An electrical and/or electronic device including at least two electrical and/or electronic components, each including two opposite faces, at least one electrical contact element arranged against at least one of the two opposite faces of each of the at least two electrical and/or electronic components, and each of them is mechanically protected by a mechanical protection system including at least one protective element, superimposed on one or plural electrical and/or electronic components that it protects such that at least one of the two opposite faces of the electrical and/or electronic components is arranged facing the at least one protective element, and at least one deformation absorption element is arranged in at least one space formed between the at least one protective element and at least one electrical and/or electronic component that it protects.

The Green Energy Smart Window of Wireless Window 5R System W5RS is constituted of the Multimedia panel, the Electrochromic panel and the transparent Solar panel, etc. The Green Energy Smart Window harvests solar energy with transparent solar panel to be electric energy to provide power to smart Multimedia panel and smart Electrochromic panel, etc. W5RS is the Green Energy Smart Window of the next generation smart home standard. W5 represents Wireless Wireline Weave Wishful Window. 5R represents Recycling Resonant Resynchronization Rectifying Regulator. The novel 5R can have the AC/DC power efficiency 95% which is the highest for the wireless power supply standards. 5S represents Smart Solar Supply Silicon System. W5RS is the killer application and 5R is the killer core technology. To integrate the W5RS technology to be the Green Energy Smart Window, the W5RS adopts the 23Less Green Technology. The 23Less Green Technology are the Noiseless Field System On Chip FSOC, Curtainless Window, Bladeless Turbofan, Brakeless Vehicle, Sawless LNA, Resistorless, Capless, Inductorless, Diodeless Random Number Generator, Xtaless Clock Generator, Clockless Switch Mode Power Supply, Ground-Bounceless I/O, Switch Lossless Rectifier, Power-Lossless PA, Rippleless and EMI-Less Battery Charger, Overshootless and Rippleless LDO.

In the soil cultivation system (80) equipped with a solar panel, a light transmitting region (A) is provided in a solar panel (50), and thus a larger amount of light is captured into a frame unit and can thereby be utilized for the cultivation of agricultural plants (P1, P2). Double-sided light receiving solar cells (52) are adopted in the solar panel (50), and thus light reflected off an agricultural ground surface, the agricultural plants (P1, P2), a sheet-shaped member and the like can be effectively utilized for power generation. In this way, it is possible to compensate for a reduction in the area of the solar cells caused by the formation of the transmitting regions A, and it is possible to obtain a large amount of power generated while acquiring the amount of light on the agricultural plants.

Provided is a solar battery module having an outer edge maintained by a frame, and comprising a group of strings formed by using a plurality of solar battery cells, connecting adjacent solar battery cells in a longitudinal direction by an inter-cell wiring material to form a plurality of strings, and arranging the plurality of strings in a transverse direction, wherein a spacing distance A between the interior of the frame and the frame-side edge of solar battery cells of the outermost string in the group of strings, a spacing distance B between solar battery cells constituting adjacent strings in the group of strings, and a spacing distance C between the solar battery cells in the transverse direction satisfy the relationship {(995A20C)/1005}<B<{(1005A+20C)/995}. Additionally, an olefinic resin is used in a first sealing member on the light receiving surface side.

The disclosure relates to solar cell, and especially to a method for manufacturing a crystalline silicon solar cell module. The method includes: a) providing a solar cell module to be laminated, including a back plate, a first bonding layer, a crystalline silicon solar cell component, a second bonding layer and a top plate in contact in sequence, where the crystalline silicon solar cell component is a crystalline silicon solar cell or a cell string formed by connecting multiple crystalline silicon solar cells; b) laminating the solar cell module to be laminated under current injection, to obtain a laminated solar cell module; and c) installing a frame and a junction box on the laminated solar cell module, to obtain a crystalline silicon solar cell module. The crystalline silicon solar cell module is under the current injection during the laminating process, improving the performance against light-induced degradation.

The present invention relates to systems and methods for solar energy utilization. One embodiment of the present invention relates to a rotating panel system for solar energy utilization, including thermal, electrical, and visual applications. The system includes a plurality of rotatable panels, a rotation system, and a housing. The housing both mechanically supports the rotatable panels and thermally insulates and/or redirects the heat and/or electricity generated by the panels. A second embodiment of the present invention relates to an automatic climate control system utilizing a rotating panel system. The system includes an enclosed region and a multi-panel solar system. The multi-panel solar system is positioned to extend between the interior and exterior regions of an enclosed region. A third embodiment of the present invention relates to a method for utilizing a plurality of panels to desirably accommodate for visual and thermal forms of solar energy. The method includes positioning a multi-panel solar system in an unobstructed interior to exterior recess and rotating the panels so as to optimally affect the thermal and visual components of the solar energy, depending upon the application.

A solar module assembly is provided that can include a framed solar panel. The panel may include bifacial solar cells, a front facing glass cover layer, and a back facing glass cover layer. A junction box may be mounted over the back facing glass cover layer. In particular, the back facing glass cover layer may have a cutout portion through which conductive leads connect to the bifacial solar cells and the junction box. The cutout portion may be formed along an edge or a corner of the back facing glass cover layer. The frame may have a first flange member that extends at least partially over the junction box and a second flange member that extends over the front facing glass layer. The junction box and the frame may be attached to the solar panel and hermetically sealed using silicone adhesive material, for example.

In a solar cell module, a first encapsulant and a second encapsulant are provided between a first protective member and a second protective member, and solar cells are provided between the first encapsulant and the second encapsulant. A connecting tab wire cover is laminated on the first encapsulant. A connecting tab wire encapsulant is laminated on the connecting tab wire cover. The multiple solar cells are laminated on the first encapsulant. Through a slit formed on the connecting tab wire encapsulant, fixing members fix a connecting tab wire, which connects multiple solar cells, and the connecting tab wire cover.

One embodiment of the invention can provide a solar panel. The solar panel can include a plurality of strings of photovoltaic strips sandwiched between a front cover and a back cover. The strings can be arranged into an array that includes multiple blocks, and a respective block can include a subset of strings that are electrically coupled to each other in parallel. The subset of strings within the block can be coupled to a bypass diode. The multiple blocks can be electrically coupled to each other in series.

A solar cell module includes a solar cell panel and a first flame. The solar cell panel includes first and second substrates that are rectangular, and a photoelectric convertor. The first substrate includes a first extension portion and has: a first surface; a second surface on a back of the first surface; and a first A-side and a second A-side facing to each other. The second substrate has a third surface facing the second surface, a fourth surface on a back of the third surface, and a first B-side and a second B-side facing to each other. The photoelectric convertor is arranged between the second surface and the third surface. The first flame includes a first fixing portion that fixes an end of the first extension portion that extends more outside than the first B-side of the second substrate. The first fixing portion forms a groove with the second substrate.