AZUR SPACE SOLAR POWER GMBH Patent applications |
Patent application number | Title | Published |
20160133775 | SOLAR CELL STACK - A solar cell stack, having a first semiconductor solar cell having a p-n junction made of a first material with a first lattice constant, and a second semiconductor solar cell having a p-n junction made of a second material with a second lattice constant, and the first lattice constant being at least 0.008 Å smaller than the second lattice constant, and a metamorphic buffer, the metamorphic buffer being formed between the first semiconductor solar cell and the second semiconductor solar cell, and the metamorphic buffer including a series of three layers, and the lattice constant increasing in a series in the direction of the semiconductor solar cell, and the lattice constants of the layers of the metamorphic buffer being bigger than the first lattice constant, two layers of the buffer having a doping, and the difference in the dopant concentration between the two layers being greater than 4E17 cm | 05-12-2016 |
20160133773 | MONOLITHIC MULTIPLE SOLAR CELLS - A monolithic multiple solar cell includes at least three partial cells, with a semiconductor mirror placed between two partial cells. The aim of the invention is to improve the radiation stability of said solar cell. For this purpose, the semiconductor mirror has a high degree of reflection in at least one part of a spectral absorption area of the partial cell which is arranged above the semiconductor mirror and a high degree of transmission within the spectral absorption range of the partial cell arranged below the semiconductor mirror. | 05-12-2016 |
20160133770 | MONOLITHIC MULTIPLE SOLAR CELLS - A monolithic multiple solar cell includes at least three partial cells, with a semiconductor mirror placed between two partial cells. The aim of the invention is to improve the radiation stability of said solar cell. For this purpose, the semiconductor mirror has a high degree of reflection in at least one part of a spectral absorption area of the partial cell which is arranged above the semiconductor mirror and a high degree of transmission within the spectral absorption range of the partial cell arranged below the semiconductor mirror. | 05-12-2016 |
20160118524 | STACKED INTEGRATED MULTI-JUNCTION SOLAR CELL - A stacked integrated multi-junction solar cell, having a first subcell, whereby the first subcell has a layer of an InGaP compound with a first lattice constant and a first band gap energy, and the thickness of the layer is greater than 100 nm and the layer is formed as part of an emitter and/or as part of the base and/or as part of the space charge region lying between the emitter and base, and a second subcell with a second lattice constant and a second band gap energy, and a third subcell with a third lattice constant and a third band gap energy, and a fourth subcell with a fourth lattice constant and a fourth band gap energy, and a region with a wafer bond is formed between two subcells. | 04-28-2016 |
20150349179 | SOLAR CELL UNIT - A solar cell unit, comprising a solar cell with a light receiving surface, and a transparent optical element frictionally connected to the receiving surface. The optical element having a portion of surface formed substantially convex such that sunlight striking the receiving surface is bundled by the convex receiving surface. The light receiving surface is surrounded by a shoulder-shaped ledge that has a first rim surface and a second rim surface. A first alignment mark is provided in association with the first rim surface and a second alignment mark is provided in association with the second rim surface to position the optical element in regard to the receiving surface of the solar cell via the two alignment marks. The first alignment mark being spaced apart from the second alignment mark in order to guide the incident sunlight totally or at least largely to the receiving surface. | 12-03-2015 |
20150340534 | SOLAR CELL STACK - A solar cell stack having a first semiconductor solar cell that has a p-n junction of a first material with a first lattice constant and a second semiconductor solar cell that has a p-n junction of a second material with a second lattice constant. The solar cell stack has a metamorphic buffer that includes a sequence of a first, lower layer and a second, center layer, and a third, upper layer, and includes an InGaAs or an AlInGaAs or an InGaP or an AlInGaP compound. The metamorphic buffer is formed between the first and second semiconductor solar cells and the lattice constant in the metamorphic buffer changes along the buffer's thickness dimension. The lattice constant of the third layer is greater than the lattice constant of the second layer, and the lattice constant of the second layer is greater than the lattice constant of the first layer. | 11-26-2015 |
20150340533 | SOLAR CELL STACK - A solar cell stack having a first semiconductor solar cell that has a p-n junction of a first material with a first lattice constant, and having a second semiconductor solar cell that has a p-n junction of a second material with a second lattice constant. The first lattice constant is smaller than the second lattice constant. The solar cell stack has a metamorphic buffer that includes a sequence of a first, lower AlInGaAs or AlInGaP layer and a second, center AlInGaAs or AlInGaP layer, and a third, upper AlInGaAs or AlInGaP layer, and the metamorphic buffer is formed between the first semiconductor solar cell and the second semiconductor solar cell. The lattice constant in the metamorphic buffer changes along the thickness dimension of the metamorphic buffer, and the lattice constant and the In content increase and the Al content decreases between at least two layers of the metamorphic buffer. | 11-26-2015 |
20150325727 | MULTIPLE SOLAR CELL AND METHOD FOR MANUFACTURING THE SAME - A multi-junction solar cell having a Ge or GaAs substrate, as well as a solar cell structure having several subcells deposited on the substrate, the substrate having peripheral side faces, and the solar cell structure having a peripheral circumferential surface, which runs spaced apart from the side faces. To prevent oxidation and penetration of moisture, the circumferential surface of the solar cell structure is coated with a protective, electrically insulating first coating under essential exclusion of the upper surface facing the rays, or that without encroaching on the solar cell structure, the side faces of the substrate are coated with a protective, electrically insulating second coating or that both the side faces of the substrate as well as the circumferential surface of the solar cell structure are coated with a third coating by essential exclusion of the upper surface facing the rays. | 11-12-2015 |
