ITBO20120398A1 - LAMP FOR LIGHTING GREAT SURFACES - Google Patents

Description

DESCRIPTION

of industrial invention entitled:

LAMP FOR LIGHTING LARGE SURFACES

The present invention refers to the technical field of lighting large environments such as industrial warehouses, offices, large commercial areas.

It is known in the art to make use of lamps for the lighting of large rooms, which typically consist of ceiling lights with fluorescent tubes or gas discharge lamps mounted inside a lighting body with the reflecting part having a parabolic section.

To achieve correct illumination of the area to be illuminated, it is necessary to know the lamp-area distance to be illuminated and the required level of illumination. The lighting designer normally needs a wide range of lamp models with different values of light emission intensity and beam angle, in order to be able to optimally design the type, number and arrangement of the lamps to be used. This forces lamp manufacturers to have a very rich catalog of models to offer.

The use of LEDs (Light Emitting Diodes) for ambient lighting allows better exploitation of the energy supplied for lighting: typically a fluorescent tube has an efficiency of around 15%, a discharge lamp an efficiency not exceeding 30%, modern LEDs have an efficiency close to 50%: this value could rapidly increase in the near future.

LEDs also have a much longer useful life, about ten times that of a fluorescent tube or discharge lamp, and this allows the light source to be replaced more rarely, saving both labor and money.

It is already known to use LEDs for the lighting of environments, but for similarity typically LEDs are used to recreate the structure and connection typical of incandescent bulbs, halogen spotlights and fluorescent tubes, using the same types of ceiling lights and bodies illuminants traditionally in use.

The purpose of the present invention is to provide a modular system of lamps composed of a limited number of basic elements: power supply, at least one LED bar, and at least one terminal support, which are able to illuminate a wide range of environments from the view of the required lighting intensity and the distance between the lamp and the area to be illuminated.

The object is achieved with a modular lamp system having the characteristics of the independent claim. Advantageous embodiments and improvements are specified in the dependent claims.

One of the advantages of the present invention consists in its modularity, i.e. in the fact that it is possible to obtain a large variety of lighting types with a limited number of system components: with a power supply model, a number of LED bars between one and six and two models of end supports, it is possible to obtain a multiplicity of configurations of the lighting system, as will be better described below.

A second advantage is that connected to energy saving and reduced maintenance needs linked to the use of LEDs.

A third advantage is that the particular circuit configuration adopted allows, even in case of failure of the single LED, the continuity of service of the lamp as a whole.

Indicatively, two 150 cm long LED bars produce a luminous flux of about 8,000 lumens; placed at a height of six meters, they bring about 300 lux to the lighting of an area to be illuminated of about 16 square meters. A higher ceiling height of the area to be illuminated will require a higher number of bars, and vice versa. Different types of configuration allow to obtain different lighting values.

A preferred embodiment is capable of connecting one to six LED bars to the power supply. In the following, explicit reference will be made to this preferred embodiment without thereby losing generality.

The present invention will now be described with reference to the attached drawings, which illustrate some different cases of non-limiting examples of embodiment:

Figure 1 Front view detail of the power supply;

Figure 2 Detail of the LED bar seen in section;

Figure 3 Perspective view of the simplest embodiment of the present invention, consisting of a power supply, an LED bar and an end support;

Figure 4 Perspective view of a second embodiment of the lamp of the present invention comprising four LED bars;

Figure 5 Perspective view of a further embodiment of the lamp of the present invention comprising six LED bars;

Figure 6 Perspective view of a further embodiment of the lamp of the present invention comprising six LED bars arranged apart;

Figure 7a Bottom perspective view of a further embodiment;

Figure 7b Perspective view from the top of the further embodiment.

The lamps of the present invention essentially consist of three basic elements, which can be combined in various ways as described in Figures 3 to 7. The basic elements of the combination are:

∠’a power supply 2;

∠’at least one LED bar 3;

∠’at least one terminal support 4 or 6.

