Patent application number | Description | Published |
20150144180 | ENCAPSULATING LAYER ADAPTED TO BE APPLIED TO BACK-SHEETS FOR PHOTOVOLTAIC MODULES INCLUDING BACK-CONTACT CELLS - The present invention provides for a multi-layered structure adapted to be applied to the surface of a back-contact back-sheet for a photovoltaic module comprising back-contact solar cells. The multi-layered structure comprises a non-extendible intermediate layer ( | 05-28-2015 |
20150236181 | BACK-CONTACT BACK-SHEET FOR PHOTOVOLTAIC MODULES COMPRISING A PRIMER LAYER - 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 ( | 08-20-2015 |
20150280039 | METHOD OF PRODUCTION OF BACK-CONTACT BACK-SHEET FOR PHOTOVOLTAIC MODULES - The present invention provides a method for producing a back-contact back-sheet for a photovoltaic module comprising back-contact cells. The method comprising providing a substrate ( | 10-01-2015 |
20150333204 | APPLICATION OF THE ENCAPSULANT TO A BACK-CONTACT BACK-SHEET - A method for the production of a photovoltaic module comprising back-contact solar cells ( | 11-19-2015 |
20160064575 | BACK-CONTACT BACK-SHEET FOR PHOTOVOLTAIC MODULES WITH PASS-THROUGH ELECTRIC CONTACTS - The present invention proposes a back-contact back-sheet for photovoltaic modules comprising back-contact cells and a method of manufacturing thereof. The back-contact back-sheet comprises an insulating substrate upon which a connecting circuit is attached. The back-contact back-sheet further comprises at least a region indented towards the air-side of the photovoltaic module. The indentation is performed is performed in a portion of the back-contact back-sheet comprising the connecting circuit. A through-hole is then formed within the indented region so as to bring into communication the surface of the connecting circuit exposed towards the inside of the photovoltaic module with the face of the back-contact back-sheet facing the air-side of the photovoltaic module. A transport portion of a connecting element, such as the stem of a rivet, may be introduced into the through-hole so that the contact portion of the connecting element, such as the head of the rivet, is attached and electrically connected to the surface of the connecting circuit exposed towards to the inside of the photovoltaic module. The connecting circuit thus permits exchange of an electrical signal between the photovoltaic module in which the back-contact back-sheet is embedded and the outside. | 03-03-2016 |
Patent application number | Description | Published |
20100266931 | SEALED FLEXIBLE LINK BETWEEN A METAL SUBSTRATE AND A CERAMIC SUBSTRATE, METHOD FOR MAKING SUCH A LINK, APPLICATION OF THE METHOD TO SEALING HIGH TEMPERATURE ELECTROLYZERS AND FUEL CELLS - A device including a metal substrate and a ceramic substrate including a back-tapered groove separated from each other by a sealed flexible link. The link includes: a metal element including an end connected to the metal substrate and at another end housed in the groove of the ceramic substrate, the metal element being elastically deformable both in the groove along a direction radial to the groove and, in the separation space between the metal substrate and the ceramic substrate along the separation direction, and a joint-forming mass with a greater thermal expansion coefficient than that of the ceramic substrate and adhesively bonded to the end of the metal element housed in the back-tapered groove, the joint fitting with direct contact a portion of the height of convergent sidewalls of the groove. | 10-21-2010 |
20120160900 | METHOD FOR MANUFACTURING A MODULE WITH A HOLLOW REGION, PREFERABLY FOR FLUID CIRCULATION - A manufacturing method for a module having a hollow region, including: making an assembly including at least one recessed plate having a recess open at one face, defining thereon a recess outline and, between the face and the immediately adjacent plate of the assembly, a strand of material lying along the recess outline; treating the assembly, aiming to obtain diffusion bonding of the strand to the plate(s) with which it is in contact, to constitute, along its associated recess outline, a gas-tight connection of the two plates between which it is placed; and consolidating the assembly by hot isostatic pressing. | 06-28-2012 |
20140191142 | NUCLEAR FUSION REACTOR FIRST WALL COMPONENT AND PRODUCTION PROCESS THEREOF - A nuclear fusion reactor first wall component includes a copper alloy element, an intermediate metal layer made from niobium and a beryllium element, directly in contact with the intermediate metal layer. The intermediate niobium layer is further advantageously associated with a mechanical stress-reducing layer formed by a metal chosen from copper and nickel. This mechanical stress-reducing layer is in particular arranged between the intermediate niobium layer and the copper alloy element. Furthermore, when the mechanical stress-reducing layer is made from pure copper, a layer of pure nickel can be inserted between the niobium and the pure copper before diffusion welding. Such a component presents the advantage of having an improved thermal fatigue behaviour while at the same time preventing the formation of intermetallic compounds at the junction between the beryllium and the copper alloy. | 07-10-2014 |
20150174703 | METHOD FOR THE BRAZING OF PARTS MADE FROM A COMPOSITE MATERIAL, INCORPORATING A SLUG IN THE BOND - A method of assembling together by brazing first and second parts made of composite material, each of the first and second parts having an assembly face for brazing with the assembly face of the other part, the method including making at least one perforation in the assembly face of the first part; interposing capillary elements between the assembly faces of the first and second parts made of composite material; placing the first and second parts facing each other while inserting a peg in each perforation of the first part; placing a brazing composition in contact with a portion of the capillary elements; and applying heat treatment to liquefy the brazing composition so as to cause the molten brazing composition to spread by capillarity between the assembly faces of the composite material parts. | 06-25-2015 |