AT17819U1 - Luminaire with illuminant with variable light emission direction and thermal coupling - Google Patents

Abstract

The present invention relates to a lamp (1), having a lamp housing (2), a lighting element (3) with at least one lighting means (4), the lighting element (3) being at least partially accommodated in the lamp housing (2), and relative to the Luminaire housing (2) is movably provided in order to change a light emission direction of the illuminant (4), and a heat-conducting element (5) which thermally connects the illuminant (4) to the luminaire housing in any movement position of the illuminant element (3) relative to the luminaire housing (2). (2) couples.

Description

Description

LUMINAIRE WITH VARIABLE LIGHT EMISSION LAMP AND THERMAL COUPLING

The present invention relates to a lamp, in particular a lamp whose light source is provided to be movable, and a heat-conducting element for dissipating heat generated during operation of the lamp or its illuminant.

Lamps with heat dissipation means are known in different ways from the prior art. Luminaires often have suitable cooling to dissipate the heat from the light sources (e.g. LEDs). This is usually achieved in that the lamp housing accommodating the illuminants radiates heat freely and/or, for example, air can flow convectively around it. For this purpose, the lamp often has cooling fins. Depending on the version, these are visible because they are often provided on the outside of the lamp and can thus help shape the appearance of the lamp.

In order to ensure adequate cooling of the lamp and at the same time to enable the light source to be adjusted, the prior art discloses different approaches. For example, a lamp is known from the prior art, the light source of which is arranged in a stationary manner in a housing. The housing, in turn, is movably attached to a wall or ceiling to adjust the direction of light emission. In the case of such lamps with an adjustable light emission direction, this causes the respective alignment position to be reflected in the design of the lamp, since a heat sink, which is usually fixed to the lamp housing for the purpose of heat conduction, also describes a corresponding movement of the respectively set light emission direction.

The turn encounter solutions from the prior art so that the movable parts of the lamp, which are used to emit light, are accommodated within a separate stationary housing, so that a change in their orientation have less impact on the appearance of the lamp. Since the light source together with the heat sink is thus mounted in the stationary housing, free radiation from the heat sink is reduced. The stationary housing absorbs the heat radiated by the internal heat sink and is heated up as a result. In addition, convection on the heat sink is prevented. Due to the arrangement of the heat-generating light source within the housing, the cooling of the light source is consequently made more difficult, so that additional ventilation slots are provided in the stationary housing. These in turn promote soiling of the inside of the housing and consequently increase the maintenance effort. In addition, ventilation slots and cooling fins spoil the appearance of the light. Consequently, there is a certain trade-off for a luminaire with a movable light source.

It is therefore an object of the present invention to provide a lamp with a movable light source (lamp or lamp element) and a corresponding heat-conducting element for dissipating (operating) heat from the light source, which enables sufficient cooling of the lamp and at the same time has an increased range of applications.

[0006] This object is solved by the subject matter of the independent claims. The dependent claims develop the central idea of the present invention in a particularly advantageous manner.

According to a first aspect, the present invention relates to a lamp having a lamp housing. The lamp also has an illuminant element with at least one illuminant. The illuminant element is at least partially and preferably entirely accommodated in the lamp housing; ie preferably at least partially or entirely in an interior of the lamp housing.. Furthermore, the lamp element is provided so that it can be moved relative to the lamp housing in order to change a light emission direction of the lamp (i.e. depending on the movement position). The lamp also has a heat-conducting element which

Ches thermally couples the lamp to the lamp housing in any movement position of the lamp element relative to the lamp housing. This is preferred in that the heat-conducting element absorbs the relative movement between the lamp housing and the illuminant element.

The relative movement of the lamp element to the lamp housing can include any movement such as a rotational and / or translational movement; preferably a corresponding movement of the illuminant element in the lamp housing (provided to be stationary), in which the illuminant element is movably mounted, for example, correspondingly in/on the lamp housing. The illuminant is used to emit light from the lamp; this preferably in any movement position. Consequently, the lamp housing preferably forms an outer housing of the lamp.

