Abstract: A photo-voltaic element comprising a stack of layers is disclosed, as well as a method of making the photo-voltaic element. The stack of layers at least includes the following: a first electrode layer, a first charge carrier transport layer, an insulating layer, a second electrode layer, a second charge carrier transport layer, and a photo-electric conversion layer. The photo-electric conversion layer comprises a plurality of distributed extensions extending through the second charge carrier transport layer, the second electrode layer, and the insulating layer, to the first charge carrier transport layer. The distributed extensions have an effective cross-section Deff in the range of 0.5 to 10 micron, and have an average pitch in the range of 1.1 to 5 times said effective cross-section.

Abstract: Translucent photovoltaic product, method of manufacturing the same and manufacturing apparatus. The method comprises: depositing a stack of layers on a carrier substrate, the stack comprising a first electrode layer, a photovoltaic layer and a second electrode layer; cutting through the substrate with the stack of layers to form a first and a second mutually disjoint sections; separating the first and the second section from each other; laminating the first section and the second section with a respective further substrate at a side opposite the carrier substrate to form a respective first and second photovoltaic device; and assembling the photovoltaic product from the first photovoltaic device and the second photovoltaic device, wherein the first and the second sections are mutually complementary comb shaped structures and wherein the second photovoltaic device is arranged in a second plane parallel to and in front of a first plane of said first photovoltaic device.

Abstract: A semi-translucent photovoltaic device is described having a translucent substrate with a photovoltaic stack interrupted in spatially distributed openings filled with a translucent polymer. Also disclosed is a method of manufacturing the device. The method comprises providing the substrate at a first side with the photovoltaic stack; removing material from the stack in spatially distributed regions, therewith forming openings within these regions; blanket-wise depositing a protective layer over the substrate with the photovoltaic stack; blanket-wise depositing a layer of a radiation-curable precursor for the translucent polymer over the protective layer; irradiating the substrate from a second side opposite its first side to therewith selectively cure the radiation-curable precursor within and in front of the spatially distributed openings, the radiation-curable precursor being converted therewith into said translucent polymer; removing an uncured remainder of the layer of the radiation-curable precursor.

Abstract: A partially translucent photovoltaic window is provided herein that comprises a photovoltaic module enclosed between a first window pane and a second window pane. The photovoltaic module comprises a stack with at least a first electrode layer, a second electrode layer and a perovskite photovoltaic layer sandwiched between the electrode layers. The photovoltaic window further comprises between the first window pane and the photovoltaic module as well as between the second window pane and the photovoltaic module a respective intermediate layer comprising a lead getter material.

Abstract: A screen (1) is provided comprising at least a first and a second elongate guidance element (27, 28) extending in a first direction (D1) and a structured foil (10) with a front surface and a back surface, having a variable length (L) in a first direction (D1) carried by the elongate guidance elements. The screen has slat shaped portions (11a1+11a2, 11b1+11b2) and connection portions (12ab, 2ab?) bridging the slat shaped portions. The slat shaped portions, which extend in a second direction (D2) transverse to the first direction are provided with photovoltaic elements (20) that are connectable to external terminals for supply of electric energy. The slate shaped portions are slidably coupled with the guidance elements, to allow them to slide in said first direction along said guidance elements.

Abstract: A photo-voltaic element (1) comprising a stack of layers is provided. The stack of layers at least includes the following layers arranged in the order named: a first electrode layer, a first charge carrier transport layer, an insulating layer, a second electrode layer, a second charge carrier transport layer, and a photo-electric conversion layer. The photo-electric conversion layer (70), comprises a plurality of distributed extensions (72) extending through the second charge carrier transport layer (60), the second electrode layer (50) and the insulating layer (40) to the first charge carrier transport layer (30). The extensions (72) have an effective cross-section Deff in the range of 0.5 to 10 micron, and have an average pitch in the range of 1.1 to 5 times said effective cross-section.

Abstract: A manufacturing facility is provided for manufacturing a product on a foil (FO). The manufacturing facility comprises a deposition zone (10) formed by a clean room wherein at least a first and a second deposition facility (21, 22) are arranged for depositing a layer of a material on the foil. The manufacturing facility further comprises at least one processing facility (31) for processing the deposited layer, said processing facility being arranged outside said deposition zone and comprising a processing trajectory with a first path (31a) away from said deposition zone, towards a turning facility (41) and with a second path (31b) from said turning facility back towards said deposition zone.

Abstract: A method is presented for providing a carrier (CR) with an embedded patterned metal structure (EMM). The carrier at least includes a polymer foil (FS). The method comprise the steps of providing a carrier (CR) having a first side (S1) with an initial embedded patterned metal structure (EM). The carrier is then irradiated at a second side (S2) opposite the first side with a radiation beam (BM) that is at least partially transmitted through the carrier (CR) and at least partially absorbed by the initial embedded patterned metal structure (EM), therewith locally heating the initial embedded patterned metal structure and causing a removal of metal (DB) from the initial embedded patterned metal structure.

Abstract: A manufacturing facility is provided for manufacturing a product on a foil (FO). The manufacturing facility comprises a deposition zone (10) formed by a clean room wherein at least a first and a second deposition facility (21, 22) are arranged for depositing a layer of a material on the foil. The manufacturing facility further comprises at least one processing facility (31) for processing the deposited layer, said processing facility being arranged outside said deposition zone and comprising a processing trajectory with a first path (31a) away from said deposition zone, towards a turning facility (41) and with a second path (31b) from said turning facility back towards said deposition zone.