EP3249292A1 - Lamp with air guidance surfaces - Google Patents

Abstract

The invention relates to a luminaire having a light source (2) with a plurality of light emitting elements (3), in particular in the form of LEDs. On a first side (re) next to the light source (2), the luminaire has first through openings (5) and on a second side (li) next to the light source (2) second through openings (7). The passage openings (5, 7) are designed for an air flow for cooling the light source (2). Furthermore, the light on the first side (re) next to the first passage openings (5) and below the light source (2) has a first air guide surface (6) and on the second side (li) next to the second through holes (7) and thereby below the light source (2) has a second air guide surface (8), wherein the two air guide surfaces (6, 8) are designed such that through them, from the light source (2) extending away Luftanströmbereich (A) is formed. This makes it possible to direct air in a particularly targeted manner to the passage openings (5, 7). In this way, a flow through the through holes (5, 7) is forced and thus a particularly effective heat release from the surfaces of the through holes (5, 7) allows to the environment.

Description

The invention relates to a luminaire with a light source and formed next to the light source passage openings for an air flow for cooling the light source.

By light emitting elements, such as light bulbs, fluorescent tubes, LEDs (LED: light emitting diode) u. s. w. Heat is generally generated in the form of heat loss when in a state of emitting light. In particular, if a light source of a luminaire has light-emitting elements as LEDs, care must be taken for reliable operation of the luminaire to ensure that this heat is effectively removed. Otherwise, it may, for example, come to a damage of the LEDs and / or unintentionally changed emission behavior of the LEDs.

For corresponding cooling of LEDs heatsinks are usually used, which are thermally well connected to the LEDs. An LED downlight with such a heat sink is for example from the Scriptures DE 10 2010 002 235 A1 known. The heat sink of this downlight has vertically designed cooling fins, through which the surface of the heat sink is particularly large and thus a particularly good heat emission to the environment is possible. The cooling fins extend laterally next to the LEDs, so that air can flow alongside the LEDs along the cooling fins, whereby the heat output is forced from the cooling fins to the environment.

A very effective heat dissipation is particularly important if the lamp has a very powerful light source. This is typically the case with lights that are designed to illuminate large rooms or halls, such as so-called "Highbay lights". The latter are intended to be hung at high altitude, for example, about 12 m above the floor of a hall. There are corresponding luminaires that generate a luminous flux output of more than 10,000 lm.

The invention has for its object to provide a corresponding improved luminaire. In particular, the luminaire should be able to save material and be distinguished by an improved thermal behavior.

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 light source with a plurality of light-emitting elements, the luminaire having first passage openings on a first side next to the light source and having second passage openings on a second side next to the light source. In this case, the first and the second passage openings are designed for an air flow for cooling the light source. Furthermore, the luminaire on the first side next to the first passage openings and below the light source on a first air duct and on the second side next to the second passage openings and below the light source, a second air duct, wherein the two air ducts are designed such that through them a, from the light source away widening Luftanströmbereich is formed.

By the Luftanströmbereich formed by the two air guide can cause air is directed specifically targeted to the through holes. In this way, a flow through the through holes is forced and thus allows a particularly intense heat transfer from the surfaces of the through holes to the environment. In this way, a particularly effective cooling of the light source is achieved.

Preferably, the luminaire is configured such that the first air guide surface directly adjoins the first through openings and / or the second air guide surface directly adjoins the second through openings. As a result, it can be achieved that air is directed in a particularly targeted manner through the air guide surfaces to the corresponding through openings.

Preferably, the first air guide surface is at least to a first approximation plan or curved and in particular has a first surface normal, which includes a vertical angle at a first angle which is between 20 ° and 85 °, preferably between 30 ° and 70 °, particularly preferably between 35 ° and 60 °. This allows a particularly effective air line. Furthermore, the second air-guiding surface is also preferably planar or arched, and in particular has a second surface normal, which includes a second angle with the vertical, which is between 20 ° and 85 °, preferably between 30 ° and 70 °, more preferably between 35 ° and 60 °. This also makes a particularly effective air line possible.

