| Patent application number | Description | Published |
|---|
| 20080311375 | Method of Fabricating a Polymeric Membrane Having at Least One Pore - A method of fabricating a polymer membrane having at least one pore, polymeric membranes fabricated by the method, and uses of such polymeric membranes. The pores formed are in the nanometer range and therefore make such porous membranes amenable for use in devices for single molecule detection. | 12-18-2008 |
| 20090050205 | METHOD OF OPTIMIZING THE BAND EDGE POSITIONS OF THE CONDUCTION BAND AND THE VALENCE BAND OF A SEMICONDUCTOR MATERIAL FOR USE IN PHOTOACTIVE DEVICES - The present invention relates to a semiconductor compound having the general formula A | 02-26-2009 |
| 20090121185 | METHOD OF FORMING A COMPOSITE CONTAINING A MATRIX COMPONENT AND AT LEAST ONE LIQUID CRYSTAL COMPONENT - A method of forming a composite containing a matrix component and at least one liquid crystal component includes providing a matrix, providing a first material that is phase separable from the matrix, adding the first material to the matrix, and replacing the first material that is phase separable form the matrix with a second material exhibiting liquid crystalline behavior. | 05-14-2009 |
| 20090159873 | FUNCTIONAL MOLECULAR DEVICE - A functional molecular device displaying its functions under the action of an electrical field is provided. A Louis base molecule, exhibiting positive dielectric constant anisotropy or exhibiting dipole moment along the long-axis direction of the Louis base molecule, is arrayed in the form of a pendant on an electrically conductive linear or film-shaped principal-axis molecule of a conjugated system, via a metal ion capable of acting as a Louis acid. The resulting structure is changed in conformation on application of an electrical field to exhibit its function. The electrically conductive linear or film-shaped principal-axis molecule and the Louis base molecule form a complex with the metal ion. On application of the electrical field, the Louis base molecule performs a swinging movement or a seesaw movement to switch the electrical conductivity of the principal-axis molecule. This molecule exhibits electrical characteristics which may be reversed depending on whether or not the molecule has been subjected to electrical field processing. A molecular device having a function equivalent to one of CMOS may be produced from one and the same material. | 06-25-2009 |
| 20100300521 | SQUARYLIUM DYES INCLUDING AN ANCHORING GROUP - The present invention relates to squarylium dyes including an anchoring group, to a method of synthesis of such dye, to an electronic device comprising such dye, and to uses of such dye. | 12-02-2010 |
| 20110051235 | MICROSCOPE MEASUREMENT SYSTEM - A microscope measurement system including: an optical microscope including a microscope body and an objective connected to the microscope body; a chamber including a support mechanism holding an object to be examined therein, the chamber including an opening inserting the objective into the chamber such that the objective is located essentially within the chamber and the microscope body is located essentially outside of the chamber; a sealing mechanism that provides an essentially gas-tight connection between the optical microscope and the chamber such that the chamber is sealed. | 03-03-2011 |
| Patent application number | Description | Published |
|---|
| 20090032327 | STEERING ASSISTING SYSTEM FOR VEHICLE - A steering assisting system has a variable transfer ratio steering apparatus and an electric power steering apparatus. The variable transfer ratio steering apparatus has an electric motor for a rotation transfer ratio varying operation. When a predetermined failure occurs in the electric power steering apparatus, the motor is driven to assist the steering operation of the steering wheel. Therefore, without providing the electric power steering apparatus in two sets, the power-assisting torque generation can be continued even when the electric power steering apparatus fails to generate the power-assisting torque. | 02-05-2009 |
| 20090059548 | ELECTRONIC DEVICE MOUNTING STRUCTURE FOR BUSBAR - An electronic device mounting structure includes an electronic device, a busbar, and a solder. The electronic device has a body and a lead protruding from the body. The busbar has a flat portion and a wall portion rising from a periphery of the flat portion. The flat portion of the busbar extends parallel to a tip portion of the lead and is in contact with a back surface of the tip portion. The wall portion of the busbar faces a side surface of the tip portion with a predetermined space. The solder is located in the space and joins the side surface of the tip portion and the wall portion of the busbar | 03-05-2009 |
| 20090067131 | ELECTRONIC DEVICE MOUNTING STRUCTURE - An electronic device mounting structure includes a thermally conductive base, a busbar located on the base, an electronic device mounted on the busbar, a thermally conductive wall standing on the base and having first and second portions located opposite each other across the electronic device, and a plate spring supported by the first and second portions of the wall. The plate spring presses the electronic device against the base so that thermal resistance between the electronic device and the base is reduced. The plate spring has a thermal conductivity so that heat in the electronic device is transferred to the wall through the plate spring. | 03-12-2009 |
| 20090071683 | ELECTRONIC DEVICE MOUNTING STRUCTURE AND METHOD OF MAKING THE SAME - An electronic device mounting structure includes a printed circuit board, a busbar, and an electronic device mounted on the busbar. The busbar includes a parallel portion extending parallel to the printed circuit board and a bent portion extending from the parallel portion toward the printed circuit board. The bent portion of the busbar includes a first bent portion, a second bent portion, and a tip portion A thickness direction of the first bent portion is substantially parallel to a length direction of the parallel portion A thickness direction of the second bent portion is substantially parallel to a width direction of the parallel portion. The tip portion stands substantially at a right angle with respect to the second bent portion and is soldered to the printed circuit board. | 03-19-2009 |
