20160270563 SOLAR POWERED SYSTEMS AND DEVICES FOR IMPROVED SHOPPING CART CORRAL||US||22.09.2016|
||15071076||RENEWABLE EDGE LLC||Richard C. CONTRATA, JR.|
A solar power system that generates a power supply for features of a shopping cart corral is provided. In particular, a shopping cart corral has a self-contained solar power system for powering, directly by the corral or indirectly by the shopping carts, at least one of a personal device recharging system, lighting system, and advertising system.
20160272779 FLAME RETARDANT LED FOR INDOOR LIGHTING||US||22.09.2016|
||15034108||SOLVAY SPECIALTY POLYMERS USA, LLC||Alessandro BONGIOVANNI|
The present invention relates to Light Emitting Diode (LED) devices featuring outstanding reflectivity and flame resistance. The LED according to the present invention comprises at least a part comprising a polymer composition (C) comprising at least one polymer (P) selected from the group consisting of a polyamide, a polyester, an epoxy and a silicon resin; a flame retardant and magnesium oxide.
20160272820 CONDUCTIVE ALUMINUM PASTE FOR LOCAL BACK SURFACE FIELD SOLAR CELL AND SOLAR CELL REQUIRING THE CONDUCTIVE ALUMINUM PASTE||US||22.09.2016|
||14661472||PANCOLOUR INK CO., LTD.||HSIANG-MING HSUEH|
A conductive aluminum paste for a local back surface field solar cell includes an aluminum powder; an organic carrier including a resin and a solvent; and a vanadium oxide. A solar cell which includes the conductive aluminum paste is further provided. Both the conductive aluminum paste and the solar cell enhance the photoelectric conversion efficiency of the local back surface field solar cell and the pulling strength even though its lead content is reduced or it is lead-free.
20160272852 Double Initiated Fast Crosslinking EVA Adhesive Film||US||22.09.2016|
||14777689||HANGZHOU FIRST PV MATERIAL CO.LTD.||Ping JIN|
The invention provides a dual-initiated and fast cross-linked EVA (ethylene/vinyl acetate copolymer) film for the encapsulation of solar modules, which greatly enhances the speed of the encapsulation. The EVA film is mainly prepared from the following raw materials: 100 parts by mass of ethylene/vinyl acetate copolymer, 0.01 to 1.5 parts by mass of a free-radical photoinitiator, 0.01 to 1.5 parts by mass of a free-radical thermal initiator, 0.5 to 10 parts by mass of an auxiliary cross-linking agent, 0.1 to 5 parts by mass of a tackifier and 0.01 to 5 parts by mass of a light stabilizer. The present invention adds photothermal dual-initiated free-radical initiators and the auxiliary cross-linking agent of multi-functional acrylates or methacrylates to the EVA and use a thermal-UV dual curing process to prepare the solar module. The curing time is shorten to 5 to 10 min and the yield is high; meanwhile, the EVA film has advantages of uniform curing, high crosslink density, high bonding strength between the film and glass, and good anti-aging property.
20160273115 PHOTOCATHODES AND DUAL PHOTOELECTRODES FOR NANOWIRE PHOTONIC DEVICES||US||22.09.2016|
||15071268||ZETIAN MI||ZETIAN MI|
Important components of direct solar based nanowire enabled chemical processing and electrochemical systems are a high efficiency and highly stable photocathode and 2-photon dual electrodes. The former enables photo-excited electrons that lead to hydrogen generation whereas the later with complementary energy bandgap photoanode and photocathode enables high efficiency, unassisted solar-driven water splitting. Accordingly, it would be beneficial to leverage the high surface areas and self-contained conversion of direct solar illuminated hydrogen generation from such nanowires with multiple junctions for broad solar spectrum absorption by providing monolithically integrated multi-junction photocathodes. It would be further beneficial to provide nanowire based dual-photoelectrode systems that together with a parallel illumination scheme, can fundamentally address these critical challenges. It would be further beneficial for these nanowire based dual-photoelectrode systems to exploit a semiconductor material family that can be tuned across the solar spectrum, can be doped both p-type and n-type and supported large current conduction.
20160275912 DISPLAY DEVICE, METHOD OF MANUFACTURING THE SAME, AND METHOD OF HMD INTERFACING USING THE SAME||US||22.09.2016|
||15058569||OPTOLANE Technologies Inc.||DoYoung LEE|
A display device includes an upper structure, a lower structure, and a connecting element. The upper structure includes a display element having a first electrode, a light emitting layer, and a second electrode. The light emitting layer is disposed on the first electrode to generate light. The second electrode is disposed on the light emitting layer to transmit the light. The lower structure includes a display driving circuit. The display driving circuit receives an image signal to apply an electric power to the first electrode. The lower structure is physically separated from the upper structure to be spaced apart from the upper structure by a predetermined distance with respect to a vertical direction. The connecting element is disposed between the upper structure and the lower structure to connect the first electrode to the display driving circuit.
20160272419 WASTE MANAGEMENT DEPOSIT AND COMPACTION STATION WITH WIRELESS CAPABILITY||US||22.09.2016|
||14768471||Grant Jenkins||Grant Jenkins|
A multipurpose refuse receptacle comprising an outer shell defining an inner chamber, a receiving assembly disposed within the inner chamber, and a door assembly. The door assembly is movable between an open position and a close position. The receptacle has a basket carrier and a basket, the basket being disposable within the basket carrier. Further, a hydraulic lift assembly is operably coupled to the basket carrier, the hydraulic lift assembly having a pump assembly. A mechanism is operably coupled to the pump assembly and the door assembly, the mechanism being movable in a first direction. Wherein, when the mechanism is moved in the first direction the door assembly moves to the open position. Further wherein, when the mechanism is moved in the first direction, hydraulic pressure is generated by the pump assembly.
20160276318 Package of LED Chip and Manufacturing Method Thereof||US||22.09.2016|
||14395102||Ming SUN||Wen-Jung Chuang|
The present invention discloses a package of the LED chip and the related manufacturing method. The present invention is related to the LED package process. The package includes a transparent substrate, the LED chips, conductive wires and so on. The LED chips are installed reversely on the transparent substrate in order to improve the luminous efficiency and to simplify the process procedures.
20160276501 SOLAR PANEL CONVERTER LAYER||US||22.09.2016|
||14658772||Bright New World AB||Ola WASSVIK|
A light conversion sheet for application on top of a solar cell panel. The light conversion sheet has a front surface configured to face the sun and a back surface configured to face a solar cell, and comprises a photo luminescent layer, configured to emit light at a photo luminescent wavelength upon absorption of light of shorter wavelengths; and a spectrally selective mirror arranged between the photo luminescent layer and the front surface, configured to reflect light of the photo luminescent wavelength.
20160276503 PHOTOVOLTAIC CELL AND MANUFACTURING METHOD OF PHOTOVOLTAIC CELL||US||22.09.2016|
||15068959||Panasonic Intellectual Property Management Co., Ltd.||Masahiro KASANO|
A photovoltaic cell includes a translucent substrate; a photoelectric conversion element disposed on a light emission surface of the substrate; and a light guide member disposed on a light incidence surface of the substrate, at a position opposite the photoelectric conversion element across the substrate. A photovoltaic cell is manufactured by forming a first hydrophilic region on a light incidence surface of a translucent substrate, disposing a light guide member within the first hydrophilic region, forming a second hydrophilic region on a light emission surface of the substrate, and disposing a photoelectric conversion element in the second hydrophilic region.