A particularly good heat conduction and thereby simple design is made possible if the first passage openings and / or the first air guide surface are designed as parts of a heat sink.

In this case, the cooling body preferably has vertically extending cooling ribs, in particular on a side opposite the first air guiding surface. In this case, if the heat sink is designed such that only connecting areas are formed between the cooling fins whose surfaces are inclined at least 30 °, preferably at least 40 ° relative to the horizontal, a possible deposition of dust or the like during operation of the lamp can effectively reduce.

The first air guide surface and / or the second air guide surface are advantageously designed to be reflective, preferably white, in particular white lacquered. As a result, they can act as a reflector for a light emitted by the light source. In particular, this makes it possible to influence or limit a radiation area of the luminaire.

Preferably, the second air guide surface is formed by an outer surface of a housing, wherein preferably the housing is designed for mounting a control gear of the lamp. As a result, the lamp can be particularly material-saving and thereby make thermally advantageous. Thermally advantageous, the lamp is further preferably designed such that the housing has an interior whose vertical projection extends outside the vertical projection of the light source.

Thermally and manufacturing technology advantageous, the housing is designed profile-shaped.

A particularly suitable thermal separation between the housing or the operating device therein on the one hand and the light source on the other hand can be achieved if the housing is connected to the heat sink only supported mechanically via a screw.

Preferably, the lamp also has a further light source, which is arranged on the second side next to the housing, wherein the further light source is preferably designed analog or identical to the first-mentioned light source. In this case, the lamp further preferably has a further cooling body for cooling the further light source, which is arranged on the second side next to the housing, wherein the further heat sink is preferably designed analog or identical to the first-mentioned heat sink.

A particularly powerful and technically advantageous light can be achieved if the luminaire is designed symmetrically with respect to a vertical plane of symmetry. The plane of symmetry preferably passes through the housing.

Fig. 1

eine perspektivische Skizze einer erfindungsgemäßen Leuchte von schräg unten,

Fig. 2

eine entsprechende Skizze von schräg oben,

Fig. 3

eine Ansicht von unten,

Fig. 4

eine Querschnitt-Skizze und

Fig. 5

eine Skizze nach Art einer Explosionsdarstellung zu Aufbau und Halterung der Lichtquelle am Kühlkörper.

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

Fig. 1

a perspective sketch of a lamp according to the invention obliquely from below,

Fig. 2

a corresponding sketch from diagonally above,

Fig. 3

a view from below,

Fig. 4

a cross-sectional sketch and

Fig. 5

a sketch in the manner of an exploded view to build and support the light source on the heat sink.

In Fig. 1 an embodiment of a lamp according to the invention is sketched from below obliquely. The luminaire shown here is a so-called "Highbay luminaire", ie an interior luminaire that is intended to illuminate large rooms or halls and is correspondingly powerful. In the example shown, the luminaire is a pendant luminaire designed to be suspended from a ceiling suspended from a pendulum or a similar suspension element. Accordingly, the luminaire is designed to be so arranged in a room for operation that it is surrounded on all sides by room air.

The luminaire has a light source 2 with a plurality of light-emitting elements 3 in the form of LEDs. The LEDs are preferably arranged on an LED board 25.

In Fig. 3 is a view of the light sketched from below. The light source 2 is made oblong in the example shown, so that it extends along a longitudinal axis L.

The LEDs of the light source 2 are arranged in a field or matrix manner. In particular, the light source 2 may comprise a plurality of LEDs, preferably more than 30 LEDs, more preferably more than 50 LEDs. As a result, a correspondingly large luminous flux can be generated with the luminaire.

The LEDs extend over a horizontal LED area which has a length l in the direction of the longitudinal axis L and a width b transverse thereto . The ratio of 1: b can be, for example, between 4: 1 and 20: 1 , more preferably between 5: 1 and 15: 1.

