Patent Description:
Existing luminaire heads are usually quite complex and involve the use of a large number of components which have to be assembled. This makes the production of luminaire heads expensive.

The document <CIT> shows an LED lamp including a heat dissipating base and a plurality of light strips. The heat dissipating base is formed by aluminum extrusion and has a length direction defined by the aluminum extrusion direction. The heat dissipating base has a main body and a plurality of heat dissipating fins. The bottom side of the main body has a flat connecting surface. The heat dissipating fins extend outward from the main body. Each light strip has a circuit board and at least one LED module provided on the circuit board. The circuit board of each light strip is provided on the connecting surface of the heat dissipating base.

The object of the invention, as disclosed in claim <NUM>, is to provide a simple, robust, low cost modular luminaire head with a limited number of components. Preferably, the luminaire head should be easy and quick to assemble and provide for a simple pole fixation.

According to a first aspect of the invention there is provided a luminaire head comprising a thermally conductive metal body and at least one support substrate with a plurality of light emitting elements. The thermally conductive metal body comprises a plate like portion, a tube portion and at least one cooling fin. The plate like portion extends in a longitudinal direction of the metal body and has a flat first surface and a second surface opposite said first surface. The tube portion extends in said longitudinal direction at the second surface. The at least one cooling fin extends away from the second surface adjacent to the tube portion, i.e. upwardly from the second surface, when looking in a direction away from the second surface. The at least one support substrate is arranged against the first surface, at least in an area opposite the tube portion. The tube portion is shaped to receive in a first open end thereof a rigid cylindrical end portion of a mounting base, such as a pole for the luminaire head. The tube portion is provided with at least one hole for receiving a fixation means to fix the tube portion to the cylindrical end portion of the mounting base.

Such a luminaire head has the advantage that the metal body of the luminaire head functions as heatsink, as pole fixation, and as mounting means for the light emitting elements. Such metal bodies can be easily produced in large quantities with a low level of investment. Also such metal bodies make the luminaire head modular: the metal body can be produced as a long body which is cut at the required length depending on the required use. Also, the luminaire head is quick and easy to assemble as only little components are involved.

Preferably, the at least one support substrate extends over a width perpendicular to the longitudinal direction which is at least <NUM>%, preferably at least <NUM>% of the width of the plate like portion. The at least one support substrate may then comprise a first and at least a second support substrate arranged next to each other, seen in the longitudinal direction. In other embodiments the width perpendicular to the longitudinal direction may be less than <NUM>% of the width of the plate like portion. In that case, the at least one support substrate may comprise a first and at least a second support substrate arranged next to each other, seen in the width direction. In both embodiments, heat can be easily transported from the support assemblies to the metal body and in particular to the one or more cooling fins of the metal body.

In a preferred embodiment, the flat first surface extends over a length in the longitudinal direction of the metal body, and the tube portion extends over substantially the same length in said longitudinal direction. More preferably, the metal body is an extruded body extruded in one piece in the longitudinal direction, preferably an extruded body extruded from aluminium. In that manner the production cost can be low, whilst providing good heat conduction. Typically the plate like portion extends over the same length in the longitudinal direction.

In a preferred embodiment, the tube portion extends substantially in the middle of the second surface of the plate like portion. In that manner the luminaire head can be well balanced and more or less symmetrically arranged with respect to the mounting base.

In a preferred embodiment, the width of the plate like portion, seen in a width direction perpendicular to the longitudinal direction, is at least <NUM>% larger than a maximum width of the tube portion, preferably at least twice the width of the tube portion. In that manner sufficient mounting surface area is provided through the first surface, and there is sufficient surface area adjacent the tube portion for arranging the one or more cooling fins on the second surface.

