公开(公告)号：KR1020170003077A

公开(公告)日：2017-01-09

申请号：KR1020150093269

申请日：2015-06-30

Applicant: 한국생산기술연구원

Inventor： 강민규 ,  강경태 ,  이상호 ,  조관현 ,  신권용

IPC: H01L51/00 ,  H01L27/12 ,  H01L21/67 ,  H01L21/78 ,  H01L27/32

Abstract: 본발명은노즐프린팅을이용하여패턴을형성하는방법및 장치에관한것이다. 본발명의일면에따른노즐프린팅을이용한패턴형성방법은보호필름을절단하고, 이를기판상에전사시키는단계와, 절단된보호필름을제거시키고, 노즐프린팅으로코팅을수행하는단계및 보호필름을제거하여패턴을형성하는단계를포함하는것을특징으로한다.

公开(公告)号：KR101561994B1

公开(公告)日：2015-10-20

申请号：KR1020140089735

申请日：2014-07-16

Applicant: 한국생산기술연구원

Inventor： 강경태 ,  노윤수 ,  이성구 ,  황준영 ,  강희석 ,  신권용

IPC: B05B5/025

CPC classification number: B05B5/0255

Abstract: 본발명은전기수력학적분사노즐모듈에관한것으로서, 특히나노와이어가분산된용액에서나노와이어를일방향으로정렬시켜인쇄또는분사시킬수 있는전기수력학적분사노즐모듈에관한것이다. 본발명의전기수력학적분사노즐모듈은, 전도성재질로이루어지고, 일단이튜브와연결되며, 내부에상기튜브를통해공급된용액이유동하는제1통로가형성된제1어댑터와; 절연성재질로이루어지고, 일단이상기제1어댑터의타단에결합되며, 내부에상기제1통로와연통되는제2통로가형성된제2어댑터와; 전도성재질로이루어지고, 일단이상기제2어댑터의타단에결합되어상기제1어댑터와이격되며, 내부에상기제2통로와연통되는제3통로가형성된분사노즐과; 상기분사노즐의타단과이격되어배치되고, 상기제1통로, 제2통로및 제3통로로이루어진분사통로를통해분사된상기용액이도포되는기판;을포함하여이루어지되, 상기용액에는나노와이어가분산되어있고, 상기제1어댑터및 분사노즐에는전원이인가되는것을특징으로한다.

Abstract translation: 本发明涉及一种电动液压动力喷嘴模块，更具体地说，涉及一种电动喷雾喷雾模组，其可以通过在纳米线分散的溶液中单向排列纳米线而进行印刷或喷涂。 根据本发明，电动喷雾喷嘴组件包括：第一适配器，其由导电材料制成，其端部连接到管，并且形成通过管供应的第一通道流体在其中流动; 第二适配器，其由绝缘材料制成，其端部与第一适配器的另一端联接，并形成与第一通道连通的第二通道; 喷嘴，其由导电材料制成，其端部与所述第二适配器的另一端耦合以与所述第一适配器分离，并形成与所述第二通道连通的第三通道; 以及通过与喷嘴的另一端分离并且通过由第一通道，第二通道和第三通道组成的喷射通道喷射的溶液而设置的基板。 在该解决方案中，纳米线被分散并且功率被施加到第一适配器和喷嘴。

公开(公告)号：KR1020150072170A

公开(公告)日：2015-06-29

申请号：KR1020130159532

申请日：2013-12-19

Applicant: 한국생산기술연구원

Inventor： 이상호 ,  노윤수 ,  강경태 ,  강희석 ,  황준영 ,  윤규영 ,  유준호

IPC: G01N27/30 ,  G01N27/416

CPC classification number: G01N27/30 ,  G01N27/416

Abstract: 본발명은전기화학센서모듈및 그제조방법에관한것으로서, 특히액체시료를감지하여전기화학신호를발생시킬수 있는전기화학센서모듈및 그제조방법에관한것이다. 본발명의전기화학센서모듈은, 소수성층과; 상기소수성층의상면에적층되고, 액체시료가유동하는통로를형성하는공급통로부와; 상기소수성층의상면에적층되고, 상기공급통로부과연결된전극부를포함하여이루어지되, 상기액체시료는상기공급통로부를통해상기전극부로이동하고, 상기전극부는상기공급통로부를통해공급된상기액체시료에반응하여전기화학신호를발생시키는것을특징으로한다.

