1 |
미세유동채널에 위치하는 전기화학센서용 미세기준전극제조방법 |
KR1020080065028 |
2008-07-04 |
KR1020100004710A |
2010-01-13 |
이내응; 김덕진; 엔구엔튜이녹튜이 |
PURPOSE: A method of manufacturing a fine reference electrode located in micro-fluidic channel for an electrochemical sensor are provided to implement the integration of a minute micro-flow channel by selectively coating the membrane on a reference electrode. CONSTITUTION: In a method of manufacturing a fine reference electrode located in micro-fluidic channel for an electrochemical sensor, an electrode metal is evaporated on the surface of a material(110). A micro-flow channel(130) in which a metal layer is located is formed. The surface of the metal layer is processed through chlorination, and a metal and a reference electrode(124) are formed. A membrane(140) is coated on the surface of the metal and reference electrode. |
2 |
마스크의 제조 방법, 배선 패턴의 제조 방법, 및 플라스마디스플레이의 제조 방법 |
KR1020070063647 |
2007-06-27 |
KR1020080003256A |
2008-01-07 |
히라이도시미츠; 기구치히로시 |
A method for manufacturing a mask, a method for manufacturing a wiring pattern, and a method for manufacturing a plasma display are provided to reduce a manufacturing cost by using an inexpensive mask. A method for manufacturing a mask(20) includes the steps of: performing a lyophobic treatment on at least one surface of a translucent substrate(5); disposing a light-shielding material on the surface subjected to the lyophobic treatment of the translucent substrate in a desired shape by using a droplet discharge method; and firing the light-shielding material so as to form a light-shielding pattern(MP) on the translucent substrate. |
3 |
박막패턴층을 제조하기 위한 방법 |
KR1020060123776 |
2006-12-07 |
KR1020070066875A |
2007-06-27 |
서,연혜; 왕,우녕; 주,징위 |
A method for manufacturing a patterned thin film layer is provided to increase viscosity of an ink and to improve uniformity of the patterned thin film layer by simultaneously controlling temperature of a substrate. A substrate(102) has a plurality of walls(106) defining plural spaces(108). An ink(110) is injected into the spaces. Temperature of the substrate is controlled in order to increase viscosity of the ink injected into the spaces. The ink is solidified to form a patterned thin film layer on the substrate. The walls and the substrate are monolithically formed through an injection molding process. |
4 |
중간층을갖는레이저어드레서블열전사이미지소자 |
KR1019980708214 |
1997-03-13 |
KR1020000005446A |
2000-01-25 |
창제프리시; 스타랄존에스; 톨버트윌리암에이; 울크마틴비; 잘버트클레어에이; 초우하신-하신 |
PURPOSE: The thermal transfer image device is provided to improve the efficiency and the speed of a laser addressable system without deteriorating image quality or resolution. CONSTITUTION: The image transfer method comprises the steps of: contacting a thermal transfer layer on the surface of a receptive body by closely positioning the receptive body at a thermal transfer device including a substrate where a middle layer and the thermal transfer layer is sequentially deposited; exposing the thermal transfer device in a pattern of image with a radiating source; forming a transfer image to the receptive body by transferring the thermal transfer layer corresponding to the image pattern to the receptive body without transferring to the middle layer in fact. |
5 |
Production of test prints |
US12989398 |
2009-04-22 |
US08681376B2 |
2014-03-25 |
David Radtke; Jürgen Wurster |
In order to improve a method for producing test prints such that the same results in reproducible test prints in a narrow deviation spectrum at high accuracy with the highest possible print flexibility, the invention provides a method for the production of test prints (proofs) of print data intended for printing on an industrial printing machine on a digital printer, wherein the print data is converted from a color space for any given industrial printing machine into digital proof print data in a color space for any given digital printer, as a function of a given state based on conversion tables, wherein the given state comprises parameters, such as paper type, ink, printing mode, and wherein conversion data is determined and considered during the printing process for a calibration file for the printer based on data compatible with the color space, by means of printing a test image, measuring the same, and comparing the same to a typical printer target image, wherein parameters dependent on a measuring device utilized during the measuring of the test image are considered during the determination of the correction data. |
