EP3217084A1 - Lamp - Google Patents

Abstract

The present invention relates to a luminaire (1) comprising a luminaire housing (10) with an end wall (11) and a side wall (12), a light source device (20) arranged in a housing interior (13) with a light source carrier (21) and at least one light source on this arranged illuminating means (22), an insulating component (30) formed of an electrically insulating material with a main portion (31) and a skirt portion (32), the main portion (31) between the end wall (11) and the illuminating device (20) and wherein the skirt portion (32) extends from the main portion (31) such that the skirt portion (32) is disposed between the lamp device (20) and the sidewall (12) of the lamp housing (10).

Description

The present invention relates to a luminaire, in particular a luminaire for illuminating a room in a building.

From the general state of the art luminaires are known in which light sources arranged on a light source carrier are operated with an operating voltage. The operating voltage is usually provided by a power supply connected to the electronic ballast, which is disposed within a housing of the lamp and relative to a housing has a corresponding electrical insulation.

To remove heat from the housing is from the DE 20 2013 007 592 U1 For example, a lamp known in which the ballast is surrounded by a paste-like heat conducting material, which connects the ballast to the housing.

It is an object of the present invention to provide a luminaire which has a compact construction with efficient heat dissipation.

This object is achieved by a lamp with the features of claim 1.

According to the invention, a luminaire is provided which has a luminaire housing, with an end wall and a side wall, the end wall and the side wall forming a housing interior. The luminaire furthermore has a luminous means device arranged in the interior of the housing with a luminous means carrier and at least one luminous means arranged on the latter. In addition, the lamp has an insulating component formed from an electrically insulating material with a Main portion and a skirt portion, wherein the main portion between the end wall and the illuminant device is arranged and wherein the skirt portion extending from the main portion transversely to this such that the skirt portion between the illuminant device and the side wall of the lamp housing is arranged.

The luminous means device can be operated with an electrical operating voltage, wherein light can be emitted by the at least one luminous means. In particular, the luminous means device is arranged in the housing interior such that the at least one luminous means is located facing a light exit opening of the luminaire housing.

Due to the insulating component, the illuminating device is shielded in an electrically insulating manner from the luminaire housing. This has the advantage that the distance between the illuminant device and the luminaire housing can be very small, without resulting in a current flow between the illuminant device and housing during operation of the lamp. In this way, a particularly compact construction of the lamp is achieved. In particular, the luminous means device can thereby also advantageously be operated with high operating voltages.

The side wall of the lamp housing extends in particular transversely to the end wall and along a lamp longitudinal direction. The luminaire housing is generally formed from a metal material and preferably from an aluminum material.

Der Hauptwand des Leuchtengehäuses bzw. transverse to the lamp's longitudinal direction. In particular, the insulating component extends at least in sections along the end wall of the lamp housing. The skirt portion of the insulating member extends from and transversely of the main portion of the insulating member.

It can be provided that the main portion of the insulating component has a recess and the illuminating device is arranged on the main portion of the insulating component such that a luminous means region of the illuminant carrier, in which the at least one luminous means is arranged, and the recess of the main portion of the insulating component at least partially overlap , In particular, the recess of the main section of the insulating component and the illuminant region of the illuminant device overlap at least partially or in sections with respect to a radial direction directed transversely to the luminaire longitudinal direction.

This overlapping of the illuminant area and the recess of the main section has the advantage that the heat-conducting resistance between the luminaire housing and the illuminating device in the area of the illuminant is reduced, so that efficient heat transfer from the illuminant device to the luminaire housing is achieved.

The skirt portion of the insulating component may in particular have an at least partially curved cross-sectional profile.

Furthermore, it can be provided that the luminous means device and the insulating component are connected by means of a clamping device with the end wall of the lamp housing. For this purpose, the clamping device between an attachment point, which is located on the side wall of the lamp housing, and the Illuminant carrier of the illuminant device to be biased. The bias of the clamping device can be achieved in that it is formed of an elastically deformable material and this is clamped between the mounting location and the light source carrier such that the material of the clamping device is elastically deformed at least in individual areas or sections. The bias can also be applied by applying a pressing force, for example by means of an Adaperbauteils which snaps or screwed into the mounting location.

