously provided that the luminaire determines the position of the luminous modules based on the falling temperature values in order to determine the position of the luminous modules, such that the luminous module has the highest measured temperature value the switched-on lighting module is, the lighting module with the second highest measured temperature value is the first switched off light module arranged directly next to the switched-on lighting module, the lighting module with the third highest measured temperature value is the second switched-off lighting module arranged directly next to the first switched-off lighting module, etc.

In this case, it can then also be provided that each luminous module is switched on one after the other, starting with the luminous module having the second highest measured temperature value, and after each switching on of a luminous module, the temperature values of the luminous modules are determined again. The position of the lighting modules preferably results as described above, and the temperature values of the lighting modules which have been switched on before the last-connected lighting module are ignored. In addition, there is also the possibility that in each case the light module is switched off before the last switched on light module.

Furthermore, it may then also be provided that the temperature sensors are asymmetrical, i. not centered, are arranged within the lighting modules.

With an asymmetrical arrangement of the temperature sensors, it is then also possible to determine the position of the lighting modules within the luminaire when no luminous module arranged at the edge of the luminaire is known and can not be fixed. In this case, it is then advantageously provided that for determining the position of the lighting modules, the light switches on a randomly selected lighting module.

Advantageously, the luminaire then determines the relative position of the other lighting modules relative to the switched-on lighting module on the basis of the falling temperature values, such that the lighting module with the highest measured temperature value is the switched-on lighting module, the lighting module with the second highest measured temperature value directly to the left or right next to the switched-on Luminous module arranged first light module is switched off, the light module with the third highest measured temperature value is directly to the right or left of the switched light module arranged second switched off light module, etc., depending on the asymmetric arrangement of the temperature sensors, the first light module switched off to the left and the second light module off right or the first light module switched off to the right and the second light module switched off to the left of the switched-on light module are arranged.

To determine the position of the lighting modules can then be further provided that the light turns off the randomly selected switched on lighting module and successively the other lighting modules on and off and each determines the relative position of the switched off lighting modules against the switched light module based on the falling temperature values. Subsequently, the luminaire can then determine the absolute positions of the luminous modules within the luminaire on the basis of all relative positions.

Advantageously, furthermore, it can be provided that previously created temperature profiles or thermal models are stored in the luminaire and, for determining the position of the luminous modules, the luminaire compares the stored temperature profiles with the resulting temperature profile.

Furthermore, it can also be provided that the luminaire briefly switches on the luminous modules for generating a thermal pulse for determining the position of the luminous modules and takes into account the temporal temperature profile when determining the position.

The lamp may be elongated, wherein the lighting modules are then arranged linearly or one behind the other in the lamp. Likewise, the lighting modules could also be arranged in the form of a matrix in the luminaire.

Figur 1

schematische Darstellung einer erfindungsgemäßen Leuchte mit mehreren Leuchtmodulen;

Figur 2

Leuchtmodul mit einem mittig angeordneten Temperatursensor;

Figur 3

Leuchtmodul mit einem asymmetrisch angeordneten Temperatursensor.

The invention will be explained in more detail with reference to embodiments and the accompanying drawings. Show it:

FIG. 1

schematic representation of a lamp according to the invention with a plurality of lighting modules;

FIG. 2

Light module with a centrally located temperature sensor;

FIG. 3

Light module with an asymmetrically arranged temperature sensor.

In FIG. 1 schematically a luminaire or lighting arrangement 1 according to the invention is shown, which has a plurality of lighting modules or lighting segments 2. The lamp 1 is configured elongated, wherein the lighting modules 2 are arranged linearly or one behind the other, so that an arrangement results in series. In detail, four light modules 2 are provided in the luminaire 1, which are labeled with the letter AD for later detailed explanation of the position determination and address assignment.

Furthermore, it is then also provided that each lighting module 2 is connected via a bus 4 to a central control device 5. This central control device 5 is provided on the one hand to control the individual lighting modules 2 individually and independently of each other. In addition, by the central control device 5 but also the position of each light module 2 is determined within the lamp 1 and assigned a corresponding address based on the position.