6 |
Method of Creating a Digital Mask for Flexographic Printing Elements In Situ |
US12413753 |
2009-03-30 |
US20090186303A1 |
2009-07-23 |
David Recchia |
A method of creating a digital mask in situ for use in a process of making digital flexographic printing elements. The digital mask is created by laminating the negative image that is the by-product of a thermal proofer to a photosensitive printing plate. Thereafter, the photosensitive printing element can be imaged, exposed, and developed in the usual manner. |
7 |
Laser addressable thermal transfer imaging element with an interlayer |
US11272240 |
2005-11-10 |
US07226716B2 |
2007-06-05 |
Jeffrey C. Chang; John S. Staral; William A. Tolbert; Martin B. Wolk; Claire A. Jalbert; Hsin-hsin Chou |
A thermal transfer donor element is provided which comprises a support, a light-to-heat conversion layer, an interlayer, and a thermal transfer layer. When the above donor element is brought into contact with a receptor and imagewise irradiated, an image is obtained which is free from contamination by the light-to-heat conversion layer. The construction and process of this invention is useful in making colored images including applications such as color proofs and color filter elements. |
8 |
Method, system, and computer readable medium for digital proofing |
US10890584 |
2004-07-14 |
US20060012662A1 |
2006-01-19 |
Pierre Ferland; Donald Pederson |
A method, system, and computer readable medium for digital proofing comprises producing a digital proof on at least one substrate, wherein the substrate has been surface-treated with at least one coating, wherein an overall appearance of the substrate is unaltered by the coating, and wherein the substrate is adapted to be printed on a printing device. |
9 |
Image-forming material, image formation method and method for manufacturing color proof |
US10230057 |
2002-08-29 |
US06962893B2 |
2005-11-08 |
Naotaka Wachi; Akira Hatakeyama |
To provide an image-forming material, an image formation method and a method for manufacturing a color proof, where even when laser recording is performed with a higher energy by multi-beam laser light, a light-to-heat conversion substance or a decomposition product thereof is prevented from transferring to the image-forming layer and at the same time, a transfer image having sufficiently high image density, high resolution, and no layer fogging can be formed on an image-receiving sheet.An image-forming material comprising an image-receiving sheet having at least an image-receiving layer and a thermal transfer sheet comprising a support having thereon at least a light-to-heat conversion layer and an image-forming layer, wherein the light-to-heat conversion layer of the thermal transfer sheet comprises a homopolymer and/or a copolymer of vinylpyrrolidone. |
10 |
Ink-jet recording material for proof |
US10421860 |
2003-04-24 |
US20030203133A1 |
2003-10-30 |
Iwao
Maekawa |
Disclosed are an ink-jet recording material for proof comprising a water-resistant support and at least one ink-receptive layer containing inorganic fine particles and a hydrophilic binder provided on the support, wherein the water-resistant support has a center line average roughness Ra75 with a cut off value of 0.8 mm according to JIS-B0601 of 1.0 nullm or less, and an uppermost ink-receptive layer farthest from the water-resistant support contains a colorless or white matting agent having an average particle size of 1 to 10 nullm and a colored pigment having an average particle size of 1 nullm or less, and use of the same for proof. |
11 |
Thermal imaging process and products using image rigidification |
US10188518 |
2002-07-03 |
US20030064302A1 |
2003-04-03 |
Jonathan
V.
Caspar; Harvey
Walter
Taylor
JR.; Gregory
C.
Weed; Rolf
S.
Gabrielsen |
Improved processes and products for laser thermal imaging are described. These improved processes and products utlilize an image rigidification element and significantly reduce halftone dot movement, swath boundary cracking and banding. |
12 |
Laser addressable thermal transfer imaging element with an interlayer |
US10219427 |
2002-08-15 |
US20030003390A1 |
2003-01-02 |
Jeffrey
C.
Chang; John
S.
Staral; William
A.
Tolbert; Martin
B.
Wolk; Claire
a.