With reference to the light source 2 and the longitudinal axis L horizontally on a first side re , here right next to the light source 2, the lamp first through openings 5 and on a second side li , here to the left of the Light source 2 second through holes 7. In particular, while the second side li of the first page re exactly opposite.

The first and the second passage openings 5, 7 are designed for an air flow for cooling the light source 2. The first and second through holes 5, 7 may be formed by slots. The first and the second passage openings 5, 7 are preferably designed as nozzles, which cause an increase in the velocity of a flowing air. This makes it possible to enhance the cooling effect.

Preferably, the design is such that the first passage openings 5 extend parallel to the longitudinal axis L and preferably extend over the entire length l of the LED area. In the example shown, the first passage openings 5 are formed in a row, that is to say in a single row.

Further preferably, the first passage openings 5 are formed almost directly next to the light source 2; For example, it can be provided that a distance d transverse to the longitudinal axis L between the LEDs and the first passage openings 5 is smaller than the width b of the LED area.

The first passage openings 5 are in particular designed such that an air can flow from bottom to top through them. Preferably, the first through-openings 5 are designed such that they are closed on all sides viewed in a horizontal cross-section. In this case, the design is furthermore preferably such that - viewed in the horizontal cross section - for each of the first passage openings 5, an inner diameter e transverse to the longitudinal axis L is smaller than the width b of the LED area. The cross-sectional shape of the first Durchgangsöffnunen 5 may be circular or rectangular in first approximation, in particular, the ratio of an inner diameter f in the direction of the longitudinal axis L to the inner diameter e , ie transversely thereto, between 0.3 and 3, more preferably between 0, 5 and 2 is.

Also, the second passage openings 7 preferably extend parallel to the longitudinal axis L and thereby almost directly next to the light source 2; for example can - analogously to above - be provided that a further distance d ' transverse to the longitudinal axis L between the LEDs and the second through holes 7 is smaller than the width b of the LED area.

In Fig. 2 is a perspective view of the lamp diagonally outlined above, in Fig. 4 a cross section normal to the longitudinal axis L. As in Fig. 4 indicated and already mentioned above, the LEDs or the LED area are preferably arranged in a horizontal plane E.

The light further has on the first side re or right next to the first passage openings 5 and below the light source 2 and the plane E a first air guide surface 6 and on the second side li or left next to the second through holes 7 and also below the light source 2 or the second air guide plane e a 8. the two air guide surfaces 6, 8 are configured such that through them is formed a a Luftanströmbereich which widens from the light source 2 away. In particular, the two air guide surfaces 6, 8 may be configured such that they diverge in a direction away from the light source 2, in particular downwards. The Luftanströmbereich A , which is formed by the two air guide surfaces 6, 8 is - viewed in particular in a cross section normal to the longitudinal axis L - funnel-shaped, wherein it narrows upwards to the light source 2 out.

By the two air guide surfaces 6, 8 can be achieved that air, which enters from below into the Luftanströmbereich A, is directed to the first and second through holes 5, 7. A heat transfer from the inner walls of the through holes 5, 7 to the environment is thereby significantly forced.

In the example shown, the two air guide surfaces 6, 8 are designed profile-shaped, wherein they each extend parallel to the longitudinal axis L. As in Fig. 3 by way of example, the first air guiding surface 8 preferably has a longitudinal extent λ in the direction of the longitudinal axis L which is at least half as large as the length 1 of the LED area; Preferably, the longitudinal extent λ is at least three-quarters of the length l . How out Fig. 3 In the example shown, λ > 1 applies. For the corresponding longitudinal extent of the second air duct 8 analogous applies.

The first air guide surface 6 preferably has an area size that is at least as large as half the area size of the LED area, particularly preferably at least as large as the area size of the LED area. The same applies to the area size of the second air guide 8.

