EP2453170A2 - Mounting device for sensors to lights - Google Patents

Abstract

The fixing device has an upper surface area (20) with truncated cone or cylinder that forms a symmetrical shape to a symmetrical axis (S). A rotational position locking unit (6) for locking a rotational position of the sensor based on symmetrical axis relative to support element. An independent claim is also included for a light has a support element, a sensor with a surface area.

Description

The invention relates to a fastening device for fastening a sensor to a support element of a lamp, wherein the sensor has a surface region which has the shape of a truncated cone or cylinder formed symmetrically to an axis of symmetry.

The sensor may, for example, be a presence sensor with the aid of which a control of the luminaire can take place.

In general, in this context, there is the problem that the sensor may have a non-circular detection field, for example, a rectangular detection field, so that it is usually desirable to fix the sensor in a certain way aligned with the lamp.

There is known a presence sensor having a surface area which has the shape of a truncated cone or a cylinder. Due to this shape, ensuring the desired orientation of the sensor relative to the carrier element of the luminaire is fundamentally problematic.

The invention has for its object to provide a corresponding fastening device with which a desired orientation of the sensor can be ensured. In addition, a luminaire with a corresponding sensor should be specified.

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

According to the invention, a fastening device for fastening a sensor to a support element of a luminaire is provided, wherein the sensor has a surface region which has the shape of a truncated cone or cylinder formed symmetrically with respect to an axis of symmetry. The fastening device has a rotational position securing element for securing a rotational position of the sensor with respect to the axis of symmetry relative to the carrier element.

The rotational position securing element makes it possible to ensure that a desired alignment of the sensor relative to the carrier element and thus relative to the luminaire can be ensured. The expression "securing a rotational position" is to express that the correspondingly fixed sensor is either fixed in a specific rotational position or at least held so that it can be rotated in the mounted position only within a "small" rotational position range, the For example, 5 °, 2 ° or 1 ° can be.

Preferably, the rotational position securing element has at least one projection which is designed to engage in a recess of the sensor and / or notch into a surface region of the sensor. By such a projection can be appropriate and reliable to ensure that the sensor remains in the desired rotational position or in the small rotational position range.

Preferably, the rotational position securing element has a recess which is adapted to encompass the surface region or its imaginary continuation. This allows a more secure position between the sensor and the rotary position fuse element.

Preferably, the rotational position securing element is plate-shaped. It is particularly advantageously produced by stamping or by laser. This allows easy production.

Further advantageously, the rotational position securing element consists of an electrically non-conductive material; This makes it possible in particular to avoid the risk of an electrical short circuit between the sensor and the carrier element.

Advantageously, the fastening device further comprises a holding element which is designed to hold the rotational position securing element on the carrier element. This makes it possible to ensure reliable retention of the rotational position securing element on the carrier element.

Advantageously, the holding element is designed as a spring element. This allows a particularly simple mounting of the fastening device on the carrier element. A particularly simple embodiment can be achieved if the holding element comprises a wire spring or consists of such.

A further particularly simple and reliable embodiment is made possible when the rotational position securing element has at least one recess or opening, wherein the fastening device is designed such that the holding element, in a provided for mounting the sensor relative position to the rotational position securing element in the Recess or engages in the opening. Preferably, the recess or opening is elongated, because this makes it possible to produce a particularly simple and reliable safeguard against unwanted mutual rotation between the rotational position securing element and the holding element.

Preferably, the rotational position securing element further comprises a further recess or a further opening, which is arranged opposite with respect to the axis of symmetry of the first-mentioned recess or opening and is preferably formed analogous to the first-mentioned recess or opening. In this way, a particularly uniform pressure on the sensor can be generated with the holding element and thus a particularly secure mounting of the sensor.

Preferably, the fastening device further comprises a plate-shaped support element, which is designed to the sensor in the region of To include surface area such that it is secured against movement along the axis of symmetry. As a result, the fastening device is also suitable in a case in which the sensor is shaped such that an additional support is required for its attachment.

According to a further aspect of the invention, there is provided a luminaire comprising a support element and a sensor having a surface area which has the shape of a truncated cone or cylinder formed symmetrically with respect to an axis of symmetry; Furthermore, the lamp comprises a fastening device according to the invention, wherein the carrier element has a passage opening and the sensor with its surface area, the passage opening is arranged cross-through and wherein the sensor is fastened with the fastening device to the support element.

