EP3366993A1 - Lamp with reflector element and reflector element - Google Patents

Abstract

A luminaire has a housing (1), light sources (2) for generating a light, a first reflector element (3) and a second reflector element (4) for influencing the light, wherein the reflector elements (3, 4 ) of the housing (1) are arranged and wherein the first reflector element (3) has a first side region (31) and the second reflector element (4) has a second side region (41) and the second side region (41) contacted the first side area (31). The first reflector element (3) further comprises on the first side region (31) a spring element (5), which rests under elastic tension on the second side region (41), such that thereby a passage of the light between the first side area (31) and the second side area (41) is prevented.

Description

The invention relates to a lamp with a reflector element, and a reflector element for a lamp.

From the prior art, a so-called light band system is known, are used in the elongated lights in a mounting rail. Such a lamp has a housing and arranged therein LED light sources (LED: light emitting diode) for generating a light, as well as reflector elements for influencing the light. In this case, the housing on the one hand and the reflector elements on the other hand consist of different materials, wherein the thermal expansion coefficient of the material of the housing differs from that of the material of the reflector elements. During operation, the luminaire is generally exposed to temperature fluctuations, for example due to current flow-induced heating of the LED light sources. This has the consequence that the housing and the reflector elements expand or contract differently in the longitudinal direction.

If the luminaire has a comparatively long length, such as 100 cm, 150 cm or 200 cm, it is fundamentally problematic to provide only a single corresponding reflector element which extends practically over the entire length of the lamp, because of the different Expansion behavior with corresponding temperature changes, it comes to unfavorable deviations of the intended geometric and optical association between the reflector element on the one hand and the housing mounted in the LED light sources on the other.

Therefore, it is advantageous from a certain length of the luminaire, if several reflector elements along the longitudinal axis are provided, because this way, corresponding undesirable shifts can in principle keep so small that they make virtually no noticeable in the light output behavior of the lamp. However, in this case, with temperature changes, it may happen that gaps form between the reflector elements through which undesired light escapes, which is generally regarded as undesirable. Also at the end portions of the lamp can lead to corresponding columns, for example, between the relevant end-side reflector element and an end cap of the Lamp. By manufacturing tolerances of the relevant components, which can reach quite 2 mm, this problem is exacerbated in practice.

The reflector elements can also not be designed so that they are joined together on impact, since in this case very high mechanical stresses would occur; It could also come with such a design to unwanted noise.

The invention has for its object to provide an improved lamp or an improved reflector element; In particular, it should thus be particularly advantageous to achieve that the probability of unwanted light leakage is reduced.

This object is achieved according to the invention with the object mentioned in the independent claim. Particular embodiments of the invention are indicated in the dependent claims.

According to the invention, a luminaire is provided, which has a housing and arranged in the housing light sources for generating a light. Furthermore, the luminaire has a first reflector element for influencing the light and a second reflector element for influencing the light, wherein said reflector elements are arranged surrounded by the housing. The first reflector element has a first side region and the second reflector element has a second side region. In this case, the second side area contacts the first side area. The first reflector element has on the first side region on a spring element which rests under elastic tension standing against the second side region, such that thereby a passage of the light between the first side region and the second side region is prevented.

By means of the spring element, a practically light-tight contacting of the two side areas can be achieved in a particularly simple and efficient manner.

Preferably, the first reflector element further comprises a frame portion, through which an opening for the passage of the light is formed, wherein the spring element is arranged behind the frame area. This makes it possible that, when viewing the lamp from the outside, the appearance of the frame area is independent of temperature.

Preferably, the first side region extends along a transverse direction, the spring element having a substantially C-shaped cross-section normal to the transverse direction. By this shape, particularly advantageous elastic properties of the spring element can be achieved, in particular a comparatively long spring travel.

Preferably, the housing made of metal and the first reflector element made of a plastic, in particular polycarbonate. In this choice of material, the spring element is particularly advantageous.

Preferably, the lamp is elongated so that it extends along a longitudinal axis, wherein the first reflector element and the second reflector element along the longitudinal axis are arranged one behind the other. In such a case, the temperature fluctuation-caused different changes in length are generally particularly noticeable, so that the solution according to the invention is particularly suitable. For example, viewed along the longitudinal axis, the luminaire may have a length of at least 100 cm.