As an alternative or in addition to the clamping device, provision may be made for the illuminating device and the insulating component to be connected to the end wall of the luminaire housing by means of fixing parts extending through the illuminant carrier and the main section of the insulating component, the fastening parts being enclosed by an insulating sleeve. The fastening parts can be formed for example by screws, rivets, pins or the like.

The insulating component may in particular be formed from a polybutylene terephthalate material. This material has the advantage that it has a high dielectric strength, for example, greater than or equal to 4 kV / mm and at the same time is cost-effective with a vacuum forming process. Such materials also have a high heat resistance, for example, they are usable at temperatures of more than 105 degrees Celsius. Also, polybutylene terephthalate materials meet the requirements of so-called FR-1 ("Flame Retardant 1") material in terms of flammability and dielectric strength.

Furthermore, the luminaire can have a heat conduction component that is formed from an electrically insulating material and is arranged between the illuminant device and the insulation component or between the insulation component and the end wall of the luminaire housing. If the fastening of the luminous means device and of the insulating component takes place by means of fastening parts, it can be provided that the heat-conducting component has corresponding through-holes through which the fastening parts extend.

The heat conduction component is advantageously formed from an electrically insulating material with high thermal conductivity. The material may in particular be elastically deformable and has a thermal conductivity of greater than or equal to 1 W / mK and an electrical breakdown strength greater than or equal to 4 kV / mm. Due to the deformability of the material of the heat conduction component, a large contact surface between the heat conduction component and end face and heat conduction component and insulation component or heat conduction component and lighting device is achieved. This ensures an efficient heat dissipation from the illuminant device to the luminaire housing.

In the case of a high electrical breakdown strength of the illuminant carrier of the illuminant device, the heat conduction component can also be formed of a material with lower electrical breakdown strength.

The heat conduction member may have a thickness in a range between 0.1 mm and 10 mm, preferably between 0.2 mm and 5 mm and particularly preferably between 0.3 mm and 3 mm. This thickness results in a state in which the heat conduction member installed in the lamp and optionally through the insulating part and the end wall or the illuminant carrier and the insulating part or the Illuminant carrier and the end wall is compressed. As a result, on the one hand a spacing of the illuminant device is ensured by the end wall of the lamp housing, whereby the risk of unwanted electrical current flow, such as leakage currents or the like, between the illuminant device and the housing is reduced. At the same time high heat fluxes can be transmitted from the lighting device to the lamp housing in this thickness range.

The at least one light-emitting means can be integrated on the light-emitting means carrier in such a way that the light-emitting device acts as a chip-on-board LED module, COB LED module for short or as a PCBA LED module, short for "printed circuit board". Assembly LED module ", is formed.

Both with COB LED modules and with PCBA LED modules, the light source carrier is formed from a carrier substrate, for example as a ceramic or aluminum carrier. In the case of an aluminum carrier, an insulating layer made of an electrically insulating material is additionally provided.

In the case of COB LED modules, one or more light sources in the form of LED elements are generally arranged directly on the light source carrier. The LED elements can additionally be covered with a phosphor layer. In a PCBA LED module several LED elements are combined to form one LED unit, which are soldered to the illuminant carrier.

In this case, the illuminating device can be designed in a plan view of the illuminant carrier, for example, round, rectangular or polygonal. The lighting means can be arranged distributed in a suitable manner on the carrier substrate.

The lighting device may generally be designed so that it can be operated with an operating voltage of greater than or equal to 90 volts. Particularly advantageously, the lighting device can be operated with an operating voltage in a range between 90 volts and 380 volts. This range is therefore above safety extra-low voltages and in particular includes the voltages that are usually provided in public power grids as terminal voltages. This has the advantage that the illuminant device can be operated without additional electronic ballast, which converts the voltage provided by the power supply into an operating voltage for operating the illuminant device. In this way, the overall structure of the lamp is more compact.

In general, the luminous means device can be operated with a DC voltage and / or with an AC voltage.

With respect to direction indications and axes, in particular to directions and axes which relate to the course of physical structures, herein is understood to mean a course of an axis, a direction or a structure "along" another axis, direction or structure, that these, in particular the tangents resulting in a respective location of the structures, each at an angle of less than or equal to 45 degrees, preferably less than or equal to 30 degrees, and more preferably parallel to each other.