In a preferred embodiment, the tube portion is a cylindrical portion, and the maximum width corresponds with the diameter thereof. However, in other embodiments the tube portion may have an inner surface, seen in a cross section perpendicular to the longitudinal direction, having substantially any one of the following shapes: circular, a closed shape (e.g. a polygon) having at least three vertices touching a virtual inner circle, a closed shape having at least three curved or straight segments contacting a virtual inner circle. More generally any shape adapted to snugly receive in a first open end thereof a cylindrical end portion of a mounting base may be envisaged. The tube portion may have an outer surface, seen in a cross section perpendicular to the longitudinal direction, having a shape which is the same as or different from the shape of the inner surface. More generally, the outer surface may have any shape.

In a preferred embodiment, the at least one cooling fin extends in the longitudinal direction. The at least one cooling fin may comprises at least one first cooling fin arranged on a first side of the tube portion and at least one second cooling fin arranged on a second side of the tube portion opposite the first side. Preferably the at least one cooling fin comprises at least three first cooling fins arranged on a first side of the tube portion and at least three second cooling fins arranged on a second side of the tube portion opposite the first side. In that manner a very good heat transport can be achieved, resulting in a good cooling of the one or more support substrates.

The at least one cooling fin may extend perpendicular on the second surface. Alternatively, the at least one cooling fin may extend under an angle with respect to the second surface, said angle being between <NUM>° and <NUM>°.

In a preferred embodiment, the tube portion has a second open end which is closed by a removable closure. At least one connector such as an electrical connector may be attached to the removable closure. In that manner no extra room needs to be provided in the metal body for connectors. More generally any required components may be arranged in the tube portion such that they are at the same time protected as well as easily accessible.

According to an exemplary embodiment, the removable closure comprises an attaching means configured for attaching at least one electrical or mechanical or optical component, e.g. an electrical connector, a sensor, an electrical circuit such as a driving means, etc., such that the at least one electrical or mechanical or optical component is arranged within the tube portion.

In this manner, the at least one electrical or mechanical or optical component may be easily accessed by removing the removable closure. More in particular, the need to provide attachment structures to an inner surface of the tube portion is avoided or reduced, which improves fabrication of the luminaire head.

Additionally, since the at least electrical or mechanical or optical component may be attached to the removable closure via an attaching means, replacing or changing the at least electrical or mechanical or optical component can be done easily. Thus, maintenance and upgradability of the luminaire head is facilitated.

When the at least one electrical or mechanical or optical component comprises a connector, the connector may be used to connect one or more electrical components of the luminaire head. For example, the connector may be used to connect an electrical cable, e.g. an electrical cable connected to the mains and passing from the pole into the tube portion, to one or more electrical lines connected to a PCB which is arranged on the first surface of the plate like portion. Those one or more electrical lines may pass through one or more through-holes extending between the inside of the tube portion and the first surface of the plate-like portion. In another example, the connector may be used to connect a terminal of a first component, e.g. a controller to a terminal of another component, e.g. a driver.

When the at least one electrical or mechanical or optical component comprises a driver, the driver may have input terminals connected to an electrical cable coming from the mains, on the one hand, and output terminals connected to one or more electrical components of the luminaire head, on the other hand. For example, the driver may be connected to a PCB which is arranged on the first surface of the plate like portion, in order to provide power to components arranged on the PCB, such as the light emitting elements or a sensor or more generally any other component which needs to be powered. To that end one or more electrical lines may extend from the output terminals of the driver through one or more through-holes extending from the inside of the tube portion to the first surface of the plate-like portion, to the PCB.

When the at least one electrical or mechanical or optical component comprises a cable retainer, the cable retainer may be used to fix an electrical cable, e.g. the cable coming from the mains. For example, the electrical cable may be connected directly or indirectly to a PCB with the light emitting elements, which is arranged on the first surface of the plate like portion. To that end one or more electrical lines may extend through one or more through-holes extending from the inside of the tube portion to the first surface of the plate-like portion, to the PCB.