20150214427 | LED SEMICONDUCTOR COMPONENT - An LED semiconductor component having an n-doped substrate layer and a first, n-doped cladding layer, wherein the cladding layer is located on the substrate layer, and having an active layer, wherein the active layer comprises a light-emitting layer and is located on the first cladding layer, and having a second, p-doped cladding layer, wherein the second cladding layer is located on the active layer, and having a p-doped current spreading layer, wherein the current spreading layer is located on the second cladding layer, and having a p-doped contact layer, wherein the p-doped contact layer is located on the current spreading layer, wherein the p-doped contact layer is made of an aluminiferous layer and has carbon as dopant. | 07-30-2015 |
20150144189 | SOLAR CELL UNIT - A solar cell unit having a semiconductor body formed as a solar cell, whereby the semiconductor body has a front side with a first electrical connection and a back side with a second electrical connection and a side surface formed between the front side and the back side, and having a substrate with a top side and a bottom side, whereby the substrate on the top side has a first conductive trace region, configured as part of the substrate, and the first electrical connection is electrically connected to the first conductive trace region, and the substrate on the top side has a second conductive trace region, configured as part of the substrate, and the second electrical connection is electrically connected to the second conductive trace region, and having a secondary optical element, which has a bottom side and guides light to the front side of the semiconductor body. | 05-28-2015 |
20140190559 | MONOLITHIC MULTIPLE SOLAR CELLS - A monolithic multiple solar cell includes at least three partial cells, with a semiconductor mirror placed between two partial cells. The aim of the invention is to improve the radiation stability of said solar cell. For this purpose, the semiconductor mirror has a high degree of reflection in at least one part of a spectral absorption area of the partial cell which is arranged above the semiconductor mirror and a high degree of transmission within the spectral absorption range of the partial cell arranged below the semiconductor mirror. | 07-10-2014 |
20140190554 | MONOLITHIC MULTIPLE SOLAR CELLS - A monolithic multiple solar cell includes at least three partial cells, with a semiconductor mirror placed between two partial cells. The aim of the invention is to improve the radiation stability of said solar cell. For this purpose, the semiconductor mirror has a high degree of reflection in at least one part of a spectral absorption area of the partial cell which is arranged above the semiconductor mirror and a high degree of transmission within the spectral absorption range of the partial cell arranged below the semiconductor mirror. | 07-10-2014 |
20140048120 | SOLAR GENERATOR UNIT - A solar generator unit for converting sunlight, having a mirror array, a light converter, support designed to hold the mirror array, and a tracking unit for causing the mirror array to track the sun position. The light converter is arranged above the mirror array and the concentrated light strikes a receiver surface of the light converter. The support has an essentially horizontal first shaft with a first radial bearing point and a second radial bearing point arranged on mutually opposite sides of the mirror array. A third radial bearing point accommodates a second shaft that is essentially perpendicular to the first shaft is flange-mounted between the first bearing point and the second bearing point so that the axis of rotation of the second shaft is pivoted along with a rotation of the first shaft, and the mirror array is connected in a non-positive way to the second shaft. | 02-20-2014 |
20140026959 | SOLAR CELL RECEIVER - A solar cell receiver is provided that includes a semiconductor element that has a front face, a solar cell provided on the front face, a rear face, multiple lateral surfaces and two electric connectors; a carrier for receiving the semiconductor element, the rear face of the element being fixed to the carrier; and an optical element for concentrating the light onto the rear face of the semiconductor element. The optical element has an underside which partially faces the upper side of the semiconductor element, the underside of the optical element has a first shaped section with a first surface that lies on the front face of the semiconductor element and a second surface that lies on the carrier. The shaped section is designed as a cavity or groove. | 01-30-2014 |
20120285510 | SOLAR CELL MODULE - A solar cell module having sub-units of solar cells connected in parallel, the sub-units being connected in series. To enable individual adjustment to the impinging light intensity distribution such that substantially the same photocurrent is generated in each sub-unit, the solar cells have at least first and second solar cells, which each have radiation-sensitive surfaces that are different from each other, and at least one sub-unit of the solar cell module has a first and at least one second solar cell. | 11-15-2012 |
20120240991 | MULTIPLE SOLAR CELL AND METHOD FOR MANUFACTURING THE SAME - A multi-junction solar cell having a Ge or GaAs substrate, as well as a solar cell structure having several subcells deposited on the substrate, the substrate having peripheral side faces, and the solar cell structure having a peripheral circumferential surface, which runs spaced apart from the side faces. To prevent oxidation and penetration of moisture, the circumferential surface of the solar cell structure is coated with a protective, electrically insulating first coating under essential exclusion of the upper surface facing the rays, or that without encroaching on the solar cell structure, the side faces of the substrate are coated with a protective, electrically insulating second coating or that both the side faces of the substrate as well as the circumferential surface of the solar cell structure are coated with a third coating by essential exclusion of the upper surface facing the rays. | 09-27-2012 |