DE202024104937U1 - Optical unit, lamp and reflector for an optical unit - Google Patents

Abstract

Optical unit (1) for a lamp (20), with a reflector (3) for reflecting and/or bundling light, and with a lens (4) for mixing and/or scattering light, characterized in that
- that the lens (4) is arranged at least partially, in particular completely, in an interior space (5) of the reflector (3) and/or projects into the interior space (5) during the intended use of the optical unit (1), and/or
- that the reflector (3) is designed such that both the lens (4) and a heat sink (6) of the lamp (20) can be connected to the reflector (3) in a force-fitting and/or form-fitting manner.

Description

The present invention relates to an optical unit for a lamp, with a reflector for reflecting and/or bundling light and with a lens for mixing and/or scattering light. The invention further relates to a lamp and a reflector for an optical unit.

From the DE 10 2009 014 526 A1 An LED lamp with an LED unit, a heat sink for cooling the LED unit and a reflector is known. Fasteners are provided on the reflector for mechanically detachable fastening of the reflector to the heat sink. A disadvantage of this and other optical units known from the prior art is that despite the use of a reflector and/or lens, high light losses continue to occur due to scattered light. In addition or alternatively, assembly is complicated due to the large number of components.

The object of the present invention is to eliminate the disadvantages known from the prior art.

The object is achieved by an optical unit, a lamp and/or a reflector for an optical unit with the features of the independent claims. Advantageous or preferred embodiments or developments of the invention are characterized by the features of the dependent claims.

An optical unit is proposed. The optical unit can be used, for example, in a light, in particular in a track light and/or a track spotlight. The optical unit preferably comprises a reflector for reflecting and/or bundling light, whereby reflection in the sense of the application can be understood in particular to mean both diffuse and direct reflection, preferably direct reflection. The reflector brings about an improved light output by reflecting and bundling the light in a targeted manner. This leads to a more uniform and more intensive illumination of the target area. Additionally or alternatively, the optical unit preferably comprises a lens for mixing and/or scattering light. The lens brings about a homogeneous light distribution by mixing and scattering the light. This leads to a reduction in glare and pleasant illumination.

The optical unit can additionally or alternatively be designed as a lamp unit and/or comprise a lamp for emitting light. Additionally or alternatively, the optical unit is adjacent to the lamp when used as intended. The light from the lamp can thus be introduced into the optical unit, preferably into the lens. The lamp is preferably designed as an LED lamp, in particular a COB-LED lamp. LED and COB-LED lamps are characterized by their long service life and high energy efficiency, which reduces the operating costs of the optical unit. Additionally or alternatively, the lamp comprises a circuit board.

The reflector is preferably made of plastic, more preferably of uncoated plastic, in particular of at least partially reflective plastic, e.g. plastic containing TiO2 additives. The use of uncoated plastic contributes to cost efficiency. In particular, the reflectivity of the reflector can depend on the plastic used and/or its surface, with the use of plastic with TiO2 additives, for example, having a positive effect on the reflectivity. The lens is preferably made of plastic. A lens made of plastic offers high breaking strength and enables flexible shaping, which increases the adaptability of the lens to different requirements, for example in connection technology.

The lens is preferably arranged at least partially, preferably completely, in an interior of the reflector and/or protrudes into the interior. This arrangement optimally directs the light in the desired direction, which leads to improved light output. The light emitted by the lamp can thus be guided completely with the help of the reflector and the lens. A large part of the light initially penetrates the lens. The light that passes the side of the lens and/or exits the side of the lens can be reflected and/or guided back into the lens with the help of the reflector. This makes it possible to keep the loss of light due to scattered light as low as possible.

Additionally or alternatively, the reflector is preferably designed such that both the lens and a heat sink of the lamp can be connected to the reflector in a force-fitting and/or form-fitting manner. The reflector can thus provide the direct connection between the heat sink and the lens, so that no further holding means are necessary. The elimination of additional holding means reduces the weight and complexity of the optical unit, which lowers manufacturing costs. This additionally or alternatively makes it possible to reduce the number of components of the optical unit and/or simplify assembly.