Jalbert; Hsin-Hsin
Chou |
A thermal transfer donor element is provided which comprises a support, a light-to-heat conversion layer, an interlayer, and a thermal transfer layer. When the above donor element is brought into contact with a receptor and imagewise irradiated, an image is obtained which is free from contamination by the light-to-heat conversion layer. The construction and process of this invention is useful in making colored images including applications such as color proofs and color filter elements. |
13 |
Method for preparing proof for plate printing, and recording medium |
US09832898 |
2001-04-12 |
US20010043240A1 |
2001-11-22 |
Isao
Gotou; Nobuyuki
Yokota; Hiroyuki
Fujii; Yasuo
Yamada; Motoi
Kamba |
A method for preparing a proof for plate printing, which comprises applying inkjet printing to an ink receiving layer of a recording medium having the ink receiving layer formed on the surface of a support made of plate printing paper for regular printing or made of paper having substantially the same brightness and glossiness as such plate printing paper, to obtain a printing proof. |
14 |
Ceramic calibration filter |
US09649847 |
2000-08-29 |
US06320887B1 |
2001-11-20 |
Roger S. Kerr; Kurt M. Sanger |
The present invention is for a ceramic calibration filter, in one embodiment a ceramic attenuator (410), for attenuating radiation between a light source (402) and a sensor (422). A laser signal is reduced by ceramic attenuator (410) to a low-level signal that can be measured the sensor (422). |
15 |
Image transfer process for ink-jet generated images |
US09835606 |
2001-04-16 |
US20010031344A1 |
2001-10-18 |
Charles
Kevin
Nordeen; Donald
Lawrence
Knutson |
An image transfer process is provided for transferring an ink-jet image composite from an original receptor to a final receptor. The transfer process allows one to view an ink-jet image on a variety of substrates including mock-ups for packaging and other materials that would not be capable of receiving an image directly in an ink-jet printer. |
16 |
Thermal imaging process and products using image rigidification |
US09419680 |
1999-10-15 |
US06294308B1 |
2001-09-25 |
Jonathan V. Caspar; Harvey Walter Taylor, Jr.; Gregory C. Weed; Rolf S. Gabrielsen |
Improved processes and products for laser thermal imaging are described. These improved processes and products utilize an image rigidification element and significantly reduce halftone dot movement, swath boundary cracking and banding. |
17 |
Thermal color proofing process |
US09603277 |
2000-06-26 |
US06197474B1 |
2001-03-06 |
David A. Niemeyer; Gerard J. Brien; Charles DeBoer |
A process of forming a halftone color proof containing at least one dye transfer image and at least one pigment transfer image, comprising imagewise-exposing, for less than about 10−4 sec., by means of a laser having a power density of greater than 104 W/cm2, a dye-donor element comprising a support having thereon a dye layer comprising a dye dispersed in a polymeric binder, the dye layer having an infrared-absorbing material associated therewith, the laser exposure taking place through the side of the support of the dye-donor element which does not have the dye layer thereon, and transferring a portion of the dye in the dye layer to a receiving element having thereon an image-receiving layer; and imagewise-exposing, for less than about 10−4 sec., by means of the laser, an ablative or propulsive pigment-donor element comprising a support having thereon a transfer layer comprising a pigment dispersed in a binder, the transfer layer having an infrared-absorbing material associated therewith, the laser exposure taking place through the side of the support of the pigment-donor element which does not have the transfer layer thereon, and transferring a pigment image to the receiving element to obtain the halftone color proof. |
18 |
Laser addressable thermal transfer imaging element with an interlayer |
US09410508 |
1999-10-01 |
US06190826B1 |
2001-02-20 |
Jeffrey C. Chang; John S. Staral; William A. Tolbert; Martin B. Wolk; Claire A. Jalbert; Hsin-hsin Chou |
A thermal transfer donor element is provided which comprises a support, a light-to-heat conversion layer, an interlayer, and a thermal transfer layer. When the above donor element is brought into contact with a receptor and imagewise irradiated, an image is obtained which is free from contamination by the light-to-heat conversion layer. The construction and process of this invention is useful in making colored images including applications such as color proofs and color filter elements. |
19 |
Laser donor element |
US475579 |
1999-12-30 |
US6165671A |
2000-12-26 |
Charles H. Weidner; Kevin W. Williams |
A laser donor element comprising a transparent support having thereon the following layers in the order recited:a) a hydrophilic layer;b) a propellant layer comprising a gas-producing polymer being capable of forming a gas upon heating by the laser and an infrared-absorbing material, the propellant layer having been coated using a polar solvent having an E.sub.t value of between about 0.3 and 1.0; andc) a colorant transfer layer comprising a colorant dispersed in a binder. |
20 |
Method for matching optical density in color proofing |
US293803 |
1999-04-19 |
US6060208A |
2000-05-09 |
Tangyu Wang |
A method for controlling the color density of colorant transferred to a substrate involves creating tiny gap areas in the coverage of the colorant. The method is useful in producing color proofs of halftone images. The gap areas are typically much smaller than a screen dot in a halftone image. The method permits the generation of a proof which has the same sizes of screen dots as will appear in the final printed image while operating in the saturation portion of the transfer function for the colorant being used. Suitable gap areas may be provided by pulsing a laser used to transfer colorant from a donor to a substrate. The method does not require the use of a variable power laser and therefore is more stable than previous proofing methods. |