This application claims the priority of Italian Application No. TO2012A000836 filed Sep. 27, 2012, the entire content of which is hereby incorporated by reference.
The present description relates to lighting devices. Various embodiments may relate to lighting devices using solid state light radiation sources, for example LED sources.
Lighting devices, for street lighting for example, with solid state light radiation sources (for example LED sources) are considered to be competitive because of their efficiency and their lighting performance, for example in terms of high luminosity per watt (lm/W) and because of the possibility of increasing the spacing between the standards on which they are mounted.
Devices intended for specific applications (such as ordinary street lighting and the lighting of highways, pedestrian areas, bicycle paths, etc.) may offer special forms of lighting distribution provided by means of standard structures, in such a way that the same basic components (light radiation sources, mounting boards such as printed circuit boards (PCBs), casings, wiring, etc.) can be used with changes in the associated optical systems, as required by the specific applications.
However, solutions of this type may be limited in their flexibility by the generally small number of different combinations that can be obtained with the same basic components.
These considerations are valid not only for solutions based on refractive optics but also for those based on reflective optics.
In the case of refractive optics, a distributed array of light radiation sources (for example, 8 to 16 LEDs spaced a few centimeters apart) may have an associated “family” of lenses, made of plastic material for example, formed in one piece. Each type of lens provides a specific radiation configuration on the road surface, making it possible to provide different applications by using multiple arrays of multiple lenses.
These solutions are inherently limited in terms of the reliability of the lenses, particularly those made of plastic material, which are to be placed in the proximity of the light radiation sources, and also in terms of the high sensitivity to the configuration of the radiation emission from the source (of the LED type for example), and the possibility of causing a greater amount of dazzle than where reflective optics are used.
Reflective optics may, for example, include the use of a certain number of groups (or “clusters”) of LEDs on a printed circuit board (PCB) coupled to aluminized reflectors which can be made, for example, in different versions. In all cases it may be possible to include additional components so as to provide, for example, a radiation configuration suited to the lighting of pedestrian areas, on the basis of a version used for street lighting. Various solutions may also allow the lighting configuration to be rotated, through 180° for example, by rotating the module inside the lighting device in a corresponding way.
However, solutions of this type may be subject to limitations due, for example, to the fact that the rotation of the reflector may require a corresponding rotation of the board on which the light radiation source is mounted, or may require the provision of board and radiation source assemblies of a different type. Because of all these factors, there are evident limitations in terms of flexibility of use.
A lighting device comprising a bowl-shaped body having a base surface with a plurality of mounting studs projecting from the base surface; at least one board for mounting light radiation sources, provided with holes for the passage of respective studs of said plurality, the at least one board having pairs of mounting locations for light radiation sources, each pair being arranged on opposite sides of a respective hole so as to be located on opposite sides of the stud which extends through said respective hole; and
a plurality of reflectors for projecting the light radiation from the device, the reflectors having an inlet opening for the light radiation and being capable of being mounted on the aforesaid mounting studs selectively in one of at least two opposite mounting positions in which the inlet opening is placed at one of said mounting locations.
Various embodiments will now be described, purely by way of non-limiting example, with reference to the appended drawings, of which:
The following description illustrates various specific details intended to provide a deeper understanding of various exemplary embodiments. The embodiments may be produced without one or more of the specific details, or with other methods, components, materials, etc. In other cases, known structures, materials or operations are not shown or described in detail, in order to avoid obscuring various aspects of the embodiments.
The reference to “an embodiment” in this description is intended to indicate that a particular configuration, structure or characteristic described in relation to the embodiment is included in at least one embodiment. Therefore, phrases such as “in an embodiment”, which may be present in various parts of this description, do not necessarily refer to the same embodiment. Furthermore, specific formations, structures or characteristics may be combined in any suitable way in one or more embodiments.
The references used herein are provided purely for convenience and therefore do not define the scope of protection or the extent of the embodiments.
The drawings relate to embodiments of a lighting device L.
In various embodiments, the device may be a street lighting device intended to be mounted, for example, at the top of a standard, suspended from an overhead line, or in other ways.
For this purpose (that is to say, for the purpose of mounting and also for the purpose of protection from the external environment), the lighting device L may be provided with a casing H, shown in chained lines in
In various embodiments (described in greater detail below), the device comprises a base body 10 in which one or more boards 12a, 12b (made, for example, with printed circuit board (PCB) technology) can be mounted, these boards being capable of being fitted with arrays or clusters of solid state light radiation sources (such as LED sources) 14 (see, in particular,
In order to project the light radiation generated by the sources 14 toward the outside of the device, reflectors 16 are mounted in the body 10 and can be held in position by a retaining bar 18.
