DE102018133108A1 - Laser light lamp with remote phosphor - Google Patents

Abstract

The invention relates to a luminaire (1) comprising a laser light generating source (2), a conversion element (3) for converting the laser light (20) from the source (2) into light (30) of a defined wavelength in the visible range, and a hollow one Luminaire mast (4) with a side wall (41) which is closed all round in cross section and laterally delimits a cavity (40) and which extends at least between the source (2) and a light exit region (42) facing the conversion element (3) in such a way that in the Cavity (40) coupled laser light (20) from the source (2) is emitted onto the conversion element (3), so that the luminaire (1) emits light (30) of a defined wavelength in the visible range.

Description

The present invention relates to a lamp with a hollow lamp pole that laterally delimits a cavity.

Basically, lamps with a lamp mast or a column are known, such as floor lamps, table lamps, street lamps, bollard lamps and the like. The illuminant for emitting light is located at the spaced end (usually the upper end) of the lamp mast. In the case of floor lamps, there is usually a pedestal at the lower end of the mast. Lights of this type can also be designed, for example, as street lights (street lights), in which case they are then firmly connected to the floor at their lower end or are embedded therein.

Because of the lamp head provided or suspended opposite from the standpoint of the lamp mast, it is necessary for such lamps to electrically connect the lamps which are generally located in the lamp head in order to operate them. For this purpose, the cables required for this are usually routed along and inside the lamp mast up to the lamp head, where they can then supply the lamps with electrical current. The illuminants themselves and, if appropriate, corresponding operating devices of the same also require a certain amount of space, so that such lamp heads require minimum limits both in size and in shape. In addition, the appearance of such lighting poles is usually characterized by their outer shell, which is usually opaque to hide the cables running through them.

It is an object of the present invention to provide a luminaire of the type mentioned at the outset, which is simple in construction and is also visually appealing.

This object is achieved by the subject matter of the independent claim. The dependent claims develop the central idea of the present invention in a particularly advantageous manner.

In one aspect, the present invention relates to a luminaire with a laser light-generating source, a conversion element for converting the laser light from the source into light of a defined wavelength in the visible range, and a hollow luminaire mast. The hollow lamp pole has a side wall that is closed all around in cross section and laterally delimits a cavity, which extends at least between the source and a light exit area (optically) facing the conversion element (preferably a light exit opening) in such a way that laser light from the source coupled into the cavity onto the conversion element is emitted so that the luminaire emits light of a defined wavelength in the visible range.

A luminaire is thus provided which is particularly simple in its construction, since it essentially has a hollow luminaire mast. Since the illuminant or the light-generating source is not provided in a lamp head, but instead is provided on or in the lamp mast (e.g. in a lamp base or at least at a distance from the light emitting point), there is no need for complex cabling along and in the lamp mast . Light can thus be generated at a different location than it is - converted into visible light - emitted for lighting. In addition to avoiding complex cabling, the flexibility of the luminaire can also be significantly increased.

The conversion element is preferably provided in the region of the outlet opening inside or outside of the cavity and preferably in a straight line extension of the outlet opening in order to receive and convert the laser light from the laser light-generating source accordingly.

The luminaire can also have a light-influencing component, such as a reflector and / or optics, such as a lens, which is optically downstream of the conversion element. The light emitted by the conversion element for illumination can thus be directed or influenced in a defined manner in any way. For example, all possible types of lenses for bundling or expanding or deflecting or also scattering light are conceivable under optics.

The light-influencing component is preferably designed in such a way that it emits the light of a defined wavelength converted by the conversion element in a directed manner, preferably in and / or against an exit direction of the light from the light exit region. In street lighting, for example, the light can be directed downwards. In the case of a table lamp or floor lamp for a room, it is also conceivable, for example, to point a main light down here, for example, and to emit a secondary light upwards, for example. Of course, other light emission directions are also conceivable. These in combination or individually.

The luminaire can also have a luminaire head, which preferably carries the conversion element and / or the light-influencing components on the outlet opening side. The lamp head can preferably at least partially span the light exit area. Overall, the luminaire head can thus be used to provide an element on which existing components for emitting light can be accommodated in a defined manner.