It is advantageous if the reflector comprises a first connecting section for the lens, wherein the first connecting section is preferably arranged in the interior of the reflector. In particular, the first connecting section can be arranged in the vicinity of the heat sink in a state in which the reflector is connected to the heat sink. Such a connecting section ensures secure and precise positioning of the lens, in particular in the interior.

It is also advantageous if the lens comprises a second connecting section designed to correspond to the first connecting section. The corresponding connecting sections enable simple and precise assembly, reduce the production time and/or increase the mechanical stability of the optical unit.

It is also advantageous if the reflector and the lens are connected to one another via the first connecting section and the second connecting section, in particular in a form-fitting and/or force-fitting and/or separable manner, during the intended use of the optical unit. This connection enables the optical unit to be easily dismantled, which facilitates maintenance and/or the replacement of components. Additionally or alternatively, the lens can be exchanged to change the light. This means that the optical unit can be adapted to different circumstances and/or requirements.

It is also advantageous if the reflector comprises a reflector inner surface, in particular a reflection surface, which is in particular conical and/or parabolic, and/or the lens comprises a lens outer surface, in particular conical and/or parabolic. The special shape of the reflector inner surface and/or the lens outer surface ensures efficient light guidance and/or reduces undesirable light losses.

It is advantageous if the inner surface of the reflector and the outer surface of the lens are spaced apart from each other all the way around and/or completely and/or evenly when the optical unit is used as intended. A uniform distance between the inner surface of the reflector and the outer surface of the lens contributes to consistent light distribution, prevents hotspots and/or prevents shadows from forming.

It is also advantageous if the reflector inner surface comprises the first connecting section and/or the first connecting section adjoins the reflector inner surface. The integration of the first connecting section in or on the reflector inner surface reduces the need for additional connecting elements. Additionally or alternatively, this can prevent the light from escaping between the first connecting section and the reflector inner surface, in particular the reflection surface.

It is advantageous if the optical unit comprises at least one diaphragm ring, wherein the diaphragm ring is preferably connected to the reflector in a force-fitting and/or form-fitting and/or detachable manner. The diaphragm ring enables precise control of the light exit angle and minimizes glare, which increases the user-friendliness of the optical unit.

It is also advantageous if the reflector comprises at least one contact section for contact with the heat sink and/or an adapter of the heat sink and/or the lamp, at least one fastening section for fastening to the heat sink and/or the adapter of the heat sink and/or a third connecting section for the cover ring. The fastening section ensures stable and secure fastening of the reflector to the heat sink or to its adapter. In particular, the adapter of the heat sink can be designed as an adapter plate. With the help of the third connecting section, the cover ring can be connected to the reflector, preferably detachably. The cover ring can thus be installed or removed as required. It is advantageous if the contact section and the third connecting section are spaced apart from one another along a light axis. This distance along the light axis achieves optimal alignment of the light rays and/or improved light output and/or more uniform illumination.

Furthermore, it is advantageous if the reflector inner surface, in particular the reflection surface, connects the contact section and/or the first connection section to the third connection section. Additionally or alternatively, the reflector inner surface is arranged between the first connection section and the third connection section. This arrangement of the reflector inner surface, in particular the reflection surface, enables optimal light guidance between the connection sections, which improves the efficiency of the light reflection and leads to uniform illumination.

It also has advantages if the at least one fastening section is designed as a fastening pot and/or fastening embossing. The design as a fastening pot and/or fastening embossing enables a safe and secure mounting of the reflector, which improves the stability of the optical unit.

It is advantageous if at least one fastening section covers the reflector inner surface, in particular the reflection surface, and/or is arranged at least partially in the area of the inner surface of the reflector. Such a fastening section enables simple and precise assembly and helps to ensure that the reflector can be designed as compactly as possible.

It is also advantageous if at least one connecting element of the first connecting section protrudes from the inner surface of the reflector, in particular the reflection surface, and/or projects into the interior. A corresponding connecting element enables secure fastening and facilitates the assembly of the lens. This ensures a positive connection between the reflector and the lens.

Furthermore, it is advantageous if the third connecting section of the reflector and a light exit surface of the lens are flush along the light axis. A flush design of these components ensures a seamless transition, which minimizes the occurrence of light losses due to scattering or reflection at edges and increases the efficiency of the light output. In addition, the flush alignment contributes to the aesthetics of the optical unit and/or reduces potential dirt or dust deposits at transitions. Flush means that there can be a circumferential gap between the third connecting section and the light exit surface, but this does not have to be the case.

