Patent application number | Description | Published |
20100288351 | THIN-FILM SOLAR CELL - The thin-film solar cell includes at least one Na | 11-18-2010 |
20100288361 | THIN-FILM SOLAR CELL AND PROCESS FOR PRODUCING A THIN-FILM SOLAR CELL - The thin-film solar cell includes at least one Na | 11-18-2010 |
20110039079 | STRUCTURED SUBSTRATE GLASS FOR LED'S AND METHOD FOR PRODUCTION THEREOF - A composite material designed as a substrate glass for LED's is provided. The composite material includes a structured coating made of a hybrid polymer matrix that contains nanoparticles made of an oxide. | 02-17-2011 |
20110045259 | SUBSTRATE GLASS FOR LEDS WITH LAYER CONTAINING SCATTERING PARTICLES AND METHOD FOR PRODUCTION THEREOF - A composite material for LED's is provided. The composite material has a coating comprising scattering particles with an index of refraction greater than 1.6. | 02-24-2011 |
20120128938 | ETCHING METHOD FOR SURFACE STRUCTURING - An etching method for selective introduction of structures into surfaces of different substrates, such as glass or glass ceramic substrates, is provided. The method provides for surface structuring using an etch mask. The etchmask allows for the production of very fine structures on the substrate surfaces using liquid etching media. In this method the etch mask is produced on the substrate. | 05-24-2012 |
20120157290 | HIGH PERFORMANCE GLASS CERAMICS AND METHOD FOR PRODUCING HIGH-PERFORMANCE GLASS CERAMICS - The invention relates to a glass ceramic comprising article, wherein the integral, non-post-processed and non-reworked glass ceramic comprising article comprises at least three different types of microstructures. The microstructures differ in the number and/or size of the crystallites contained per unit volume, and/or in the composition of the crystallites, and/or in the composition of the residual glass phases. The different microstructures are characterized by different relative ion content profiles across a cross-section perpendicular to the transition areas. The relative ion content profiles are determined from intensities which are determined using secondary ion mass spectrometry, and each of the three different types of microstructures preferably has different intensity plateaus for individual ions, wherein the individual ions are components of the main crystal phases. | 06-21-2012 |
20120295081 | COMPOSITE MATERIAL AND METHOD FOR PRODUCING SAME - A method for producing a glass or glass ceramic composite material is provided. The method includes: providing a glass or glass ceramic substrate with a coefficient of thermal expansion of α≦5*10 | 11-22-2012 |
20130034702 | COMPOSITE AND METHOD FOR THE PRODUCTION THEREOF - A composite is provided that has a structured sol-gel layer on a substrate. The sol-gel layer is extremely resistant against mechanical stress and other influences from outside due to its production method. The composite is suitable for use in a lot of technical fields, since the sol-gel layer can be provided with nearly any arbitrary structure. For example, the structure may result in optical effects and may be used in optical systems. | 02-07-2013 |
20130040116 | METHOD FOR PRODUCING A PANE WITH A PATTERNED SURFACE, AND PANE HAVING A PATTERNED SURFACE - A method for producing a pane of a household appliance or a viewing window of an oven is provided. The method includes the steps of: providing a substrate; applying a sol-gel layer to the substrate; embossing a haptically perceptible pattern using an embossing tool in the sol-gel layer; and curing the sol-gel layer. A pane of a household appliance or piece of furniture is also provided that includes a glass or glass-ceramic substrate with a patterned sol-gel layer which has a haptically perceptible pattern. | 02-14-2013 |
20130183487 | GLASS OR GLASS-CERAMIC COMPOSITE MATERIAL AND METHOD FOR PRODUCING SAME - A method for producing a glass or glass ceramic composite material with a metallic decorative appearance is provided. The method includes: applying a layer onto a glass or glass ceramic substrate, the layer comprising a sol-gel and/or a polysiloxane; patterning the layer; and applying a metallic-looking layer onto the patterned layer. | 07-18-2013 |
20140213044 | METHOD FOR PRODUCING PERIODIC CRYSTALLINE SILICON NANOSTRUCTURES - A method for producing periodic crystalline silicon nanostructures of large surface area by: generating a periodic structure having a lattice constant of between 100 nm and 2 μm on a substrate, the substrate used being a material which is stable at up to at least 570° C., and the structure being produced with periodically repeating shallow and steep areas/flanks, and, subsequently, depositing silicon by directed deposition onto the periodically structured substrate, with a thickness in the range from 0.2 to 3 times the lattice constant, or 40 nm to 6 μm, at a substrate temperature of up to 400° C., followed by thermally treating the deposited Si layer to effect solid-phase crystallization, at temperatures between 570° C. and 1400° C., over a few minutes up to several days, and optionally subsequently wet-chemically selective etching to remove resultant porous regions of the Si layer. | 07-31-2014 |