A light guide part can extend in the cavity between the source and the conversion element — preferably completely or only partially — by way of which the laser light is guided from the source to the conversion element. The light guide part can preferably have particles, such as microparticle inclusions, or a structure on the surface, such as a micro injury, for making the laser light visible. By using an optical fiber, the laser light can also be defined and, for example, also guided in a non-straight line to the conversion element. The light guide part can be made of PMMA.

The lamp pole can be made of an opaque material, such as steel. This is particularly the case when using lasers with higher protection classes. However, it is also conceivable that the lamp mast is formed from a translucent material; e.g. PMMA. In a preferred embodiment, the luminaire mast can be designed as a light guide, the side wall preferably being formed from a light-conducting material, such as a transparent material. In particular, the translucent or transparent variant of the lamp mast can be used for the visually appealing design of the lamp. This is particularly so because no cables run inside the cavity of the lamp mast.

The luminaire can also have (further) illuminants for (visible) light to emit light via the side of the luminaire mast (optically) facing the light exit area into the luminaire mast, preferably into the side wall, preferably at an end of the side wall facing away from the light exit area. The light from the additional illuminants can either be used (to support) the lighting and / or for optical purposes, namely to illuminate the lamp mast or other components of the lamp. As an alternative or in addition, it is also conceivable for the additional illuminants to couple light into the light guide part for emitting light via the side of the lamp mast facing the light exit region. In all the cases described above, the light emitted in this way from the illuminants can preferably interact optically with the light-influencing components; can be influenced accordingly, for example by means of optics or reflectors. The illuminants can be LEDs.

The conversion element can have different optical areas, which are provided separately or integrally with one another. The different optical areas can interact with different laser beams from the source. Of course, it is also conceivable that only one laser beam is provided which interacts with the different optical areas. By means of the optical areas, it should preferably be possible to effect a conversion of the laser light of the source into light of different defined wavelengths and / or light colors in the visible area. For this purpose, the different areas can be areas with different (layer) thickness, different conversion material and / or different orientation to one another. The different areas can interact optically with different light-influencing components or different areas of the light-influencing components. In this respect, it is possible to use the different areas to produce different optical effects or to convert the light differently. These different areas can also interact with the same or different light-influencing components.

The source can emit one or more laser beams statically or with a variable delivery direction. The laser beam or beams can then preferably interact with different optical areas of the conversion element. The plurality of laser beams can also be aligned or aligned in parallel or at least partially in a convergent manner with a common focal point on the conversion element. Thus, the lamp can be designed to be particularly flexible. In particular, the use of several light beams either static or movable, and this preferably in cooperation with the different optical areas, can enable a particularly flexible luminaire with a broad spectrum of light emission characteristics.

The conversion element can be provided such that it can be moved and preferably rotated in order to change the light output of the light emitted by the conversion element in cooperation with the laser light from the source. A change in the light output can be a different light color, a different light temperature, a different light emission direction and the like. The conversion element can have the different optical areas in a circumferential direction, which can preferably be brought into optical interaction by rotation and / or simultaneously with the laser light of the source. Especially in combination with several laser beams, it is therefore possible to simply move the Conversion element or the laser beams to produce different lighting effects.

The source can have a laser diode or preferably one laser diode per laser beam. The plurality of laser diodes can preferably emit laser light of different wavelengths. In combination with other components for converting light or changing the light characteristics, a particularly simple and flexible luminaire can be provided.

The lamp can also have a control unit for controlling the source and / or the conversion element. The source can preferably be controlled separately per laser beam and further preferably preferably by means of the control unit and preferably dimmable and / or changing the wavelength. An automatic or semi-automatic control of the lamp can thus be provided.

The luminaire can furthermore have sensors for detecting the light of a defined wavelength emitted by the conversion element or also of the laser light. The control unit can preferably be designed in such a way that it controls the source and / or the conversion element on the basis of data acquired by the sensor system, so as to influence the light output accordingly. For example, a defined light color can be specified, which can be set by detecting the sensors and controlling the lighting components accordingly.

The sensor system can preferably be provided in the lamp head. The sensor system can be connected to the control unit in a wired or wireless manner, for example by radio. The sensor system can have its own power supply, such as solar cells, for autonomous operation of the sensor system.