The present invention makes it possible to reliably carry away the heat generated on the bulb by this, although the bulb element is at least partially accommodated in the lamp housing. The thermal coupling to the luminaire housing then enables safe heat dissipation via the luminaire housing. In this way, an increase in temperature within the lamp housing can be avoided or at least significantly reduced compared to the known solutions. This enables sufficient cooling of the light source and at the same time increases the range of uses of the lamp, since the appearance of the lamp to the viewer is essentially independent of the orientation of the lamp element or its lamp in the lamp housing due to the lamp element being at least partially accommodated in the lamp housing. Optimized cooling of the lamp also increases its service life, its reliability and consequently reduces the maintenance effort for the entire lamp.

The heat conducting element, preferably a first coupling area of the same, can be surface-coupled to the lamp housing, and/or the heat-conducting element, preferably a second coupling area thereof, can be surface-coupled to the illuminant element.

By the heat conducting element being coupled flat to the lamp housing and/or lamp element, a defined coupling surface is provided, and thus the corresponding thermal coupling with the heat conducting element and thus thermal conduction from the lamp element to the lamp housing is reliably provided and consequently improved.

The heat conducting element can be mechanically coupled, preferably with its first coupling area, on the side of the lamp housing on the one hand and/or, preferably with its second coupling area, on the side of the lamp element on the other hand, in order to thermally couple the lamp to the lamp housing.

[0013] A particularly safe and effective heat transfer can be achieved by the mechanical coupling of the heat-conducting element. The heat-conducting element can be mechanically coupled directly or indirectly to the lamp housing or the lighting element.

The mechanical coupling can be detachable, preferably by means of a screw connection, or non-detachable, preferably by means of a welded or adhesive connection.

While an inseparable mechanical coupling enables a permanent, secure mechanical coupling, a detachable mechanical coupling offers the possibility of making the lamp more flexible and possibly providing the customer with a desired heat-conducting element, the lamp being easier to maintain and only if necessary replace individual components.

The heat-conducting element can have a connecting section which is designed in such a way as to maintain the thermal coupling between the lamp and the lamp housing in any movement position of the lamp element relative to the lamp housing.

Thus, preferably at least one defined section (ie the connecting section) of the heat-conducting element can absorb the relative movement between the lamp housing and the illuminant element in order to maintain a permanent thermal coupling regardless of the movement position.

The connecting portion can extend at least partially between the illuminant element and the lamp housing, preferably between the first coupling area and the second coupling area.

In this way, an arrangement that is as compact as possible with effective heat dissipation can be made possible.

The heat-conducting element, preferably at least its connecting portion, can be deformable in order to maintain the thermal coupling between the lamp and the lamp housing by deformation of the heat-conducting element in any movement position of the lamp element relative to the lamp housing.

The deformation of the heat-conducting element allows the relative movement between the lamp housing and the illuminant element to be accommodated, and thus adequate heat transfer regardless of the movement position. In addition, any number of degrees of freedom of the relative movement can be provided without having a negative effect on the thermal coupling.

The heat-conducting element, preferably at least its connecting portion, can be designed to be movable in order to maintain the thermal coupling between the lamp and the lamp housing by the movement of the heat-conducting element in any movement position of the lamp element relative to the lamp housing. For this purpose, the heat-conducting element or its connecting section can preferably have at least one joint section.

In this way, a defined relative movement between the lamp housing and the illuminant element can preferably be provided. The movable design of the heat-conducting element or its connecting section also allows, for example, the use of rigid components as heat-conducting element or rigid materials for the heat-conducting element in order to accommodate the relative mobility between the luminaire housing and the lighting element and thus permanently maintain the thermal coupling regardless of the movement position. For example, the use of a hinge is conceivable. The use of a spring hinge is particularly preferred, which pretensions the heat-conducting element towards the thermal coupling, ie in particular towards the lamp housing or the illuminant element, in order to reliably maintain the thermal coupling. The mechanical coupling can also be provided in this way; this, for example, in the form of a force fit and/or (for safe maintenance) a form fit.