Preferably, the spring element is designed such that an elastic spring travel of the spring element is at least 1 mm, in particular at least 2 mm. As a result, the spring element is particularly suitable in the case of the usual dimensions of the lamp.

In terms of manufacturing technology, the first reflector element is configured in one piece, in particular in the form of an injection-molded part. This is also advantageous with respect to the assembly of the lamp.

Preferably, the second reflector element on another spring element which rests under elastic tension standing against the spring element of the first reflector element. This is advantageous with respect to achieving a corresponding light-tight contacting of the two spring elements. In this case, the spring element of the first reflector element and the spring element of the second reflector element are advantageously designed symmetrically.

According to a further aspect of the invention, a reflector element is provided for a luminaire, wherein the reflector element has a frame region, through which an opening for the passage of light is formed. Furthermore, the reflector element has a side region for abutment with another component of the luminaire, in particular a further reflector element or a housing or an end cap of the luminaire. In this case, the side region has a spring element for an abutment against the further component of the luminaire, which serves to prevent passage of light between the side region and the further component of the luminaire.

Preferably, the side portion extends along a transverse direction, the spring member having a substantially C-shaped cross section normal to the transverse direction. Further preferably, the spring element is designed such that an elastic spring travel of the spring element is at least 1 mm, preferably at least 2 mm.

Preferably, the reflector element consists of a plastic, in particular polycarbonate. Due to the elastic properties of the material polycarbonate, this material is particularly well suited for the production of the reflector element, in particular of the spring element. Preferably, the reflector element is designed in one piece, in particular in the form of an injection-molded part.

Fig. 1

eine Skizze eines Abschnitts einer anmeldungsgemäßen Leuchte,

Fig. 2

eine Skizze eines Endbereichs der Leuchte,

Fig. 3

eine Längsschnitt-Skizze eines Kontaktierungsbereichs zweier aneinandergrenzender Reflektor-Elemente der Leuchte,

Fig. 4

einen Längsschnitt des ersten Seitenbereichs im separierten Zustand des ersten Reflektor-Elements,

Fig. 5a

eine, der Fig. 3 entsprechende Skizze bei einem ersten Abstand zwischen den beiden Rahmenbereichen der Reflektor-Elemente und

Fig. 5b

eine, der Fig. 3 entsprechende Skizze bei einem zweiten, größeren Abstand zwischen den beiden Rahmenbereichen der Reflektor-Elemente.

The invention is explained in more detail below with reference to exemplary embodiments and with reference to the drawings. Show it:

Fig. 1

a sketch of a section of a lamp according to the application,

Fig. 2

a sketch of an end area of the luminaire,

Fig. 3

3 is a longitudinal sectional sketch of a contacting region of two adjoining reflector elements of the luminaire,

Fig. 4

a longitudinal section of the first side region in the separated state of the first reflector element,

Fig. 5a

one of the Fig. 3 corresponding sketch at a first distance between the two frame portions of the reflector elements and

Fig. 5b

one of the Fig. 3 corresponding sketch at a second, larger distance between the two frame portions of the reflector elements.

Fig. 1 shows a perspective sketch of an embodiment of a lamp according to the application. The luminaire is elongated in the example shown, so that it extends along a longitudinal axis L. In Fig. 1 a middle section of the lamp is shown. The luminaire may be designed, for example, as part of a lighting system in which along the longitudinal axis L a long mounting rail is provided, in which the lamp can be used, the support rail is longer than the lamp, so that several corresponding lights are used in the mounting rail can.

The length of the luminaire viewed along the longitudinal axis L can be at least 100 cm, for example 100 cm, 150 cm or 200 cm. With such a length, there are generally comparatively large changes in length with temperature fluctuations.

In Fig. 2 an end area of the luminaire is sketched. The luminaire has a, for example made of sheet metal housing 1, and light sources 2 for generating a light; the light sources 2 are arranged in the housing 1, as exemplified in FIG Fig. 2 indicated by dashed lines. The light sources 2 are preferably LED light sources. The LED light sources can each consist of one LED or of several LEDs, so to speak of a "LED cluster"; Preferably, the LED light sources are arranged equidistantly in a row along the longitudinal axis L. Preferably, the LED light sources are each assigned a lens-like appearance.

In particular, the design is such that the light is emitted from the luminaire in a main emission direction R, which preferably extends at right angles to the longitudinal axis L.