As well as further from FIG. 1 shows, each light module 2 has a temperature sensor 3. Until now, this temperature sensor 3 was merely used to measure and detect an excess temperature and, if necessary, to switch off the corresponding lighting module 2 in order to avoid damage, which is important, for example, if the lighting modules 2 are configured as LED modules.

According to the invention, it is now provided that in order to determine the position of the lighting modules 2, the temperature in each case is determined in the lighting modules 2 with the aid of the temperature sensors 3 and transmitted to the central control device 5 via the bus 4. The central control device 5 can then determine the position of the light modules 2 within the light 1 on the basis of the transmitted temperature values of the individual light modules 2.

For this purpose, however, it is then additionally necessary for the lighting modules 2 to be thermally coupled to one another, which is however usually provided in such luminaires 1.

The thermal coupling then ensures that the heat of a switched-on lighting module 2 is transmitted to the adjacent lighting modules 2, it being noted that the temperature or heat is not evenly distributed to all lighting modules, but is transmitted depending on how far a lighting module 2 is removed in each case from the heat-generating switched-on lighting module 2. This then results in a temperature profile or results in different temperature values for the individual lighting modules 2, as a result of which the position of the respective lighting module 2 with respect to the heat-generating lighting module 2 switched on can be determined.

In a first embodiment of the invention can then be provided that a arranged on the edge of the lamp 1 lighting module 2 is already known or determined prior to determining the position of the lighting modules. In FIG. 1 could be, for example, the lighting modules A or D. A manual determination can take place, for example, by a jumper, which has at least one of the light modules 2 arranged on the edge. When installing the lamp 1 or the lighting modules 2 is then set either in the light module A or the light module D, the jumper accordingly to signal the edge position of the light module A or D or set.

An alternative possibility to set the edge position of a light module 2 is that one of the modules 2 has poorer thermal properties than the other light modules 2 and then arranged on the edge of the lamp 1 or that automatically by the positioning of the light modules 2 at the edge of the lamp 1 worse thermal properties for this result, in which case additionally should be provided that, for example, the light module A has even worse properties than the light module D due to the position in the lamp 1. This could, for example, be achieved by a corresponding construction within the luminaire 1.

In order to be able to determine the lighting module 2, which is arranged on the edge of the luminaire 1, all luminous modules 2 are switched on at the same time and then the luminous module 2 is set with the highest measured temperature value as the luminous module A or D arranged at the edge of the luminaire. It may u.U. make sense that after the simultaneous turning on all lighting modules 2 a certain time to heat up the lighting modules 2 is waiting, as in the event that, for example, previously switched on some lighting modules 2 and others were turned off, only after a certain heat-up the light module 2 with the worst thermal properties also has the highest measured temperature value.

After a light module 2 has been set as arranged at the edge light module A and D, by a jumper or worse thermal properties, it is provided that all lighting modules 2 are turned off. To ensure that no temperature values are measured that lead to incorrect position determinations lead after switching off the lighting modules 2 also also be provided that the lighting modules 2 remain off for a certain time to ensure that the temperature of all lighting modules 2 is below a certain threshold or within a certain range and thus more or less, a static off state of the lighting modules 2 is achieved.

Following this, it is provided that the luminous module 2 arranged at the edge is turned on. In FIG. 1 this is either the light module A or the light module D, wherein in the following example, the light module A is used. After the light module A has been turned on, it is still possible to wait a bit until a certain heating is achieved.

Subsequently, a temperature value is then determined in each light module 2 with the aid of the temperature sensors 3. This results in a different temperature value for each light module 2, wherein in the case of in FIG. 1 1, the light module A has the highest temperature value, the light module B the second highest temperature value, the light module C the third highest temperature value and the light emitting module D the fourth highest temperature value, since - as already explained above-the height of the temperature value depends on the distance to the light module A connected and the lighting module B is arranged closest to the lighting module A, then subsequently follows the lighting module C in the row and finally the lighting module D is placed. Of course, the switched on lighting module A itself has the highest measured temperature value.