The heat conducting element, preferably at least its connecting section, can have a resetting section in order to thermally reset the heat conducting element, preferably its first coupling area and/or its second coupling area, preferably in any movement position of the light source element relative to the light housing to the light source element and/or the light housing Bias coupling between the bulb and the lamp housing. The recovery section is preferably elastic.

The integration of a reset section in the heat-conducting element simplifies thermal coupling of the heat-conducting element to the lamp housing and/or lamp (element) by achieving a prestress in the heat-conducting element, regardless of the movement position of the lamp element relative to the lamp housing, so that the heat conduction from the lamp to the lamp housing is reliable maintained and thus improved. In addition, the mechanical coupling of the heat-conducting element to the lamp housing and/or the lamp element means that there is no need for fasteners or other complex joining techniques, so that the manufacturing costs can be reduced and individual components of the lamp can also be replaced during maintenance.

[0026] The restoring section can have a spring (for example as part of a spring hinge described above) or an elastic section of the heat-conducting element.

[0027] When using a spring as a reset section, it is possible in a simple and preferably

Standardized components can be used to generate the preload described. In particular, the combination of spring and hinge (e.g. as a spring hinge) to achieve the restoring effect is one way of achieving the restoring effect described using inexpensive components in turn, preferably simplifies the assembly work and reduces the number of parts.

The heat conducting element, preferably at least its connecting portion, can be made of a deformable, preferably an elastically deformable or flexible material, to accommodate the relative movement between the lamp housing and the illuminant element, so as to permanently maintain the thermal coupling.

In this way, the heat-conducting element can absorb a relative movement between the lamp housing and the lamp element in a particularly simple manner, while the thermal coupling between the lamp and the lamp housing is maintained regardless of the movement position of the lamp element relative to the lamp housing. Since this effect is preferably achieved solely or at least in a supporting manner through the choice of a suitable material, costs for additional components can be saved. In particular, an elastic, i.e. reversibly deformable, heat-conducting element (or connecting section) guarantees that the heat-conducting element will rest securely against the corresponding elements, even after frequent adjustment of the movement position of the lighting element relative to the lamp housing, and consequently effective heat transfer over the long term. A thermally conductive element made of an elastic material in the context of the present invention means that the material is elastic enough to allow the movement position of the lighting element to be adjusted relative to the luminaire housing and at the same time the thermally conductive element to be in contact with or on the sides of the corresponding element(s) in each of the intended movement positions is possible and repeatable.

The heat-conducting element can be designed as a heat-conducting sheet, heat-conducting plate or heat-conducting foil.

[0031] Consequently, the heat-conducting element can be produced from any known materials or components. In particular, the design of the heat-conducting element as a heat-conducting foil or heat-conducting sheet creates a certain flexibility of the heat-conducting element, so that a thermal coupling from the lamp element to the lamp housing is possible regardless of the movement position of the lamp element relative to the lamp housing. In addition, a thermally conductive foil can preferably be rolled up and is therefore easy to store or process.

The heat-conducting element can be made of a material which has copper and/or carbon, preferably oriented carbon, such as graphene and/or graphite, particularly preferably carbon nanotubes, in particular in combination with plastic.

The materials listed are particularly suitable for the production of a thermally conductive element, since they have a particularly high thermal conductivity coefficient and thus a high thermal conductivity. In particular, by combining the materials copper and/or carbon, preferably carbon nanotubes, with a plastic, which preferably has high elastic deformability, a flexible or even elastically deformable heat-conducting element with a particularly high thermal conductivity can be provided that is particularly suitable for use in the lamp according to the invention.

The heat conducting element can be accommodated at least partially and preferably completely in the light housing—preferably an interior space of the same. The heat-conducting element, preferably its first coupling region, preferably rests against an inner surface or an inner wall of the lamp housing.

[0035] Such an arrangement of the heat-conducting element prevents that from being directly visible from the outside; This is independent of the movement position of the lighting element relative to the lamp housing. Consequently, the lamp according to the invention can be used more flexibly, since

it has an aesthetically pleasing appearance despite a particularly movable illuminant element.