It is advantageous if the reflector can be attached to the heat sink and/or the heat sink adapter and/or the lamp via the contact section and/or the fastening section. This makes it easier to attach the reflector to the heat sink of the lamp or to the heat sink adapter. The reflector preferably rests on the lamp, in particular the lamp's circuit board, with the contact section and/or the lamp can be centered and/or aligned using the contact section. The fastening section preferably rests at least partially on the heat sink and/or the heat sink adapter. This makes it easier to mount the optical unit on the lamp because the lamp can be centered and/or aligned when the reflector is attached to the heat sink.

It is also advantageous if the at least one lamp can be arranged, in particular clamped, between the reflector and a heat sink and/or an adapter of the heat sink of the luminaire, wherein the reflector and the heat sink and/or the adapter of the heat sink can be connected in a force-fitting manner. In embodiments, the reflector can be connected in a force-fitting manner to the heat sink, wherein the adapter of the heat sink can be clamped between the reflector and the heat sink. Clamping the lamp between the reflector and the heat sink and/or the adapter of the heat sink when the optical unit is used as intended in the luminaire ensures safe and stable positioning, which can minimize vibrations and increase the reliability of the optical unit. Additionally or alternatively, assembly can be simplified because no separate fastening is required for the lamp.

It is also advantageous if the reflector can be screwed to the heat sink of the lamp and/or an adapter of the heat sink using at least one screw, so that the clamping force between the reflector and/or heat sink and/or adapter and/or lamp can be set and/or adapted. By using a screw connection, the clamping force can be set precisely. This enables individual adjustment of the mechanical load and ensures that the components are securely fastened. This leads to increased flexibility during assembly.

It is also advantageous if the first connecting section of the reflector with the second connecting section of the lens and/or the third connecting section of the reflector with a fourth connecting section of the aperture ring forms a positive and/or frictional and/or separable connection, in particular a bayonet connection, when the optical unit is used as intended. Such a connection enables simple and quick assembly and disassembly of the components, which facilitates maintenance and replacement. The bayonet connection also ensures a secure and firm connection that prevents unwanted movements or loosening during operation.

It is advantageous if the reflector is made of plastic, in particular polycarbonate, whereby the plastic preferably contains TiO2 additives. Polycarbonate offers high impact strength and temperature resistance, which increases the longevity and reliability of the optical unit. The addition of TiO2 additives improves the reflectivity of the reflector and contributes to a higher light output, thereby increasing the efficiency of the optical unit.

Furthermore, a luminaire is proposed. The luminaire is preferably designed as a track luminaire and/or track spotlight. The luminaire preferably comprises an optical unit according to the previous description. exercise, whereby the above-mentioned features can be present individually or in any combination.

As already described above, in addition to the optical unit, the luminaire preferably comprises a heat sink, an adapter and/or a cover ring. When the luminaire is used as intended, the reflector of the optical unit is preferably connected to the heat sink and the lens in a force-fitting and/or form-fitting manner.

Furthermore, a reflector for an optical unit is proposed. The reflector is preferably designed according to the previous description, wherein the features mentioned can be present individually or in any combination.

For example, the reflector comprises the interior, the first connecting section, the third connecting section, the reflector inner surface, in particular the reflection surface, the contact section, the fastening section and/or the connecting element according to the preceding description and/or is made of the plastic, in particular containing TiO2 additives.

• 1 eine schematische perspektivische Ansicht einer Leuchte gemäß einem Ausführungsbeispiel,
• 2 eine schematische, perspektivische Ansicht einer Leuchte gemäß einem alternativen Ausführungsbeispiel, und
• 3 eine schematische Schnittansicht einer Leuchte gemäß einem weiteren Ausführungsbeispiel.

Further advantages of the invention are described in the following embodiments. It shows:

• 1 a schematic perspective view of a luminaire according to an embodiment,
• 2 a schematic, perspective view of a luminaire according to an alternative embodiment, and
• 3 a schematic sectional view of a luminaire according to another embodiment.