The carrier element preferably has a rail-shaped or profile-shaped region which comprises two rectilinear grooves, wherein the holding element is designed to engage in the grooves in a resilient or latching manner for fastening the sensor.

Fig. 1

eine Skizze eines Ausführungsbeispiels einer erfindungsgemäßen Befestigungsvorrichtung mit einem entsprechenden Sensor,

Fig. 2

die Befestigungsvorrichtung, montiert an einem Trägerelement einer Leuchte,

Figuren 3A und 3B

zwei detailliertere, perspektivische Ansichten der an dem Trägerelement montierten Befestigungsvorrichtung aus unterschiedlichen Richtungen,

Fig. 4

das separierte Drehstellungs-Sicherungselement der Befestigungsvorrichtung,

Fig. 5

das separierte Halteelement der Befestigungsvorrichtung,

Fig. 6

das Drehstellungs-Sicherungselement und das Halteelement in ihrer vorgesehen Relativposition,

Fig. 7

einen alternativ geformten Sensor mit einem Unterstützungselement,

Fig. 8

das separierte Unterstützungselement,

Fig. 9

die Befestigungsvorrichtung im Fall des alternativen Sensors,

Figuren 10A und 10B

zwei perspektivische Ansichten der an dem Trägerelement montierten Befestigungsvorrichtung im Fall des alternativen Sensors aus unterschiedlichen Richtungen,

Figuren 11A bis 11D

weitere Skizzen zu der Befestigungsvorrichtung im Fall mit dem zuerst gezeigten Sensor und

Figuren 12A bis 12D

weitere Skizzen zu der Befestigungsvorrichtung im Fall mit dem alternativ geformten Sensor.

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 an embodiment of a fastening device according to the invention with a corresponding sensor,

Fig. 2

the fastening device mounted on a support element of a luminaire,

FIGS. 3A and 3B

two more detailed, perspective views of the mounting device mounted on the support member from different directions,

Fig. 4

the separated rotational position securing element of the fastening device,

Fig. 5

the separated retaining element of the fastening device,

Fig. 6

the rotational position securing element and the retaining element in their provided relative position,

Fig. 7

an alternatively shaped sensor having a support element,

Fig. 8

the separated support element,

Fig. 9

the fastening device in the case of the alternative sensor,

Figures 10A and 10B

two perspective views of the mounting device mounted on the support member in the case of the alternative sensor from different directions,

FIGS. 11A to 11D

further sketches to the fastening device in the case with the first shown sensor and

FIGS. 12A to 12D

further sketches to the fastening device in the case with the alternatively shaped sensor.

Fig. 2 shows a sketch of a first embodiment of a fastening device according to the invention for fastening a sensor 2 to a (partially shown) support member 4 a (not shown as such) lamp. The sensor 2 may in particular be a presence sensor.

The luminaire may in particular be a continuous line luminaire which has a downwardly open carrier rail, which is provided for receiving electrical or electronic components of the luminaire, and a so-called light bar, which is intended to be attached to the carrier rail be that it covers the lower opening at least partially, so that a housing of the lamp is formed by the support rail and the light bar. The light bar forms the carrier element 4 in the above-mentioned sense, to which the sensor 2 is fastened with the fastening device or is.

The light bar can also be designed to support a light source of the light, for example a fluorescent tube.

Fig. 1 shows a sketch of the separated fastening device and the sensor. 2

The sensor 2 has a surface region 20, which in this embodiment has the shape of a truncated cone formed symmetrically with respect to an axis of symmetry S. The truncated cone shape is thus rotationally symmetrical to the symmetry axis S.

For ease of description, it is assumed below that the sensor 2 is oriented in such a way that the axis of symmetry S of the surface region 20 is oriented vertically and the surface of the surface region 20 diverges upwards. A corresponding orientation is also assumed for the components of the fastening device arranged as intended and the carrier element.

Below the frustoconical surface region 20, another surface region of the sensor 2 adjoins, which has a plurality of surface regions 22 whose surface normals point in different directions into the lower half-space. This further surface area is intended to allow rays or waves to pass through, which are then detected by sensor elements in the interior of the sensor 2. Accordingly, the sensor 2 is preferably to be arranged on the carrier element 4 in such a way that the further surface area with the surface regions 22 is not covered by the carrier element 4 in the assembled state of the luminaire but projects freely downwards, ie forms an immediate boundary with the lower half space.