The illuminant element can have an illuminant housing, which preferably accommodates the illuminant.

The provision of a lamp housing can increase the handling of the lamp and simplify the thermal connection of the heat-conducting element. In addition, the movable configuration of the illuminant element can preferably be simplified, since this can be provided in a simple manner on the illuminant housing or can be formed integrally with it. In addition, a lamp housing has a certain protective effect for the lamp; this in particular when the light source is accommodated in this, but also in the case of a plate-shaped light source housing. The lamp housing also makes it possible to provide a defined coupling surface for reliable thermal coupling of the heat-conducting element.

The lamp housing can have a lamp space and/or at least one flat receiving section for receiving the lamp.

[0039] In particular, the integration of the illuminant in a luminaire space leads to a secure accommodation of the illuminant. Optical elements such as reflectors or lenses can also be easily provided in this way. It is also conceivable that the lamp housing or its lamp space is preferably designed to be reflective, which results in a particularly effective light emission. A flat receiving section preferably ensures secure positioning of the lamp and good heat transfer to the lamp housing, which in turn can then be effectively transferred to the heat-conducting element. Alternatively, an overall planar configuration of the lamp housing is also conceivable. Such a lamp housing is particularly inexpensive and easy to manufacture. In addition, a flat lamp housing can be connected to the heat-conducting element just as easily and effectively.

The light source element, preferably the light source or the light source housing, can be movably connected to the light housing via a movement element, the movement element preferably having a joint, such as a ball joint or a rotary joint, and/or a rail and/or a hinge.

The arrangement of a movement element between the lamp housing and the lamp element enables a particularly simple and space-saving provision of the mobility of the lamp relative to the lamp housing. Alternatively or additionally, such a movement element can also be arranged between the lamp and the lamp housing in order to ensure the mobility of the lamp element according to the invention relative to the lamp housing. Due to the resulting adjustability of the lamp element relative to the lamp housing, the light output of the lamp can be individually adapted to the needs of the user, the installation location and/or the spatial conditions. Depending on the design, a joint in particular allows any number of degrees of freedom. A rail enables in particular a translatory displacement of the illuminant element relative to the lamp housing, so that a correspondingly elongated space can be covered with light from the illuminant without giving up the thermal coupling. The combination of both movement elements maximizes the number of degrees of freedom when adjusting the movement position of the lamp element relative to the luminaire housing.

The light source can have at least one LED or one LED module.

As is known, LEDs are characterized by a particularly efficient light output. In addition, LEDs offer a particularly high luminous intensity in a small space. Alternatively or additionally, however, the lighting means can also have at least one so-called conventional light source, such as an incandescent lamp, fluorescent tube or halogen lamp. The arrangement of several LEDs connected in parallel or in series is also conceivable.

The illuminant element can have at least one optical system for optically influencing light emitted by the illuminant.

The additional use of optics allows a defined and thus effective light output and consequently increases the range of uses of the entire light.

The lamp can also have a reflector, which is arranged in such a way that it interacts optically with the light emitted by the lamp, preferably deflects the light in a directed manner, this preferably in each of the movement positions. The reflector can preferably also be arranged at least partially in the lamp housing.

Consequently, the range of use of the lamp can be further increased; this preferably without interfering with the external appearance of the lamp and preferably independently of the direction of light emission or movement position.

The lamp housing and/or, if present, the lamp housing can have at least one heat dissipation-promoting heat dissipation means such as cooling fins, preferably at least in a lamp housing section that is thermally coupled to the heat-conducting element.