With respect to directional indications and axes, and in particular to directional data and axes concerning the course of physical structures, herein a progression of an axis, a direction or a structure is understood to be "transverse" to another axis, direction or structure, that in particular the tangents resulting in a respective position of the structures, in each case at an angle of greater than 45 degrees, preferably greater than or equal to 60 degrees, and more preferably perpendicular to each other.

Embodiments of the invention are illustrated in the figures of the drawing and explained in more detail in the following description.

Fig. 1

eine schematische Schnittansicht einer Leuchte gemäß einem Ausführungsbeispiel der vorliegenden Erfindung;

Fig. 2

eine schematische Schnittansicht einer Leuchte gemäß einem weiteren Ausführungsbeispiel der vorliegenden Erfindung;

Fig. 3

eine Außenansicht einer Leuchte gemäß eines Ausführungsbeispiels einer Leuchte der Vorliegenden Erfindung, wobei ein Leuchtengehäuse der Leuchte teilweise transparent dargestellt ist; und

Fig. 4

eine vergrößerte Ansicht des in Fig. 3 mit dem Buchstaben Z gekennzeichneten Bereichs;

Fig. 5

ein Ausführungsbeispiel einer Leuchtmittelvorrichtung der Leuchte gemäß der vorliegenden Erfindung;

Fig. 6

ein weiteres Ausführungsbeispiel einer Leuchtmittelvorrichtung der Leuchte gemäß der vorliegenden Erfindung.

It illustrate:

Fig. 1

a schematic sectional view of a lamp according to an embodiment of the present invention;

Fig. 2

a schematic sectional view of a lamp according to another embodiment of the present invention;

Fig. 3

an external view of a lamp according to an embodiment of a lamp of the present invention, wherein a lamp housing of the lamp is shown partially transparent; and

Fig. 4

an enlarged view of the in Fig. 3 area marked with the letter Z;

Fig. 5

an embodiment of a lighting device of the lamp according to the present invention;

Fig. 6

a further embodiment of a lighting device of the lamp according to the present invention.

Fig. 1 schematically shows a sectional view of an embodiment of a lamp according to the invention 1. The lamp 1 has a lamp housing 10 with an end wall 11 and a side wall 12, wherein the end wall 11 and the side wall 12 form a housing interior 13. The side wall 12 extends in particular from the end wall 11 and extends along a lamp longitudinal direction L1. The side wall 12 has a first end portion 14 connected to the end wall 11 and a second end portion 15 opposite to the first end portion 14.

The housing interior 13 is defined in particular by mutually facing surfaces of the side wall 12 and the end wall 11. In particular, an end surface 11a of the end wall 11 and an inner surface 12a of the side wall 12 define the housing interior 13. The housing interior has a light exit opening 16 defined by the side wall 12, in particular by the second end section 15 of the side wall 12.

The end wall 11 and the side wall 12 may be formed, for example, as one piece. Alternatively, the side wall 12 and the end wall 11 may be formed as two separate parts. Here, the side wall 12 may be connected to the first end portion 14 with the end wall 11, in particular with the end surface 11a of the end wall 11, for example by welding, gluing or the like. The end wall 11 and the side wall 12 are preferably made of a material with high thermal conductivity, such as e.g. Aluminum, an aluminum alloy or the like formed. In this way, the luminaire housing 10 forms a heat sink for waste heat, which accumulates during operation of a luminaire device 20 which is described in more detail below and is arranged in the housing interior 13 of the luminaire housing 10.

The luminaire 1 furthermore has a luminous means device 20 arranged in the housing interior 13. This points in general, a light source carrier 21, which may be formed in particular disk-shaped or plate-shaped, and at least one arranged on this bulb 22. The illuminating device 20 preferably has a multiplicity of luminous means 22 or luminous elements which are incorporated into the Fig. 1 to 4 are not shown individually. The light-emitting elements or light-emitting means 22 may be arranged on the light-emitting means carrier 21 or integrated thereon, for example in the form of light-emitting diodes, in short LEDs.

The at least one luminous means 22 can advantageously be integrated on the illuminant carrier 21 such that the illuminant device 20 is designed as a so-called chip-on-board LED module or as a PCBA LED module.

Fig. 5 shows an example of an embodiment of a light-emitting device which is realized as a chip-on-board LED module, COB LED module for short. At the in Fig. 5 shown example of the COB LED module, a surface designed bulb 22 in the form of LED elements arranged directly on the light source carrier 21. The light-emitting means 22 is round in this case. However, the luminous means 22 may also have a rectangular or polygonal or similar shape. The light source carrier 21 is according to Fig. 5 trained around. This may for example also be rectangular or polygonal.