At its upper end region, the sensor 2 has electrical connections 26, which accordingly preferably project into an inner region of the luminaire in the assembled state of the luminaire, with reference to FIG Fig. 2 So after "above".

Accordingly, to support or support the sensor 2 in the vertical direction, provision may be made for the carrier element 4 to have a horizontal section with a particularly circular passage opening which is shaped in such a way that the sensor 2 engages with its frustoconical surface area 20 into the passage opening but can not enforce. The sensor 2 can then be inserted from above to a certain depth in the passage opening so that it protrudes downward with the other surface area accordingly.

The fastening device has a rotational position securing element 6 for securing a rotational position of the sensor 2 with respect to the axis of symmetry S relative to the carrier element 4. In this way it can be achieved that the sensor 2 remains in its fastened position with respect to the carrier element 4 in a desired rotational position or at least within a certain small rotational position range. This is particularly important if the detection field of the sensor 2 is not circular, that is, for example, rectangular.

In Fig. 4 is the rotational position fuse element 6 outlined in a separate form. As shown by way of example, the rotational position securing element 6 may have at least one projection 62, which is designed to engage in a recess 24 of the sensor 2. Alternatively or additionally, the projection could also be designed to score in a surface region of the sensor 2 (not shown in the figures). In the example shown, the recess 24 is formed at the upper edge of the frusto-conical surface region 20 of the sensor 2. The projection 62 may be designed in this case so that it engages from one side into the recess 62; it can therefore be designed substantially horizontally.

As shown by way of example, the sensor 2 may also have a further recess 24 'which, for example, with respect to the symmetry axis S symmetrical to the first mentioned recess 24 is formed. In this case, the rotational position securing element 6 - as shown and in Fig. 4 also advantageously has a further projection 62 ', which is adapted to engage in the further recess 24'. As a result, a further assurance of the rotational position is possible. Accordingly, the further projection 62 'may be formed analogously to the first-mentioned projection 62.

Further advantageously, the rotational position securing element 6 has a, in Fig. 4 designated, recess 64, for example in the form of a through hole, the - as exemplified Fig. 1 suggestively - is adapted to encompass the frusto-conical surface portion 20. The embodiment could alternatively (not shown in the figures) be provided so that the rotational position securing element 6 with its recess 64, the imaginary continuation of the surface region 20, in particular its continuation upwards, surrounds.

In the illustrated embodiment, the recess 64 of the rotational position securing element 6 is formed in the form of a through hole, wherein the two projections 62, 62 extend 'from the edge of the through hole in the direction of a central region of the through hole. In this case, the passage opening - apart from the two projections 62, 62 '- circular designed.

As exemplified in Fig. 4 sketched, the rotational position securing element 6 may be plate-shaped. Preferably, it is made by punching or by laser. In order to avoid unwanted electrical interactions, the rotary position fuse element 6 is also advantageously made of an electrically non-conductive or insulating material.

Advantageously, the fastening device further comprises a holding element 8, which is designed to hold the rotational position securing element 6 on the carrier element 4. The holding element 8 may be formed as a spring element, for example as a wire spring. In Fig. 5 is a corresponding wire spring than Holding element 8 outlined in a separate form. In particular, the holding element 8 can be configured to be connected to the carrier element 4 in a fixed orientation or rotational position with respect to the axis of symmetry S. For this purpose, the holding element 8 can, for example, have a rectilinearly shaped section 84, which is designed to rest on a rectilinearly shaped region of the carrier element 4, for example in the form of a groove.

Preferably, the rotational position securing element 6 has at least one recess or opening 66, wherein the fastening device is designed such that the holding element 8 engages in its intended relative position to the rotational position securing element 6 in the recess or in the opening 66, as an example in Fig. 1 outlined. Fig. 6 shows the two components rotational position securing element 6 and retaining element 8 again separately in their intended relative position.

Preferably, the recess or opening 66 is elongated. In this way, by engaging the holding element 8, an undesired relative rotation between the rotational position securing element 6 and the holding element 8 can be reliably avoided. The holding element 8 or the wire spring expediently has, for example, a bent or bent section 82 which is designed to engage in the depression or opening 66 for holding the rotational position securing element 6.