In the following description of the figures, the same reference symbols are used for identical and/or at least comparable features in the various figures. The individual features, their design and/or mode of operation are usually only explained in detail when they are first mentioned. If individual features are not explained in detail again, their design and/or mode of operation corresponds to the design and mode of operation of the features with the same effect or the same name that have already been described.

1 shows a schematic, perspective view of a lamp 20 with an optical unit 1 according to an embodiment. As can be seen from the embodiment of the 1 As can be seen, the optical unit 1 in this example comprises a reflector 3 which is designed to reflect and/or concentrate light. A lens 4 which serves to mix and/or scatter light is also provided in the optical unit 1. In addition, the optical unit 1 is adjacent to at least one lamp 2 which serves to emit the light. The light from the lamp 2 preferably penetrates into the optical unit 1, in particular into the lens 4 of the optical unit 1.

For a clearer illustration, the lens 4 and the reflector 3 in the illustrated embodiment are 1 spaced apart and/or not connected to each other. The 1 thus shows the lamp 20 and/or the optical unit 1 in a so-called exploded view. When the lamp 20 and/or the optical unit 1 is used as intended, the lens 4 is at least partially, preferably completely, arranged in an interior 5 of the reflector 3 and/or protrudes into the interior 5 of the reflector 3. The lens 4 is additionally or alternatively connected to the reflector 3 in a force-fitting and/or form-fitting and/or separable manner.

In the exemplary embodiment shown, the reflector 3 is also connected to a heat sink 6 of the lamp 20 in a force-fitting and/or form-fitting manner. The reflector 3 is thus designed in the exemplary embodiment shown in such a way that both the lens 4 and the heat sink 6 of the lamp 20 can be connected to the reflector 3 in a force-fitting and/or form-fitting manner. This makes it possible for both the lens 4 and the heat sink 6 to be connected to the reflector 3. For example, a separate fastening arrangement, as is usually known from the prior art, can be omitted. In this exemplary embodiment, the reflector 3 is made of plastic, in particular polycarbonate, wherein the plastic preferably contains TiO2 additives.

The reflector 3 has a first connecting section 7, which is used for connection to the lens 4. In the example shown, this first connecting section 7 is preferably arranged in the interior 5 of the reflector 3, in particular in the vicinity of the heat sink 6. Accordingly, the lens 4 comprises a second connecting section 8, which is designed to be complementary to the first connecting section 7. When the optical unit 1 is used as intended, the reflector 3 and the lens 4 are connected to one another via these connecting sections 7 and 8, wherein the connection is preferably positively locking and/or non-positively locking and/or separable.

Furthermore, the reflector 3 comprises a reflector inner surface 11, in particular a reflection surface, which is in particular conical and/or parabolic in shape. The lens 4 has a lens outer surface 12, which can also be conical and/or parabolic in shape. In the intended According to the use of the optical unit 1, the reflector inner surface 11 and the lens outer surface 12 are circumferentially and/or completely and/or evenly spaced from each other. The first connecting section 7 is arranged adjacent to the reflector inner surface 11. This ensures the most stable connection possible.

In addition, the reflector 3 comprises at least one contact section 14, which serves to be placed on the lamp 2, in particular a circuit board of the lamp 2. The lamp 2 used in the present embodiment is preferably a COB-LED lamp, which preferably comprises the circuit board. The at least one contact section 14 can, for example, rest on this circuit board. Additionally or alternatively, the contact section 14 is designed and/or shaped in such a way that the reflector 3 can be guided and/or positioned to the lamp 2 with its aid. The reflector 3 also comprises at least one fastening section 15, which serves to fasten it to the heat sink 6. As an alternative to the embodiment shown, the contact section 14 can additionally or alternatively be designed to rest on the heat sink 6.

In the embodiment shown, the heat sink 6 comprises an adapter 19, in particular an adapter plate, with the aid of which the reflector 3 can be mounted, connected and/or fastened to the heat sink 6. Additionally or alternatively, the cooling effect and/or the heat conduction from the lamp 2 to the heat sink 6 can be influenced with the aid of the adapter 19, in particular the adapter plate. The reflector 3 can preferably be screwed to the heat sink 6 of the lamp 20 and/or the adapter 19 of the heat sink 6. In this way, the clamping force between the reflector 3 and the heat sink 6 can be set and/or adjusted. This makes it possible to adjust the clamping force acting on the lamp 2. For example, at least one screw (not shown) can be used for this. The screw can, for example, be arranged within the fastening section 15.