[0049] The additional installation of a heat dissipation means on and/or in the lamp housing enables a further improved heat dissipation of the lamp. As a result, for example, the lamp housing could be made smaller (smaller surface area for heat dissipation, lower thermal mass) without jeopardizing adequate cooling of the lamp. Alternatively, a light source with a higher heat output and preferably a higher light output could be used. In addition, better cooling of the lamps increases their service life. Cooling fins in particular have an effect that promotes heat dissipation. Cooling ribs could, for example, be arranged on the preferably stationary light housing in such a way that they cannot be recognized as such by the viewer of the light when installed. This is promoted in particular by the heat-conducting element which absorbs the movement and which conducts the heat as specifically as possible to the corresponding lamp housing section, independently of the movement position. Since the heat conducting element can basically be guided or placed on any area of the lamp housing, the positioning of these heat dissipating means can be selected independently of the point of origin of the operating heat of the lamps to be dissipated by means of the heat conducting element. In addition, the heat dissipation of the lamp housing to the environment can also be optimized by choosing a suitable material that has a high thermal conductivity coefficient/high thermal conductivity. Examples of such materials have already been mentioned in connection with the heat-conducting element. In particular, metals, preferably copper, but also carbons, such as for example aligned carbons and/or plastics mixed with carbon nanotubes, are suitable. Thermally conductive coatings can also promote heat dissipation from the luminaire housing to the environment.

The lamp can have a plurality of heat-conducting elements, each of which thermally couples the lamp to the lamp housing.

[0051] Several heat-conducting elements, which are thermally coupled to a lamp, improve the heat conduction from the lamp to the lamp housing, so that better cooling of the lamp is made possible. In addition, a plurality of preferably symmetrically arranged heat-conducting elements can ensure sufficient, permanent thermal coupling even with great relative mobility between the illuminant element and the lamp housing.

According to a second aspect, the invention relates to a heat-conducting element for use in a lamp according to the invention.

Further embodiments and advantages of the present invention are explained using the following exemplary embodiments in connection with the figures of the accompanying drawings. Show it:

[0054] FIG. 1 shows a schematic lateral sectional view of a lamp according to a first embodiment of the invention.

[0055] FIG. 2 shows a schematic lateral sectional view of a lamp according to a second embodiment of the invention.

[0056] FIG. 3 shows a schematic lateral sectional view of a lamp according to a third embodiment of the invention.

[0057] FIG. 4 shows a schematic lateral sectional view of a lamp according to a fourth embodiment of the invention.

The figures show four exemplary embodiments of a lamp 1 according to the invention. The lamp 1 can be designed as a built-in lamp, surface-mounted lamp or pendant lamp.

The lamp 1 according to the invention has a lamp housing 3 . The lamp housing 3 can have different shapes. Thus, for example, lamps 1 are shown in FIGS. 1 and 3, which have a rectangular cross-sectional shape. However, lamp housings 3 of other shapes are also conceivable. FIGS. 2 and 4 show, for example, lamp housings 3 with other cross-sectional shapes. In general, the lamp housing 3 can have an elongate extension, in order to be designed, for example, in the form of a support rail for a continuous-row lamp. However, lamps that have a rectangular, round, oval or other shape are also conceivable.

In addition, the lamp housing 3 at least partially accommodates at least one illuminant element 3 , which in turn has at least one illuminant 4 . The illuminant 4 can have at least one LED or an LED module, for example. In the exemplary embodiments shown (FIGS. 1-4), each illuminant element 3 has only one LED. However, it is also conceivable to provide several LEDs on one lighting element 3. Alternatively or additionally, the lighting element 3 can also have another lighting means 4, such as an incandescent lamp. In addition, at least part of the electronics required to operate the light source 4 can be provided in/on the light source element 3 .

While Figures 1, 2 and 4 disclose lamps 1 each with a lamp element 3, Figure 3 shows a lamp 1, which has two lamp elements 3. However, it is also conceivable to provide more than two corresponding illuminant elements 3.

In order to optically influence the light emitted by the illuminant 4, the illuminant element 3 can have an optical system 12 in accordance with the exemplary embodiments illustrated in FIGS. 2-4. FIG. 1, on the other hand, shows an exemplary embodiment in which additional optics 12 are dispensed with. For example, optics 12 in the form of lenses are conceivable.

