IT201700000161A1 - SUPPLY DEVICE INCLUDING PHOTOVOLTAIC PANELS ASSOCIATED WITH ARTIFICIAL LIGHT SOURCES, IN PARTICULAR FOR ELECTRONIC EQUIPMENT - Google Patents

Description

PATENT APPLICATION FOR INDUSTRIAL INVENTION WITH THE TITLE:

"POWER SUPPLY DEVICE INCLUDING PHOTOVOLTAIC PANELS ASSOCIATED WITH ARTIFICIAL LIGHT SOURCES, IN PARTICULAR FOR ELECTRONIC EQUIPMENT"

FIELD OF THE INVENTION

The invention subject of this application refers to the technical field of power supplies for electronic circuits.

STATE OF THE ART

The power supply of electronic equipment from the electrical network is notoriously a critical point of any project, due to the disturbances that are transferred from the electrical network, together with the supply voltages and currents, to the electronic circuit to be powered. Electromagnetic background noise, electromagnetic interference (EMI), spurious signals transferred capacitively or inductively or by radio frequency (RF) coupling are examples of the disturbances that can be transferred to the electronic circuit from and / or via the electrical network. There are numerous electrical filtering techniques developed to limit the drawbacks described. As effective as they are, however, the available filtering techniques can limit but not completely eliminate the problem.

An example of a device for powering electronic equipment designed to overcome the problems described deriving from the power supply from the electrical network is described in European patent application no. EP1396074, by the owner of the present application, relating to a power supply comprising a solar cell converter suitable for wrapping artificial light sources, powered by the electrical network, and for producing electrical energy which is effectively separated and galvanically isolated from the electrical network. A realization of the invention described in application no. EP1396074 above includes a parallelepiped-shaped structure - on whose internal walls are fixed solar cells - and having the upper part open to allow the dissipation of heat and the internal space suitable for accommodating a light source, even of high wattage, powered by the eletricity grid. The current supplied by the system described is effectively devoid of the disturbances caused by the power supply from the mains.

The system described in question no. EP1396074 above, however, has a drawback linked to the dimensions of the system structure itself which must necessarily occupy a considerable space, necessary for its installation and implementation. The volume of the structure represents a clear constraint as it cannot be reduced beyond a certain limit since the light source, having a 360 degree light emission, is placed in the center of the structure and therefore, to obtain the maximum energy transfer from the system , the greatest and most uniform possible illumination of the internal surfaces of the system structure covered by photovoltaic cells must be guaranteed. This requires that the structure itself has a certain footprint, so as to be able to distance the light source from the walls sufficiently to be able to optimize the lighting.

Furthermore, in the device described in application no. EP1396074 the structure of the described system is open in the upper part to allow the dissipation of the heat produced by the light source. This obviously involves the fact that part of the energy produced by the source is dispersed and not transformed into electric current, lowering the overall efficiency of the device.

The systems made according to this invention, for what has been said above, are difficult to use for the construction of portable systems or to be mounted in racks or small containers typical of electronic devices for domestic use. Furthermore, the systems made according to the invention described in application no. EP1396074, emitting a quantity of light dispersed through the upper part, can cause disturbance in all those cases in which the lighting of the environment in which the system is placed must be controlled. Examples are theaters, concert halls and similar environments where very low or no lighting is often required.

The present invention allows to overcome the technical problem described above, with the introduction of a power supply device capable of totally eliminating the disturbances present on the supply voltages and currents coming from the electrical network, said device being small in size, portable and having a flat structure and optimized efficiency as it is able to contain all the luminous flux emitted by the lighting sources used, eliminating any dispersion of light, while maintaining the ability to dissipate the heat produced by the light source by means of the use of a heat sink equipped with a suitable exchange surface.

