This specification claims priority of DE 10 2018 115 419.4 filed on 27 Jun. 2018, the disclosure of which is incorporated herein in its entirety.
The present specification relates to embodiments of an adjustable carrier structure for a lamp. The specification likewise relates to a lamp for illuminating a film environment, studio environment, stage environment, event environment and/or theatre environment. In particular, the adjustable carrier structure is embodied for setting a light emitting angle of the lamp.
Lamps are typically used to illuminate a film environment, studio environment, stage environment, event environment and/or theatre environment. Occasionally it is desirable for different types of illumination to be able to be performed using a single lamp. In this context, a lamp may render possible, for example, a setting in which the light is pointedly oriented toward a circular or elliptical surface. In this setting, a transition between the illuminated surface and the surfaces surrounding said illuminated surface is clearly visible. Alternatively, a lamp may also be set in such a manner that a comparatively large surface is illuminated and the light field gently blends into the surrounding area.
For this purpose, it is known to fit lamps with (Fresnel) lenses that may be displaced relative to a light source of the lamp along an optical axis. A large adjustment range of the lamp in this case implies a large adjustment travel of the lens along the optical axis. This leads to the fact that lamps of this type comprise a large installation length along the optical axis. The lamp housing, which is also referred to as a lens barrel, is therefore relatively large. In particular, the lamp housing must be as long as the focus travel requires and must comprise a diameter that renders it possible to receive the (Fresnel) lens in the lamp housing. Moreover, the lighting means and its mounting parts may be received in the lamp housing. In addition, in one setting in which the lens sits comparatively close to a light source, therefore comparatively deep in the lamp housing, the light field that is emitted is cut off by the lamp housing. In this case, this is often also referred to as vignetting. In order to avoid this, the lamp housing would have to comprise a particularly large diameter in relation to the optical axis, as a result of which the required installation space of such a lamp would further increase. However, lamps that are constructed as compactly as possible are typically desirable.
Lamps having (Fresnel) lenses are also known in which the (Fresnel) lens is fixedly mounted on a front side of said lamp, and the light source and where applicable further elements such as a reflector, electrical lines, a cooling body, a fan or similar are moved with respect to the lens within the lamp. This construction in general is widespread, however as a whole it is perceived to be less suitable for lamps that comprise a light source (LED light engine) that includes LEDs. This is because in the case of LED lamps, efficient cooling systems are frequently used for the LED light engine and the procedure of adjusting said cooling systems relative to the (Fresnel) lens is often complex.
As a consequence, a conflict of objectives occurs between a compact construction of a lamp and a large setting range of the light field that is emitted by the lamp.
The object of the present invention is therefore to solve or at least to mitigate this conflict of objectives and to propose a lamp in which a large setting range is combined with a compact construction.
In accordance with an embodiment, an adjustable carrier structure for a lamp is proposed. This carrier structure comprises an optical component carrier on which an optical component may be fastened, a coupling device for fastening the carrier structure to the lamp, and at least one threaded spindle that comprises a first threaded spindle end that is mounted in an axially-fixed and non-rotatable manner on the optical component carrier, and is connected to the coupling device via a threaded socket that cooperates with the threaded spindle, wherein the threaded socket is connected to the coupling device in an axially-fixed and rotatable manner, wherein the threaded spindle extends essentially parallel to an optical axis of the adjustable carrier structure and a distance may be set between the first threaded spindle end and the coupling device by means of rotating the threaded socket. The term “optical components” in this context is also understood to mean, in addition to lenses, for example screens, polarization filters, and colored glass or protective glass. Moreover, the invention is not limited to a lamp with the result that the adjustable carrier structure may also be fastened to other optical components.
It is clear that the adjusting mechanism, which comprises the threaded spindle and the threaded socket, for setting the distance between the first threaded spindle end and the coupling device may also be kinematically reversed. The threaded socket is then connected to the optical component carrier in lieu of to the coupling device.
In accordance with a further embodiment, an adjustable carrier structure for a lamp is proposed, in particular for setting a light emitting angle of the lamp, said carrier structure comprising an optical component carrier, on which an optical component may be fastened for receiving the light that is emitted by the lamp, a coupling device for fastening the carrier structure on the lamp and an adjusting device that is embodied for adjusting the distance between the coupling device and the optical component carrier along an optical axis of the lamp. In the case of this embodiment, the adjusting device may comprise a threaded spindle and/or a toothed rod. It is also conceivable to embody the adjusting device as a hydraulic or pneumatic adjusting device.
Furthermore, a lamp having an adjustable carrier structure of the above-mentioned type is proposed. As used herein, the term “lamp” may likewise refer to a spotlight (in German: “Scheinwerfer”).
The parts that are illustrated in the figures are not necessarily to scale; on the contrary the emphasis is on illustrating the principles of the invention. Moreover, identical reference numerals in the figures refer to parts that correspond to one another. In the figures:
In the following detailed description, reference is made to the attached drawings that are associated with said description and in which it is illustrated by means of specific embodiments how the invention may be used in practice.