As in the example shown, the housing 1 preferably has a first housing wall 11 and a second housing wall 12, wherein these two housing walls 11, 12 each extend parallel to the longitudinal axis L. The light output of the lamp takes place between the two housing walls 11, 12. The housing 1 may be designed as a profile part, wherein the profile axis parallel to the longitudinal axis L. extends, so that the two housing walls 11, 12 are components of the profile part, wherein at one end - as in Fig. 2 outlined - an end cap 13 is provided.

Furthermore, the lamp has a first reflector element 3, which serves to influence the light and a second reflector element 4, which also serves to influence the light. The two reflector elements 3, 4 are arranged one behind the other along the longitudinal axis L in the example shown.

The reflector elements 3, 4 are arranged downstream of the light sources 2 along the main emission direction R. In other words, the reflector elements 3, 4 are arranged between the light sources 2 on the one hand and an outer space of the luminaire on the other hand. Thus, in the case of the reflector elements 3, 4, a visible or outer side facing the outer space can be distinguished from an inner side facing the light sources 2.

The first reflector element 3 preferably has at least one opening 6 for an exit of the light, for example in the form of a square or rectangular opening. In particular, the first reflector element 3 may have a plurality of corresponding openings which form a row along the longitudinal axis L. In this case, for example, exactly one of the openings may be provided for each of the LED light sources. The same applies with respect to the second reflector element. 4

The two reflector elements 3, 4 are each designed as a component; In particular, they are not materially interconnected. The two reflector elements 3, 4 can be designed identical.

The aforementioned reflector elements 3, 4 are arranged surrounded by the housing 1. In the example shown, the housing 1 comprises the two reflector elements 3, 4 on the two longitudinal sides of the luminaire, specifically between the first housing wall 11 and the second housing wall 12.

The two reflector elements 3, 4 are arranged in the example shown, as mentioned, along the longitudinal axis L one behind the other; they thus form a row along the longitudinal axis L. In general, more than two corresponding reflector elements may be provided, which together form a row along the longitudinal axis L. At the end region, the respective end reflector element can be the end cap 13 contact. To keep deviations in the geometrical or optical association between the reflector elements 3, 4 on the one hand and the light sources 2 on the other hand with temperature fluctuations as low as possible, it is desirable that the distances between the reflector elements 3, 4 as uniformly as possible with a change in temperature change. This can be achieved particularly advantageously with the lamp according to the application.

The first reflector element 3 has a first side region 31 and the second reflector element 4 a second side region 41. The second side region 41 contacts the first side region 31. In other words, the two mentioned reflector elements 3, 4 abut with the mentioned side areas 31,41 together.

In Fig. 3 is a section along the longitudinal axis L outlined in which the two reflector elements 3, 4 - here separated from other components of the lamp - are shown in their contacting area. The first reflector element 3 has on the first side region 31 a spring element 5, which rests under elastic tension against the second side region 41, in such a way that thereby a passage of the light between the first side region 31 and the second side region 41 is prevented. The spring element 5 is preferably a particularly flexible section of the first reflector element 3.

In the case of a temperature decrease - for example, after switching off the light sources 2 - it is generally the case that the housing 1 contracts to a different extent, for example, less than the reflector elements 3, 4. By the spring element 5 can be achieved in that in such a case no gap arises between the two reflector elements 3, 4, through which light could undesirably escape. The spring element 5 therefore represents, so to speak, a "compensating element".

As in the example shown, the first reflector element 3 can have a frame region 32, through which the opening 6 is formed for the passage of the light. The frame portion 32 forms, so to speak, a kind of reflector pot. In this case, the design is preferably such that the spring element 5 is disposed behind the frame area 32. In this case, the design is furthermore preferably such that the spring element 5 engages behind the frame region 32 on the inside. So can be achieved that - in the case of a corresponding Temperature change - the appearance of the frame portion 32 as such viewed from the outside by the spring element 5 is not changed.

How out Fig. 3 it can be seen, by the frame portion 32, a flange 33 may be formed on which the spring element 5 with a leg 51 rests on the inside.