Further objects, characteristics and advantages of the present invention will become clearer from the following detailed description, given in an exemplary and non-limiting form and illustrated in the attached figures in which:

Fig. 1 illustrates a first preferred embodiment of the present invention which employs an LED strip;

fig. 2 illustrates a second preferred embodiment of the present invention employing a plurality of LED strips;

fig. 3 illustrates said second preferred embodiment of the present invention which uses a plurality of LED strips, with the lid comprising the photovoltaic panels facing the LED strips arranged on the bottom of the container; fig. 4 illustrates a cross section of said second preferred embodiment of the present invention employing a plurality of LED strips;

DETAILED DESCRIPTION OF THE INVENTION

With reference to the attached figures, a preferred embodiment of the present invention comprises a container comprising a mounting base 1 suitable for housing a plurality of point light sources 2 and a cover suitable for housing at least one photovoltaic panel 3, said cover being able to engage with said container in such a way that said point light sources 2 and said at least one photovoltaic panel 3 are facing each other and suitably spaced apart. Said photovoltaic panel 3 can also be composed of single solar cells connected to each other so as to deliver the desired current and voltage. Said point light sources 2 are suitably connected to an input power supply wiring 4, possibly associated with a connector placed on the surface of said container, through which it is possible to supply the necessary power supply current and voltage to the point light sources 2. Similarly, said photovoltaic panel 3 is suitably connected to an output power supply wiring 5, possibly associated with a connector placed on said container, through which it is possible to supply the current and voltage supplied by the device according to the present invention, to an external user device .

When the container according to the present invention is closed, the distance between the light sources and the solar cells or panels also depends on the type of light source used. It can vary from zero, in the case of direct contact between the light source and the cells, to a distance such as to optimize the efficiency, normally chosen equal to about 1 - 2 centimeters.

Said point light sources 2 can be chosen from the categories available in the state of the art, among which the most widely populated includes LEDs (Light Emitting Diodes) and OLEDs (Organic Light Emitting Diodes). The LEDs used in the device according to the present invention can be arranged on the mounting base 1 in strips comprising a plurality of aligned LEDs, or in groups of single LEDs. Preferably the LEDs used are of the high luminous power type, capable of emitting 100 lm / Watt and more, and may also be of the so-called Chip On Board (COB) type, a technology that provides that the individual LED diodes are directly placed on a aluminum or ceramic substrate, having a surface that can be even a few square centimeters and then incorporated into the epoxy resin or silica gel. The lighting sources used, for example the LEDs used, are suitably fixed on said mounting base 1, which acts as a heat sink or is suitably associated with a heat sink, so as to ensure optimal heat transfer between the LEDs themselves and the base. assembly 1, so as to ensure the necessary heat dissipation to ensure that the LEDs themselves operate at operating temperatures such as to maximize their average life time. In fact, one of the most important parameters to consider during assembly is the thermal interface between LED and heatsink. If the LED is, for example, glued, it is important that the adhesive layer is as thin as possible in order to allow sufficient heat transfer. In addition, the contact surfaces between the LED and the heatsink are not perfectly smooth and have tiny cavities in which air can remain which acts as a thermal insulator, reducing the exchange. In order to reduce the thermal resistance and transfer the heat in the best way from the LED to the heatsink, therefore, special thermally conductive materials are used to fill the aforementioned surface cavities. Thermo-conductive pastes are effective, but rather difficult to use in mass production. Thermal pads or adhesive films are easier to handle, but have a less efficient thermal interface and therefore greater thermal resistance. Another option involves the use of phase change materials, designed to adapt to the surface of the heatsink and reduce the resulting thermal resistance. As for fixing the lighting sources, such as LEDs, on the heatsink, it is possible to use screws or special clips, commonly called holders, designed to press the LED onto the heatsink. LEDs fixed with screws often have an uneven temperature distribution, since the pressure exerted on the LEDs themselves is greater at the screwing points than, for example, at the points at the soldering points. The LEDs fixed to the heatsink by means of a holder have a more homogeneous temperature distribution, as the pressure applied on the LED is more uniform.

Said at least one photovoltaic panel 3 is chosen so as to provide a total output voltage and current of suitable value. A plurality of photovoltaic panels 3 can obviously be used if the voltage and current requirements make it necessary.