By knowing that the lighting module A is arranged at the edge of the luminaire 1, and by the falling temperature values as a function of the distance to the luminous module A, the position of the other luminous modules B, C and D can then be determined. With the aid of this position information, it is the central control device 5 possible to assign the lighting modules 2 corresponding addresses, wherein in FIG. 1 is provided that the light module A, the address 001, the light module B, the address 002, the light module C, the address 003 and the light module D receives the address 004, which already results from the address, the position of the light modules 2 within the lamp 1.

In addition, it may also be provided that each lighting module 2 is switched on one after the other, with the temperature values of the lighting modules 2 being determined again every time a lighting module 2 is switched on. This results in each new measurement further temperature values that give a more accurate picture of the positions of the individual lighting modules 2. For the lamp 1 in FIG. 1 For example, it would be provided that, after switching on the light module A and a first temperature measurement in all light modules 2, the light module B is turned on and again the temperature values are measured at all light modules 2, etc .. Then, the positions of the light modules arise comparable As already described above, the temperature values of the lighting modules 2 that have been switched on before the last-connected lighting module 2 are disregarded.

In addition, it can then also be provided that in each case the lighting module 2 is switched off before the last switched on lighting module 2. For the lamp 1 in FIG. 1 Then the light module A would be turned off after the light module B has been turned on, wherein only after switching off the light module A, the further temperature measurement would be made.

In the FIGS. 2 and 3 in each case a lighting module 2 and 12 is shown, wherein in the lighting module 2 in FIG. 2 the temperature sensor 3 is arranged centrally in the light module, as in FIG. 1 is shown. In contrast, in the lighting module 12 in FIG. 3 the temperature sensor 3 is arranged asymmetrically, that is, the temperature sensor 3 is placed outside the center.

This in FIG. 3 shown light module 12 could also in the lamp 1 in FIG. 1 Application, wherein the asymmetrical arrangement of the temperature sensor 3 is particularly advantageous in a second embodiment of the invention, in which no arranged at the edge light module 12 is known or could be set, as different temperature values for the left or right of a turned on by the asymmetric arrangement Light module 12 arranged light modules 12 result.

With regard to the lamp 1 in FIG. 1 would correspond to the asymmetric arrangement of the temperature sensors 3 FIG. 3 in a switched on light module B different temperature values for the switched off lighting modules A and C result, in detail, light module C would have a higher temperature value than light module A, since the temperature sensor 3 of the light module C would be located closer to the light module B than the temperature sensor 3 of the light module A and thus more heat would get transferred from the light module B. This asymmetrical arrangement of the temperature sensors 3 thus makes it possible to distinguish whether a respective lighting module 12 is arranged to the left or to the right of a lighting module 12 that is switched on.

In this embodiment, too, it would again be provided that, at the beginning of the determination of the position of the lighting modules 12, all the lighting modules are switched off and wait until all temperature values have fallen below a certain threshold value in order to achieve a more or less static off state. Subsequently, a randomly selected lighting module 12 is then turned on, in which case a certain time can then be waited until the light module 12, which has been switched on at random, has heated up. Thereafter, the relative position of the other lighting modules 12 relative to the switched-on lighting module 12 can then be determined on the basis of the falling temperature values.

Regarding the lamp 1 in FIG. 1 For example, it would be conceivable that the randomly selected lighting module 12 is the lighting module B and accordingly the lighting module B is switched on. The light module B then has the highest measured temperature value. As already explained above, the luminous module C then has the second highest measured temperature value due to the asymmetrical arrangement of the temperature sensors 3, the luminous module A the third highest measured temperature value and the luminous module D the fourth highest measured temperature value, since the temperature sensor 3 of the luminous module D despite the asymmetrical arrangement is further away from the light module B than the temperature sensor A of the light module A. This then results in the relative position of the different light modules A, C and D to the light module B.