Fig. 6 shows an example of a light source device, which is designed as a PCBA LED module, short for "Printed Circuit Board Assembly LED Module". In this case, the lighting means 22 in the form of LED units 24, which in each case combine a plurality of LED elements, are soldered onto the illuminant carrier 21.
The lighting means 22 may be arranged distributed in a suitable manner on the carrier substrate, for example as in Fig. 6 shown in rows. The light source carrier 21 is according to Fig. 6 trained around. This may for example also be rectangular or polygonal.

As in the FIGS. 5 and 6 2, the illuminant devices 20 may each comprise further electronic circuit components 25, which will not be discussed in detail below.

As in particular in the Fig. 1 and 2 is shown, the lighting means 22 can be arranged generally in a luminous means region 23 of the illuminant carrier 21. For example, planar, concentric, row-shaped or matrix-shaped arrangements of the lighting means 22 may be provided.

The luminous means device 20 can be designed so that it can be operated with an operating voltage of greater than or equal to 90 volts. Advantageously, the luminous means device 20 can be operated with an operating voltage which is operable in a range between 90 volts and 380 volts. This range includes in particular the voltages which are usually provided in public power grids as terminal voltages. This has the advantage that the illuminant device 20 can be operated without additional electronic ballast, which converts the voltage provided by the power supply into an operating voltage for operating the illuminant device.

As in particular in the Fig. 1, 2 and 4 1, the luminaire 1 has an insulation component 30 formed from an electrically insulating material. The insulation component 30 has a particular areally extending, for example, disk-shaped or disk-shaped main section 31 and a skirt section 32. The skirt portion 32 extends from and across the main portion 31. The main portion 31 and the skirt portion 32 thus form a total cup-shaped insulating member 30th

As exemplified in the Fig. 1 to 4 is shown, the main portion 31 of the insulating member 30 may have a recess 33. Preferably, this may be formed in a central region 34 of the main portion 31, wherein the central region 34 may be given in a plan view of the main portion 31, for example, by an area which extends concentrically around the centroid of the main portion 31.

As exemplified in Fig. 4 is shown, the skirt portion 32 of the insulating member 30 may have a curved cross-sectional shape.

As in particular in the Fig. 1, 2 and 4 is shown, the main portion 31 is arranged with respect to the lamp longitudinal direction L1 between the end wall 11 and the illuminant device 20 and the skirt portion 32 and the skirt portion 32 is with respect to a transversely to the lamp longitudinal direction L1 extending radial direction R1 between the light emitting device 20 and Side wall 12 of the lamp housing 10 is arranged.

The skirt portion 32 thus extends from the main portion 31 of the insulating member 30 across the main portion 31 such that the skirt portion 32 is disposed between the bulb device 20 and the sidewall 12 of the lamp housing 10.

In this way, the bezel section 32 shields the luminous means device 20 in the radial direction R1 and the main section 31 shields the luminous means device 20 in the lamp longitudinal direction L1 with respect to the luminaire housing 10. Since the insulating member 30 of an electrically insulating Material is formed, between the luminaire housing 10 and the illuminating device 20 flowing creepage currents or possible electrical arcs may be advantageously prevented. In particular, the skirt portion 32 allows, with respect to the radial direction R1, a small lateral distance s1 between the illuminant device 20 and the sidewall 12, in particular between the illuminant device 20 and the inner surface 12a sidewall 12, without resulting in a flow of current between the illuminant device 20 and the housing 10. In this way, a particularly compact construction of the lamp 10 is made possible.

As already described, the main portion 31 of the insulating component 30 may have a recess 33. In this case, it is preferably provided that the luminous means device 20 is arranged on the main portion 31 of the insulating component 30 such that the luminous means region 23 of the illuminant carrier 21 and the recess 33 of the main portion 31 of the insulating component 30 at least partially overlap with respect to the radial direction R1. In a plan view of the luminous means device 20 and the main section 31 of the insulating component 30, for example in a plan view of a second surface 21b of the illuminant carrier 21 which faces the light exit opening 16, the illuminant region 23 of the illuminant device 20 is preferred with respect to the radial direction R1 completely or at least partially located within the recess 32.