The adjustable carrier structure 12 is embodied for setting a light emitting angle of the lamp 10 and comprises for this purpose an optical component carrier 14 on which an optical component 16 is fastened for receiving the light that is emitted by the lamp 10. For this purpose, a light emitting opening 18 is provided.
In the illustrated example, the optical component 16 comprises a lens 16a. The optical component carrier 14 may therefore in this case also be referred to as a lens holder or lens carrier. It is clear that in other exemplary embodiments, other optical components 16 may also be fastened to the optical component carrier 14.
The carrier structure 12 is fastened by means of a coupling device 20 on the lamp 10, more precisely on the lamp housing 22 that is also referred to as a lens barrel. In this case, the coupling site of the carrier structure 12 is arranged on the lamp 10 on the light emitting side of said lamp, where the light emitting opening 18 is also provided.
The carrier structure 12 may also be screwed, clamped and/or hooked on the lamp 10 via the coupling device 20. Alternatively, other suitable fastening means are also possible. The procedure of fastening the carrier structure 12 on the lamp 10 may also be performed using tools that correspond to the fastening means or also may be performed without using tools.
A distance along an optical axis 24 between the coupling device 20 and the optical component carrier 14 may be set by means of an adjusting device 26. In this manner, the lamp 10 may be transferred by way of example from a spot setting into a flood setting and conversely.
In the embodiment that is illustrated in the figures, a distance of the lens 16a from a lens-side end of the lamp housing 22 is therefore set via the adjusting device 26.
For this purpose, the adjusting device 26 in the illustrated example comprises four threaded spindles 28 that comprise respectively a first threaded spindle end 28a and a second threaded spindle end 28b (cf.
The connection of the threaded spindles 28 to the coupling device 20 is provided via respectively allocated threaded sockets 30 that cooperate with the respective threaded spindle 28. These threaded sockets are connected to the coupling device 20 in an axially-fixed and rotatable manner.
All the threaded spindles 28 extend essentially parallel to the optical axis 24.
In addition to the connection of the carrier structure 12 to the lamp housing 22, the coupling device 20 therefore also serves for the mounting and guiding of the threaded rods 28. The coupling device 20 therefore may also be referred to as the base plate.
In this embodiment, the distance between the optical component carrier 14, more precisely the first threaded spindle end 28a, and the coupling device 20 may now be set by virtue of the fact that the threaded sockets 30 are rotated with respect to the coupling device 20.
For this purpose, one or multiple of the threaded sockets 30, preferably one single threaded socket 30, is or are coupled to a drive component 32 in such a manner that the threaded socket 30 may be set into rotation relative to the allocated threaded spindle 28.
In the present embodiment, the drive component 32 comprises a rotary knob 32a that may be rotated by hand about a rotary knob axis 34. Such a rotary knob may also be referred to as a focus knob.
In alternative embodiments, two focus knobs may also be provided that are arranged on opposite sides of the carrier structure 12.
In alternative embodiments, the drive component 32 may alternatively or additionally comprise an electric motor. Hydraulic and/or pneumatic drive components are also conceivable. Moreover, the drive components may be arranged in an arbitrary position on the carrier structure 12.
The threaded socket 30 that is coupled to the drive component 32 is connected in the illustrated embodiment to a gear wheel 36 in a non-rotatable manner, said gear wheel cooperating with the drive component 32. The drive component 32 comprises for this purpose a toothed section 32a that is in engagement with the gear wheel 36.
The toothed section 32a and the gear wheel 36 therefore form a transmission that may be embodied as a spur gear or bevel gear.
The second threaded spindle ends 28b are arranged in the illustrated embodiment radially outside the lamp in relation to the optical axis 24. As the distance between the optical component carrier 14 and the coupling device 20 or the lamp housing 22 is adjusted, said threaded spindle ends therefore always move outside the same.
For this purpose, groove-shaped depressions or openings, in particular holes, are provided on the lamp housing 22 in which the second threaded spindle ends 28b may move during the adjusting procedure along the optical axis 24.
In order to be able to reliably and precisely position the optical component carrier 14, all the threaded sockets 30 are coupled in a rotatable manner to one another via a pulling means 38 that is a toothed belt 40 in the present embodiment.
The toothed belt 40 in this case engages with its teeth in the toothing arrangement 42 that is provided respectively on the outer circumference of the threaded sockets 30.
All the threaded sockets 30 are therefore set into rotation via toothed belts 40 by means of the drive component 32. A V-belt, a chain or any other suitable pulling means may also be used as an alternative to the toothed belt 40.
It is naturally also possible in lieu of coupling all the threaded sockets 30 by means of a single toothed belt 40 to couple the threaded sockets 30 in pairs or groups to a toothed belt. In this case, multiple toothed belts may be necessary in order to set all the threaded sockets 30 into rotation.
In addition to the threaded spindles 28, it is possible to provide one or multiple guiding rods that extend along the optical axis 24 that then represents a guiding axis, said guiding rod/rods comprising a guiding rod end that is mounted in an axially-fixed manner on the optical component carrier 14 and being mounted in a guiding opening that is connected to the coupling device 20 so that said guiding rod end may move axially. The kinematically-reversed case is likewise also conceivable. The guiding rod end is then mounted in an axially-fixed manner on the coupling device 20 and is mounted in a guiding opening that is connected to the optical component carrier 14 so that said guiding rod end may move axially.