As shown in FIG. 6, the first air guide surface 6 extends downward to a level which is a height difference Δh below the plane E , and it is preferable that this height difference Δh is at least half the width b of the plane LED area, so .DELTA.h> 0.5 b. Preferably, Δh> 0.9 b . The same applies in turn to the second air guiding surface 8.

In the example shown, the design is such that the first air guiding surface 6 directly adjoins the first through openings 5. As a result, the air is passed directly to the first passage openings 5. The same applies to the second air guide surface 8 and the second through holes 7.

The first air guiding surface 6 is preferably flat or arched, in particular concave, at least in the first approximation, having a first surface normal N1 , which encloses a first angle α with a vertical V , which is between 20 ° and 85 °. Preferably, the first angle α is between 30 ° and 70 °, in the example shown about 45 °. The same applies in turn with reference to the second air guide surface 8, which accordingly has a second surface normal N2 , which includes a second, correspondingly large angle β with the vertical V.

A particularly simple design can be achieved if the first passage openings 5 are designed as parts of a heat sink 4, wherein the heat sink 4 is designed in particular for cooling the light source 2. The heat sink 4 is - as known from the prior art - good heat conducting connected to the light source 2.

In Fig. 5 a sketch is shown in the manner of an exploded view, which represents a slightly modified version. As can be seen by way of example from this figure, FIG the heat sink 4 is preferably a horizontal, planar, downwardly facing surface 49, on which the light source 2 and the LED board 25 is arranged.

Optically following the LEDs, an optical element 27 for influencing a light emitted by the LEDs can be provided and / or a light-permeable cover element for protecting the LEDs. The optical element 27 and the cover are preferably designed so that they extend to the first side re maximum up to the first through holes 5 out and to the second side li towards maximum up to the second through holes 7th

For the mechanical mounting of the LED board 25 and optionally of the optical element 27 or of the cover, a holding element 29 is preferably provided, which holds the said components from below encompassing. Preferably, the holding element 29 has latching elements 28, which are designed for mechanical connection to the heat sink 4.

In the example shown, the first air guiding surface 6 is also advantageously formed by the cooling body 4. The heat sink 4 is preferably made of one piece, so it is preferably in one piece. For example, it is made of aluminum.

Furthermore, the heat sink 4 advantageously - in Fig. 4 exemplified - cooling ribs 41, in particular on one, the first air duct 6 opposite side, ie on the first side re or right of the first air duct 6. This can be achieved to save material that between the cooling fins 41 through the heat sink 4 only connecting areas are formed with surfaces 42 which are inclined relative to the horizontal, preferably at least 30 °, more preferably at least 40 ° inclined. In the example shown, the surfaces 42 to the right of the first air guide surface 6 are inclined approximately as much as the first air guide surface 6, that is to say approximately 45 °, particularly in terms of material saving. By means of correspondingly inclined surfaces 42, a deposit of dust, dirt, etc. can be reduced particularly effectively during operation of the luminaire-in comparison to a corresponding horizontal surface design.

The cooling fins 41 are formed in the example shown parallel to each other, in particular in planes which are oriented normal to the direction of the longitudinal axis L.

Advantageously, the heat sink 4 also has further, in particular vertical cooling ribs 43, which are designed such that they are formed on the first side re or right and on the second side li or left above the light source 2 also protruding. A protruding at the second side li region 44 of the further cooling fins 43 may be designed for forming the second through-holes 7, one on the first side re projecting portion for forming the first through-holes 5. As the first-mentioned cooling fins 41, and the other cooling ribs 41 in the example shown formed parallel to each other, in particular in planes that are normal to the direction of the longitudinal axis L oriented.

Preferably, the first air guiding surface 6 is designed to be reflective, for example white, in particular white lacquered. In this way, the light output of the lamp can be favorably influenced. The inclination of the first air guide 6 in dependence - - in particular can be a lateral boundary of the light output to the first page re cause out. The same applies with respect to the second air guide surface 8 on the second side li. In other words, this makes it possible to define an angular range in which light is emitted by the luminaire.