This overlapping arrangement of the illuminant area 23 and recess 33 of the main portion 31 has the advantage that the illuminant device 20 in the region of the recess 33 unhindered heat to the end wall 11 and an optionally provided below in detail Heat conduction component 40 can deliver, for example by radiation or convection.

The recess 34 may further, as in exemplary Fig. 4 is shown to be formed for centering of the insulating member 30 on the end surface 11a of the end wall 11. For example, it can be provided that the end surface 11a forms a shoulder 18 of the end wall 11. The insulation component 30 can then be arranged in the housing interior 13 such that the recess 34 receives the shoulder 18 of the end wall 11.

The insulating component 30 may in particular be formed from a polybutylene terephthalate material. Such materials have the advantage that they are inexpensive and have a good heat resistance, for example, even at a temperature of more than 105 degrees Celsius are still usable.

With the abovementioned material, insulating components 30 can be produced, for example in a vacuum forming process, in a particularly cost-effective manner from a foil-like material blank.

As already described in connection with the insulation component 30, the luminaire 1 may additionally have a heat conduction component 40. The heat conduction member 40 is also formed of an electrically insulating material. In particular, the heat conduction component 40 may be formed as a surface extending, in particular plate or disk-shaped component.

As in the Fig. 1 and 2 is shown as an example, the heat conduction member 40 may be disposed with respect to the lamp longitudinal direction L1 between the insulating member 30 and the end wall 11 of the lamp housing 10. Alternatively to this For example, the heat conduction member 40 may be disposed between the light emitting device 20 and the insulating member 30 with respect to the lamp longitudinal direction L1 as shown in FIG Fig. 4 is shown.

The heat conduction component 40 is advantageously formed from a material with high thermal conductivity. In particular, the heat conduction component 40 may be formed of a soft, in particular elastically deformable material. Furthermore, the heat-conducting component 40 rests against the end surface 11a of the end wall 11 at least with a partial region of a first contact surface 40a. With at least a portion of a second contact surface 40b opposite to the first contact surface 40a, the heat conduction member 40 as shown in FIGS Fig. 1 and 2 shown abutting a first surface 31a of the main portion 31 of the insulating member. It can also be provided that the heat conduction component 40 with at least a portion of the second contact surface 40b or, as in Fig. 4 shown by way of example, with the second contact surface 40b in total on a first surface 21a of the illuminant carrier 21 is present.

Because the heat conduction component 40 bears against the end surface 11a of the end wall 11 with at least a portion of the first contact surface 40a, a reliable and efficient heat transfer from the illuminant device 20 to the luminaire housing 10 is ensured.

The heat conduction component 40 may, for example, have a thickness d40, in particular a cross-sectional thickness, in a range between 0.1 mm and 10 mm, preferably between 0.2 mm and 5 mm and particularly preferably between 0.3 mm and 3 mm. In this area, a spacing of the lighting device 20 in the lamp longitudinal direction L1 of the Achieved end wall 11, on the one hand creep currents between the light emitting device 20 and the lamp housing 10 are reliably prevented. At the same time, the heat conduction component 40 has a low heat conduction resistance in this thickness range, as a result of which efficient heat dissipation from the illuminant device 20 to the luminaire housing 10 is ensured.

The Fig. 1 and 2 show exemplary possible fixings of the housing interior 13 arranged in the components of the lamp housing 10th

As in Fig. 1 2, the illuminating device 20 and the insulating component 30 may be connected to the end wall 11 of the luminaire housing 10 by means of a clamping device 2. In particular, it can be provided that the clamping device 2 is prestressed between an attachment point 17, which is located on the side wall 12 of the luminaire housing 10, and the illuminant carrier 21 of the illuminant device 20.

The clamping device 2 may for example be formed as a funnel-shaped component having elastically deformable side walls 7. In this case, it may be provided that a first end section 8 of the side wall 7 of the clamping device 2 engages in an attachment point 17 designed as a depression of the side wall 12 of the lamp housing 10 and a second end section 9 of the side wall 7 of the clamping device 2 located opposite the first end section 8 on a second surface 21 b of the illuminant carrier 21 is applied. Such a variant is exemplified in Fig. 1 shown.