The lamp mast can have a tubular and preferably a cylindrical shape. The lamp post can extend in a straight line. It is also conceivable that the lamp pole does not extend in a straight line. In this case in particular, light guide elements, such as reflectors and / or light guides, can preferably be provided in the cavity and / or the side wall in order to guide the light from the source to the conversion element along the cavity. For example, corresponding deflection mirrors can be provided in angled areas in order to guide the laser light from the source to the conversion element or the light exit area.

The conversion element can have an aperture on the laser light entry side with an opening for passing the laser light. As already mentioned, the conversion element can be positioned in the area of the exit opening in the cavity or at least in the vicinity of the light exit area in such a way that the laser light from the source reaches it; For example, in (optical) extension of the light exit area in front of the same. The lamp mast or the lamp head can have a holding element in order to carry the conversion element, the holding element preferably being designed as a reflector and / or having the diaphragm. In particular when the conversion element is positioned on the lamp head or in other conceivable embodiments, it is of course also conceivable that the conversion element is provided in front of the conversion in an (optical or spatial) extension of the light exit area in such a way that the laser light of the source naturally reaches it. The bracket enables the conversion element to be positioned in a defined manner. An exchange of the conversion element can, for example, be made possible in any manner by means of such a holder. Dimming of the conversion element can be achieved by means of the diaphragm, with only the above-described small opening for passing the laser light being required on the laser light entry side in order to achieve interaction of the laser light with the conversion element for the defined light emission. On the light exit side, the surface of the conversion element can preferably be open and thus be designed to be comparatively large in order to achieve homogeneous and efficient light emission.

The cavity can have a medium that makes the laser light emitted by the source optically visible. This can preferably be a liquid or gaseous fluid. In this case, the cavity can preferably be fluid-technically sealed from the surroundings; this, for example, by means of appropriate sealing or sealing elements or sealing areas. Such a medium makes it possible to make the laser light sent from the source to the conversion element optically visible and thus to use the laser light as an optical element for designing the luminaire as well. The medium itself can have laser-visualizing properties and can be fluorescent, for example. The medium can preferably have a mixture. This can preferably have a carrier fluid for and with particles for optically making the laser light visible. The carrier fluid may preferably be water, such as distilled water. The particles can, for example, be color particles and / or be fluorescent and / or have particles of the same charge that repel one another.

The lamp can also be designed such that the medium is movable in the cavity. This is preferably done by convection, for example by operating heat of the lamp, such as the Source and / or the illuminants. As an alternative or in addition, it is also conceivable that separate fans are provided in order to produce a corresponding movement of the medium and thus a special optical effect of the lamp.

The luminaire can also have a light guide profile in the cavity for deflecting part of the laser light from the source and preferably for emitting the deflected light via the side wall. The light guide profile can also preferably have a conversion element (for example the conversion element or a second conversion element) for converting the laser light from the source into light of a defined wavelength in the visible range. Of course, the light guide profile can also have other laser light optically visible properties or components. The light guide profile can be made of PMMA.

The lamp can preferably have a base at one end of the lamp mast facing away from the outlet opening, the base preferably carrying the lamp mast. The base can have a foot section for installation on or integrated into the floor. In a particularly preferred embodiment, the lamp mast and preferably its base can accommodate the source. A floor lamp or bollard lamp is thus provided. The provision of the base makes it possible to securely record the source. Thus, the light source and electronics necessary for operating the lamp for operating the lamp can preferably be moved to a lower end of the lamp mast. There is usually more space to accommodate such components without affecting the overall appearance of the lamp. In the case of floor lamps in particular, it is therefore also possible to shift the weight at the lowest possible point in order to significantly improve the overall stability of the lamp. This means that there is no need for additional weights in the base, which has an overall positive effect on the weight of the lamp and also enables resource-saving production. The lamp and preferably the base can also have a heat sink, which can be formed from a highly heat-conducting material such as aluminum, and is preferably thermally coupled to the source. The operating heat can thus be dissipated effectively.