In another embodiment, there may be provided a connector inside the tube portion, which allows connection between an electrical or mechanical or optical component attached to the removable closure and another component, e.g. a component located on the plate like portion, e.g. the light emitting elements and/or a sensor and/or a communication module, etc. To that end one or more electrical lines may extend from the connector through one or more through-holes in the metal body to the other component arranged on the first surface of the plate like portion.

The attaching means allowing the at least one electrical or mechanical or optical component to be attached to the removable closure may be a connector plate. Optionally, the connector plate may be provided with a cable retainer, e.g. to fix the electrical cable connected to the mains, to the connector plate. In another exemplary embodiment, the attaching means may comprise a slot provided to the removable closure and a support substrate, e.g. a PCB, and the support substrate may be inserted in the slot provided to the removable closure.

According to a preferred embodiment, the removable closure is a cap configured for closing off substantially fully the second open end. Preferably, the cap and/or the tube portion is provided with a sealing means, e.g. a gasket, such that the cap can be coupled to the tube portion in a sealed manner.

In this way, the removable closure may serve a double function of protection and connection. The cap may protect the elements arranged within the inner part of the tube portion from undesired foreign elements, e.g. debris, moisture. At the same time, the surface of the cap facing the inner part of the tube portion may be configured for being attached to the at least one electrical or mechanical or optical component and for supporting the at least one electrical or mechanical or optical component within the inner part of the tube portion.

In a preferred embodiment, the at least one support substrate corresponds with at least one PCB, more preferably a so-called AC PCB configured to convert an AC voltage or current into a DC current for driving the plurality of light emitting elements. By using one or more AC PCBs there is no need to use a separate driver.

In a preferred embodiment, at least one lens plate may be arranged over the at least one support substrate, wherein preferably at least one gasket is inserted between the at least one lens plate and the at least one support substrate. The plurality of light emitting elements comprises at least six, preferably at least eight light emitting elements. The at least one lens plate may comprise a plurality of lens elements, wherein the plurality of lens elements comprises at least six, preferably at least eight lens elements, more preferably at least twelve lens elements. Such arrangements are especially useful in outdoor luminaires.

In the context of the invention, a lens element may include any transmissive optical element that focuses or disperses light by means of refraction. It may also include any one of the following: a reflective portion, a backlight portion, a prismatic portion, a collimator portion, a diffusor portion. For example, a lens element may have a lens portion with a concave or convex surface facing a light source, or more generally a lens portion with a flat or curved surface facing the light source, and a collimator portion integrally formed with said lens portion, said collimator portion being configured for collimating light transmitted through said lens portion. Also, a lens element may be provided with a reflective portion or surface or with a diffusive portion.

In an exemplary embodiment, the luminaire head may comprises a cover, e.g. above the metal body of the luminaire head for esthetical purposes. The cover may be in any suitable material, e.g. plastic or metal. The cover may be a perforated cover. The cover may have any particular shape or texture. In case of a metallic cover, it may be arranged to be in contact with the at least one cooling fin to improve head dissipation. The cover may be fixed to the plate like portion in any known manner, e.g. using screws, a clamping mechanism, etc..

According to another exemplary embodiment the tube portion has a cross section with at least two flat outer surfaces including the first flat surface and a further flat surface. The tube portion may have an inner surface as defined above, e.g. an inner surface in the form of circle such that the tube portion is adapted for receiving a cylindrical end portion. The first flat surface may be part of the plate like portion, and the further flat surface may be part of a further plate like portion. A first support substrate with light emitting elements may be arranged against the first surface, and a further support substrate with light emitting elements or another component may be arranged against the further surface. At least one of the plate like portion and the further plate like portion may be provided with cooling fins extending adjacent to the tube portion. More in particular, one or more cooling fins may extend on the second surface of the plate like portion and/or on a further second surface of the further plate like portion. Optionally, one or more cooling fins may extend on the first surface of the plate like portion and/or on the further surface of the further plate like portion.