After the relative position of the other lighting modules 12 has been determined with respect to the switched-on lighting module 12, the switched-on lighting module 12 is turned off and the other lighting modules 12 and switched off and off and the relative position of the switched-off lighting modules 12 relative to the switched-on lighting module 12 by means of the falling Temperature values determined.

In the light 1 in FIG. 1 It would then be provided, for example, that the lighting module B is switched off and another lighting module, for example a lighting module D, is selected. This lighting module D is in turn turned on and the relative positions of the light modules A, B and C to the light module D are determined, wherein the light module C has the second highest temperature value, the light module B the third highest temperature value and the light emitting module A the fourth highest temperature value. Following this, then the light module D would be switched off and successively still the light modules C and A or A and C on and off.

Overall, the absolute position of each lighting module 12 can then be determined by the combination of all relative positions and by appropriate sorting.

In both embodiments, furthermore, it may also be provided that, instead of permanently switching on a lighting module, the lighting module is only switched on briefly in order to generate a thermal pulse and to take into account the temporal temperature profile when determining the position.

In addition, it is also possible for reference measurements to be carried out, for example, during the production of the luminaires or luminous modules in order to describe the thermal propagation within the framework of a thermal model or a temperature profile. These thermal models or temperature profiles can be stored in the luminaire and correspondingly taken into account in the later measurements for determining the position, it also being possible to carry out a pausibility check as to whether the then measured temperature values are realistic or not. In the context of these reference measurements It can also be determined whether or below which threshold value the temperatures should fall before a corresponding determination of the position can be carried out.

In addition, it should also be noted that it is not absolutely necessary that as in FIG. 1 shown a central controller 5 performs the determination of the position and the address assignment. Likewise, it would also be conceivable, for example, for one or more lighting modules to be designed to determine the position of the lighting modules and to assign an address to each lighting module.

In the FIG. 1 shown lamp 1 is shown schematically as an elongated lamp. However, the luminaire according to the invention is not limited to an elongated luminaire. It would be conceivable, for example, also a matrix-like arrangement of the lighting modules.

Claims (15)