• 1 eine schematische Seitenschnittansicht einer Leuchte gemäß einem ersten Ausführungsbeispiel der vorliegenden Erfindung,
• 2 eine schematische Seitenschnittansicht einer Leuchte gemäß einem zweiten Ausführungsbeispiel der vorliegenden Erfindung,
• 3 eine schematische Seitenschnittansicht einer Leuchte gemäß einem dritten Ausführungsbeispiel der vorliegenden Erfindung,
• 4 eine schematische Seitenschnittansicht einer Leuchte gemäß einem vierten Ausführungsbeispiel der vorliegenden Erfindung, und
• 5 eine Draufsicht auf ein Konversionselement einer erfindungsgemäßen Leuchte.

These and other embodiments of the present invention are described below with reference to the figures of the accompanying drawings. Show it:

• 1 2 shows a schematic side sectional view of a lamp according to a first exemplary embodiment of the present invention,
• 2nd 2 shows a schematic side sectional view of a lamp according to a second exemplary embodiment of the present invention,
• 3rd 2 shows a schematic side sectional view of a lamp according to a third exemplary embodiment of the present invention,
• 4th is a schematic side sectional view of a lamp according to a fourth embodiment of the present invention, and
• 5 a plan view of a conversion element of a lamp according to the invention.

especially the 1 to 4th show two embodiments of a lamp according to the invention 1 . This lamp 1 has a laser light generating source 2nd on. The source 2nd can be a laser diode. Is it used to deliver multiple laser beams 21st trained, so can also per laser beam 21st a laser diode can be provided. The multiple laser diodes can preferably be laser light 20 emit different wavelengths. Of course, the laser light can also 20 a laser diode can be adjusted accordingly to laser light 20 emit different wavelengths.

Furthermore, the lamp points 1 a conversion element 3rd to convert the laser light 20 the source 2nd in light 30th defined wavelength in the visible range. Like especially the 5 can be seen, the conversion element 3rd different areas 31 to 34 which are provided separately or integrally with each other; according to 5 integral here. The different optical areas 31 to 34 can with the same or different laser beams 21st the source 2nd work together. The different optical areas 31 to 34 can also convert the laser light 20 the source 2nd in light 30th effect different defined wavelengths and / or light colors in the visible range. For example, it is conceivable that the different optical areas 31 to 34 Areas with different layer thickness, different conversion material and / or different orientation to one another. For example, the areas 31 and 33 have a different layer thickness than the areas 32 and 34 . Also the areas 31 to 34 each have a different layer thickness. A different number or arrangement of the different optical areas can of course also be used 31 to 34 be provided depending on the desired application and luminaire characteristics. There are no limits to the invention here.

The source 2nd can have one or more laser beams 21st deliver statically or with a variable delivery direction. The laser beam (s) 21st can then preferably with different areas 31 to 34 of the conversion element 3rd work together. This is especially true when the laser beams 21st allow a variable dispensing direction and thus optionally to the different areas 31 to 34 can be directed. With multiple laser beams 21st it is conceivable that these are aligned in parallel. It is also conceivable that this (optionally) is partially convergent with a common focus on the conversion element 3rd aligned or optionally alignable. Alignment or alignment in another way alone or in relation to one another or to the conversion element 3rd or the different optical areas 31 to 34 is conceivable.

The conversion element 3rd is preferably provided to be movable and particularly preferably rotatable in order to interact with the laser light 20 the source 2nd the light output from the conversion element 3rd emitted light 30th to change. The conversion element 3rd can, as in 5 shown, the different optical areas in a circumferential direction 31 to 34 exhibit. These can then preferably be rotated alternately and / or simultaneously with the laser light 20 the source 2nd can be brought into optical interaction. In this case, a change in the direction of emission of the laser beams may be necessary 21st be dispensed with because the rotation causes a relative movement. Of course you can also use a laser beam 21st on the one hand and conversion element 3rd on the other hand, both are designed to be movable in order to ensure the flexibility of the lamp 1 further increase.

