ITRN20090056A1 - LED LIGHTING DEVICE - Google Patents

Description

DESCRIPTION

â € œLED LIGHTING DEVICE.â €

The invention relates to a LED lighting device.

Nowadays, the problem of being able to illuminate streets, parking lots, urban areas and even interiors and exteriors of residential, working, commercial, sports, recreational buildings, using LED systems in such a way as to have an illuminated surface as much as possible, is particularly felt. uniform and of adequate luminous intensity and in line with regulations.

LED lighting, although it offers the advantage of an important containment in energy consumption and a much longer duration of the LEDs themselves than the other most commonly used devices on the market, on the other hand it presents a problem given by the geometric characteristics of the light beam obtainable with this technology. In fact, the emission angle of this light beam normally assumes very low values and this makes this type of light tending to a point light, otherwise definable as a â € œ spot effectâ €. This makes it impossible for lighting devices equipped with LEDs only and without lenses or optics to illuminate sufficiently large surfaces and to do so in a homogeneous way.

To partially obviate this problem, it is known to use particular lenses preferentially shaped like a truncated cone and with a geometric and optical axis perpendicular to the two parallel planes of the truncated cone. With these devices placed in front of the LEDs themselves, the optical axis of the lens is coaxial or coincident with the LED axis and an increase in the emission angle is achieved, thus opening the light beam and distributing the light on a larger surface. In physical terms this is equivalent to saying that, thanks to the use of lenses or optics of a known type, an increase in the solid emission angle and therefore a decrease in the luminous intensity is achieved with the same luminous flux. however, the advantage of a larger illuminated surface, thanks to the increased solid angle of emission.

The aforementioned lenses or optics of a known type are preferably made of plastic material with high optical qualities and are geometrically conceived as truncated cones with the two planes parallel to each other and perpendicular to the axis of the aforementioned cone.

From the point of view of mounting on the electronic board that will house these lenses inside a suitable container, the axis of these lenses coincides, as previously explained, with the axis of the LEDs previously fixed on the board.

described above, they are able to increase the angle of light emission without changing the optical axis. What is obtained is that the light produced by the LED effectively illuminates larger surfaces with a type of light that is no longer tending to point, but more extensive.

However, this known system has a major drawback given by the fact that it is impossible with this lens to be able to illuminate extended surfaces off-center with respect to the position of the LED itself, as in the case, for example, of a road. This limit is motivated by the fact that, starting from a certain angle of emission of the luminous flux of an LED, keeping the lens and the coaxial LEDs, it is impossible to illuminate large and decentralized surfaces only by intervening on the increase of the opening angle of the truncated cones that make up the geometry of the lenses.

The luminous yield on the ground that would be obtained by doing so would in fact end up being very low especially at the edges of the illuminated parts, which are further away from the light source. This low brightness would then be completely insufficient and inadequate to allow the luminous device to comply with the requirements of the street and urban lighting regulations.

To overcome this major drawback, the solution of arranging the LEDs and therefore the lenses on inclined support surfaces is known. In this way, the LEDs and the lenses are directed in such a way as to better reach the surfaces to be illuminated while maintaining high luminous yields. In fact, it should be noted that the variation of light intensity and flux with direction is of fundamental importance in all lighting devices. In fact, the characteristics of the luminous flux produced by an LED are not of the isotropic type but vary within the emission angle. This means that the closer you get to the limits of this emission angle, the smaller the flux itself. It is therefore evident that by keeping the support surfaces of the electronic boards on which the LEDs are fixed inclined, it is possible to take into account this characteristic of anisotropy of the LED light, emphasizing the use of light in the central area of the cone defined by the angle. of issue.

However, if on the one hand this solution allows to keep the brightness of the projected beam sufficiently high, on the other it requires, as mentioned, the construction of inclined supports for the electronic boards with fixed LEDs and lenses or optics. This often leads to an increase in the cost of processing which is more difficult. Moreover, by doing so, the electronic card can no longer be one with the various LEDs required, but it is necessary to prepare the assembly of several electronic cards, each for each inclined plane. This solution therefore leads to a significant increase in costs with respect to the single card, due to the higher cost of the cards themselves and to the costs for the electrical connections to be made between the various cards.