It is noted that in all embodiments disclosed above, the cooling fins may extend anywhere on the plate like portion. More in particular, they may be arranged on one side of the tube portion or on two sides of the tube portion. Further the tube portion may be arranged anywhere on the plate like portion and does not have to be arranged in the middle of the plate like portion.

According to another aspect of the invention there is provided a luminaire assembly comprising a luminaire head according to any one of the previous embodiments, and a mounting base having a cylindrical end portion, wherein said cylindrical end portion is arranged in the first end of the tube portion and fixed to the tube portion using a fixation means which extends through the hole in the tube portion.

<FIG> illustrate a first exemplary embodiment of a luminaire head. The luminaire head comprises a thermally conductive metal body <NUM>, a first and second support substrate <NUM>, <NUM> with a plurality of light emitting elements <NUM> and electronic circuits <NUM>, a first and a second lens plate <NUM>, <NUM>, and a cap <NUM> with a connector plate <NUM>.

The thermally conductive metal body <NUM> comprises a plate like portion <NUM>, a tube portion <NUM> and at least one cooling fin <NUM>. The plate like portion <NUM> extends in a longitudinal direction L of the metal body <NUM> and has a flat first surface <NUM> and a second surface <NUM> opposite said first surface. The tube portion <NUM> extends in the longitudinal direction L at said second surface <NUM>. A plurality of cooling fins <NUM> extend away from the second surface <NUM> adjacent to the tube portion <NUM>, here at both sides of the tube portion <NUM>. Preferably, the flat first surface <NUM> extends over a length <NUM> in the longitudinal direction L of the metal body <NUM>, and the tube portion <NUM> extends over substantially the same length <NUM> seen in the longitudinal direction L. Preferably, the metal body <NUM> is an extruded body extruded in one piece in the longitudinal direction L. Preferably, the metal body <NUM> is made from aluminium. The metal body <NUM> may be anodized to improve the corrosion resistance.

The first surface <NUM> functions as a mounting surface for the first and second support substrate <NUM>, <NUM>. The first and second support substrate <NUM>, <NUM> are arranged against the first surface <NUM>, at least in an area opposite the tube portion <NUM>, see <FIG>. Preferably, the first and second support substrate <NUM>, <NUM> each extend over a width perpendicular to the longitudinal direction L which is at least <NUM>%, more preferably at least <NUM>% of the width w of the plate like portion <NUM>, and even more preferably over substantially the entire width w of the second surface <NUM> of the plate like portion <NUM>, see <FIG>. As illustrated, the first and second support substrate <NUM>, <NUM> may be arranged next to each other, seen in the longitudinal direction L. It is noted that in other embodiments there may be provided a single support substrate or more than two support substrates, depending on e.g. the length <NUM> of the metal body and the required application. Also, it is possible to arrange two or more support substrates next to each other seen in the width direction perpendicular on the longitudinal direction L.

Preferably, the tube portion <NUM> extends substantially in the middle of the second surface <NUM> of the plate like portion <NUM>. In other words, the first surface <NUM> functions as a mounting surface for the substrates <NUM>, <NUM> with the light emitting elements <NUM>, whilst the tube portion <NUM> is provided at the opposite second surface <NUM> of the plate like portion <NUM>. The tube portion <NUM> may be directly connected to the second surface <NUM>, as illustrated, or may be connected through a flange part (not illustrated) with the plate like portion <NUM>. In that manner not only the plurality of cooling fins <NUM> transport heat away from the plate like portion <NUM>, but also the tube portion <NUM> itself can conduct heat away from the plate like portion <NUM>.

Generally, the luminaire head, when mounted to a support, is oriented substantially parallel respective to the surface to be illuminated. As a result, the first surface <NUM> may face downwardly towards the surface to be illuminated, and the plurality of cooling fins <NUM> may extend upwardly, away from the second surface <NUM>.