The lamp 1 also has a hollow lamp pole 4th with a closed in the cross-section and a cavity 40 side wall 41 . The side wall 41 extends at least between the source 2nd and one the conversion element 3rd (optically) facing light exit area 42 such that in the cavity 40 coupled laser light 20 the source 2nd on the conversion element 3rd is delivered so that the lamp 1 light 30th a defined wavelength in the visible range. The conversion element 3rd is particularly preferred in the area of the light exit area 42 in the cavity 40 or also in (optical) extension of the light exit area 42 positioned in front of the same. In any case, that's from the source 2nd emitted laser light 20 which the cavity 40 happened inside or outside the cavity 40 or the lamp mast 4th on the conversion element 3rd can hit, then correspondingly visible light 30th over the light exit area 42 or also behind (preferably seen in the beam guiding direction) the light exit area 42 as light 30th for lighting the lamp 1 can give up. The light exit area 42 can be formed as a light exit opening, as in the 3rd and 4th . It is also conceivable that the light exit area 42 is physically closed but translucent, as in the 1 and 2nd shown where the light exit area 42 through the conversion element 3rd (see. 1 ) or the side wall ( 41 ) or the lamp mast ( 4th ) (see. 2nd ) is spatially limited but optically permeable.

The lamp 1 can also be a conversion element 3rd optically downstream light-influencing component 5 exhibit. This can be, for example, a reflector or an optical system, such as a lens. In the embodiment of the 1 here is a reflector as a light influencing component 5 provided, which deflects the light down here. This is particularly desirable with street lights, around the floor area around the lamp 1 to illuminate around. The light influencing component 5 is preferably designed in such a way that of the conversion element 3rd converted light 30th to deliver a defined wavelength, preferably in and / or against an exit direction A of light 20 or 30th from the light exit area 42 .

How in particular 1 , 3rd and 4th can be seen, the lamp 1 also a lamp head 6 exhibit. How 1 can be seen, the lamp head 6 The light-influencing components on the light exit area side 5 - here the reflector - wear. The same applies in a comparable manner to the exemplary embodiments in FIG 3rd and 4th . Likewise, as shown, the lamp head 6 further preferred the light exit area 42 at least partially span. It is also conceivable that in a case in which the conversion element 3rd in the extension of the light exit area 42 the conversion element is positioned in front of the same 3rd Light exit area side carries, as in the 3rd and 4th is shown.

As in 4th is shown, it is also conceivable that in the cavity 40 a light guide part 8th between the source 2nd and the conversion element 3rd extends (at least partially) over which the laser light 20 from the source 2nd to the conversion element 3rd is directed there. This is particularly advantageous if the laser light is not guided in a straight line 20 should be desired or possible. This light guide part 8th can preferably have particles, such as microparticle inclusions, or a structure on the surface, such as a micro-injury, for making the laser light visible. Thus, the light guide part 8th further used as well to the laser light 20 effective use as an optical element of the luminaire.

The lamp post 4th can be made of an opaque material, such as steel. The lamp post is preferred 4th however made of a translucent or transparent material. So the lamp can 1 be visually appealing. This is particularly possible because there are no cables through the lamp mast 4th must run because the entire electronics or source 2nd at a base of the lamp post 4th and can be provided at a distance from the location of the light emission, as shown in FIGS 1 to 4th is shown. In a preferred embodiment, such as the 2nd to 4th can be seen, the lamp mast 4th preferably be designed as a light guide. This is the side wall 41 particularly preferably made of a light-conducting material, such as a transparent material.

Like the one in particular 2nd to 4th can be seen, the lamp 1 also illuminants 7 have to (visible) light for emitting light over the light exit area 42 (optically) facing side of the lamp mast 4th in the lamp pole 4th , preferably in the side wall 41 , preferably at one of the light exit areas 42 opposite end of the side wall 41 to couple. Additional light can thus be provided either as secondary light or as an (additional) main light source. With the illuminants 7 can be LEDs. By using the lamp mast 4th as a light guide, this (in particular the coupling of light) can also be done from the base of the lamp 1 from happening, so that there is still no wiring within the lamp mast 4th is necessary. Alternatively or in addition, it is also conceivable that the illuminants 7 Light for emitting light over the light exit area 42 facing side of the lamp pole 4th into the light guide part 8th can couple. Thus, for example, an effect can be created as if the laser light were made visible. This is particularly the case when the light guide part 8th has no elements or structures to make the laser light visible. The light emitted in this way 70 the illuminant 7 can preferably also with the light-influencing components 5 interact visually, as in the 3rd and 4th is shown as an example.

