|1.||WO||WO/2013/177724 - MONO (MULTI) CRYSTAL SILICON SOLAR CELL ASSEMBLY USED FOR BUILDING ROOF TILE||05.12.2013||
|PCT/CN2012/000870||HEFEI CHINALAND SOLAR ENERGY CO., LTD||DONG, Peicai|
A monocrystalline or multicrystal silicon solar cell assembly used for building roof tile comprises solar cell components (1) arranged on a roof frame (2) in turn. The solar cell component (1) is composed of an assembling frame (4) and solar cell plates (3) fixed therein. A junction box (5) is provided at backside of the solar cell plates (3), and one positive and one negative pole connecting wires are lead out from the junction box (5). The assembling frame (4) is composed of an upper short frame (6), a lower short frame (7), a left long frame (8) and a right long frame (9) which are respectively provided with a groove matched with the solar cell plate (3) and provided with a mounting groove matched with the roof frame (2). A laminated board is cushioned between the solar cell plates (3) and the upper short frame (6), the lower short frame (7), the left long frame (8) and the right long frame (9).
|2.||WO||WO/2013/177845 - STRUCTURE FOR QUICK ASSEMBLY AND DISASSEMBLY OF SOLAR PANEL BRACKET||05.12.2013||
|PCT/CN2012/078186||XIAMEN GRACE SOLAR TECHNOLOGY CO., LTD||HUANG, Laifu|
A structure for quick assembly and disassembly of a solar panel bracket, comprising a guide rail (9); the guide rail (9) comprises at least one first groove (10); the opening end of the first groove (10) is provided with an inwardly extending inner edge (11); the end of the inner edge (11) is provided with a stopper part (12) reversely protruding toward the orientation of the opening; the stopper (12) is provided with back to back oblique guide surfaces; an upper clamping block (30) having a threaded hole is movably fitted in the first groove (10), and the tail end thereof in the first groove (10) is matched with the oblique guide surfaces of the stopper (12); the upper clamping block (30) can extend into the first groove (10) in an oblique attitude; when the upper clamping block (30) is under a vertical pulling force, the tail end thereof can be positioned and fixed after matching with the oblique guide surfaces, thus saving the matching time of the upper clamping block (30) and the guide rail (9), and ensuring fixing precision. The present invention has fewer moving parts, and is reliably fixed, with simple and quick assembly and disassembly.
|3.||WO||WO/2013/177962 - AUTOMATIC SOLAR TRACKING ADJUSTMENT AND CONTROL DEVICE FOR SOLAR POWER GENERATION UNIT||05.12.2013||
|PCT/CN2013/071456||TOPPER SUN ENERGY TECHNOLOGY CO., LTD.||LUO, Chia-Ching|
An automatic solar tracking adjustment and control device for a solar power generation unit comprises: a support assembly (1); a pivot assembly (5) which can achieve two-dimensional pivoting movement and is arranged on the support assembly (1); a solar power generation module (2) which can accept the action of solar light to generate electric energy and is arranged on the support assembly (1) via the pivot assembly (5); at least one linkage assembly (3, 4, 7, 8) arranged between the support assembly (1) and the solar power generation module (2), the linkage assembly (3, 4, 7, 8) respectively driving the solar power generation module (2) to slope in different directions and angles through a control unit according to a standard parameter thereof stored in advance; and a detection and correction module (6) which is arranged on the solar power generation module (2), can sense actual parameters such as the corresponding direction and slope angle of the solar power generation module (2), etc., and is compared with the standard parameter stored in advance to correct the linkage assembly (3, 4, 7, 8) according to the comparison result, so as to enable the slope direction and angle of the solar power generation module (2) to approach the standard parameter to make adjustment.
|4.||WO||WO/2013/178641 - ELECTRICAL CONNECTION AND JUNCTION BOX FOR A SOLAR CELL MODULE||05.12.2013||
|PCT/EP2013/060992||KOSTAL INDUSTRIE ELEKTRIK GMBH||SCHMIDT, Marcel|
According to the invention, an electrical connection and junction box for a solar cell module, comprising a housing, in which a connecting device for electrically contacting the conductor strips of the solar cell module with connection cables led out of the housing is accommodated, the connection cables each being provided with a plug connector at the ends of the connection cables facing away from the housing, and retaining devices being present on the outside of the housing, on which retaining devices the plug connectors can be detachably fastened, is characterized in that the retaining device are designed in such a way that the plug connectors accommodated in the retaining devices are retained in such a way that the plug connectors are fixed in the axial and radial directions and freely rotatable about the longitudinal axes of the plug connectors.