The mounting location 17 can also be considered to be one in the radial direction R1 of the side wall 12 of the lamp housing 10 protruding increase may be formed at the lower end surface 11a with respect to the lamp longitudinal direction L1, the first end portion 8 of the side wall 7 of the clamping device 2 is applied.

The mounting location 17 can also be formed by a thread formed on the inner surface 12 a of the side wall 12 of the luminaire housing 10. In this case, the first end portion 8 of the clamping device 2 or an adapter component receiving this 53 has a corresponding counter-thread, which can be screwed into the thread of the side wall 12.

The attachment site 17 is located generally spaced from the face surface 11a with respect to the lamp's longitudinal direction L1. In particular, the attachment point 17 is located with respect to the lamp longitudinal direction L1 between the light exit opening 16 and a spaced from the main portion 31 end portion 35 of the skirt portion 32 of the insulating member 30.

Instead of a funnel-shaped component, the clamping device 2 may also be formed by a plurality of elastically deformable rod-shaped components which each engage with a first end portion at the attachment point 17 and abut against the second surface 21b of the illuminant carrier 21 with a second end portion opposite the first end portion.

Furthermore, the clamping device 2 may also be formed as a lens device 50, as shown in the example Fig. 3 and 4 is shown. The lens device 50 has a first end portion 51, which is received in a form-fitting manner in an adapter component 53. The adapter component 53 has a latching section 54, projecting from the latter in the radial direction R1, which engages through an elastically deformable Bracket 55 and a locking jaw 56 is formed, wherein the locking jaw 56 engages in the formed in this case as a recess attachment point 17. Alternatively, the attachment point 17 can also be formed by a thread formed on the inner surface 12a of the side wall 12 of the lamp housing 10 and the adapter component 53 have a corresponding mating thread which can be screwed into the thread of the side wall 12.

As an alternative or in addition to a fastening of the components arranged in the interior of the housing 13 to the luminaire housing 10 by means of a clamping device 2, it is possible for the luminous means device 20 and the insulating component to pass through the illuminant carrier 21 and the main section 31 of the insulating component 30 - and optionally through the heat conduction component 40 - extending through fasteners 3, 4 are connected to the end wall 11 of the lamp housing 10, as exemplified in Fig. 2 is shown. In the Fig. 2 and 4 the fastening parts 3, 4 are exemplified as screws. However, the fastening parts 3, 4 can also be realized as rivets, pins or the like.

The fastening parts 3, 4 generally each have an elongate shaft 3A, 4A which extends through corresponding through holes 20A, 20B, 30A, 30B, 40A, 40B formed in the illuminant carrier 20, the insulating component 30 and optionally the heat transfer member 40, and in FIG a corresponding formed in the end wall 11 mounting recess 11A, 11B is positively and / or non-positively received. The fastening parts 3, 4 further each have a connected to the shaft 3A, 3B head 3B, 4B, which with a due to the positive and / or non-positive reception of the shaft 3A, 4A in the fastening recess 11A, 11B presses against the second surface 21b of the illuminant carrier 21.

On the one hand, the fastening parts 3, 4 cause the illuminant carrier 20, the insulating component 30 and optionally the heat transfer part 40 on the end wall 11 to be fastened. If the luminaire 1 has a heat transfer part 40, the fastening parts 3, 4 also cause a deformation of the heat transfer part 40 and thus increase it the size of the adjacent areas of the surfaces 40a, 40b of the heat transfer member 40, which is advantageous in terms of heat dissipation from the illuminant device 20 to the lamp housing 10.

As in the Fig. 3 and 4 is shown, the screw can also be provided in addition to a fastening means of a clamping device 2.

As in the Fig. 2 to 4 is shown, the fastening part 3, 4 are each surrounded by an insulating sleeve 5, 6. The insulation sleeves 5, 6 are each formed from an electrically insulating material and ensure that no electrically conductive connection between the fastening parts 3, 4 and the light source carrier 21 comes about.

As exemplified in Fig. 3 is shown, the lamp 1 may have a holding device 60, by means of which the lamp 1 at a connection point (not shown) can be fastened. The connection point can be formed, for example, by a floor slab or a wall of a building or a rail attached thereto.