It is also possible for some of the threaded spindles 28 to be replaced with such guiding rods. In this case, the guiding rods do not comprise threads and are merely used for the stable guiding of the optical component carrier 14 along the optical axis 24. The guiding rods therefore render possible a movement of the optical component carrier 14 along the optical axis 24. Movements transverse with respect to the optical axis 24 are prevented by means of the guiding rods.
In addition, a guiding element 44 may also be allocated to one or multiple of the threaded spindles 28 and/or one or multiple of the guiding rods. Such a guiding element 44 is connected to the coupling device 20 and is used for the purpose of guiding the respectively allocated threaded spindle 28 or the respectively allocated guiding rod in the direction of the optical axis 24 in a region that is spaced from the coupling device.
Moreover, the guiding element 44 is used for the purpose of holding a respectively allocated threaded socket 30 along the optical axis 24 on the coupling device 20. Consequently, it is ensured via the guiding element 44 that although the threaded socket 30 may rotate relative to the coupling device 20, said threaded socket cannot move along the optical axis 24.
In an alternative embodiment, for this purpose the threaded socket 30 may also be held via a groove that is provided on the threaded socket 30 and a lock washer that engages in said groove may be held on the coupling device 20.
It is clear that exemplary embodiments are also conceivable in which more or less threaded spindles 28 and/or guiding rods are used. However, in accordance with an embodiment at least one threaded spindle 28 is provided. It is preferred that the carrier structure 12 moreover comprises at least one guiding rod on which the optical component carrier 14 slides along the optical axis 24.
As an alternative to a guiding rod, a guiding rail or guiding plate may also be provided on which the optical component carrier 14 slides along the optical axis 24.
In the illustrated exemplary embodiment, the adjusting device 26 comprises four threaded spindles 28. Likewise, alternative embodiments are conceivable in which one or multiple toothed rods are provided in lieu of the threaded spindles 28. The adjusting device may also comprise one or multiple hydraulic cylinders or pneumatic cylinders.
As is apparent in
In this case, the folding bellows 46 is fastened both on the coupling device 20 as well as on the optical component carrier 14 in relation to the optical axis 24 in a radial edge region. Reference is to be made here to the fact that the coupling device 20 is covered by means of a housing in the exemplary embodiment that is illustrated in
In a further-developed embodiment, the optical component carrier 14 may in addition be embodied for the purpose of receiving further lamp components. In particular, the optical component carrier 14 may comprise fastening means via which a leaf door may be fastened on the optical component carrier 14.
Number | Date | Country | Kind |
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10 2018 115 419 | Jun 2018 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
1691475 | Hall | Nov 1928 | A |
5029992 | Richardson | Jul 1991 | A |
6092914 | Esakoff | Jul 2000 | A |
9182106 | Melzner | Nov 2015 | B2 |
10495802 | Jurik | Dec 2019 | B2 |
20020060911 | Brockmann | May 2002 | A1 |
20040017685 | Dedoro | Jan 2004 | A1 |
20050286250 | Tanaka | Dec 2005 | A1 |
20060133079 | Callahan | Jun 2006 | A1 |
20090122549 | Hou | May 2009 | A1 |
20110080735 | Quadri | Apr 2011 | A1 |
20110103063 | Jurik | May 2011 | A1 |
20120127710 | Jurik | May 2012 | A1 |
20130170222 | Lin | Jul 2013 | A1 |
20140233244 | Jurik | Aug 2014 | A1 |
20140301071 | Jorgensen | Oct 2014 | A1 |
20140313744 | Collias | Oct 2014 | A1 |
20160047533 | Jurik | Feb 2016 | A1 |
20160238217 | Latteo | Aug 2016 | A1 |
20160245490 | Jurik | Aug 2016 | A1 |
20160298829 | Jurik | Oct 2016 | A1 |
20170074497 | Jurik | Mar 2017 | A1 |
20170090115 | Jurik et al. | Mar 2017 | A1 |
20170269292 | Jurik | Sep 2017 | A1 |
20180313521 | Jurik | Nov 2018 | A1 |
20180347788 | Vilem | Dec 2018 | A1 |
20190093860 | Peard | Mar 2019 | A1 |
Number | Date | Country |
---|---|---|
2757614 | Jun 1979 | DE |
2831461 | Feb 1980 | DE |
20 2005 001 704 | Jun 2005 | DE |
10 2005 044 237 | Mar 2007 | DE |
202013007715 | Dec 2014 | DE |
Entry |
---|
EP Office Action in Application No. 19170807.2 dated Nov. 8, 2019. |
DE Office Action in application No. 10 2018 115 419.4 dated Jan. 21, 2019. |
EP Office Action in Application No. 19 170 807.2 dated Jul. 31, 2020. |
Number | Date | Country | |
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20200003399 A1 | Jan 2020 | US |