In various embodiments, the device may also comprise additional reflectors 20.
In various embodiments, the body 10 may be generally bowl-shaped with a base surface 10a from which emerges a plurality of mounting studs 100 aligned with each other in a direction of alignment.
The exemplary embodiment considered herein relates to the possible presence of four mounting studs 100, arranged with equal spaces between them and aligned in the direction of the longer sides of the body 10, which has a generally rectangular shape.
In various embodiments, both the number and arrangement of the studs may be different (for example, with the studs not equally spaced and not aligned).
In various embodiments, the shape of the body 10 and the shape of the casing H (
In various embodiments, the boards 12a, 12b (indicated by different references for reasons given below) may be provided with holes 120 through which the studs 100 are intended to pass when the boards 12a, 12b are inserted into the body 10, as shown more clearly in
The boards 12a, 12b are provided, in a known way, with arrays of contacts, clamps or terminals forming “locations” for the mounting of the light radiation sources 14.
The exemplary embodiments illustrated herein relate to light radiation sources 14 formed by arrays or clusters of LEDs, comprising, for example, eight LEDs arranged in a 4×2 rectangular matrix. Clearly, the nature, number and distribution of the sources in question may be different, according to the specific application requirements.
In various embodiments, the boards 12a, 12b may include, for each hole 120, two mounting locations 122, 122′ which are mutually opposed, that is to say arranged on opposite sides of the hole 120 in question. Thus, when the boards 12a, 12b are mounted in the body 10 (see
In various embodiments, the two mounting locations 122, 122′, which form a mirror image of each other, may lie on opposite sides of the stud 100 in the direction of alignment of the studs 100. In various embodiments, the direction of opposition may be different, being for example orthogonal to the direction of alignment of the studs 100.
In
The choice of which of the two opposite positions 122, 122′ associated with each combination of hole 120 and stud 100 is to be populated with the light radiation sources (in practice, the choice is between the two opposite locations 122, 122′ in which a light radiation source 14 can be mounted) may have any outcome and may be made according to the application requirements in line with the criteria described more fully below.
By making the studs 100 penetrate into the holes 120, the boards 12a, 12b (connectable according to the electrical connection or wiring system described more fully below) can be mounted in the body 10, and the reflectors 16 can be fitted onto the studs 120.
In various embodiments, the reflectors 16 (which can be made, for example, of internally aluminized plastic material) may have shapes such as those shown by way of example in
In various embodiments, the single reflector 16 may be composed of two parts 16a, 16b that can be joined together.
In various embodiments, the reflectors 16 may have, in addition to a hole 160 which allows the reflector 16 to be fitted onto one of the studs 100, an inlet opening 162 for the light radiation produced by the sources 14 and one or more outlet openings 164. Through the outlet opening or openings, the light radiation produced by the sources 14, which enters the reflector 16 through the opening 162, is projected to the outside of the device.
This may take place, for example, through the casing H, made of transparent material.
In various embodiments, the reflectors 16 may be generally V-shaped (or U-shaped, if this description is preferred, that is to say in the form of an “inverted saddle”) with a pair of outlet openings 164.
In various embodiments, the reflectors may then be held in position with the boards 12a, 12b held between the reflectors 16 and the base wall 10a of the body 10 by means of the retaining bar 18.
In various embodiments, the bar 18 may be provided with holes 180 for the passage of fastening screws 182 (self-tapping screws, for example) screwed into the heads of the studs 100 (and if necessary also into other parts, such as further end studs) of the body 10.
In various embodiments, the reflectors 16 may be shaped in such a way that they can be fitted onto the studs 100 in two opposite mounting positions, such that the radiation inlet opening 162 can be located, alternatively, at one or the other of the locations 122, 122′ provided for the mounting of the light radiation sources 14 at the position of each opening 120 (and of each stud 100).
For example, this result can be achieved by selecting a distance between the hole 160 and the inlet opening 162 which corresponds to the distance which, in the boards 12a, 12b, separates the holes 120 and the mounting locations 122, 122′ arranged on the opposite sides of each hole.
Thus, each reflector 16 can be mounted in two positions mutually rotated through 180° relative to each other, with a corresponding modification of the orientation of the “lobe” of light radiation projected by each reflector to the outside of the device 10.
As shown more fully in
In various embodiments, the two portions 16a, 16b can be connected together permanently, or can be kept in the coupled condition by the same methods as those used to keep the reflector 16 as a whole in position, for example by means of the fastening bar 18.
