ITRM20100690A1 - PHOTOINDUCTIVE PANEL - Google Patents

Description

Description Photoinductive panel

Field of interest: renewable energies.

The Photoinductive Panel (Table 1, Figure 1) is an instrument that produces electrical energy through the indirect transformation of solar radiation.

Currently solar panels directly convert photons into electrical energy, based on the photoelectric effect. The photoinductive panel, on the other hand, is based on a principle totally different from the photoelectric effect, exploiting an indirect conversion of solar radiation into electricity through a previously unknown electric induction effect, obtaining higher yields than a traditional solar one for the same exposed surface.

The Photoinductive Panel fits perfectly into the field of renewable solar energy by providing higher yields than traditional photovoltaics and partly solving the problem depending on the orientation that characterizes current photovoltaic panels. In fact, the Photoinductive Panel, having a surface of the individual cells much greater than the surface of a standard photovoltaic cell (it is possible to make cells with areas of several hundred square cm), enjoys a greater effective irradiation angle.

Furthermore, with the same performance, the Photoinductive Panel has a surface, and therefore a final size, smaller than that of traditional photovoltaics, allowing the construction of more compact systems with less impact on the landscape.

The Photoinductive Panel is composed of a production block composed of several hundreds of superimposed pairs of metal sheets of copper and aluminum with a thickness of a few microns, with a watertight dielectric frame in the center that serves to contain a mixture of magnesium hydroxide and water used as a catalyst element of the induction effect which is mixed with thickeners, such as vegetable starches, gelling agents, polymers, resins or plastic powders, which only serve to facilitate the industrial application of the catalyst.

An upper plate of blackened copper is added to the production block to increase the absorption spectrum of solar radiation. The plate has a greater thickness than the thickness of the other sheets (about one millimeter), thus allowing not to damage the production block due to the high energy focused by the lens. Instead, an aluminum sheet is placed on the lower part of the production block which is also thicker than the thickness of the other sheets (about one millimeter); this plate serves only to facilitate the transport and positioning of the other sheets constituting the production block. Two electrodes are welded onto the upper and lower plate which are able to take the current produced and transmit it to a user device. A watertight protective sheath is placed around the cell block as an additional protection to prevent leakage of the catalyst element of the induction effect. The whole is then enclosed in an insulating casing and irradiated by sunlight through a Fresnel lens placed on the upper part of the same.

The Panel is represented in figure 1 of table 1.

The scheme of one of the production pairs is shown in figure 2 of table 1.

The Panel is made up of a series of a thousand superimposed pairs of metal sheets (table 1, figure 1, element I), each of which is composed of a copper sheet (table 1, figure 2, element O) and one of aluminum (table 1, figure 2, element R) separated by an element (magnesium hydroxide, water and thickeners) catalyst of the induction effect (table 1, figure 2, element Q) bordered by a watertight sheath ( table 1, figure 2, element P). The entire series of foils, hereafter referred to as the production block, is positioned between a blackened copper plate (to increase the absorption of sunlight) with a thickness of one millimeter (table 1, element H) and a plate of aluminum, also of one millimeter (table 1, element J). A watertight protective sheath is placed around the cell block (table 1, element D) and on the two plates (upper and lower), composed respectively of copper and aluminum, two electrodes are welded (table 1, element C, E), in turn welded to the two electric wires at the output which are used to take the current produced by the Panel. Insulating material is placed under the aluminum foil and around the edges of the cell block (table 1, element K, M) equipped with two holes provided with gaskets (table 1, element F, G) to let out the cables . All this is placed inside a heat-resistant plastic casing (pl. 1, element L, N) slightly higher than the cell block; the casing is equipped, on the bottom, with two holes for the exit of the electric cables and a frame lid (table 1, element A) with a hole in the center which contains a Fresnel lens (table 1, element B). The frame is fixed to the casing with screws inserted in the appropriate holes in the frame (table 1, figure 1, element S) which are inserted into the edges of the casing itself which contain as many threaded holes for re-inserting the screws (tab. 1, figure 1, element T).

Claims (2)

- Photoinductive Panel Claims 1) Photoinductive panel composed of various / overlapping pairs of metal sheets formed by copper and aluminum, with a mixture of magnesium hydroxide and water in the center as a catalyst element of the induction effect radiated by sunlight through a focusing lens and enclosed in a insulating casing. 2) Photoinductive panel according to claim 1, characterized in that the lens used 3) Photoinductive panel according to claim 1, characterized by the fact that the catalyst element of the induction effect is mixed with a thickener, such as vegetable starches, gelling agents, polymers, resins or plastic powders, suitable for making application easier industrial catalyst. 4) Photoinductive panel according to claim 1, characterized by the fact that it uses a final upper layer of blackened copper to increase the absorption spectrum of solar radiation with a thickness greater than the thickness of the other sheets, thus allowing not to damage the production block due to of the high energy focused by the lens. 5) Photoinductive panel according to claim 1, characterized in that it uses insulating material to limit thermal exchanges with the environment, avoiding too high production changes. 6) Photoinductive panel according to claim 1, characterized in that it uses a lower final layer of aluminum with a thickness greater than the thickness of the other sheets to make the structure of the production block more stable. 7) Photoinductive panel according to claim 1, characterized in that a watertight protective sheath is placed around the cell block as a further protection to avoid losses of the catalyst element of the induction effect.