Abstract: A thin-film solar module with a substrate and a layer structure applied thereon that comprises a rear electrode layer, a front electrode layer, and an absorber layer arranged between the back electrode layer and the front electrode layer. Serially connected solar cells are formed in the layer structure by patterning zones, wherein each patterning zone comprises a first patterning line for subdividing at least the rear electrode layer, a second patterning line for subdividing at least the absorber layer, and at least one third patterning line for subdividing at least the front electrode layer. At least one patterning zone has one or more optically transparent zones in a zone region reduced by the first patterning line, which are in each case rear-electrode-layer-free, wherein the one or more optically transparent zones are implemented such that the rear electrode layer is continuous in the zone region.

Abstract: A low dielectric sealing glass powder for a miniature radio-frequency glass insulator is made of the following raw materials expressed in molar percentages: SiO2: 70.5-74.0%, B2O3: 20.5-23.5%, Ga2O3: 0.5-2.0%, P2O5: 0.25-2.0%, Li2O: 0.4-6.0%, K2O: 0.1-1.5%, LaB6: 0.05-1.0%, and NaCl: 0.03-0.3%. The raw material components are simple, and the preparation method is easy to implement. The dielectric constant and dielectric loss of the prepared glass powder are low, and the melting and molding temperature is low, which are convenient for large-scale industrial production. The melting and molding temperature of the low dielectric sealing glass powder ranges from 1320° C. to 1360° C., and the obtained glass has a dielectric constant ranging from 3.8 to 4.1 and a dielectric loss ranging from 4×10?4 to 10×10?4 at a frequency of 1 MHz, and a sealing temperature ranging from 900° C. to 950° C.

Abstract: A solar module having on the front a cover plate with an outer surface and an inner surface is described. An optical interference layer for reflecting light within a predefined wavelength range is arranged on the inner surface. The inner surface and/or the outer surface have a patterned region. The patterned region has a height profile with hills and valleys, and a portion of the patterned region is composed of flat segments that are inclined relative to a plane of the cover plate.

Abstract: A process for producing a chalcogen-containing compound semiconductor includes providing at least one substrate coated with a precursor for the chalcogen-containing compound semiconductor in a process chamber; heat treating the at least one coated substrate in the process chamber, wherein during a heat treatment, a gas atmosphere comprising at least one gaseous chalcogen compound is provided in the process chamber; removing the gas atmosphere present after the heat treatment of the at least one coated substrate as a waste gas from the process chamber; cooling the waste gas in a gas processor, wherein a plurality of gaseous chalcogen compounds-present in the waste gas after the heat treatment of the at least one coated substrate are separated in time and space from one another from the waste gas by respective conversion into a liquid or solid form. Further provided is a device designed to carry out the process.

Abstract: A method for processing a transparent cover plate for a flat body includes the following steps of providing the transparent cover plate having an outer side and an opposite inner side, wherein the transparent cover plate includes a structured area with a light-scattering structure, forming of at least one optical interference layer on a cover plate side including applying a mask to the transparent cover plate, wherein the mask does not cover a first area of a cover plate surface and covers a second area of the cover plate side, and the first area and the second area are arranged to overlap the structured area, the at least one optical interference layer is applied in overlap with the mask, and removing of the mask, whereby the at least one optical interference layer is also removed.

Abstract: A facade element includes a coloring transparent or semi-transparent first pane and a mechanically supporting transparent second pane firmly connected to one another by an intermediate layer. The first pane has a front surface arranged on the light incidence side and an opposite back surface, at least one surface of the front and back surfaces has at least one structured region, and at least one optical interference layer is arranged on the at least one surface for reflecting light within a predetermined wavelength range. The structured region has the following features: perpendicular to the plane of the first pane, a height profile comprising peaks and valleys, wherein an average height difference between the peaks and valleys is at least 2 ?m, at least 50% of the structured region is composed of segments which are inclined with respect to the plane of the first pane (2).