Preferably, the width w of the plate like portion <NUM>, seen in a width direction perpendicular on the longitudinal direction L, is at least <NUM>% larger than a maximum width d of the tube portion <NUM>, preferably at least twice the width d of the tube portion <NUM>, see <FIG>. In the illustrated embodiment the tube portion <NUM> is a cylindrical portion, and the maximum width d corresponds with the diameter thereof. More generally, the inner surface <NUM> of the tube portion <NUM>, seen in a cross section perpendicular on the longitudinal direction L, may have substantially any one of the following shapes: circular (as in <FIG>, <FIG>), a polygon or closed shape having at least three vertices touching a virtual inner circle (as in <FIG>), a closed shape having at least three curved or straight segments contacting a virtual inner circle (as in <FIG>). The maximum width d may be e.g. between <NUM> and <NUM>. The width w may be e.g. between <NUM> and <NUM>, more preferably between <NUM> and <NUM>. The length <NUM> may be e.g. between <NUM> and <NUM>, preferably between <NUM> and <NUM>.

Preferably, the plurality of cooling fins <NUM> extends in the longitudinal direction L, allowing the cooling fins <NUM> to be extruded integrally with the other parts of the metal body <NUM>. Preferably the plurality of cooling fins <NUM> comprises at least three first cooling fins <NUM> arranged on a first side of the tube portion <NUM> and at least three second cooling fins <NUM> arranged on a second side of the tube portion <NUM> opposite the first side. In the illustrated exemplary embodiment of <FIG>, eleven cooling fins <NUM> are provided on either side of the tube portion <NUM>. Preferably, the plurality of cooling fins extends perpendicular on the second surface <NUM>. Alternatively, the plurality of cooling fins <NUM> extends under an angle with respect to the second surface, said angle being between <NUM>° and <NUM>°.

The tube portion <NUM> is shaped to receive in a first open end <NUM> thereof a rigid cylindrical end portion <NUM> of a mounting base <NUM>, such as a pole for the luminaire head, see <FIG>. The tube portion <NUM> is provided with at least one hole <NUM>, <NUM> for receiving a fixation means <NUM>, <NUM> to fix the tube portion <NUM> to the cylindrical end portion <NUM> of the mounting base <NUM>. In the illustrated embodiment the fixation means <NUM>, <NUM> comprises a fixation clamp <NUM> with two bore holes for receiving two matching screws <NUM>, e.g. grub screws, see <FIG> and <FIG>. The fixation clamp is arranged inside the tube portion <NUM> and receives end portions of the screws <NUM> which extend through holes <NUM>, <NUM>. Preferably, the holes <NUM>, <NUM> are arranged in a portion of the metal body where the tube portion <NUM> joins the plate like portion. Further, the fixation clamp <NUM> is provided with an upwardly extending part <NUM> forming a stop for an end portion of the mounting base. The skilled person understands that instead of two screws <NUM> also one or more than two screws may be used, and that instead of a fixation clamp <NUM> also other fixation means may be provided for receiving the one or more screws, e.g. one or more nuts.

The tube portion <NUM> has a second open end <NUM> which is closed by a removable closure <NUM>, here in the form of a cap. The removable closure <NUM> is provided with an attaching means, here a connector plate <NUM> extending inwardly in the tube portion <NUM>. The connector plate <NUM> is provided with one or more connectors <NUM> and with a cable retainer <NUM>. More generally any components useful for connecting the plurality of light emitting elements <NUM> or any other device located on the plate like portion (e.g. a sensor, a communication module) may be provided on the connector plate <NUM>. In that way those components are easily accessible since the removable closure <NUM> with connector plate <NUM> can be removed from the tube portion <NUM>.

More generally, the removable closure may comprise any attaching means configured for attaching at least one electrical or mechanical or optical component, e.g. the connector <NUM>, a sensor, an electrical circuit such as a driving means, etc., such that the at least one electrical or mechanical or optical component is arranged within the tube portion <NUM>.