Luminaire or lighting arrangement (1) with a plurality of lighting modules or lighting segments (2, 12), wherein the lighting modules (2, 12) are thermally coupled to each other and each having a temperature sensor (3) and wherein the lamp (1) is adapted to To determine the position of each lighting module (2, 12) within the luminaire (1) and to assign an address to each luminous module (2, 12) depending on the position,
characterized,
in that the temperature in the lighting modules (2, 12) is determined with the aid of the temperature sensor (3) for determining the position of the lighting modules (2, 12) by the lamp (1) and with the aid of this information the position of the respective lighting module (2 , 12) within the luminaire (1) is determined. Luminaire according to claim 1,
characterized,
that the lamp (1) for determining the position of the lighting modules (2, 12) and the address assignment, a central control means (5), or
that a light module (2, 12) or more lighting modules (2, 12) is adapted / are the position of the lighting modules (2, 12) to determine and each light-emitting module (2, 12) to assign an address. Luminaire according to claim 1 or 2,
characterized,
in that the luminaire (1) is designed to determine the temperature values for all luminous modules (2, 12) of the luminaire (1) for determining the position of the luminous modules (2, 12) and to determine the position of each luminous module (2, 12) on the basis of to determine the resulting temperature profile or the different high temperature values. Luminaire according to claim 3,
characterized,
that the lamp (1) is adapted to determine the position in front of the lighting modules (2, 12), all of the luminous modules (2, 12) off,
wherein preferably the luminaire (1) is designed to determine the position of the lighting modules (2, 12) only when the temperature values of the lighting modules (2, 12) measured by the temperature sensors are below a threshold value. Luminaire according to claim 4,
characterized,
in that the temperature sensors (3) are arranged asymmetrically within the lighting modules (12). Luminaire according to claim 4 or 5,
characterized,
in that the luminaire (1) is designed to determine the position of the luminous modules (2) by switching on a luminous module (2) arranged on the edge of the luminaire (1), whereby the luminous module (2) arranged at the edge of the luminaire (1) is switched on is known or has been established, which light module (2) is arranged on the edge of the lamp (1),
wherein preferably the lamp (1) is designed to determine the position of the lighting modules (2) the position of the lighting modules (2) on the basis of the falling temperature values, such that the lighting module (2) with the highest measured Tertoorurwert the switched on lighting module ( 2), the lighting module (2) having the second highest measured temperature value is the first switched-off lighting module (2) arranged directly next to the switched-on lighting module (2), the lighting module (2) having the third highest measured temperature value being the light module directly switched off next to the first lighting module (2). 2) arranged second switched-off light module (2) is, etc .. Luminaire according to claim 6,
characterized,
in that the luminaire (1) is designed to switch on each luminous module (2) in succession to determine the position of the luminous modules (2), starting with the luminous module (2) having the second highest measured temperature value, and after each switching on of a luminous module (2) To determine the temperature values of the lighting modules (2) again,
wherein preferably the position of the lighting modules (2) according to claim 7 results and the temperature values of the lighting modules (2), which have been turned on before the last switched on lighting module (2) are disregarded. Luminaire according to claim 7,
characterized,
that the lamp (1) is adapted for determining the position of the lighting modules (2) respectively to disable the light module (2) in front of the last turned-on light-emitting module (2). Luminaire according to one of claims 6-8,
characterized,
in that at least one of the lighting modules (2) has a device, for example a jumper, by means of which it can be established whether the lighting module (2) is arranged on the edge of the luminaire (1). Luminaire according to one of claims 6-8,
characterized,
that a light-emitting module (2) has poorer thermal properties than the other and is arranged at the edge of the luminaire (1),
wherein preferably the luminaire (1) is designed to switch on all lighting modules (2) simultaneously before determining the position of the lighting modules (2) and before switching off all lighting modules (2) and the lighting module (2) having the highest measured temperature value than that at the edge the luminaire (1) arranged light module (2) set. Luminaire according to claim 5,
characterized,
in that the luminaire (1) is designed to determine a randomly selected lighting module (12) for determining the position of the lighting modules (12), wherein preferably the luminaire (1) is designed to determine the position of the lighting modules (12) to determine other light modules (12) relative to the switched-on light module (12) on the basis of the falling temperature values, such that the light module (12) with the highest Temperarturwert measured is the switched on light module (12), the light module (12) with the second highest Temperarturwert measured the first switched-off lighting module (12) arranged directly to the left or right next to the switched-on lighting module (12), the lighting module (12) having the third highest measured temperature value the second switched-off lighting module (12) arranged directly to the right or left of the switched-on lighting module (12) is, etc., depending on the asymmetric arrangement of the temperature sensors n (3) the first light module (12) switched off to the left and the second light module (12) switched off to the right or the first light module (12) switched off to the right and the second light module (12) to the left of the light module (12). Luminaire according to claim 11,
characterized,
in that the luminaire (1) is designed to determine the position of the lighting modules (12) to switch off the randomly selected switched-on lighting module (12) and to switch the other lighting modules (12) on and off one after the other and respectively to determine the relative position of the switched-off lighting modules (12). relative to the switched-on lighting module (12) on the basis of the falling temperature values to determine according to claim 11,
and wherein preferably the lamp (1) is adapted to determine the position of the lighting modules (12) based on all relative positions to determine the absolute positions of the lighting modules (12) within the lamp (1). Luminaire according to one of claims 3-12,
characterized,
that previously created temperature profiles or thermal models are stored in the luminaire (1) and the luminaire (1) is designed to determine the position of the luminous modules (2, 12) to compare the stored temperature profiles with the resulting temperature profile. Luminaire according to one of claims 1-13,
characterized,
that the lamp (1) is adapted for determining the position of the lighting modules (2, 12), the light-emitting modules (2, 12) briefly to switch on for generating a thermal pulse and to take into account the temperature history in determining the position. Luminaire according to one of claims 1-14,
characterized,
that the lamp (1) is elongate and the lighting modules (2, 12) linear or behind one another in the luminaire (1) are arranged,
or
that the lighting modules (2, 12) are arranged like a matrix.

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