The lamp 1 can also have a control unit (not shown) for controlling the source 2nd and / or the conversion element 3rd exhibit. The source 2nd can preferably be per laser beam 21st and further preferably can be controlled separately by means of the control unit, preferably dimmable and / or changing the wavelength.

The lamp 1 can also have a sensor system for detecting the conversion element 3rd emitted light of a defined wavelength. The control unit can then preferably be designed such that the source 2nd and / or the conversion element 3rd to be controlled on the basis of data recorded by the sensor system. The sensors can be in the lamp head, for example 6 be provided. The sensor system can be connected to the control unit by cable or preferably wirelessly, for example by radio. The sensor system can have its own power supply, such as solar cells, for autonomous operation of the sensor system.

As shown, the lamp mast can have a tubular and preferably cylindrical shape. However, the invention is not limited to this. Likewise, the lamp post 4th extend in a straight line, as shown in the exemplary embodiments of the figures. However, it is also conceivable that the lamp mast 4th does not extend straight. In this case, preferably in the cavity 40 and / or the side wall 41 Light guiding elements, such as reflectors and / or light guides, can be provided to direct the light from the source 2nd to the conversion element 3rd along the cavity 40 respectively.

Like especially the 1 can be seen, the conversion element 3rd An aperture on the laser light entry side 35 with an opening 36 for passing the laser light 20 exhibit.

The lamp post 4th or the lamp head 6 can be a holding element 43 have to the conversion element 3rd to wear. The holding element 43 can also preferably be designed as a reflector and / or the diaphragm 35 exhibit. In the latter case, these can also be formed integrally with one another, for example. However, there is preferably a non-integral design, for example the diaphragm 35 and / or the conversion element 3rd can be easily replaced and by means of the holding element 43 worn or used in this. For the rotary provision of the conversion element 3rd can the holding element 43 have corresponding drive elements. However, it is particularly preferred if no electronics are provided in the lamp head area. A rotation of the conversion element 3rd can then be done manually, for example. For this purpose, for example, corresponding devices, such as levers and the like, can be provided to make it easier for the user, the conversion element 3rd easy to move. It is also conceivable that the conversion element 3rd for example only when integrating the luminaire 1 once set accordingly (rotated) and then fixed by the installer. A permanent desired light emission can thus be achieved. However, there are no limits to the invention here.

The cavity 40 can this be from the source 2nd emitted laser light optically visible medium M exhibit (cf. 2nd ). This can preferably be a liquid or gaseous fluid. In this case, the cavity 40 be particularly preferably sealed fluidically to the environment. Such a seal 44 is exemplary of the embodiment of 2nd refer to. The medium M can have properties that make laser light visible and, for example, fluorescent. The medium M can preferably have a mixture. This can preferably be a carrier fluid for and with particles for optically making the laser light visible 20 exhibit. The carrier fluid can be, for example, water, such as distilled water. The particles can be color particles. The particles can be fluorescent. The particles can have the same charge and repel each other.

The lamp 1 can be designed such that the medium M in the cavity 40 is movable. This can be done, for example, by convection, which is caused by the operating heat of the lamp 1 as the source 2nd and / or the illuminant 7 , is triggered. As an alternative or in addition, it is also conceivable to use means (not shown) for moving the medium M , such as separate fans.

The lamp 1 can also be a light guide profile 9 in the cavity 40 to redirect part of the laser light 20 the source 2nd and preferably to emit the redirected light 30th over the side wall 41 have, as for example in 2nd is shown. The light guide profile 9 can also preferably use a (second) conversion element 3rd to convert the laser light 20 the light source 2nd in light 30th have a defined wavelength in the visible range. The conversion element can be the same conversion element 3rd the lamp 1 or act as another conversion element.

