||WO||WO/2014/056168 - POWER SUPPLY DEVICE BY INTEGRATING WIND POWER GENERATION AND SOLAR PANEL||17.04.2014||
||PCT/CN2012/082762||AA WIND & SOLAR ENERGY DEVELOPMENT GROUP LLC.USA||YANG, Liang Chih James Young|
A power supply device by integrating wind power generation and a solar
panel, which comprises a turbofan (1), multiple extension wings (19), a solar
panel group (2), a transmission mechanism (4), at least one electric generator (5), and a motor (6). The solar
panel group is disposed above a turbine frame (11) of the turbofan. The transmission mechanism is disposed on a top surface of the turbine frame. Each electric generator comprises a rotor shaft (52). The rotor shaft is connected to the transmission mechanism. The transmission mechanism rotates with the rotation of the turbine frame and drives the rotation of the rotor shaft, thereby making the electric generator generate power. The motor is connected to the solar
panel group through a wire and comprises a rotating shaft (61). The rotating shaft of the motor is connected to the transmission mechanism. Each extension wing comprises a joint shaft (191) and is disposed on the periphery of the turbine frame of the turbofan through the joint shaft. The power supply device integrates solar
power and wind power generation, fully utilizes the two types of natural energy, and converts
them to electric energy.
||WO||WO/2014/057367 - BACK-CONTACT BACK-SHEET FOR PHOTOVOLTAIC MODULES COMPRISING A PRIMER LAYER||17.04.2014||
||PCT/IB2013/054953||EBFOIL S.R.L.||BACCINI, Elisa|
The present invention proposes a back-contact back-sheet for a photovoltaic
modules comprising back-contact solar cells
. The back-contact back-sheet comprises an insulating substrate (210). On the surface of the insulating substrate (210) an electrically conductive material layer (220) is attached, which is adapted to be formed as a connecting circuit (220c). The insulating substrate (210) comprises a lower insulating portion (211) exposed toward the air-side of the photovoltaic
module and a primer layer and a primer layer (218) applied onto the insulating portion (211). Thus, the primer layer (218) lies between the lower insulating portion (211) and the electrically conductive material layer (220). The primer layer (218) preferably comprises a material or a material mixture akin to and compatible with an encapsulating foil (400, 1000) to be applied to the inner face of the back-contact back-sheet.
||WO||WO/2014/057708 - LIFTING FRAME AND LIFTING METHOD||17.04.2014||
||PCT/JP2013/064741||SHARP KABUSHIKI KAISHA||MASUDA, Yuji|
A lifting frame for lifting a photovoltaic
cell module comprises a main support (21) disposed on a photovoltaic
cell module body (11) and an auxiliary support (22) that can be attached and detached from the main support (21), and is configured so that the photovoltaic
cell module (10) is lifted, by way of the auxiliary support (22) supporting the bottom face of the photovoltaic
cell module body (11), by lifting the main support (21) when the auxiliary support (22) is mounted
to the main support (21).
||WO||WO/2014/059445 - SENSING, INTERLOCKING SOLAR MODULE STYSTEM AND INSTALLATION METHOD||17.04.2014||
||PCT/US2013/065144||SMASH SOLAR, INC.||GOLDBERG, Neil|
A frameless photovoltaic
) module system
and methods secur solar
panels directly to a fixed structure either individually or collectively as an array. Universal mounting
brackets attached to the back of each solar
panel module connect to one another and to mounting
feet that anchor to the fixed structure. Mounting
brackets interlock with mounting
brackets on adjacent solar
modules and include a quick release mechanism to connect to and disconnect from mounting
feet appropriately selected for the given fixed structure or roof type.
||WO||WO/2014/057445 - PHOTOVOLTAIC CELL||17.04.2014||
||PCT/IB2013/059255||PAUWELS, Donat||PAUWELS, Donat|
This invention relates to flexible, photovoltaic
cell for a sail comprising at least two photovoltaic
layers separated by an insulating layer.
