Patent application number | Description | Published |
20130284354 | SUBSTRATE FOR AN ORGANIC LIGHT-EMITTING DEVICE AND METHOD FOR MANUFACTURING THE SAME - Provided is a substrate for an organic light emitting diode including a base substrate, a high refractive scattering layer formed on the base substrate, and having a scattering particle scattering light in a high refractive material, and an adhesive layer formed between the base substrate and the high refractive scattering layer to laminate the base substrate with the high refractive scattering layer, wherein the high refractive scattering layer has a structure in which the scattering particle is immersed in the high refractive material, an average thickness of the high refractive scattering layer is smaller than an average diameter of the scattering particle, a surface of the high refractive scattering layer laminated with the base substrate by the adhesive layer has unevenness formed by the scattering particle, the opposite surface of the high refractive scattering layer laminated with the base substrate by the adhesive layer has a planarized surface, and a method for manufacturing the same. The substrate may have an excellent degree of planarization and improved light extraction efficiency without degradation in performance of the diode, and low process and material costs and mass-production of the substrate may be easily achieved. | 10-31-2013 |
20130286659 | SUBSTRATE FOR AN ORGANIC LIGHT-EMITTING DEVICE AND METHOD FOR MANUFACTURING THE SAME (As Amended) - Provided is a substrate for an organic light emitting diode including a base substrate, a high refractive scattering layer formed on the base substrate, and having a scattering particle scattering light in a high refractive material, and an adhesive layer formed between the base substrate and the high refractive scattering layer to laminate the base substrate with the high refractive scattering layer, wherein the high refractive scattering layer has a structure in which the scattering particle is immersed in the high refractive material, an average thickness of the high refractive scattering layer is smaller than an average diameter of the scattering particle, a surface of the high refractive scattering layer laminated with the base substrate by the adhesive layer has unevenness formed by the scattering particle, the opposite surface of the high refractive scattering layer laminated with the base substrate by the adhesive layer has a planarized surface, and a method for manufacturing the same. The substrate may have an excellent degree of planarization and improved light extraction efficiency without degradation in performance of the diode, and low process and material costs and mass-production of the substrate may be easily achieved. | 10-31-2013 |
20130302565 | SUBSTRATE FOR AN ORGANIC ELECTRONIC ELEMENT AND A PRODUCTION METHOD THEREFOR - The present invention relates to a substrate for an organic electronic element that enables surface resistance to be reduced and light-extraction efficiency improved, the substrate including: a base substrate; a scattering layer which is formed on the base substrate and includes an conductive pattern for reducing the surface resistance of an electrode, scattering particles for scattering light and a binder, and which forms an uneven structure in the surface opposite the base substrate; and a planarizing layer which is formed on the scattering layer and flattens the surface undulations caused by the uneven structure of the scattering layer, wherein the refractive index (Na) of the scattering particles and the refractive index (Nb) of the planarizing layer satisfy the relationship in formula 1 below. [Formula 1] |Na−Nb|≧0.3. In the formula as used herein, Na signifies the refractive index of the scattering particles and Nb signifies the refractive index of the planarizing layer. | 11-14-2013 |
20140014923 | SUBSTRATE FOR AN ORGANIC ELECTRONIC DEVICE AND AN ORGANIC ELECTRONIC DEVICE COMPRISING THE SAME - A substrate including a base substrate; a scattering layer which is formed on the base substrate, includes a binder and scattering particles for scattering light, and has an uneven structure formed on a surface thereof opposite the base substrate; and a planarizing layer which is formed on the scattering layer and has a flat surface formed thereon, is provided. Here, the refractive index Na of the scattering particles and the refractive index Nb of the planarizing layer satisfy the expression |Na−Nb|≧0.3, an organic electronic device including the substrate, and a method of manufacturing the same are provided. Light-extraction efficiency can be improved and the manufacturing process can be simplified without degrading device performance. | 01-16-2014 |
20140048788 | SUBSTRATE FOR ORGANIC ELECTRONIC DEVICE - The present invention relates to a substrate for an organic electrode device, a manufacturing method thereof, and an organic electronic device. An exemplary substrate of the invention, if an organic light emitting element is formed on an upper part of the substrate, can obtain luminance with high emission and uniformity by efficiently controlling the surface resistance of an electrode even when the device is configured into larger sizes. | 02-20-2014 |