When the at least one electrical or mechanical or optical component comprises the connector <NUM>, the connector <NUM> may be used to connect one or more electrical components of the luminaire head. For example, the connector <NUM> may be used to connect an electrical cable, e.g. an electrical cable connected to the mains and passing from the pole into the tube portion <NUM>, to one or more electrical connection lines connected to the support substrate, typically PCB's, <NUM>, <NUM> which are arranged on the first surface <NUM> of the plate like portion <NUM>. Those one or more electrical lines may be connected via one or more through-holes <NUM>, <NUM> extending from the first surface <NUM> of the plate-like portion <NUM> into the tube portion <NUM>. Optionally, a wire or cable guide <NUM> may be provided in each through-hole for guiding the electrical lines in a sealed manner through the through-holes <NUM>, <NUM>. In another example, the connector <NUM> may be used to connect a terminal of a first component arranged in the tube portion <NUM>, e.g. a controller to a terminal of another component arranged in the tube portion <NUM>, e.g. a driver.

When the at least one electrical or mechanical or optical component comprises a driver, the driver may have input terminals connected to an electrical cable coming from the mains, on the one hand, and output terminals connected to one or more electrical components of the luminaire head, on the other hand. For example, the driver may be connected to a PCB <NUM>, <NUM> which is arranged on the first surface <NUM> of the plate like portion <NUM>, in order to provide power to components arranged on the PCB <NUM>, <NUM>, such as the light emitting elements or a sensor or more generally any other component which needs to be powered. To that end one or more through-holes <NUM>, <NUM> may be provided in the metal body between the first surface <NUM> of the plate-like portion <NUM> and the inner part of the tube portion <NUM>.

The at least one electrical or mechanical or optical component attached to the removable closure <NUM> may be easily accessed by removing the removable closure <NUM>. The need for additional mounting structures within the inner part of the tube portion <NUM> is reduced, which improves the ease of fabrication of the luminaire head. Additionally, since the at least one electrical or mechanical or optical component may be adapted to be attached to the removable closure <NUM> only via the attaching means <NUM>, replacing or changing the one or more electrical or mechanical or optical component can be done easily without the need to modify the rest of the luminaire head. In another exemplary embodiment, the attaching means <NUM> may be a slot receiving a support substrate, e.g. a PCB, mounted therein.

The removable closure <NUM> is a cap in the exemplary embodiment of <FIG> which may be configured for closing off substantially fully the second open end, preferably in a sealed manner. The cap <NUM> may protect the elements arranged within the inner part of the tube portion <NUM> from undesired foreign elements, e.g. debris, moisture. At the same time, the surface of the cap <NUM> facing the inner part of the tube portion <NUM> may be configured for being attached to the one or more electrical or mechanical or optical components and for supporting and holding the one or more electrical or mechanical or optical component within the inner part of the tube portion <NUM>.

The first and second support substrate <NUM>, <NUM> may be printed circuit boards. In a preferred embodiment the printed circuit boards are so-called AC PCBs comprising circuitry that is able to convert an AC current or line voltage into a DC current, allowing therefore to eliminate the use of a driver.

As illustrated, there may be provided a first and a second lens plate <NUM>, <NUM> which are arranged over the first and the second support substrate <NUM>, <NUM> using gaskets <NUM>, <NUM>, preferably in order to obtain an IP66 rating of the luminaire head. Each lens plate <NUM>, <NUM> may be provided with a plurality of lens elements <NUM>, <NUM> corresponding with the plurality of light elements <NUM>. Preferably, the plurality of light emitting elements <NUM> of each support substrate <NUM>, <NUM> comprises at least six light emitting elements <NUM>, more preferably at least eight light emitting elements <NUM>. In the illustrated embodiment each support substrate <NUM>, <NUM> is provided with twenty-eight light emitting elements <NUM> and a corresponding number of lens elements <NUM>, <NUM>.

Using an embodiment as illustrated in <FIG> various advantages are obtained:.