The lamp 1 can preferably at one of the light exit area 42 opposite end of the lamp mast 4th a pedestal 10 exhibit. The base can preferably be the lamp pole 4th wear like this in the 1 to 4th is shown. In addition, the lamp mast 4th for example in the base 10 be inserted from above and be fixed there, for example. Between base 10 and light pole 4th can also use the seals 44 be provided (cf. 2nd ). The base 10 can be a foot section 11 to set up on (cf. 2nd ) or integrate in (cf. 1 , 3rd and 4th ) have the floor. The lamp post 4th and preferably its base 10 can, as shown, the source 2nd record, tape. Thus the source 2nd spaced from the light exit area or light emission area and in particular in an area where they have little influence on the optical design of the lamp 1 Has. The lamp 1 and preferably the base 10 can also have a heat sink, which is preferably formed from a highly heat-conducting material (for example aluminum), and particularly preferably with the source 2nd be thermally coupled. Thus the heat of the source 2nd can be safely removed in a simple manner. It is also advantageous in the arrangement of the source 2nd in a foot of the lamp 1 advantageous that this then has a particularly low center of gravity, so that the lamp 1 has a particularly high stability.

The present invention is not restricted to the preceding exemplary embodiments, provided that it is covered by the subject matter of the following claims. All features of the above-described exemplary embodiments can be combined with one another in any manner and can be interchanged.

Claims (22)

