Letsch
Andreas Letsch, Stuttgart DE
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20120044966 | LIGHT SOURCE WITH A DIODE LASER AND A LARGE NUMBER OF OPTICAL FIBERS - A light source, e.g., for optical excitation of a laser device, includes a diode laser having a large number of emitters and a light-guiding device, the light-guiding device including a large number of optical fibers. Each fiber has a first end and a lateral surface, the first ends being arranged relative to the emitters in such a manner that light generated by the emitters is coupled into the first ends of the optical fibers, the optical fibers being arranged in abutting relationship along their lateral surfaces at least in the region of their first ends. The optical fibers are connected in the region of their first ends to a fiber support. | 02-23-2012 |
20120068369 | METHOD FOR PRODUCING A LIGHT SOURCE HAVING A DIODE LASER AND A PLURALITY OF OPTICAL FIBERS - A method is described for producing a light source, in particular a light source for optically exciting a laser device, for example a laser device of a laser ignition system of an internal combustion engine, including a diode laser having a plurality of emitters and a fiber optic device. The fiber optic device includes a plurality of optical fibers, each fiber having a first end and a lateral surface area. The first ends are situated relative to the emitters in such a way that light generated by the emitters is injected into the first ends of the optical fibers. The optical fibers are situated in abutment along their lateral surface areas, at least in the region of the first ends of the optical fibers. The method is characterized by the following steps: arranging a plurality of optical fibers which form a fiber section in a subregion, the fiber section being situated between two opposite pressing surfaces; heating the fiber section; and exerting a force on the heated optical fibers with the aid of the pressing surfaces. The force and the heating initially result in deformation of the heated optical fiber. The exerted force and/or a temperature of the optical fibers is/are selected in such a way that the deformation ceases when the optical fibers for the first time fill, at least largely, a region between the pressing surfaces. | 03-22-2012 |
20120304959 | LASER SPARK PLUG - A laser spark plug having an antechamber is designed to irradiate laser radiation, which is guided and/or generated in the laser spark plug on at least two ignition points which are different from one another and are lying in the antechamber. The laser spark plug is designed to irradiate the laser radiation into the antechamber in such a way that a distance between at least one first ignition point and one second ignition point adjoining thereto is larger than a minimum distance between the first and/or the second ignition point(s) and an inner surface of the antechamber. | 12-06-2012 |
20130047946 | LASER IGNITION SYSTEM - A laser device for a laser ignition system of an internal combustion engine includes a laser-active solid, an optical Q-switch, a first resonator in which at least the laser-active solid is situated, and a second resonator optically coupled to the first resonator. The length of the second resonator is set or modulated via actuators to optimize the ignition. | 02-28-2013 |
20150110140 | CIRCUIT SYSTEM AND MANUFACTURING METHOD FOR SAME - A circuit system includes: a first optoelectronic semiconductor component situated with an n-conductive surface facing an electrically conductive support surface and connected to the support surface in an electrically conductive manner; and a second optoelectronic semiconductor component situated with a p-conductive surface facing the support surface and connected to the support surface in an electrically conductive manner. | 04-23-2015 |
Anne Letsch, Berlin DE
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20100254958 | Antigen-Specific T-Cell Preparations from Bone Marrow - A method for the generation of antigen-specific T-cell preparations for adoptive therapy is provided, comprising the steps of obtaining lymphoid cells from the bone marrow of a patient in a first step, expanding the lymphoid cells in cell culture medium ex-vivo in the presence of at least one of IL2 and IL7 and or more antigens, yielding a T-cell preparation, and isolating the T-cell preparation from the culture medium in an isolation step. T-cell preparations provided according to the inventive method, and the use of such T-cell preparations for the treatment of infectious disease and cancer is also provided. | 10-07-2010 |
Holger Letsch, Muehlhausen DE
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20110284975 | MICROSTRUCTURE, METHOD FOR PRODUCING THE SAME, DEVICE FOR BONDING A MICROSTRUCTURE AND MICROSYSTEM - A microstructure has at least one bonding substrate and a reactive multilayer system. The reactive multilayer system has at least one surface layer of the bonding substrate with vertically oriented nanostructures spaced apart from one another. Regions between the nanostructures are filled with at least one material constituting a reaction partner with respect to the material of the nanostructures. A method for producing at least one bonding substrate and a reactive multilayer system, includes, for forming the reactive multilayer system, at least one surface layer of the bonding substrate is patterned or deposited in patterned fashion with the formation of vertically oriented nanostructures spaced apart from one another, and regions between the nanostructures are filled with at least one material constituting a reaction partner with respect to the material of the nanostructures. A device for bonding a microstructure, which has at least one bonding substrate and a reactive multilayer system, to a further structure, which has a bonding substrate. The device has a bonding chamber, which can be opened and closed and evacuated and in which the microstructure and the further structure can be introduced and aligned with one another, and also an activation mechanism, which is coupled to the bonding chamber and by means of which the reactive multilayer system of the microstructure, said reactive multilayer system being formed from reactive nanostructures with—situated therebetween—a material constituting a reaction partner with respect to the material of the nanostructures, can be activated mechanically, electrically, electromagnetically, optically and/or thermally in such a way that a self-propagating, exothermic reaction takes place between the nanostructures and the material constituting a reaction partner with respect to the material of the nanostructures. A microsystem is formed from two bonding substrates and a construction lying between the bonding substrates, the construction having a reacted reactive layer system, wherein the reacted reactive layer system is a reacted structure sequence composed of at least one surface layer—provided on the bonding substrate—with vertically oriented nanostructures spaced apart from one another, and regions filled between the nanostructures with at least one material constituting a reaction partner with respect to the material of the nanostructures. The microsystem is a sensor coated with biomaterial and/or has elements composed of polymeric material and/or at least one magnetic and/or piezoelectric and/or piezoresistive component. | 11-24-2011 |
Thomas Letsch, Duesseldorf DE
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20160121335 | GRINDING ROLLER - The invention relates to a grinding roller having an inclined, fixed inner roller axle ( | 05-05-2016 |