The power supply 2 and the terminal support 4 or 6 are equipped, in the upper part, with anchoring points 20 for fixing the rooms to be illuminated to the ceiling (not shown).

The power supply is contained in a boxed body equipped with different connections, which are used according to the need to connect one, two or three LED bars for each side of the power supply itself. The power supply is designed to provide correct power to the bar (s) to which it is connected. In the preferred embodiment, a maximum of six LED bars can be connected to the power supply, as will be better highlighted in Figures 3 to 7.

In one embodiment, for cost reasons, the power supply 2 is provided in at least two versions 2a, 2b differentiated by power, according to the number of LED bars to be powered and their length. In a preferred embodiment, a 100 Watt power supply 2a and a 150 Watt power supply 2b are provided which are selected according to the overall power of the LED bars 3 to be powered.

Figure 1 shows a detail of the power supply 2 which highlights the holes 21 for fixing the LED bars 3 to the boxed structure; a similar arrangement of the holes is present in the end supports 4 or 6.

All bars are fixed with screws; the central bar 3a is in a fixed position, with the emission axis of the light beam perpendicular to the main axis of the power supply body. The side bars 3b, 3c, on the other hand, can be fixed according to need with an inclination of the longitudinal plane of the bar from 0 to ± 15 ° with respect to the longitudinal plane of the central bar 3a, so as to be able to structure the light beam by widening or narrowing it. according to the lighting needs of the area to be illuminated.

The LED bar 3 comprises a rigid structure which houses a certain number of LEDs, proportional to the length of the bar itself.

Figure 2 shows the detail of the LED bar 3, seen in section. The LED bar 3 includes an extruded aluminum support 7 which carries the holes for fastening to the power supply 2 and to the terminal support 4 or 6 at the top, while the printed circuit 9 is mounted in the lower part which carries the LEDs 5 with support means for hooking optional secondary optics 10. On the lateral edges the LED bar 3 has a groove in which a transparent semicircular protection 11 engages.

A further element of modularity of the lamp is represented by the modularity with which the LED bars 3 are also made. In fact, the LED bars 3 consist of a rigid aluminum support 7 and an external transparent protection 11 which are cut to size, and a variable number of printed circuit segments 9, each containing a group of LEDs; in a preferred embodiment from a group of five LEDs, as can be seen from Figure 3. In this way it is possible to build LED bars 3 of different lengths, starting from predefined modular construction elements 12. In a preferred embodiment, the LED bars have a length of 60 cm (two modules), 150 cm (five modules) and 210 cm (seven modules).

The LEDs can optionally be equipped with a secondary optic 10 which can be chosen with different opening angles, in a preferred embodiment of 60 ° and 90 °. In the absence of secondary optics, the beam angle of the bare LED is typically around 110 °. The smaller opening angle is more suitable for lamps located further away from the area to be illuminated; it can also be chosen when, for aesthetic reasons, the lighting designer decides on particular locations. For example, the secondary optic 10 can consist of a support that supports a Fresnel lens placed at a suitable distance in front of the single LED, or of a support that supports a multiple system of Fresnel lenses, for example five, which is placed in front of a group of LEDs, consisting for example of five LEDs.

An important point for the reliability of the system is the fact that the printed circuit is constructed in such a way that the LEDs forming part of a single module are placed in parallel with each other, while assembling the modules inside the bar the modules are in series with each other. In this way the LEDs form a matrix so that any failure of a single LED does not block the operation of the other four LEDs belonging to the same module, nor of the modules placed upstream and downstream of the one containing the faulty LED. .

Figure 3 shows a perspective view of the lamp, indicated with 1 as a whole, in its simplest embodiment. The lamp 1 comprises a power supply 2a, a LED bar 3, and a terminal support 4.

Figure 4 shows a second embodiment in which the power supply 2b is connected to four LED bars 3b, 3c and to two terminal supports 4.