Luminaire (1) comprising: a laser light generating source (2), a conversion element (3) for converting the laser light (20) from the source (2) into light (30) of a defined wavelength in the visible range, and a hollow lamp pole (4) with a side wall (41) which is closed all round in cross section and laterally delimits a cavity (40) and which is at least between the source (2) and a light exit area (42) facing the conversion element (3) extends in such a way that laser light (20) from the source (2) coupled into the cavity (40) is emitted onto the conversion element (3), so that the light (1) light (30 ) of a defined wavelength in the visible range. Light (1) after Claim 1 , further comprising a light-influencing component (5) optically downstream of the conversion element (3), preferably a reflector and / or an optical system, such as a lens, the light-influencing component (5) preferably being designed in such a way that the Conversion element (3) to convert converted light (30) of a defined wavelength, preferably in and / or against an exit direction (A) of the light (20, 30) from the light exit area (42). Luminaire (1) according to one of the preceding claims, further comprising a luminaire head (6), which preferably carries the conversion element (3) and / or the light-influencing component (5) on the light exit region side, the luminaire head (6) also preferably carrying the Light exit area (42) at least partially spanned. Luminaire (1) according to one of the preceding claims, wherein in the cavity (40) Light guide part (8) extends between the source (2) and the conversion element (3), via which the laser light (20) is guided from the source (2) to the conversion element (3), the light guide part (8) preferably particles, such as microparticle inclusions, or a structure on the surface, such as a micro-injury, for making the laser light (20) visible. Luminaire (1) according to one of the preceding claims, the luminaire mast (4) being formed from an opaque material, such as steel, or a translucent or transparent material, the luminaire mast (4) preferably being designed as a light guide, preferably the side wall (41 ) is formed from a light-conducting material, such as a transparent material. Luminaire (1) according to one of the preceding claims, wherein the luminaire (1) further comprises illuminants (7) for emitting light (70) for emitting light via the side of the luminaire mast (4) facing the light exit region (42) into the luminaire mast (4) , preferably to be coupled into the side wall (41), preferably at an end of the side wall (41) facing away from the light exit region (42), and / or into the light guide part (8), the light (70) emitted in this way preferably from the illuminants (7) interacts optically with the light-influencing components (5). Luminaire (1) according to one of the preceding claims, wherein the conversion element (3) has different optical regions (31-34) which are provided separately or integrally with one another, preferably the different optical regions (31-34) with the same or different laser beams the source (2) cooperate, and / or convert the laser light (20) of the source (2) into light (30) of different defined wavelengths and / or light colors in the visible range. Light (1) after Claim 7 , wherein the different optical areas (31-34) are areas with different layer thickness, different conversion material and / or different orientation to each other, and / or wherein the different optical areas (31-34) with different light-influencing components (5) or different Areas of the light-influencing components (5) interact optically. Luminaire (1) according to one of the preceding claims, wherein the source (2) can emit one or more laser beams (21) statically or with a variable delivery direction, the laser beam (s) preferably having different optical areas (31-34) of the Conversion element (3) cooperate, or wherein the plurality of laser beams (21) are aligned or orientable in parallel or at least partially convergent with a common focal point on the conversion element (3). Luminaire (1) according to one of the preceding claims, wherein the conversion element (3) is movable, preferably rotatable, in order to, in cooperation with the laser light (20) of the source (2), emit light from the light emitted by the conversion element (3) ), and / or wherein the conversion element (3) has the different optical areas (31-34) in a circumferential direction, which preferably by rotation alternately and / or simultaneously with the laser light (20) of the source (2) in optical interaction is feasible. Luminaire (1) according to one of the preceding claims, wherein the source (2) has a laser diode or preferably a laser diode for each laser steel (21), the plurality of laser diodes preferably emitting laser light (20) of different wavelengths. Luminaire (1) according to one of the preceding claims, further comprising a control unit for controlling the source (2) and / or the conversion element (3), and / or wherein the source (2) preferably per laser beam (21) and further preferably by means of the Control unit is separately controllable, preferably dimmable and / or changing the wavelength. Luminaire (1) according to one of the preceding claims, further comprising sensors for detecting the light (30) of defined wavelength emitted by the conversion element (3), the control unit preferably being designed such that the source (2) and / or the conversion element (3 ) on the basis of data recorded by the sensors. Light (1) after Claim 13 , wherein the sensor system is provided in the lamp head (6), and / or the sensor system is connected to the control unit in a wired or wireless manner, for example by radio, and / or the sensor system is a power supply, such as solar cells, for autonomous operation which has sensors. Luminaire (1) according to one of the preceding claims, wherein the luminaire mast (4) has a tubular, preferably a cylindrical shape. Luminaire (1) according to one of the preceding claims, wherein the lamp post (4) extends in a straight line, or wherein the lamp post (4) does not extend in a straight line, preferably in the Cavity (40) and / or the side wall (41) light guide elements, such as reflectors and / or light guides, are provided to guide the light (20) from the source (2) to the conversion element (3) along the cavity (40) . Luminaire (1) according to one of the preceding claims, wherein the conversion element (3) on the laser light entry side has an aperture (35) with an opening (36) for passing the laser light (20), and / or wherein the conversion element (3) in the region the light exit area (42) is positioned in the cavity (40) or in the extension of the light exit area (42) in front of the same, and / or wherein the lamp mast (4) or lamp head (6) has a holding element (43) in order to hold the conversion element (3) to be worn, the holding element (43) preferably being designed as a reflector and / or having the diaphragm (35). Luminaire (1) according to one of the preceding claims, wherein the cavity (40) has a medium (M) which makes the laser light (20) emitted by the source (2) optically visible, preferably a liquid or gaseous fluid, the cavity (40 ) is preferably sealed (44) from the environment in terms of fluid technology. Light (1) after Claim 18 , wherein the medium (M) has laser light (20) visualizing properties, preferably fluorescent, the medium (M) preferably having a mixture, preferably a carrier fluid for and with particles for optically visualizing the laser light (20), the carrier fluid preferably Is water, such as distilled water, and / or wherein the particles are color particles and / or are fluorescent and / or are particles of the same charge. Light (1) after Claim 18 or 19th The lamp (1) is designed such that the medium (M) can be moved in the cavity (40), preferably by convection, for example by operating heat of the lamp (1), such as the source (2) and / or the lamps (7), and / or by means of separate fans. Luminaire (1) according to one of the preceding claims, further comprising a light guide profile (9) in the cavity (40) for deflecting part of the laser light (20) from the source (2) and preferably for emitting the deflected light (30) via the side wall (41), the light guide profile (9) further preferably a conversion element (3) for converting the laser light (20) from the source (2) into light (30) of a defined wavelength in the visible range. Luminaire (1) according to one of the preceding claims, the luminaire (1) preferably having a base (10) at an end of the luminaire mast (4) facing away from the light exit region (42), the base (10) preferably having the luminaire mast (4) carries, the base (10) having a foot section (11) for installation on or integrating into the floor (B), and / or the lamp mast (4) and preferably its base (10) receiving the source (2), and / or wherein the lamp (1) and preferably the base (10) has a heat sink, which is preferably formed from a highly heat-conducting material such as aluminum, and which is preferably thermally coupled to the source (2).

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