<FIG> illustrates another exemplary embodiment of a luminaire head. The same or similar components have been indicated with the same reference numerals. In the embodiment of <FIG>, the tube portion <NUM> has a square cross section with a square inner surface <NUM> adapted for receiving a cylindrical end portion <NUM>. The other illustrated components are similar to the ones described above and therefore a detailed description thereof is omitted.

<FIG> illustrates another exemplary embodiment of a luminaire head. The same or similar components have been indicated with the same reference numerals. In the embodiment of <FIG>, the tube portion <NUM> has a cross section with a square outer surface and a round inner surface <NUM> adapted for receiving a cylindrical end portion <NUM>. Further, the cooling fins <NUM> are slightly inclined with respect to the second surface <NUM>, and not perpendicular on the second surface <NUM>. Also additional cooling fins <NUM> are provided on the first surface <NUM> of the plate like portion <NUM>, on either side of the support substrate <NUM>. The other illustrated components are similar to the ones described above and therefore a detailed description thereof is omitted.

<FIG> illustrates another exemplary embodiment of a luminaire head. The same or similar components have been indicated with the same reference numerals. In the embodiment of <FIG>, the tube portion <NUM> has a cross section with a square outer surface and an inner surface <NUM> in the form of a closed shape having three vertices touching a virtual inner circle such that the tube portion <NUM> is adapted for receiving a cylindrical end portion <NUM>. The other illustrated components are similar to the ones described above and therefore a detailed description thereof is omitted.

<FIG> illustrates yet another exemplary embodiment of a luminaire head. The same or similar components have been indicated with the same reference numerals. In the embodiment of <FIG>, the tube portion <NUM> has a cross section with a square outer surface and an inner surface <NUM> in the form of circle such that the tube portion <NUM> is adapted for receiving a cylindrical end portion <NUM>. In this embodiment two plate like portions <NUM>, <NUM>' are provided each having a flat first mounting surface <NUM>, <NUM>' and an opposite second surface <NUM>, <NUM>' on which cooling fins <NUM>, <NUM>' are arranged adjacent to the tube portion <NUM>. A first support substrate <NUM> with light emitting elements <NUM> is arranged against the first surface <NUM>, and a second support substrate <NUM> with light emitting elements <NUM> is arranged against the first surface <NUM>'. The other illustrated components are similar to the ones described above and therefore a detailed description thereof is omitted.

Claim 1:
A luminaire head comprising:
a thermally conductive metal body (<NUM>) comprising a plate like portion (<NUM>), a tube portion (<NUM>) and at least one cooling fin (<NUM>);
said plate like portion (<NUM>) extending in a longitudinal direction (L) of the metal body and having a flat first surface (<NUM>) and a second surface (<NUM>) opposite said first surface, said tube portion extending in said longitudinal direction at said second surface, preferably extending substantially in the middle of the second surface of the plate like portion;
said at least one cooling fin (<NUM>) extending away from said second surface adjacent to the tube portion (<NUM>);
at least one support substrate (<NUM>, <NUM>) with a plurality of light emitting elements (<NUM>), said at least one support substrate being arranged against the first surface, at least in an area opposite the tube portion;
wherein the tube portion has a first open end (<NUM>) which is closed by a removable closure (<NUM>), wherein the removable closure (<NUM>) is a cap configured for closing off substantially fully the first open end;
wherein at least one connector (<NUM>) is attached to the removable closure (<NUM>);
wherein the removable closure (<NUM>) comprises an attaching means (<NUM>) configured for attaching at least one electrical or mechanical or optical component, such that the at least one electrical or mechanical or optical component is arranged within the tube portion (<NUM>);
wherein the tube portion (<NUM>) is shaped to receive in a second open end (<NUM>) thereof a rigid cylindrical end portion (<NUM>) of a mounting base (<NUM>), such as a pole for the luminaire head;
wherein the tube portion (<NUM>) is provided with at least one hole (<NUM>, <NUM>) for receiving a fixation means (<NUM>) to fix the tube portion to the cylindrical end portion (<NUM>) of the mounting base.