Patent Application
20090032100
The current application relates to a metal awning structure with solar cell plates installed thereon, especially to an awning that can be adjusted manually according to the movement of the sun.
Since the development of photovoltaic solar cell, many kinds of solar cells and methods of assembling the cells into a module, including the methods of assembling the solar cells for mounting on a house roof, have been introduced. Those methods teach only how to assemble each solar cell and the parts to connect them in a planar shape. According to those illustrations, a lot of heavy metal parts and ceramic insulators are necessary to make whole solar cell modules for mounting them on the roof of a house. The final solar cell module for a house may too heavy for the roof of a house. The heavy weight of the module limits the number of module plates that can be installed on a roof and the magnitude of the power that can be got from them. Moreover, the roof top mounted solar cell plates have a fixed position. This limits the efficiency of utilizing sunlight. However, there are many other places that solar cell plates can be installed. An awning is an instrument that provides shades over a window to block the heat of the sun. It is the purpose of the current application to create an awning that collects the sunlight to generate electricity and maximize the efficiency of the sunlight until sunset.
U.S. Pat. No. 4,238,912 to Mac Donald, U.S. Pat. No. 4,860,509 to Laaly, et al., U.S. Pat. No. 5,232,518 to Nath, et al., U.S. Pat. No. 5,409,549 to Mori, U.S. Pat. No. 5,990,414 to Posnansky, U.S. Pat. No. 6,065,256 to Joko, et al., U.S. Pat. No. 6,606,830 to Nagao, et al., and U.S. Pat. No. 4,636,577 to Peterpaul illustrate a solar panel module for direct mounting on a roof surface. Irrespective of the way of the solar cells are assembled, all methods need many connecting parts comprised of heavy weights.
U.S. Pat. No. 4,204,523 to Rothe illustrates a support for mounting solar energy collectors on the roof of a building, which roof has an opening in the roof sheeting, including a shell that has a generally flat rectangular base and an upstanding edge secured to, and extending about, the periphery of the shell. The frame is configured and dimensional to correspond to the outer surface shape of the roof sheeting and to permit mating receipt thereof in the opening of the sheeting. The mounting support consists of a flat, rectangular shell having a shell edge and a shell bottom. An outer frame surrounds this flat shell, which in its shape is adapted to the shape of the roof sheeting. Thereby, outer frame imitates the form of the often-used roof tiles or any other type of roof sheeting, so that an even sealing off is obtained when inserted into the existing roof sheeting in a manner in which the roofing tiles seal off with each other. The purpose of this solar cell support is to seal off the openings of the roofing.
None of the prior arts illustrate a support frame structure for mounting solar cell plates on an awning of a window to collect the solar energy and shade the window at the same time.
Since the development of photovoltaic solar cell, many kinds of solar cells and methods of assembling the cells into a module, including the methods of assembling the solar cells for mounting on a house roof, have been introduced. Those methods teach only how to assemble each solar cell and the parts to connect them in a planar shape. According to those illustrations, a lot of heavy metal parts and ceramic insulators are necessary to make solar cell modules for mounting them on the roof of a house. The final solar cell module for a house may be too heavy for the roof of a house. The heavy weight of the module limits the number of module plates that can be installed on a roof and the magnitude of the power that can be got from them. Moreover, the roof top solar cell plates have a fixed position. This limits the efficiency of utilizing sunlight. However, there are many other places that solar cell plates can be installed. An awning is an instrument that provide over a window to block the heat of the sun. It is the purpose of the current application to provide an awning that collects the sunlight to generate electricity and maximize the efficiency of the sun light until the sun set. The solar cell plates mounted awning according to current application can manually be positioned according to the movement of the sun. The awning is comprised of a square metal frame that has multiple square sectional divisions. Solar cell plates are installed on each dividing. Two wheels that rotate-ably attached on each corner of the upper end of the awning, two rails are fixed to a part of wall above a window and two telescopic supporting arms connected both sides of the awing and the wall enables the awning to change its position according to movement of the sun. The owner of the house, who installed the awning, can enjoy the sunset over the window while the awning absorbs the last of the sunlight to provide electricity for the appliances inside the room.
Upper end (9-1) of the supporting arm (9), which is a part of the upper body (9-U), has an open hole (9-H), through which a side shaft (1-S) of the awning (1) is engaged. One end of the side shaft (1-S) is welded to a side of the awning (1). The other end of the side shaft (1-S) is screw threaded. A nut (9-N) is engaged to the screw threaded end of the side shaft (1-S).
The lower end (9-2) of the supporting arm (9), which is a part of the lower body (9-L), also has a second open hole (9-H′). The second open hole (9-H′) is inserted between two wings (9-3) of a flange (9-4) that is fixed to the wall (7) via screw bolts (9-5) through holes (9-6). When the lower end (9-2) of the supporting arm (9) is inserted between the two wings, the second open hole (9-H′) and another two holes (9-7) that are developed on the wings (9-3) are aligned. Then a pin (9-8) is inserted through the holes (9-H′), (9-7) and locked by a nut (9-9).
The upper body (9-U) and the lower body (9-L) of the supporting arm (9) are telescopically connected. The upper body (9-U) is slide-ably engaged into the lower body (9-L). Pluralities of small holes (9-S) are developed along the length of the both bodies (9-U), (9-L). Relative position of the both bodies (9-U), (9-L) are adjusted by pulling out and pushing the upper body (9-U) from and into the lower body (9-L). Positions are fixed by a small pin (10).