||WO||WO/2014/056086 - HYBRID POWER SOURCE LIGHTING AND ENERGY SYSTEM FOR OPERATION IN HARSH AND/OR REMOTE LOCATIONS||17.04.2014||
||PCT/CA2013/000865||HORIZON OILFIELD SOLUTIONS INC.||CURLETT, Joshua|
The invention relates to a portable, skid mounted
, wheeled and/or collapsible hybrid-power lighting and energy management system
for harsh, remote and/or high latitude locations. The system
combines an internal combustion engine (ICE) power source with a control system
for providing power to light system
. The system
may also include a battery storage system
, an ICE heating system
and/or renewable solar
and/or wind power systems
in a manner that improves efficiency and reliability of operation in such locations, while preserving and improving functionality of operation and significantly reducing operator interaction during set-up and operation.
||WO||WO/2014/058256 - SOLAR CELL AND METHOD OF FABRICATING THE SAME||17.04.2014||
||PCT/KR2013/009077||LG INNOTEK CO., LTD.||JEONG, Jong Seon|
A method of fabricating a solar cell
includes: forming a back electrode layer on a support substrate; forming a light absorbing layer, which is formed on a top surface thereof with a plurality of pin holes, on the back electrode layer; and forming a buffer layer on the light absorbing layer, wherein the forming of the buffer layer includes: depositing a first buffer layer on the top surface of the light absorbing layer and an inner surface of the pin hole; and depositing a second buffer layer on a top surface of the first buffer layer and an inner side of the pin hole.
||WO||WO/2014/059204 - SOLAR CELL MODULE WITH A NANOFILLED ENCAPSULANT LAYER||17.04.2014||
||PCT/US2013/064425||E. I. DU PONT DE NEMOURS AND COMPANY||SAMUELS, Sam, Louis|
A solar cell
module comprising a solar cell
layer and a sheet comprising at least one layer of a nanofilled ionomer composition, wherein the nanofilled ionomer composition comprises (1) an ionomer that is derived from a precursor α-olefin carboxylic acid copolymer wherein (a) the precursor α-olefin carboxylic acid copolymer comprises (i) copolymerized units of an α-olefin and (ii) about 20 to about 25 weight % of copolymerized units of an α,β-ethylenically unsaturated carboxylic acid; and (b) at least a portion of the total content of the carboxylic acid groups present in the precursor α-olefin carboxylic acid copolymer have been neutralized to form metal salts of the carboxylic acid groups; and (2) one or more nanofillers.
||WO||WO/2014/058224 - LIGHT-EMITTING DEVICE||17.04.2014||
||PCT/KR2013/009013||LG INNOTEK CO., LTD.||HAN, Dae Seob|
An exemplary embodiment relates to a light-emitting device, a method for manufacturing the light-emitting device, a light-emitting device package, and an illuminating system
. The light-emitting device according to the embodiment may include: a first conductive-type semiconductor layer; a gallium nitride-based superlattice layer on the first conductive-type semiconductor layer; an active layer on the gallium nitride-based superlattice layer; a second conductive-type gallium nitride-based layer on the active layer; and a second conductive-type semiconductor layer on the second conductive-type gallium nitride-based layer. The second conductive-type gallium nitride-based layer may include on the active layer, a second conductive-type GaN layer having a first concentration, a second conductive-type InxAlyGa(1-x-y)N layer having a second concentration (where, 0＜x＜1, 0＜y＜1), and a second conductive-type AlzGa(1-z)N layer having a third concentration (where, 0＜z＜1).
||WO||WO/2014/058792 - THICK FILM SILVER PASTE AND ITS USE IN THE MANUFACTURE OF SEMICONDUCTOR DEVICES||17.04.2014||
||PCT/US2013/063713||E. I. DU PONT DE NEMOURS AND COMPANY||HANG, Kenneth, Warren|
The present invention is directed to an electroconductive silver thick film paste composition comprising Ag particles and a Bi-Cu-B-Zn-based glass frit dispersed in an organic medium. The present invention is further directed to an electrode formed from the paste composition and a semiconductor device and, in particular, a solar cell
comprising such an electrode. The paste is particularly useful for forming a tabbing electrode.