Preferably, the design is such that the first side region 31 extends along a transverse direction Q, which is oriented in particular at right angles to the longitudinal axis L and preferably also at right angles to the main emission direction R. The sectional view of FIG Fig. 3 shows accordingly a section normal to the transverse direction Q. Preferably, the first side portion 31 extends on the one hand to the first housing wall 11 and on the other hand to the second housing wall 12, in particular straight along the transverse direction Q. Also, the second side portion 41 preferably extends on the one hand up to the first housing wall 11 and on the other hand up to the second housing wall 12, in particular straight along the transverse direction Q. In this case, a passage of the light over the entire extension between the two side regions 31, 41 is prevented by the spring element 5. It thus occurs along the contact region of the two reflector elements 3, 4 no light from the lamp in the outer space.

In Fig. 4 is the side portion 31 of the first reflector element 3 in section parallel to the longitudinal axis L and normal to the transverse direction Q sketched, wherein the first reflector element 3 is shown separated from the rest of the lamp. The spring element 5 preferably has normal to the transverse direction Q considered - ie according to the representations in the Figures 3 and 4 - Essentially a C-shaped cross section. In this way it can be achieved that the leg 51 of the spring element 5 - in the separated state of the first reflector element 5 - particularly suitable from a, in Fig. 4 shown, relaxed rest position out elastically deflect, in the direction of the frame member 32, as in Fig. 4 indicated by an arrow.

Preferably, the spring element 5 is designed profile-like, with the profile axis extending parallel to the transverse direction Q. In this case, a first end 55 of the C-shaped cross-section to the frame member 32 and the other end of the C-shaped cross section is formed by the leg 51. The leg 51 points to the frame element 32. The first end 55 may be fastened, for example, to the frame element 32 or to the reflector pot.

The design of the spring element 5 is preferably such that an elastic spring travel of the spring element 5 is at least 1 mm, in particular at least 2 mm. In this way, the first reflector element 3 is particularly suitable for a luminaire, in particular if the luminaire is designed as part of a continuous band system. As mentioned in the beginning, component tolerances can easily reach 2 mm and changes in length caused by temperature changes can be expected in the order of about 0.3 mm.

The housing 1 of the lamp is preferably made of a metal, for example as mentioned from a metal sheet. The first reflector element 3 is preferably made of a plastic, in particular of polycarbonate. By means of this material, particularly suitable elastic properties of the spring element 5 can be achieved. The properties of the material polycarbonate can be achieved that the spring element 5 can not break practically. The second reflector element 4 is preferably made of a plastic, in particular of polycarbonate.

Manufacturing technology advantageous is the first reflector element 3 designed as consisting of one piece. For example, it can be designed as an injection-molded part. The same again applies to the second reflector element 4.

As in the example shown, the case, the second reflector element 4 on another spring element 7, which rests under elastic tension standing against the spring element 5 of the first reflector element 3. In this case, the spring element 5 of the first reflector element 3 and the spring element 7 of the second reflector element 4 are preferably designed symmetrically, in particular mirror-symmetrical.

As already mentioned, the two reflector elements 3, 4 can be designed to be identical. Thus, the second reflector element 4 may in particular have a corresponding frame region 42, on which the further spring element 7 is arranged.

The FIGS. 5a and 5b show - analogous to the representation from Fig. 3 - Two cases in which the two reflector elements 3, 4 are arranged relative to each other so that their two frame portions 32, 42 are far different from each other. In Fig. 5a a case is shown in which between the two frame portions 32, 42 viewed along the longitudinal axis L, the distance δ1, in Fig. 5b a case where the distance δ2 is larger than the distance δ1. These two cases are by way of example for two relative arrangements of the two frame regions 32, 42 in the case of the assembled luminaire at two different temperatures. For example, shows Fig. 5a the situation at an operating temperature of the luminaire and Fig. 5b the situation when the lamp is cooled after switching off the light sources 2.

If - as in Fig. 5b sketched - the two frame portions 32, 42 are further apart, a light-tight contact between the two side regions 31, 41 is still given due to the design according to the application. In particular, the two spring elements 5, 7 contacted over the entire distance between the two housing walls 11, 12, since they press elastically against each other.

In particular, if more than two reflector elements are provided in the row along the longitudinal axis L, it is advantageous to provide the reflector elements at both longitudinal end regions or end faces with a corresponding spring element. The two end regions can advantageously be formed or designed to be particularly mirror-symmetrical in terms of manufacturing technology. In this way it is possible to achieve that the distances between the reflector elements remain practically identical in the case of temperature changes.