LIST OF REFERENCE NUMBERS

1

lamp

2

Einspannungseinrichtung

3

attachment portion

4

attachment portion

3A, 4A

Shaft of the fastening part

3B, 4B

Head of the fastening part

5

insulation sleeve

6

insulation sleeve

7

Side wall of the clamping device

8th

first end portion of the side wall of the clamping device

9

second end portion of the side wall of the clamping device

10

luminaire housing

11

End wall of the luminaire housing

11a

Front surface of the end wall

11A, 11B

mounting recess

12

Side wall of the luminaire housing

12a

Inner surface of the side wall

13

Housing interior

14

first end portion of the side wall

15

second end portion of the side wall

16

Light exit opening of the luminaire housing

17

for mounting

18

Paragraph of the front wall

20

Lamp device

20A, 20B

Through holes of the lighting device

21

Lamp support

21a

first surface of the illuminant carrier

21b

second surface of the illuminant carrier

22

Lamp

23

Lamp area

24

LED unit

25

circuit components

30

insulating member

30A, 30B

Through holes of the insulation component

31

main section

31a

first surface of the main section

32

casing section

33

Recess of the main section

34

central area of the main section

35

End portion of the skirt portion

40

Heat conduction component

40A, 40B

Through holes of the heat conduction member

40a

first contact surface of the heat conduction member

40b

second contact surface of the heat conduction member

50

lens device

51

first end portion of the lens device

52

second end portion of the lens device

53

adapter component

54

detent portion

55

hanger

56

latching cheek

L1

Lights longitudinally

R1

radial direction

d40

Thickness of the heat conducting component

s1

lateral distance

Claims (10)

Light (1), comprising: a lamp housing (10) having an end wall (11) and a side wall (12), the end wall (11) and the side wall (12) forming a housing interior (13); a light-emitting device (20) arranged in the housing interior (13) with a light-emitting means carrier (21) and at least one light-emitting means (22) arranged thereon; an insulation member (30) formed of an electrically insulating material, comprising a main portion (31) and a skirt portion (32), the main portion (31) being disposed between the end wall (11) and the light emitting device (20), and wherein the skirt portion (32 ) extends transversely of the main portion (31) such that the skirt portion (32) is disposed between the illuminant device (20) and the sidewall (12) of the lamp housing (10). Luminaire (1) according to claim 1, wherein the main portion (31) of the insulating component (30) has a recess (33) and the illuminating device (20) is arranged on the main portion (31) of the insulating component (30) such that a luminous means region (FIG. 23) of the illuminant carrier (21), in which the at least one luminous means (22) is arranged, and the recess (33) of the main portion (31) of the insulating component (30) at least partially overlap. Luminaire (1) according to claim 1 or 2, wherein the skirt portion (32) of the insulating member (30). has an at least partially curved cross-sectional shape. Luminaire (1) according to one of the preceding claims, wherein the luminous means device (20) and the insulating component (30) by means of a clamping device (2) with the end wall (11) of the lamp housing (10) are connected, wherein the clamping device (2) between a Attachment point (17) which is located on the side wall (12) of the lamp housing (10), and the illuminant carrier (21) of the illuminating device (20) is biased. Luminaire (1) according to one of the preceding claims, wherein the luminous means device (20) and the insulating component by means of the illuminant carrier (21) and the main portion (31) of the insulating member (30) therethrough mounting hardware (3, 4) with the end wall ( 11) of the lamp housing (10) are connected, wherein the fastening parts (3, 4) by an insulating sleeve (5, 6) are enclosed. Luminaire (1) according to one of the preceding claims, wherein the insulating member (30) is formed of a polybutylene terephthalate material. Luminaire (1) according to one of the preceding claims, wherein the lamp (1) comprises a heat conduction member (40) which is formed of an electrically insulating material and between the light emitting device (20) and the insulating member (30) or between the insulating member (30 ) and the end wall (11) of the lamp housing (10). Luminaire (1) according to claim 7, wherein the heat conduction member (40) has a thickness (d40) in a range between 0.1 mm and 10 mm, preferably between 0.2 mm and 5 mm and particularly preferably between 0.3 mm and 3 mm. Luminaire (1) according to one of the preceding claims, wherein the at least one luminous means (22) on the illuminant carrier (21) is integrated such that the illuminant device (20) as a chip-on-board LED module or as a PCBA LED Module is formed. Luminaire (1) according to one of the preceding claims, wherein the luminous means device (20) is designed so that it can be operated with an operating voltage of greater than or equal to 90 volts.

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