In addition, the illuminant element 3 can have an illuminant housing 10 which preferably accommodates the illuminant 4 . For this purpose, the lamp housing 10 can have a lamp space and/or a flat receiving section 14 . In all of the illustrated exemplary embodiments (FIGS. 1-4), an illuminant housing 10 which has a flat extension and consequently a flat receiving section 14 is disclosed. The illuminant 4 is preferably arranged on this receiving section 14, for example in the form of an LED or an LED module. The lamp housing 10 can form part of an LED module; e.g. a carrier.

In addition, the luminaire 1 can also have a reflector 13 which, for example, as shown in FIGS. 2, 3 and 4, is arranged on the illuminant element 3 itself. Alternatively or additionally, a reflector 13 could also be provided in the form of a reflective layer directly on the lamp housing 2 (preferably on its inner surface) and/or the lamp housing 10, or the housings 2, 10 could be made of a correspondingly reflective material. The exemplary embodiment illustrated in FIG. 3 has, for example, two reflectors 13 which are each assigned to one of the two illuminant elements 3 or illuminant 4 . The reflector 13 can have a wide variety of configurations. Figures 2 and 4 show reflectors that are symmetrical in cross-section

extend away from the illuminant 4, while FIG. 3 shows specially shaped reflectors 13 which partially surround the illuminant 4 in order to provide a kind of wallwasher function.

The at least one illuminant element 3 is arranged in such a way—in this case in the lamp housing 2 —that the illuminant element 3 can be moved relative to the lamp housing 2 . For this purpose, the illuminant element 3 is preferably connected to the lamp housing 2 by means of a movement element 11 . The exemplary embodiments illustrated in FIGS. 1-4 each show joints that serve as movement elements 11 . Thus, FIGS. 1-3 show exemplary embodiments that use a rotary joint as the movement element 11, so that the lighting element 3 has a two-dimensional rotational mobility relative to the lamp housing 2. FIG. 4 even shows a ball and socket joint, which serves as a movement element 11 and consequently enables three-dimensional mobility of the illuminant element 3 relative to the lamp housing 2 . However, a translational movement of the lighting element 3 relative to the lamp housing 2 is also conceivable. For this purpose, the lighting element 3 could be arranged on the lamp housing 2 by means of a rail, for example. Any combination of rotational and translational movement components through corresponding movement elements 11 can increase the degree of freedom of the illuminant element 3 as desired. FIG. 4 shows an exemplary embodiment which has a special arrangement of movement means 11, reflectors 13 and lighting elements 3. Thus, in each case the reflector 13 is arranged so that it can be moved relative to the lamp housing 2 by means of a respective movement element 11 . The two reflectors 13 are in turn each firmly connected to a lamp element 3 so that both lamp elements 3 can be moved relative to the lamp housing 2 by means of the respective reflector 13 and the respective movement element 11 .

In addition, the lamp 1 has at least one heat-conducting element 5, which thermally couples the lamp 4 to the lamp housing 2 in each movement position of the lamp element 3 relative to the lamp housing 2; therefore therefore the relative movement between the lamp housing 2 and the illuminant element 3 absorbs. It is also conceivable to use two or even more heat-conducting elements 5, which, for example, either thermally couple the lamp housing 2 to a light source 4, as can be seen in FIG. 4, or thermally couple one light source 4 each, as can be seen in FIG couple with one lamp housing 2. The heat-conducting element 5 is preferably at least partially, particularly preferably completely (as is the case in the exemplary embodiments in FIGS. 1-4) accommodated in the lamp housing 2

The heat-conducting element 5 can preferably be present in the form of a heat-conducting sheet metal, a heat-conducting plate or a heat-conducting foil. The choice of material in particular can affect heat conduction. Copper, carbon, preferably aligned carbon, such as graphene and/or graphite, and/or carbon nanotubes, especially in combination with plastic, have a particularly good coefficient of thermal conductivity and therefore particularly good thermal conductivity, and are therefore particularly well suited for use in the thermally conductive element 5.