Various embodiments may have a high degree of flexibility of use, due, for example, to the fact that two light radiation sources (for example two clusters of LEDs) can share a single board, for example with the possibility (as shown in
In various embodiments, a lighting device as described herein can be provided without the light sources 14, which can be mounted on the device only at the time of installation.
In various embodiments, a lighting device as described herein can be associated with a set of boards 12 carrying light radiation sources 14 mounted in one or the other of the mounting locations 122, 122′ with the possibility of selecting in each set the boards having the sources 14 mounted in the appropriate locations for the specific intended application.
This can all be achieved while allowing a single base board structure to have either the characteristics of a master board, intended to receive the electrical power supply from outside the device through a power supply cable 24, or the functions of a slave board which receives its power supply from a master board.
In the exemplary embodiment to which
In various embodiments, the mounting solution described herein allows electrical power to be supplied to the device 10 by using a single power supply conductor 24.
Although the examples shown in
The diagram in
The diagram of
In this context, it has also been found that the fact that any specific mounting location 122, 122′ is not populated has no appreciable effect on the overall distribution of light radiation emitted by the device.
This arrangement can be provided by making use of the fact that the light radiation inlet opening (162 in
The different orientation of the reflector 16 causes a corresponding change in the orientation of the light radiation “lobe” projected by it from the lighting device.
Since each of the reflectors 16 allows (at least) two possible mounting positions (at 0° and 180°, respectively), if there are four reflectors 16 then it is possible to have sixteen different mounting configurations, namely:
More generally, when a number n of reflectors 16 is present, 2n different mounting configurations are available, from which the configuration most suitable for the requirements of use can be selected.
The number of available configurations can be increased further by increasing the number of different mounting positions allowed by the reflectors 16 (for example, four reflectors at 90° to each other), with corresponding modification of the number of opposite mounting locations provided around each hole 120.
In various embodiments, the fact that the reflectors 16 (and the boards 12a, 12b) are kept in position by the bar 18 fastened by screwing (at 182) to the body 10 facilitates both the operation of mounting the device 10 (in terms of the wiring operations and other aspects) and any dismantling for the purpose of replacing one or more of the reflectors 16 and/or providing a different orientation of the reflectors 16 (with corresponding modification of the arrangement of the “population” of the boards 12a, 12b with light radiation sources 14).
In various embodiments, the reflectors 16 may have rotational symmetry about the mounting position on the respective studs 100, so that, except as regards the different orientation of the lobe of outgoing radiation, the relative positions of the reflector 16 and of the light radiation source 14 located in the mounting position 122 or 122′ and therefore facing the inlet opening 162 remain unchanged regardless of the chosen orientation.
In various embodiments, and as shown more fully in
In various embodiments, it is possible to use auxiliary reflectors 20 together with the “main” reflectors 16, the auxiliary reflectors being adapted, for example, to make a device L, intended to provide a street (or highway) lighting function, capable of providing a function of illuminating pedestrian areas.
In various embodiments, the auxiliary reflectors 20 may have a general bridge or link shape such that they can be mounted by means of the bar 18 in one of two opposite positions, positioned laterally on one or other side of the body 10 of the device L, as shown schematically in
Various embodiments, therefore, enable a high degree of flexibility to be achieved in the assembly of a set of members (the boards 12, populated in advance if necessary, the reflectors 16, the fastening bar 18, and the additional reflectors 20) according to the specific application requirements over a wide range of possible configurations. For example, by using two types of reflectors 16 and additional reflectors (right or left), a total of 1,820 possible different combinations can be provided.
Various embodiments facilitate the management of the logistics of the product.
Various embodiments also simplify the costs of production, both as regards the molding of the various members (which can, for example, be made of plastic material or light metallic material) and as regards the further possibility of providing all the components of the “family” of products with any necessary additional components to be fitted thereto.
Naturally, provided that the principle of the invention remains the same, the details of construction and the forms of embodiment may be varied to a more or less significant extent with respect to those which have been illustrated purely by way of non-limiting example, without thereby departing from the scope of protection, this scope of protection being defined in the attached claims.
Number | Date | Country | Kind |
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2012 A 000836 | Sep 2012 | IT | national |
Number | Name | Date | Kind |
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7914162 | Huang | Mar 2011 | B1 |
Number | Date | Country |
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20 2009 000 236 | Jun 2010 | DE |
10 2009 056 904 | Jun 2011 | DE |
WO 2010079089 | Jul 2010 | WO |
Entry |
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Search Report dated Jan. 1, 2014 issued in the corresponding European Patent Application No. 13 18 2395.7. |
Number | Date | Country | |
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20140085887 A1 | Mar 2014 | US |