20140051207 | SUBSTRATE FOR ORGANIC ELECTRONIC DEVICE - The present invention relates to a substrate for an organic electrode device, a manufacturing method thereof, and an organic electronic device. An exemplary substrate of the invention, if an organic light emitting element is formed on an upper part of the substrate, can obtain luminance with high emission and uniformity by efficiently controlling the surface resistance of an electrode even when the device is configured into larger sizes. | 02-20-2014 |
20140097423 | ORGANIC LIGHT-EMITTING ELEMENT AND LIGHT-EMITTING DEVICE INCLUDING SAME - The present invention relates to an organic light-emitting element comprising a first electrode, a second electrode, and an organic layer interposed between said first electrode and said second electrode, and to a light-emitting device including the same, wherein in the organic light-emitting element, a connection electrode for electrically connecting two or more elements in serial is formed on a non-light-emitting surface of said organic light-emitting element. The invention can electrically connect a plurality of organic light-emitting elements easily, and can be implemented as a large-scale lighting or display device or the like. | 04-10-2014 |
Patent application number | Description | Published |
20150190995 | SYSTEM FOR LAMINATING OPTICAL FILM AND METHOD FOR MANUFACTURING DISPLAY UNIT USING THE SAME - A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit to laminate an optical film full-cut into a predetermined length on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit to laminate an optical film full-cut into a predetermined length on a second surface of the panel along a second direction equal or opposite to the first direction, the second laminating unit rotating the optical film supplied in a full-cut state along the second direction in a horizontal direction and laminating the optical film. | 07-09-2015 |
20150190996 | SYSTEM FOR LAMINATING OPTICAL FILM AND METHOD FOR MANUFACTURING DISPLAY UNIT USING THE SAME - A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit installed on a transfer line of the panel to laminate an optical film on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit installed on the transfer line of the panel to laminate an optical film on a second surface of the panel, wherein the second laminating unit includes a laminating drum to laminate an optical film after adsorbing and rotating the optical film in a horizontal direction. | 07-09-2015 |
20150190997 | SYSTEM FOR LAMINATING OPTICAL FILM AND METHOD FOR MANUFACTURING DISPLAY UNIT USING THE SAME - A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit installed on a transfer line of the panel to laminate an optical film on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit installed on the transfer line of the panel to laminate an optical film on a second surface of the panel along a direction perpendicular to the first direction. | 07-09-2015 |
20150190998 | SYSTEM FOR LAMINATING OPTICAL FILM AND METHOD FOR MANUFACTURING DISPLAY UNIT USING THE SAME - A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit installed on a transfer line of the panel to laminate an optical film on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit installed on the transfer line of the panel to laminate an optical film full-cut into a predetermined length on a second surface of the panel along a direction perpendicular to the first direction. | 07-09-2015 |
20150246520 | SYSTEM FOR LAMINATING OPTICAL FILM AND METHOD FOR MANUFACTURING DISPLAY UNIT USING THE SAME - A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit installed at an area where a transfer line of the panel passes, to laminate an optical film on a first surface of the panel along a first direction parallel to a transfer direction of the panel, a reverse unit to reverse the panel having the optical film laminated on the first surface, and a second laminating unit installed at an area where the transfer line of the panel passes, to laminate an optical film on a second surface of the panel reversed by the reverse unit along a direction perpendicular to the first direction. According to the present disclosure, in the process of attaching the optical film onto both sides of the panel, process efficiency may be increased. | 09-03-2015 |
Patent application number | Description | Published |
20080204795 | DATA TRANSMISSION APPARATUS AND METHOD OF CONTROLLING THE SAME AND METHOD OF PROCESSING DATA TO BE PRINTED ONTO A PRINTABLE MEDIUM - A data and address transmission apparatus of a printer head, capable of transmitting data and address between a printer head controller and a head chip and a method of controlling the same. The data and address transmission apparatus of the printer head includes an input terminal to receive combined address data and print data through a single terminal and to output the address data and the printed data, a latch terminal to receive the combined address data and print data from the input terminal, to divide the combined address data and print data into address data and print data, to store the address data and the print data, and to output the address data and the print data, and an output terminal to receives the address data and the print data from the latch terminal and to output the address data and the print data. | 08-28-2008 |