Abstract: A thin-film solar module with a substrate and a layer structure applied thereon that comprises a rear electrode layer, a front electrode layer, and an absorber layer arranged between the back electrode layer and the front electrode layer. Serially connected solar cells are formed in the layer structure by patterning zones, wherein each patterning zone comprises a first patterning line for subdividing at least the rear electrode layer, a second patterning line for subdividing at least the absorber layer, and at least one third patterning line for subdividing at least the front electrode layer. At least one patterning zone has one or more optically transparent zones in a zone region reduced by the first patterning line, which are in each case rear-electrode-layer-free, wherein the one or more optically transparent zones are implemented such that the rear electrode layer is continuous in the zone region.

Abstract: A thin-film solar module with a substrate and a layer structure applied thereon, which comprises a rear electrode layer, a front electrode layer, and an absorber layer arranged between the rear electrode layer and the front electrode layer, wherein serially connected solar cells are formed in the layer structure by patterning zones, wherein at least one solar cell has one or more optically transparent zones that are in each case rear-electrode-layer-free, wherein the one or more optically transparent zones are implemented such that the rear electrode layer of the solar cell is continuous.

Abstract: A solar module with a flat substrate and a plurality of solar cells that are connected in series between two conductor tracks and are arranged on a first side of the substrate. The solar cells form an optically active module inner region that is surrounded by an optically inactive module edge region. A hole in the substrate, a junction box on a second side of the substrate, and an electrical connection between a tapping point on the conductor track and a connection point of the junction box are associated with each conductor track. The hole is positioned at least partially in the module inner region such that the tapping point on the conductor track is situated outside an aligning extension of the hole and at least one solar cell is divided or has a shortened length.

Abstract: A facade element includes a coloring transparent or semi-transparent first pane and a mechanically supporting transparent second pane firmly connected to one another by an intermediate layer. The first pane has a front surface arranged on the light incidence side and an opposite back surface, at least one surface of the front and back surfaces has at least one structured region, and at least one optical interference layer is arranged on the at least one surface for reflecting light within a predetermined wavelength range. The structured region has the following features: perpendicular to the plane of the first pane, a height profile comprising peaks and valleys, wherein an average height difference between the peaks and valleys is at least 2 ?m, at least 50% of the structured region is composed of segments which are inclined with respect to the plane of the first pane (2).

Abstract: A plate-shaped component includes a transparent cover plate and a planar back element attached to the cover plate. The cover plate has a front surface facing the external environment and a back surface facing the back element. At least one surface selected from the front and back surfaces has at least one structured region, and at least one color filter layer for reflecting light within a predetermined wavelength range is arranged on the at least one surface selected from the front and back surfaces. The at least one structural region is perpendicular to the plane of the cover plate. The at least one color filter layer includes at least one refractive layer having a refractive index of greater than 2.5 in the wavelength range from 400 nm to at least 700 nm and an extinction coefficient of at least 0.2 below 450 nm and less than 0.2 above 700 nm.

Abstract: A thin-film solar module with a substrate and a layer structure applied thereon comprising a rear electrode layer, a front electrode layer, and an absorber layer arranged between the back electrode layer and the front electrode layer. Serially connected solar cells are formed in the layer region by patterning zones, having a rear electrode layer section. The layer region has at least one linear decoating region. The decoating region has an alternating sequence of optically transparent zones and electrode zones. The optically transparent zones are rear-electrode-layer-free and the electrode zones are absorber-layer-free and have a rear electrode layer section. The rear-electrode-layer-sections of at least one pair made up of one solar cell of one solar cell string and one solar cell of the other solar cell string are areally connected to one another by the rear-electrode-layer-section of at least one electrode zone.

Abstract: A method for producing a thin-film solar module with serially connected solar cells and related device. A back electrode layer is deposited on one side of a flat substrate and subdivided by first patterning trenches. An absorber layer is deposited over the back electrode layer and subdivided by second patterning trenches. A front electrode layer is deposited over the absorber layer. At least the front electrode layer is subdivided by third patterning trenches. A direct succession of a first patterning trench, a second patterning trench, and two adjacent third patterning trenches forms a patterning zone. The third patterning trenches are produced by laser ablation through a pulsed laser beam, where one third patterning trench is produced with laser pulses of higher energy and the other third patterning trench of the patterning zone is produced with laser pulses of lower energy.