The fastening section 15 breaks through the reflector inner surface 11, in particular the reflection surface, and is arranged at least partially in the area of this. In the embodiment shown, the fastening section 15 is designed as a fastening pot and/or fastening embossing in which, for example, a screw can be positioned. The existing installation space of the optical unit 1 can thus also be used for fastening to the heat sink 6 of the lamp 20. The reduction in the effective reflector inner surface 11, in particular the reflection surface, and the resulting reduction in the reflection effect can be neglected. In addition or alternatively, it is conceivable that the fastening section 15 also has a reflection effect.

In the present embodiment of the 1 the first connecting section 7 comprises at least one connecting element 17. The at least one connecting element 17 preferably protrudes from the reflector inner surface 11 and/or projects into the interior 5. The first connecting section 7 can thus be connected to the corresponding second connecting section 8 in a form-fitting manner. The first connecting section 7 of the reflector 3 and the second connecting section 8 of the lens 4 provide a form-fitting and/or friction-fitting and/or separable connection, in particular a bayonet connection.

2 shows a schematic, perspective view of a lamp 20 with an optical unit 1 according to an alternative embodiment. In the embodiment of 2 In contrast to the embodiment of the 1 the lens 4 is connected to the reflector 3 and/or arranged in the interior 5 of the reflector 3.

According to 2 the reflector 3 comprises a third connecting section 9, which serves to attach a cover ring 13. In the embodiment shown, this third connecting section 9 is spaced apart from the contact section 14 of the reflector 3 along a light axis 16, which enables precise alignment of the components along the light axis 16. The reflector inner surface 11, in particular the reflection surface, of the reflector 3 extends between the contact section 14, the first connecting section 7 and the third connecting section 9, which ensures continuous reflection of the light along these sections.

The third connecting section 9 is already in the embodiment of the 1 As in the example of the 1 As shown, the third connecting section 9 of the reflector 3 can be designed as a connecting surface with outwardly projecting projections. The cover ring 13 can be attached using the projections. The third connecting section 9, which is at least partially designed as a connecting surface, can, as in the embodiment of the 2 or 3 indicated, flush with the light exit surface 18 of the lens 4.

In addition, it is advantageous that the third connecting section 9 of the reflector 3 (as shown in the present embodiment) in the intended use of the optical unit 1 with a fourth connecting section 10 of the cover ring 13 forms a positive and/or frictional and/or separable connection. This connection can in particular be designed as a bayonet connection, which enables quick and easy assembly and disassembly of the cover ring 13.

3 shows a schematic sectional view of a lamp 20 according to a further embodiment. The embodiment of the 3 clarifies the features already mentioned and described above. If individual features are not explained in detail again, their design and/or mode of operation corresponds to the design and mode of operation of the features with the same effect or the same name already described.

In the example, the 3 For example, the distance between the outer surface 12 of the lens 4 and the inner surface 11 of the reflector, in particular the reflection surface of the reflector 3, is shown. As can be seen, the outer surface 12 of the lens and the inner surface 11 of the reflector can be evenly spaced from one another, so that the most uniform reflection effect possible can be achieved.

Furthermore, in the embodiment of the 3 the fastening between the heat sink 6 and the reflector 3 is illustrated. For example, as shown, the reflector 3 can rest and/or be fastened to the heat sink 6 and/or to the adapter 19, in particular the adapter plate, via the at least one fastening section 15. By fastening the fastening section 15 to the heat sink 6 and/or the adapter 19, the lamp 2 is clamped between the contact section 14 of the reflector 3 and the heat sink 6 and/or the adapter 19 and is thereby held and/or positioned.

list of reference symbols

1

optical unit

2

lamp

3

reflector

4

lens

5

interior

6

heat sink

7

first connecting section

8

second connecting section

9

third connecting section

10

fourth connecting section

11

reflector inner surface

12

lens outer surface

13

aperture ring

14

investment section

15

fastening section

16

light axis

17

connecting element

18

light-emitting surface

19

adapter

20

light

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• DE 102009014526 A1 [0002]