20080205957 | PRINTER HEAD CHIP FOR DETECTING ERROR, PRINTER HEAD INCLUDING THE PRINTER HEAD CHIP, IMAGE FORMING APPARATUS INCLUDING THE SAME AND METHOD OF CONTROLLING THE SAME - A printer head including a printer head chip to detecting an error, capable of detecting an operation error in the printer head chip while printing is performed during a redundancy period, and a method of controlling the same. The printer head chip includes an input unit to sequentially receive printed data, a counting unit to count discharged data using the printed data and to store the number of discharged data, a generator unit to sum the stored number of discharged data during a redundancy period and to generate resultant information using the summed number of discharged data, and a transmitting unit to transmit the resultant information to a printer head controller. | 08-28-2008 |
20080309982 | IMAGE PROCESSING APPARATUS AND IMAGE PROCESSING METHOD - An image processing apparatus includes an inputting unit to receive image data having pixel data, an image processing unit to align and output the pixel data, and a control unit to prevent the pixel data from being transmitted to the image processing unit when the pixel data have null data. | 12-18-2008 |
20090273624 | Head Driving Device, Inkjet Printer Comprising the Same, and Data Processing Method Thereof - A head driving device, an inkjet printer comprising the same and data processing method of an ink jet printer are provided, in which a nozzle driving unit turns on/off a plurality of thermal elements that correspond to a plurality of nozzles and heat ink discharged from the nozzles, a data processing unit processes printing data and outputs a nozzle select signal corresponding to an image to the nozzle driving unit; and a head logic unit receives the printing data externally, divides the printing data of one address group into a plurality of data groups, transmits the plurality of data groups to the data processing unit via different data buses corresponding to the plurality of data groups, respectively, and controls the data processing unit to process the divided printing data. Accordingly, an EMI characteristic between signals can be improved by lowering the data buses density in one area, and a data processing speed can be adjusted by dividedly processing printing data. | 11-05-2009 |
20120008975 | IMAGE FORMING APPARATUS AND CONTROL METHOD THEREOF - An image forming apparatus includes a transport part which includes a transport belt to transport a printing medium, an image forming part which transfers a toner to form a color image, and a controller which controls the image forming part to form a test image for color registration of the image forming part on the transport belt while an image is formed for a plurality of printing media. Thus, both a test image and a plurality of printed media are formed during a single printing process. | 01-12-2012 |
Patent application number | Description | Published |
20100140112 | Nanoparticle Marker, Diagnostic Methods Using the Same and Diagnostic Kit and Apparatus Using the Same - A diagnostic kit disclosed herein comprises a nanoparticle-biomaterial complex, an extraction solution, a collection electrode, and a current peak measurement unit. The nanoparticle-biomaterial complex comprises: one or more nanoparticles selected from a metal group consisting of zinc, cadmium, lead, copper, gallium, arsenic, thallium, nickel, manganese and bismuth; one or more biomaterial-binding materials binding to the nanoparticles through a binding-stabilizing agent and binding specifically to the biomaterials to be detected; and a binding-stabilizing agent forming bonds between the nanoparticles and the biomaterial-binding materials. The extraction solution serves to isolate and extract the nanoparticles from the nanoparticle-biomaterial complex. The collection electrode serves to collect the nanoparticles from the extraction solution. The current peak measurement unit serves to measure current peaks corresponding to the nanoparticles collected from the collection electrode. A diagnostic kit disclosed herein comprises a nanoparticle-biomaterial complex, an extraction solution, a collection electrode and a current peak measurement unit. The nanoparticle-biomaterial complex comprises in the diagnostic kit: one or more nanoparticles selected from a metal group consisting of zinc, cadmium, lead, copper, gallium, arsenic, thallium, nickel, manganese and bismuth; one or more biomaterial-binding materials binding to the nanoparticles through a binding-stabilizing agent and binding specifically to the biomaterials to be detected; and a binding-stabilizing agent inducing the binding between the nanoparticles and the biomaterial-binding materials. The extraction solution serves to isolate and extract the nanoparticles from the nanoparticle-biomaterial complex. The collection electrode serves to collect the nanoparticles from the extraction solution. The current peak measurement unit serves to measure current peaks corresponding to the nanoparticles collected from the collection electrode. A diagnostic device disclosed herein is an information technology-integrated, miniaturized electrochemical biosensor, which comprises a disposable tip, an electrode, a container for storing a diagnostic reagent, and a unit for performing electric measurement or optical measurement, is in the form of a pipette or syringe, and has a container stopper in which the electrode is included. | 06-10-2010 |