Another considerable drawback given by this type of solution is constituted by the fact that the construction of such inclined planes leads to a greater height of the card arranged inclined than when it is only one and is arranged on a single plane. This greater height therefore requires a greater height of the container that contains it and therefore of the luminous body. This leads to severe limitations in terms of style and an increase in the sections and volumes of material required with consequent considerable cost increases for the construction of the containers. This increase in volume and therefore in the weight and cost of the container then leads to the need to have poles, in the case of urban lighting, of greater section to cope with the greater bending moments induced by the greater weight of the lighting body, and therefore to a further increase in costs.

The main task of what is the subject of this application is therefore to solve the technical problems highlighted, eliminating the drawbacks referred to in the prior art in specific areas such as urban, street, external and internal lighting of residential and working buildings, commercial, sporting, recreational.

This important task is accomplished by a solution that has the possibility of illuminating surfaces of greater extension and decentralized with respect to the lighting body without having to resort to the inclined planes mentioned above. In this way, important increases in luminous yields are achieved, it is possible to illuminate areas that are decentralized with respect to the lighting body that would otherwise remain in the shade or with insufficient lighting, a fundamental technical solution is available for compliance with the requirements of the regulations on urban and street lighting, significant reductions in the costs of creating the lighting fixtures and a reduction in construction times are achieved.

The aforementioned task and purposes, as well as others that will appear more clearly later, are achieved with a lens or optic that is characterized by the fact that it is made as a full truncated cone, or in any case as a full truncated cone of a solid of revolution. , but with an axis of revolution and optical inclined with respect to the perpendicular to the support plane of the solid of revolution itself. This inclined optical axis makes the optic realized in this way different from the lenses of the known art, where instead this axis is perpendicular to the support plane.

Further characteristics and advantages of the invention will become clearer from the detailed description of a particular, but not exclusive embodiment, illustrated by way of non-limiting example, in the attached drawings in which:

Figure 1 illustrates the invention in a condition of use according to a side view, with some parts removed to better highlight others;

- figures 2 to 7 show a detail of the invention, respectively according to a plan view from below, according to a front view, according to a plan view from above, according to the section V-V of which in figure 4, according to a view perspective from below and according to a perspective view from above;

Figures 8 and 9 illustrate the invention in the condition of Figure 1 according to sectional views, respectively lateral and front; Figures 10 to 12 illustrate a preferred embodiment of a detail of the invention, respectively according to a perspective view, according to a top plan view and according to the section XII-XII of Figure 11;

Figures 13 to 15 illustrate the invention according to a multiple solution, respectively according to a perspective view, according to a side view and according to a plan view from below; - figure 16 illustrates the invention in a condition of use relating to the solution of the preceding figures according to a side view and the relative effects;

Figures 17 to 19 show a detail of the invention according to a multiple solution, respectively according to a plan view from below, according to a perspective view from above and according to a perspective view from below.

As can be seen from the figures, the invention relates to a LED lighting device. The device (10) comprises an electronic support card (2), at least one luminous LED (3), with an optical axis (3b), applied to the electronic card (2), so as to be connected to a power supply network, at least one lens (1), provided with at least one seat (1 a), able to house at least one LED (3). The lens (1) has an optical axis (1 b) inclined at an angle (β) with respect to the optical axis (3b) of the LED (3).

Figure 1 represents the way in which the device (10) can be used inside a lamppost (5) to illuminate, for example, the roadway. Compared to the known solutions, it is possible to appreciate the deviation of the light beam and the widening of the illuminated area.

Although the lens (1) can be made in many forms equivalent to each other for the purposes of the efficacy of the invention, in figures 2 to 7 it has been represented constituted by a trunk of a solid, in particular by a trunk of cone obtained by dissecting a cone with planes (Ï € -ι, Ï € 2) not perpendicular to the axis, and in particular parallel to each other.

Figure 5 shows the section along the median plane of the truncated cone constituting the lens (1). The truncated cone is characterized by an opening angle a and an inclination angle β of the optical axis (1b) of the cone, and therefore of the lens (1), with respect to the optical axis (3b) of the LED ( 3). The planes (Ï „Î ·, Ï € 2) that help to define the truncated cone, shown here parallel, may not be.