The heat-conducting element is preferably coupled over a large area to the lamp housing 2 and/or the illuminant element 3; in the illustrated embodiments with both. For this purpose, the heat-conducting element 5 can preferably have a first coupling area 6, which preferably couples the heat-conducting element 5 to the lamp housing 2 over a large area, and a second coupling area 7, which preferably couples the heat-conducting element 5 to the lamp element 3 over a large area.

Preferably, a mechanical coupling can preferably exist at least in one of the two coupling regions 6 and 7 between the lamp housing 2 and the heat-conducting element 5 and/or the heat-conducting element 5 and the illuminant element 3; this is preferred in order to thermally couple the illuminant 4 to the lamp housing 2 . Such a mechanical coupling can be detachable or non-detachable. In the exemplary embodiments of FIGS. 1-4, only detachable mechanical couplings are shown, in which additional fastening means are dispensed with. However, the use of screws is also conceivable

(releasable), welds (non-releasable) or glued joints (non-releasable) to achieve a mechanical coupling. In principle, all conceivable types of connection, such as a force fit, form fit and/or material connection, are conceivable for the mechanical connection of the elements mentioned.

According to the exemplary embodiments illustrated in FIGS. 1-4, the heat-conducting element 5 preferably has a connecting section 8 . This connecting section 8 is preferably designed in such a way that the thermal coupling between the lamp 4 and the lamp housing 2 is maintained in any movement position of the lamp element 3 relative to the lamp housing 2 . As can also be seen from FIGS. 1-4, the connecting sections 8 of the respective exemplary embodiments preferably extend between the illuminant element 3 and the lamp housing 2; here preferably between the first coupling area 6 and the second coupling area 7 of the same.

The heat-conducting element 5 and preferably its connecting section 8 is preferably designed to be deformable and particularly preferably elastically deformable in order to maintain the thermal coupling between the lamp 4 and the lamp housing 2 in any movement position of the lamp element 3 relative to the lamp housing 2. The heat-conducting element absorbs the relative movement between the lamp housing 2 and the lighting element 3 due to the deformability of the heat-conducting element or its connecting section 8 .

Preferably, the heat-conducting element 5, preferably at least the connecting section 8, has a preferably elastic restoring section 9, which prestresses the heat-conducting element 5 for thermal coupling between the illuminant 4 and the lamp housing 2. It is also conceivable that the reset section 9 has a joint, such as a hinge. Furthermore, the restoring section 5 can have a spring, which is integrated into a hinge, for example, or an elastic section of the heat-conducting element 5 .

According to the exemplary embodiments illustrated in Figures 1-4, the entire heat-conducting element 5 can (for this purpose) also be designed to be elastically deformable in order to maintain the thermal coupling between the lamp 4 and the lamp housing 2 in any movement position of the lamp element 3 relative to the lamp housing 2 . For this purpose, the heat-conducting element 5 can have a deformable, preferably an elastically deformable or flexible material. For this purpose, the heat-conducting element 5 can be provided in a bent and thus prestressed state between the lamp housing 2 and the illuminant element 3 . A curved section of the heat-conducting element can form the reset section 9 . The sections that are in contact with the lamp housing 2 on the one hand and the lighting element 3 on the other hand and here extend flatly or planarly form the coupling regions 6, 7 here.

According to the exemplary embodiments illustrated in Figures 1-4, the respective heat-conducting elements 5 can preferably be clamped between the respective illuminant element 3 and the lamp housing 2 due to their elastic design, so that constant contact between the lamp housing 2 and the heat-conducting element 5 on the one hand and the heat-conducting element 5 and the lighting element 3 on the other hand is maintained; This is independent of the movement position of the lamp element 3 relative to the lamp housing 2.

Also conceivable is the additional arrangement of at least one heat dissipation-promoting heat dissipation means on the lamp housing 2. This heat dissipation means, such as cooling fins, is particularly preferably arranged in a lamp housing section that is thermally coupled to the heat-conducting element 5; preferably in an area of lamp 1 that is not visible during operation.