Claims (16)

Optical unit (1) for a lamp (20), with a reflector (3) for reflecting and/or bundling light, and with a lens (4) for mixing and/or scattering light, characterized in that - when the optical unit (1) is used as intended, the lens (4) is at least partially, in particular completely, arranged in an interior (5) of the reflector (3) and/or protrudes into the interior (5), and/or - that the reflector (3) is designed such that both the lens (4) and a heat sink (6) of the lamp (20) can be connected to the reflector (3) in a force-fitting and/or form-fitting manner. Optical unit according to the preceding claim, characterized in that the reflector (3) comprises a first connecting section (7) for the lens (4), wherein the first connecting section (7) is preferably arranged in the interior (5) of the reflector (3). Optical unit according to one of the preceding claims, characterized in that the lens (4) comprises a second connecting section (8) designed to correspond to the first connecting section (7), wherein the reflector (3) and the lens (4) are connected to one another in the intended use of the optical unit (1) preferably via the first connecting section (7) and the second connecting section (8), in particular in a form-fitting and/or force-fitting and/or separable manner. Optical unit according to one of the preceding claims, characterized in that the reflector (3) comprises a, in particular conically and/or parabolically shaped, reflector inner surface (11), in particular a reflection surface, and/or the lens (4) comprises a, in particular conically and/or parabolically shaped, lens outer surface (12), wherein the reflector inner surface (11) and the lens outer surface (12) are preferably circumferentially and/or completely and/or evenly spaced from one another during the intended use of the optical unit (1). Optical unit according to one of the preceding claims, characterized in that the reflector inner surface (11), in particular reflection surface, comprises the first connecting section (7) and/or the first connecting section (7) adjoins the reflector inner surface (11). Optical unit according to one of the preceding claims, characterized in that the reflector (3) comprises at least one contact section (14) for contact with the heat sink (6) and/or with a lamp (2) of the luminaire (20), at least one fastening section (15) for fastening to the heat sink (6) and/or a third connecting section (9) for a cover ring (13). Optical unit according to one of the preceding claims, characterized in that the contact section (14) and the third connecting section (9) are spaced apart from one another along a light axis (16). Optical unit according to one of the preceding claims, characterized in that the reflector inner surface (11), in particular the reflection surface, connects the contact section (14) and/or the first connecting section (7) to the third connecting section (9). Optical unit according to one of the preceding claims, characterized in that the at least one fastening section (15) breaks through the reflector inner surface (11), in particular the reflection surface, and/or is arranged at least partially in the region of the reflector inner surface (11). Optical unit according to one of the preceding claims, characterized in that at least one connecting element (17) of the first connecting section (7) protrudes from the reflector inner surface (11), in particular the reflection surface, and/or projects into the interior space (5). Optical unit according to one of the preceding claims, characterized in that the third connecting section (9) of the reflector (3) and a light exit surface (18) of the lens (4) are flush along the light axis (16). Optical unit according to one of the preceding claims, characterized in that the reflector (3) can be screwed to the heat sink (6) of the lamp (20) and/or an adapter (19) of the heat sink (6), so that the clamping force between reflector (3) and/or heat sink (6) and/or adapter (19) and/or lamp (2) is adjustable and/or adaptable. Optical unit according to one of the preceding claims, characterized in that the first connecting section (7) of the reflector (3) with the second connecting section (8) of the lens (4) and/or the third connecting section (9) of the reflector (3) with a fourth connecting section (10) of the aperture ring (13) in the intended use of the optical unit (1) has a positive and/or frictional and/or separable connection, in particular a bayonet connection. Optical unit according to one of the preceding claims, characterized in that the reflector (3) is made of plastic, in particular polycarbonate, wherein the plastic preferably contains TiO2 additives. Luminaire (20), in particular track luminaire and/or track spotlight, characterized by an optical unit (1) according to the preceding claims. Reflector (3) for an optical unit (1), characterized in that the reflector (3) comprises at least one feature of the preceding claims relating to the reflector (3).

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