Figure 5 shows a further embodiment in which the power supply 2b is connected to six LED bars 3a, 3b, 3c and to two terminal supports 4.

Figure 6 shows a further embodiment in which it is possible to appreciate that the side bars 3b, 3c, besides being able to be fixed to the power supply parallel to each other as indicated in Figures 4 and 5, can be fixed to the power supply 2b spread at an angle of about 15 ° with respect to the central bar 3a, using a different type of terminal support 6. This configuration allows to obtain a more diffused illumination, particularly advantageous in the event that the distance between the lamp and the to be illuminated is reduced.

A further preferred embodiment, shown in Figures 7a and 7b, provides that the LED bars 3 are mounted only between the end supports 4, while the power supply 2 is mounted above the bars on a protection 13 also fixed to the supports terminals 4. In this way, a ceiling light is created that allows installation compatible with standard false ceilings suitable for traditional ceiling lights in environments such as offices and commercial spaces. In fact, in this type of environments there are often false ceilings that have a modularity of 60x60 cm.

On the basis of the figures as a whole, it is evident that in the present embodiment it is possible to have configurations with one, two, three, four, five and six LED bars. By building suitable power supplies, it is possible to increase the number of LED bars that can be connected to the single power supply as desired.

For the lighting of work and commercial environments, the LEDs used are typically white LEDs; However, colored LEDs can also be used to achieve different aesthetic effects.

Claims (10)

R I V E N D I C A Z I O N I 1) Lamp (1) for lighting large surfaces, using a plurality of LEDs as a light source characterized by the fact of have a modular structure, comprising: ∠’a power supply (2), ∠’at least one LED bar (3) e ∠’at least one terminal support (4 or 6). 2) Lamp (1) for lighting large areas according to claim 1, in which the power supply (2) is equipped with sockets (21) for a number of LED bars (3) greater than one , which do not necessarily have to be used all at the same time; these attachments allow to fix the central LED bar (3a) parallel to the power supply axis (2), while the lateral LED bars (3b, 3c) can be fixed with an inclination of the longitudinal plane of the bar from 0 ° to ± 15 °. 3) Lamp (1) for lighting large-area environments according to claim 1, in which the LED bars (3) comprise at least one module (12) comprising a printed circuit (9) on which a number is mounted default of LED (5); the LED bars (3) also comprising an extruded metal profile (7) with holes at the ends for fixing to the power supply (2) and to the terminal support (4 or 6), and a transparent protection (11), both cut made to measure according to the number of modules (12) inside the LED bar (3). 4) Lamp (1) for lighting large-area environments according to claim 3, wherein the LED bar (3) optionally comprises secondary optics (10) in correspondence with the LEDs (5); said secondary optics (10) can be single for the single LED or multiple for groups of LEDs. 5) Lamp (1) for lighting large-area environments according to claim 3, in which the LED bars (3) are organized in modules (12), each module (12) comprising a printed circuit (9) , constructed in such a way that the LEDs (5) of a single module (12) are placed in parallel with each other, while the modules (12) inside the LED bar (3) are in series with each other. 6) Lamp (1) for lighting large-area environments according to one of claims 1 to 5, in which the LED bars (3a, 3b, 3c) are arranged parallel to each other. 7) Lamp (1) for lighting large areas according to one of claims 1 to 5, in which the lateral LED bars (3b, 3c) are arranged divergently from each other with an angle between 5 ° and 40 ° with respect to the central bar (3a) of each group. 8) Lamp (1) for lighting large areas according to one of claims 1 to 5, in which the LED bars (3) are mounted between two end supports (4), while the power supply (2 ) It is mounted above the LED bars (3) and the end supports (4). 9) Lamp (1) for lighting large-area environments according to claim 8, in which a protection (13) is optionally interposed between the LED bars (3) and the power supply (2). 10) Lamp (1) for lighting large area environments according to one of the preceding claims, making use of white or colored LEDs (5).