|5.||WO||WO/2013/179287 - PHOTOVOLTAIC MODULE ASSEMBLY||05.12.2013||
|PCT/IL2013/050459||ESSENCE SOLAR SOLUTIONS LTD.||HASIN, Slava|
A concentrated photovoltaic receiver and backplane assembly is described herein. A thermally conductive heat spreader is configured between the receiver and the backplane for dissipating at least a portion of the thermal energy in a direction including a horizontal component towards a portion of the heat spreader which is not directly in contact with a receiver portion. In some embodiments, the heat spreader is electrically conductive and is adapted for conducting current from the receiver to the backplane. In some embodiments, a surface area of a receiver substrate is less than 5 times larger than a surface area of a solar cell that is mounted onto the receiver substrate. In some embodiments, the receiver substrate comprises vias for conducting current from a top face to a bottom face of the receiver.
|6.||WO||WO/2013/179387 - SOLAR CELL MANUFACTURING METHOD, SOLAR CELL MODULE MANUFACTURING METHOD, AND SOLAR CELL MODULE||05.12.2013||
|PCT/JP2012/063762||SANYO ELECTRIC CO., LTD.||TAIRA, Shigeharu|
This solar cell module (10) is manufactured by connecting in series with a wiring material (15) multiple solar cells including at least two types of solar cells (11A, 11B) having different electrode structures, and covering the same with a first protective member (12) and a second protective member (13). By producing a photoelectric conversion unit, measuring characteristic values of the photoelectric conversion unit, and selecting electrode structure on the basis of the characteristic values, it becomes possible to achieve the same level of characteristics in all of the solar cells, resulting in increased yields.
|7.||WO||WO/2013/179444 - MEASUREMENT DEVICE FOR TEXTURE SIZE, MANUFACTURING SYSTEM FOR SOLAR CELL, AND MANUFACTURING METHOD FOR SOLAR CELL||05.12.2013||
|PCT/JP2012/064103||SANYO ELECTRIC CO., LTD.||INOUE, Hirotada|
A manufacturing method for a solar cell (10), wherein after a texture (26) is formed on a principal surface of a substrate (21), infrared light in a predetermined wave number range is applied to a portion, on which the texture (26) is formed, of the principal surface, a wave number at a specified transmission detection rate of the infrared light transmitted through the substrate (21) and detected is acquired, the Tx size of the substrate (21) is calculated on the basis of the acquired wave number using a previously obtained relationship between the wave number at the specified transmission detection rate and the Tx size, and when the calculated Tx size is within a reference value range, a collecting electrode is formed on the principal surface.
|8.||WO||WO/2013/179500 - SOLAR CELL MANUFACTURING METHOD, SOLAR CELL MODULE MANUFACTURING METHOD, AND SOLAR CELL MODULE||05.12.2013||
|PCT/JP2012/068820||SANYO ELECTRIC CO., LTD.||TAIRA, Shigeharu|
This solar cell module (10) is manufactured by connecting in series with a wiring material (15) multiple solar cells including at least two types of solar cells (11A, 11B) having different electrode structures, and covering the same with a first protective member (12) and a second protective member (13). This solar cell is manufactured by producing a photoelectric conversion unit, measuring characteristic values of the photoelectric conversion unit, selecting electrode structure on the basis of said characteristic values, and forming an electrode on the photoelectric conversion unit.
|9.||WO||WO/2013/179530 - PHOTOELECTRIC CONVERSION DEVICE||05.12.2013||
|PCT/JP2013/001215||PANASONIC CORPORATION||SHINOHARA, Wataru|
The present invention improves photoelectric conversion efficiency in a photovoltaic device. This photoelectric conversion device is provided with: a front surface glass plate; a photoelectric conversion unit, which is fixed onto the front surface glass plate, and which generates power corresponding to input of light; and a rear surface glass plate, which is disposed to cover the photoelectric conversion unit. In the photoelectric conversion device, at least a part of the periphery of the front surface glass plate and that of the rear surface glass plate are melted and bonded to each other, and the photoelectric conversion unit has a plurality of photoelectric conversion elements connected in series or parallel.
|10.||WO||WO/2013/179564 - SOLAR CELL AND METHOD FOR MANUFACTURING SAME||05.12.2013||
|PCT/JP2013/002784||PANASONIC CORPORATION||NOBORI, Kazuhiro|
Provided is a solar cell, which has excellent heat dissipating characteristics, excellent manufacturing qualities, and a shorter production lead time. This solar cell has: a substrate having a board-like base, and a first conductive line and a second conductive line, which are disposed on the board-like base; a plurality of multi-junction solar cells, each of which has a lower electrode bonded on and electrically connected to the first conductive line, a cell laminate, which is disposed on the lower electrode, and which includes a bottom cell layer and a top cell layer, a transparent electrode disposed on the upper surface of the top cell layer, and a conductor that connects the transparent electrode to the second conductive line; a glass plate, which has upper portions of the transparent electrodes of the multi-junction solar cells bonded to one surface thereof using an adhesive; and a collecting lens, which is disposed on the other glass plate surface with a transparent adhesive therebetween.