[0076] In addition, a lamp 1 according to the invention can have additional lamp elements 3 which, for example, cannot be moved and are consequently installed in the lamp housing 2 in a stationary manner. Such a lamp is shown in FIG

central, non-movable illuminant element 3 combined in order to achieve a desired light emission function (here, for example, two adjustable wall washers to the right and left, for example to illuminate shelves in a supermarket, and a downlight to illuminate an aisle between the shelves).

The present invention is not limited by the exemplary embodiments described above, insofar as it is covered by the subject matter of the following claims. In particular, all features of the exemplary embodiments can be combined and exchanged with and among one another in any way.

Claims (10)

Expectations 1. Lamp (1) having a lamp housing (2) and a lamp element (3) with at least one lamp (4), characterized in that the lamp element (3) is at least partially accommodated in the lamp housing (2) and relative to the Luminaire housing (2) is movably provided in order to change a light emission direction of the illuminant (4), and in that the luminaire (1) has a heat-conducting element (5) which in each movement position of the illuminant element (3) relative to the luminaire housing (2) the illuminant (4) thermally coupled to the lamp housing (2). 2. Light (1) according to claim 1, characterized in that the heat conducting element (5), preferably a first coupling region (6) of the same, is surface-coupled to the light housing (2), and/or that the heat conducting element (5), preferably a second coupling region (7) of the same, is coupled over a large area to the illuminant element (3). 3. Light (1) according to one of the preceding claims, characterized in that the heat conducting element (5), preferably with its first coupling area (6), on the side of the light housing (2) on the one hand and/or, preferably with its second coupling area (7 ), On the other hand is mechanically coupled on the part of the illuminant element (3). 4. Lamp (1) according to claim 3, characterized in that the mechanical coupling is designed to be detachable, preferably by means of a screw connection, or non-detachable, preferably by means of a welded or adhesive connection. 5. Light (1) according to one of the preceding claims, characterized in that the heat conducting element (5) has a connecting section (8) which is designed in such a way that in any movement position of the lighting element (3) relative to the light housing (2) the thermal To maintain coupling between the lamp (4) and the lamp housing (2). 6. Light (1) according to one of the preceding claims, characterized in that the heat-conducting element (5), preferably at least its connecting section (8), is designed to be deformable so that in any movement position of the lighting element (3) relative to the light housing (2). to maintain thermal coupling between the light source (4) and the lamp housing (2) by deformation of the heat conducting element (5); and/or that the heat-conducting element (5); and/or that the heat-conducting element (5), preferably at least its connecting section (8), is made of a deformable, preferably an elastically deformable or flexible material; and/or that the heat-conducting element (5), preferably at least its connecting section (8), is designed to be movable, preferably has at least one joint section, in order to ensure the thermal coupling between the lighting means ( 4) and to maintain the lamp housing (2) by the movement of the heat conducting element (5); and/or that the heat-conducting element (5), preferably at least its connecting section (8), has a preferably elastic restoring section (9) in order to hold the heat-conducting element (5), preferably its first coupling area (6) and/or its second coupling area (7) , Preferably in any movement position of the lighting element (3) relative to the lighting housing (2) to the lamp element (3) and / or the lamp housing (2) for thermal coupling between the lamp (4) and the lamp housing (2) biases. 7. Lamp (1) according to any one of the preceding claims, characterized in that the heat conducting element (5) is designed as a heat conducting sheet, heat conducting plate or heat conducting foil; and/or that the thermally conductive element (5) is made of a material which has copper and/or carbon, preferably aligned carbon, such as graphene and/or graphite, particularly preferably carbon nanotubes, in particular in combination with plastic. 8. Lamp (1) according to one of the preceding claims, characterized in that the lamp (1) further comprises a reflector (13) which is arranged such that it optically interacts with the light source (4) emitted light, preferably the light directed deflects, preferably in any movement position. 9. Lamp (1) according to one of the preceding claims, characterized in that the lamp housing (2) has at least one heat dissipation-promoting heat dissipation means such as cooling fins, preferably at least in one with the heat-conducting element (5) thermally coupled lamp housing section. 10. heat conducting element (5) for use in a lamp (1) according to any one of the preceding claims. 4 sheets of drawings