Photovoltaic panels can be of various types and made using various technologies. The type of photovoltaic panel to be used for the present invention is therefore chosen from among the various technologies available, so as to ensure maximum efficiency in relation to the operating conditions, the emission temperature, and the selected light sources. In any case, great attention must be paid to the choice of coupling between the photovoltaic panels, with the light sources that are used.

If LED devices are used with an emission characterized by a color temperature of around 3,000K, the most suitable photovoltaic panels to be used in the present invention are those made of polycrystalline silicon.

The sizing of the photovoltaic panel used, and therefore the current delivered and the voltage at the output terminals of the panel, is a function of the size of the panels used, their number and the series / parallel connections that are made between the aforementioned panels. The power obtainable by the device according to the present invention also depends on the efficiency of the photovoltaic cells and on the type of light sources used.

Typical powers that can be reached with the present invention are equal to 10 - 20 Watts with device dimensions of approximately 30cm x 20cm x 8cm. It is clear that, given the rapid progress of technology in this field, with the topology according to the present invention, even greater achievable powers and efficiencies are imminent.

In a preferred embodiment of the present invention, said mounting base 1 can be made by means of a profile, for example having a "U" cross section so that the bottom constitutes said mounting base 1 and the sides constitute the sides of the container of the device according to the present invention. Advantageously, a heat sink section can be chosen, suitably machined so as to be able to accommodate the LEDs used. In any case, the profile used can have different sections, however able to accommodate the LEDs used and to engage with the cover that houses the photovoltaic panel (s) so that said photovoltaic panels collect the emission of the LEDs, ensuring minimum light dispersion. on the outside.

If necessary, the container according to the present invention can be made with suitable protections against intrusions according to the IEC 60529 standard expressed through an IP code corresponding to the degree of impermeability achieved.

The device according to the present invention allows it to be made in different sizes, based on the current and voltage requirements to be met, always with a very low height compared to the other dimensions. The device according to the present invention is characterized by a minimized size which makes it portable and able to solve the aforementioned problems, linked to the disturbances caused by the power supply, even in those cases in which the available space is limited and in those cases in which the lighting of the environment in which the system to be powered is placed must be controlled and limited.

Claims (10)

CLAIMS 1. Power supply device comprising a container comprising a mounting base (1) which acts as or is suitably associated with a heat sink and is suitable for housing a plurality of point light sources (2) and a cover suitable for housing at least one photovoltaic panel (3), said lid being able to engage with said container in such a way that said point light sources (2) and said at least one photovoltaic panel (3) are facing each other and suitably spaced; said point light sources (2) being suitably connected to an input power supply wiring (4), said at least one photovoltaic panel being suitably connected to an output power supply wiring (5). 2. Device according to claim 1 characterized in that at least one of said input power supply wiring (4) and said output power supply wiring (5) is each connected to a different connector placed on the surface of said container. 3. Device according to one or more of claims 1 to 2, characterized in that said point light sources (2) are selected from the group comprising LEDs (Light Emitting Diodes) and OLEDs (Organic Light Emitting Diodes). 4. Device according to one or more of claims 1 to 3, characterized in that, when said container is closed, the distance between said light sources and said at least one photovoltaic panel (3) is selected in the range from zero to about 2 centimeters. 5. Device according to one or more of claims 1 to 4, characterized in that said point light sources (2) comprise LEDs of the high light power type, capable of emitting 100 lm / Watt and more 6. Device according to one or more of claims 1 to 5, characterized in that said point light sources (2) comprise LEDs of the so-called Chip On Board (COB) type. 7. Device according to one or more of claims 1 to 6, characterized in that said lighting sources are fixed on said dissipator by means of screws or by means of suitable clips, commonly known as holders. 8. Device according to one or more of claims 1 to 7, characterized in that said at least one photovoltaic panel is of the type made of polycrystalline silicon. 9. Device according to one or more of claims 1 to 8, characterized in that said mounting base (1) is made by means of a profile. 10. Device according to claim 9, characterized in that said profile has a "U" -shaped cross section such that the bottom constitutes said mounting base (1) and the sides constitute the sides of said container.