A particularly uniform pressure for holding the rotational position securing element 6 on the carrier element 4 can be achieved if the rotational position securing element 6 also has a further recess or a further opening 66 ', preferably with respect to the axis of symmetry S of the first mentioned recess or opening 66 opposite and thereby preferably analogous to the first-mentioned recess or opening 66 is formed. In particular, the further depression or opening 66 with respect to the symmetry axis S may be formed symmetrically with respect to the first-mentioned depression or opening 66.

Accordingly, in this case, the holding element 8 advantageously has a further bent or bent section 82 ', which is designed to engage in the further depression or the further opening 66' for holding the rotational position securing element 6. In particular, the further bent or kinked portion 82 'may be formed analogously to the first-mentioned bent or bent portion 82.

The holding element 8 is further preferably configured to engage in its intended relative position relative to the carrier element 4 in the latter latching or clamping, for example, intervene in undercuts of the support member 4, so that thereby a reliable attachment of the sensor 2 is made possible on the support member 4.

In the FIGS. 3A and 3B Fig. 2 are two perspective views from different directions of the fastening device connected to the support member 4 as provided. The holding element 8 in the form of the wire spring engages for holding a clamping in two undercuts, for example grooves 42, 44 of the support member 4 a. With the rectilinear shaped portion 84, it advantageously engages in one of the two grooves, in the example shown in the groove 44th

The carrier element 4 can therefore, as in the FIGS. 3A and 3B shown, a rail or profile-shaped portion having the two grooves 42, 44, so that the latter can be formed accordingly parallel.

The holding element 8 can thus - viewed from above - in a first approximation have a U-shape, wherein the two bent or kinked formed portion 82, 82 'form the legs of the U and the rectilinear shaped portion 84, the base of the U, of which both end portions extend the legs.

The holding element 8 thus engages with its two bent or bent sections 82, 82 'in the two elongated openings 66, 66' of the rotational position securing element 6 and the latter engages with its two projections 62, 62 'in recesses of the sensor 2, so that the sensor 2 with respect to its Rotary position defined relative to the axis of symmetry S by the fastening device is held on the support member 4.

For a particular desired rotational position of the sensor 2, a particular arrangement or orientation of the at least one projection 62 relative to the at least one recess or opening 66 is required. Accordingly, a plurality of different rotational position securing elements can accordingly be provided which correspond to different rotational positions of the sensor 2.

In the FIGS. 11A to 11D further sketches are shown to the fastening device described so far. 11A shows a side view, FIG. 11B a cross section normal to the grooves 42, 44, FIG. Fig. 11C a view from above and Fig. 11D a perspective view obliquely from above.

As already mentioned, can be provided to secure or support the sensor 2 in the vertical direction, that the support member 4 is a horizontal portion with a - in the FIGS. 3A and 3B has through-hole 48 which is shaped such that the sensor 2 engage with its frusto-conical surface portion 20 in the through hole 48, but this can not prevail. Like from the FIGS. 3A and 3B Furthermore hinted, the retaining element 8 may be designed such that it exerts pressure in the position provided for the attachment of the sensor 2 pressure from above on the rotational position securing element 6, thereby keeping the sensor 2 in a defined height position relative to the support member 4 secures , For this reason too, it is advantageous to design the retaining element 8 as a spring element.

More difficult is the situation in the case of an exemplary in Fig. 7 Although shown also alternatively shaped sensor 2 ', which also has a corresponding frusto-conical surface portion 20', and a corresponding, subsequent thereto, further surface area 22 ', but differs from the first-mentioned sensor 2 in that the further surface area 22' has a larger horizontal diameter than the frusto-conical surface portion 20 '. In this embodiment, the sensor 2 'can be due to the Form of the further surface portion 22 'for attachment does not insert from above into a corresponding through hole of the support member 4.

In this case, the fastening device further advantageously has a support element 10, which is configured such that it surrounds the alternatively shaped sensor 2 'adjacent to the frusto-conical surface region 20' and in this way can ensure the support necessary for the attachment. The support element 10 is therefore designed to surround the sensor 2 'in the region of the frusto-conical surface region 20' in such a way that it is secured against movement along the axis of symmetry S, namely against downward movement.

In Fig. 8 the support element 10 is sketched separated according to the embodiment. In particular, the support member 10 may be plate-shaped and have a recess 102, in particular in the form of a recess which is shaped so that they can engage around the frusto-conical surface portion 20 'of the sensor 2' and support by conditioning. In Fig. 7 the state is shown in which the sensor 2 'is assembled with the support element 10 as intended.