By a correspondingly white design of the two air guide surfaces 6, 8 is also achieved that the light when viewed from below shows a relatively large, brightly luminous surface over which light is emitted.

Preferably, the second air guide surface 8 is formed by an outer surface of a housing 9. The housing 9 can in particular be designed for mounting an operating device 10, for example in the form of a converter of the luminaire. In this way, it can be advantageously achieved that the operating device 10 is arranged laterally next to the light source 2, here on the second side li next to the light source 2. This is advantageous because the operating device 10 thereby arranged quasi thermally separated from the light source 2 leaves. In particular, the design may be such that the operating device 10 is arranged outside the vertical projection of the light source 2, particularly preferably outside the vertical projection of the heat sink 4.

For this purpose, the housing 9 can have an interior 19 whose vertical projection runs outside the projection of the light source 2.

A good thermal separation between the operating device 10 and the light source 2 is important because an operating device is generally relatively sensitive to high temperatures.

The thermal separation between the light source 2 and the operating device 10 is further promoted in the example shown that the heat sink 4 is mechanically supported with the housing 9 only connected via a quasi-point-acting connection 11, for example, a screw. For example, only two of these can be used - by way of example in FIG Fig. 2 shown screws 12 may be provided. For this purpose, the housing 10 preferably has a, to the first page preceding re toward flange 14, to which the connection 11 is formed, whereby the flange portion 14 outside the vertical projection of the operating device 10 and the inner space 19 is located.

The above on the second side li region 44 of the further cooling fins 43 of the heat sink 4 is for this purpose preferably designed such that they - at the level of the light source 2 - does not extend all the way to the housing 10 toward, but the latter is at a distance h, which is preferably between 1 mm and 10 mm. The second through holes 7 can thus be designed on the one hand by the heat sink 4, more precisely by the other cooling fins 43 on the one hand and the housing 9 on the other hand.

The flange region 14 or the connection 11 is preferably formed at a level above the plane E , in particular above the light source 2. In this case, the heat sink 4 is advantageously shaped such that it has on the second side li an upwardly projecting portion 45, at the upper end of the compound 11 is formed.

Fluidically advantageous, the heat sink 4 also on the first side re another, projecting towards the top portion 46, through which in particular an upper end portion of the first passage openings 5 may be formed. An upper end region of the first-mentioned cooling ribs 41 can also be formed by the further, upwardly projecting region 46.

In the example shown, the heat sink 4 has a profile-shaped portion 48, which extends along the longitudinal axis L and - viewed in a cross section normal to the longitudinal axis L - has two legs, namely a lower leg 48 'and an upper leg 48 "; through the lower leg 48 ', the first air guide surface 6 is formed.The upper leg 48 "extends - in particular vertically formed - upwards and forms the highest point of the further upwardly projecting portion 46 of the heat sink 4. This is in particular a fluidic advantageous embodiment of the first passage openings 5 achieved.

The housing 9 is advantageously designed as a profile part which extends parallel to the longitudinal axis L. This allows a particularly simple production of the housing 9. In addition, it can be achieved in this design that can simply insert the operating device 10 in the direction of the longitudinal axis L in the housing 9 for installation of the operating device 10 in the housing 9.

A particularly powerful lamp can be achieved if on the second side li or left of the housing 9, a further light source 2 'is provided, preferably at the same level as the first-mentioned light source 2. In particular, the further light source 2' analog or be designed identical to the first-mentioned light source 2. Accordingly, furthermore, the luminaire for cooling the further light source 2 'has a further heat sink 4', which is preferably designed analogously or structurally identical to the, first mentioned, heat sink 4.

Particularly preferably, the lamp is designed symmetrically to a vertical plane of symmetry S , which in particular runs parallel to the longitudinal axis L and thereby through the housing 9.