Figures 8 and 9 represent an enlarged view of the application of Figure 1; in them, the device (10) appears according to two orthogonal views which illustrate the lens (1) mounted on the electronic board (2) where the LED (3) is also fixed. Figure 8 shows the inclined optical axis (1 b) of the lens (1), as well as the way in which the light beam is reflected on the perimeter walls of the lens (1), while in figure 9 this optical axis ( 1b) appears perpendicular to the support plane since the view is rotated 90 ° with respect to the previous one.

This important effect, which constitutes the inventive principle of the invention, is obtained thanks to the particular geometry of the lens (1), whose optical axis (1b) is inclined with respect to the optical axis (3b) of the LED (3). In this way, the lateral surface (1c) of the lens is able to reflect at least part of the light radiation received inside the truncated cone, modifying the inclination of the optical axis (1 b) of the lens (1 ) of an angle β. Although this reflection can be obtained for particular values of the inclination of the lateral surface (1c) of the lens (1), this effect can be produced as an alternative or supplement to the previous one thanks to an opacified lateral surface (1c) of the lens (1) .

In a preferred solution, shown in Figures 10 to 12, the lens (1) is provided with an anti-glare surface (4), which in this embodiment is constituted by a plurality of flat and inclined surfaces (4a).

In practical applications, the device (10) can comprise a plurality of bright LEDs (3) and a plurality of lenses (11, 12, 13 ...) associated with the LEDs (3) with optical axes (11b, 12b, 13b ...) inclined with angles (βι, β2, β3- - -) different from the optical axes (3b) of the LEDs (3).

This solution, represented in figures 13 to 16, can be obtained both with identical lenses (1) in various orientations, for example in a specular way, and with different lenses (1); used, for example, in a lamppost for street lighting, it allows to illuminate large portions of the surface in the best possible way, as can be clearly seen in figure 16. Naturally, the invention can be made in many embodiments, such as in case of the solutions represented in Figures 17 to 19, where configurations of multiple lenses (1) are represented, integrally or temporarily connected or connectable.

It was thus found that the invention has achieved the intended aim and objects, having provided a lighting device (10) capable of deflecting the optical axis of the light beam, thus obtaining the possibility of illuminating large and decentralized surfaces. compared to the lighting body. The costs and production times were very low and decidedly reduced compared to the known technique which would provide for the use of inclined support surfaces of the electronic boards, with the same LEDs and power used.

The invention is naturally susceptible of numerous modifications and variations, all of which are within the scope of the same inventive concept.

Naturally, the materials as well as the dimensions that constitute the individual components of the invention may also be the most pertinent according to specific requirements.

Claims (8)

CLAIMS 1. LED lighting device, comprising a supporting electronic card (2), at least one bright LED (3), with an optical axis (3b), applied to the electronic card (2), so as to be connected to a network power supply, at least one lens (1), provided with at least one seat (1a), able to house at least one LED (3), characterized in that the lens (1) has an optical axis (1 b) inclined at an angle (β) with respect to the optical axis (3b) of the LED (3). 2. Device according to claim 1, characterized in that the lens (1) consists of a trunk of a solid. 3. Device according to claim 1, characterized in that the lens (1) is provided with an anti-glare surface (4). 4. Device according to claim 2, characterized in that the lens (1) is a truncated cone obtained by sectioning a cone with planes (Ï „Ï„ ι, Ï € ∠‘) not perpendicular to the axis. 5. Device according to claim 3, characterized in that the anti-glare surface (4) comprises a plurality of flat and inclined surfaces (4a). 6. Device according to claim 1, characterized in that it comprises a plurality of luminous LEDs (3) and a plurality of lenses (11, 12, 13 ...) associated with the LEDs (3) with optical axes (1 1 b, 12b, 13b ...) inclined with angles (β1, β2, β3 ...) different from the optical axes (3b) of the LEDs (3). 7. Device according to claim 4, characterized in that the planes (Ï „Ï„ ι, Ï € 2) are parallel. Device according to claim 1 or 2, characterized in that the lens (1) comprises an opacified lateral surface (1c), so as to prevent the refraction of the light of the LED (3).