The spring element 5 is not only advantageous when the first reflector element 3 contacts the second reflector element 5, but also when the first reflector element contacts the end cap 13 of the housing 1. In other words, the described design is also suitable for achieving a light-tight contacting between a corresponding reflector element arranged at the end in the row of the reflector elements and the relevant end cap 13.

More generally, a corresponding side region 31 of a reflector element 3 serves to bear against a further component of the luminaire, in particular to a further reflector element or a housing or an end cap of the luminaire.

In the described example, it can be provided that the spring elements according to the application are provided only on the two aforementioned end faces, that is to say the two longitudinal end regions of the reflector elements. However, it is generally also possible to provide corresponding spring elements also on the two longitudinal edge regions of the reflector elements. This can For example, be advantageous if the reflector elements are not only arranged along the longitudinal axis L arranged one behind the other, but also in the transverse direction thereto, ie in the case of a rather "flat" light.

With the lamp according to the application, an undesirable light emission between the reflector elements can be avoided in a cost-effective manner. Advantageously for the production of the lamp, all the reflector elements of the lamp can be made identical. In addition, in this way - compared to a case in which different components must be arranged in the length of the housing of the luminaire - a likelihood of confusion when assembling the lamp is reduced.

Claims (15)

Having light a housing (1), - In the housing (1) arranged light sources (2) for generating a light, - A first reflector element (3) for influencing the light and a second reflector element (4) for influencing the light, wherein said reflector elements (3, 4) are arranged by the housing (1), and
wherein the first reflector element (3) has a first side region (31) and the second reflector element (4) has a second side region (41) and the second side region (41) contacts the first side region (31),
characterized,
in that the first reflector element (3) has on the first side region (31) a spring element (5) which bears under elastic tension against the second side region (41), such that a passage of the light between the first side region (31) Side area (31) and the second side area (41) is prevented. Luminaire according to claim 1,
characterized,
that the first reflector element (3) further comprises a frame portion (32) through an opening (6) is formed for the passage of light, wherein the spring element (5) is arranged to the frame portion (32) engaging behind. Luminaire according to claim 1 or 2,
characterized,
in that the first side region (31) extends along a transverse direction (Q) and the spring element (5) has a substantially C-shaped cross-section viewed normal to the transverse direction (Q). Luminaire according to one of the preceding claims,
characterized,
that the housing (1) consists of metal and the first reflector element (3) consists of a plastic, in particular polycarbonate. Luminaire according to one of the preceding claims,
characterized,
that the lamp is elongated so that it extends along a longitudinal axis (L), wherein the first reflector element (3) and the second reflector element (4) along the longitudinal axis (L) are arranged one behind the other. Luminaire according to claim 5,
characterized,
that the light along the longitudinal axis (L) is considered a minimum length of 100 cm. Luminaire according to one of the preceding claims,
characterized,
that the spring element (5) is designed such that an elastic spring travel of the spring element (5) is at least 1 mm, preferably at least 2 mm. Luminaire according to one of the preceding claims,
characterized,
that the first reflector element (3) is formed consisting of one piece, preferably in the form of an injection molded part. Luminaire according to one of the preceding claims,
characterized
in that the second reflector element (4) has a further spring element (7) which bears under elastic tension against the spring element (5) of the first reflector element (3). Luminaire according to claim 9,
characterized,
that the spring element (5) are shaped symmetrically of the first reflector element (3) and the spring element (7) of the second reflector element (4). Reflector element (3) for a luminaire, comprising a frame region (32) through which an opening (6) for the passage of light is formed, - One side region (31) for contact with another component of the lamp, in particular a further reflector element (4) or a housing or a End cap (14) of the luminaire, characterized,
in that the side region (31) has a spring element (5) for engagement with the further component of the luminaire, which serves to prevent the passage of light between the side region (31) and the further component of the luminaire. Reflector element according to claim 11,
characterized,
in that the side portion (31) extends along a transverse direction (Q) and the spring element (5) has a substantially C-shaped cross section normal to the transverse direction (Q). Reflector element according to claim 11 or 12,
characterized,
that the spring element (5) is designed such that an elastic spring travel of the spring element (5) is at least 1 mm, preferably at least 2 mm. Reflector element according to one of claims 11 to 13,
characterized,
that the reflector element (3) consists of a plastic, in particular of polycarbonate. Reflector element according to one of claims 11 to 14,
characterized,
that the reflector element (3) is formed consisting of one piece, preferably in the form of an injection molded part.

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