The luminaire can therefore be constructed, so to speak, modular, wherein a central module comprises the housing 9 with the operating device 10 and on both sides re , li next to the central module each have an LED module with associated heat sink 4, 4 'is arranged. The modules mentioned are preferably connected to one another mechanically only via the abovementioned screw connections.

With the luminaire according to the invention, luminous fluxes of more than 10,000 lm can be generated. In this case, the lamp is also suitable, for example, to be connected to a further, identical lamp, so that the two lights are arranged in alignment in the direction of the longitudinal axis L in succession. The luminous flux, which is emitted by these two lights together, is then twice as large as the luminous flux of one of the two luminaires.

Claims (15)

Light, comprising
a light source (2) with a plurality of light-emitting elements (3),
wherein the luminaire has first passage openings (5) on a first side ( re ) next to the light source (2) and second passage openings (7) on a second side ( li ) next to the light source (2),
wherein the first and the second passage openings (5, 7) are designed for an air flow for cooling the light source (2),
characterized,
that the light remains on the first side (right) adjacent the first passage openings (5), while below the light source (2) a first air duct (6) and on the second side (left) next to the second through holes (7) and thereby has a second air guide surface (8) below the light source (2),
wherein the two air guide surfaces (6, 8) are designed in such a way that they form an air inflow region (A) widening away from the light source (2). Luminaire according to claim 1,
which is designed in such a way that the first air guide surface (6) directly adjoins the first through openings 5 and / or the second air guide surface (8) directly adjoins the second through openings (7). Luminaire according to claim 1 or 2,
wherein the first air duct (6) is planar at least in a first approximation, or is arched shaped and preferably a first surface normal (N1) which includes with a vertical (V) has a first angle (α) of between 20 ° and 85 ° is, preferably between 30 ° and 70 °, more preferably between 35 ° and 60 °. Luminaire according to claim 3,
in which the second air guide surface (8) at least in a first approximation plan or
is curved and preferably has a second surface normal ( N2 ) with the vertical ( V ) includes a second angle ( β ), which is between 20 ° and 85 °, preferably between 30 ° and 70 °, more preferably between 35 ° and 60 °. Luminaire according to one of the preceding claims,
in which the first passage openings (5) and / or the first air guide surface (6) are designed as parts of a heat sink (4). Luminaire according to claim 5,
in which the cooling body (4) has vertically extending cooling ribs (41), in particular on a side opposite the first air guiding surface (6). Luminaire according to claim 6,
in which the cooling body (4) is designed such that only connecting areas are formed between the cooling ribs (41) whose surfaces (42) are inclined at least 30 °, preferably at least 40 ° relative to the horizontal. Luminaire according to one of the preceding claims,
in which the first air guide surface (7) and / or the second air guide surface (8) are designed to be reflective, preferably white, in particular painted white. Luminaire according to one of the preceding claims,
in which the second air guide surface (8) is formed by an outer surface of a housing (9), wherein preferably the housing (9) for mounting a control device (10) of the lamp is configured. Luminaire according to claim 9,
which is designed in such a way that the housing (9) has an interior space (19) whose vertical projection runs outside the vertical projection of the light source (2). Luminaire according to claim 9 or 10,
in which the housing (9) is shaped like a profile. Luminaire according to one of claims 9 to 11, having the features mentioned in claim 5,
in which the housing (9) with the heat sink (4) is connected mechanically supported only via a screw connection. Luminaire according to one of claims 9 to 12,
still having
a further light source (2 '), which is arranged on the second side ( li ) next to the housing (9), wherein the further light source (2') is preferably designed analog or identical to the first-mentioned light source (2). Luminaire according to claim 13,
still having
a further heat sink (4 ') for cooling the further light source (2'), which is arranged on the second side ( li ) next to the housing (9), wherein the further heat sink (4 ') preferably analog or identical to the first mentioned Heatsink (4) is designed. Luminaire according to claim 13 or 14,
which is symmetrical with respect to a vertical plane of symmetry (S), the plane of symmetry (S) preferably passing through the housing (9).

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