Further expediently, the support element 10 is shaped such that it can be inserted into the grooves 42, 44 of the support element 4, as from Fig. 10B to take a hint. In this case, the carrier element 4 advantageously has an enlarged through opening, which is dimensioned such that the sensor 2 'with its frustoconical surface region 20' can be pushed in from below until it reaches the upper edge the further surface region 22 'strikes the carrier element 2 from below.

In this way, the support element 10 can be laterally inserted into the grooves 42, 44 of the carrier element 4 so far that it engages and supports the frustoconical surface area 20 'of the sensor 2 as described so that the sensor 2' can not fall down is secured.

Furthermore, the fastening device described can be used as shown. Fig. 9 shows the components of the fastening device in the case of the alternative sensor 2 'together with the alternative sensor 2'. Fig. 10A shows a further perspective view of the mounted on the support member 4 alternative sensor 2 'obliquely from below.

In the FIGS. 12A to 12D further sketches are shown to the fastening device described in the case with the alternatively shaped sensor 2 '. 12A shows a side view, FIG. 12B shows a cross section normal to the grooves 42, 44, FIG. Fig. 12C a view from above and Fig. 12D a perspective view obliquely from above.

The fastening device is thus advantageous for differently shaped sensors 2, 2 '. Furthermore, the fastening device is also suitable for a case in which the sensor has a cylindrically shaped surface area instead of the frusto-conical surface area, followed by another area below, which has a smaller horizontal dimension, at which the support element 10 with its recess as described can intervene, so that in turn there is appropriate support against a downward movement.

Claims (13)

Fastening device for fastening a sensor (2) to a carrier element (4) of a lamp, the sensor (2) having a surface region (20) having the shape of a truncated cone or cylinder formed symmetrically with respect to an axis of symmetry ( S ),
marked by
a rotational position securing element (6) for securing a rotational position of the sensor (2) with respect to the axis of symmetry ( S ) relative to the carrier element (4). Fastening device according to claim 1,
wherein the rotational position securing element (6) has at least one projection (62) which is designed to engage in a recess (24) of the sensor (2) and / or to indent in a surface region of the sensor (2). Fastening device according to claim 1 or 2,
wherein the rotational position securing element (6) has a recess (64) which is adapted to encompass the surface region (20) or its imaginary continuation. Fastening device according to one of the preceding claims,
in which the rotational position securing element (6) is plate-shaped and is preferably produced by punching or by laser. Fastening device according to one of the preceding claims,
wherein the rotational position securing element (6) consists of an electrically non-conductive material. Fastening device according to one of the preceding claims,
still having
a holding element (8) which is designed to hold the rotational position securing element (6) on the carrier element (4). Fastening device according to claim 6,
in which the retaining element (8) is a spring element, preferably comprising or consisting of a wire spring. Fastening device according to one of claims 6 or 7,
in which the rotational position securing element (6) has at least one recess or opening (66) and the fastening device is designed such that the retaining element (8), in a relative position provided for fastening the sensor (2) to the rotational position securing element (6 ), engages in the recess or in the opening (66). Fastening device according to claim 8,
in which the recess or opening (66) is elongated. Fastening device according to claim 8 or 9,
in which the rotational position securing element (6) has a further depression or a further opening (66 ') which is formed opposite to the first depression or opening (66) with respect to the axis of symmetry ( S ) and preferably analogously to the first one formed recess or opening (66) is formed. Fastening device according to one of the preceding claims, further comprising
a plate-shaped support element (10), which is adapted to the sensor (2, 2 ') in the region of the surface region (20, 20') to include such that it is secured against movement along the axis of symmetry ( S ). Light, comprising a carrier element (4), a sensor (2) having a surface area (20) which has the shape of a truncated cone or cylinder formed symmetrically with respect to an axis of symmetry ( S ), and - A fastening device according to one of the preceding claims, wherein the carrier element (4) has a passage opening (48) and the sensor (2) with its surface region (20), the passage opening (48) is arranged cross-through and
wherein the sensor (2) is fastened with the fastening device on the carrier element (4). Luminaire according to claim 12,
in which the carrier element (4) has a rail-shaped or profile-shaped region which comprises two rectilinear grooves (42, 44), the retaining element (8) being designed to mount the sensor (2) resiliently or latchingly into the grooves (FIG. 42, 44) intervene.

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