Abstract translation: 本发明涉及一种电化学传感器模块及其制造方法，更具体地，涉及一种检测液体样品以产生电化学信号的电化学传感器模块及其制造方法。 根据本发明，电化学传感器模块包括：疏水层; 供应通道部分，其放置在疏水层的上表面上，以形成允许液体样品流动的通道; 以及布置在疏水层的上表面上以连接到供给通道部分的电极部分。 液体样品通过供给通道部分流入电极部分。 电极部分响应于通过供应通道部分提供的液体样品而产生电化学信号。

公开(公告)号：KR101396173B1

公开(公告)日：2014-05-19

申请号：KR1020130035908

申请日：2013-04-02

Applicant: 한국생산기술연구원

Inventor： 황준영 ,  강희석 ,  강경태 ,  이상호 ,  문윤재 ,  김동근 ,  문승재

IPC: B41F23/04 ,  H05K3/12

Abstract: The present invention relates to a method for curing conductive ink using stepwise constant currents and, more specifically, to a method for curing conductive ink using stepwise constant currents capable of preventing damage to a wire caused by heat when a temperature is increased by gradually increasing constant currents. The method for curing conductive ink using stepwise constant currents comprises: an ink spreading step of forming a pattern by spreading conductive ink containing metal particles to a substrate; and a curing step of heating the conductive ink to be cured by applying the constant currents to the conductive ink. The curing step is composed of multiple heating steps using different constant currents applied thereto.

Abstract translation: 本发明涉及一种使用逐步恒定电流固化导电油墨的方法，更具体地说，涉及一种使用逐步恒定电流固化导电油墨的方法，该方法能够通过逐渐增加常数来增加温度而增加热量导致的热损伤 电流。 使用逐步恒流固化导电油墨的方法包括：油墨扩散步骤，通过将含有金属颗粒的导电油墨铺展到基材上形成图案; 以及通过向导电油墨施加恒定电流来加热要固化的导电油墨的固化步骤。 固化步骤由使用不同恒定电流的多个加热步骤组成。

公开(公告)号：KR101331589B1

公开(公告)日：2013-11-20

申请号：KR1020120052189

申请日：2012-05-16

Applicant: 한국생산기술연구원

Inventor： 황준영 ,  강희석 ,  강경태 ,  이상호 ,  윤규영 ,  신권용

IPC: H01L21/28

CPC classification number: H01L21/76898 ,  H01L21/76829 ,  H01L21/76877

Abstract: A method for fabricating an ultra fine line substrate according to the present invention includes a step for forming a first sacrificial layer on the first region of a substrate including the first region and a second region, a step for forming a second sacrificial layer on the second region of the substrate, a step for removing the first sacrificial layer, a step for forming a bonding enforcement layer in the first region, and a step for forming a conductive layer on the bonding enforcement layer. [Reference numerals] (S100) Forming a concave unit;(S102) Forming a first sacrificial layer;(S104) Forming a second sacrificial layer;(S106) Forming a third sacrificial layer;(S108) Removing the first sacrificial layer;(S110) Forming a bonding enforcement layer;(S112) Ultraviolet rays - ozone treatment;(S114) Forming a conductive layer;(S116) Removing the second and third sacrificial layers

Abstract translation: 根据本发明的用于制造超细线基板的方法包括在包括第一区域和第二区域的基板的第一区域上形成第一牺牲层的步骤，在第二区域上形成第二牺牲层的步骤 区域，用于去除第一牺牲层的步骤，在第一区域中形成接合强化层的步骤，以及在接合强化层上形成导电层的步骤。 （S100）形成凹部（S102）形成第一牺牲层;（S104）形成第二牺牲层;（S106）形成第三牺牲层;（S108）除去第一牺牲层;（S110） ）形成粘合强化层;（S112）紫外线 - 臭氧处理;（S114）形成导电层;（S116）去除第二和第三牺牲层

公开(公告)号：KR101232858B1

公开(公告)日：2013-02-13

申请号：KR1020110074718

申请日：2011-07-27

Applicant: 한국생산기술연구원

Inventor： 황정호 ,  이낙규 ,  강경태

IPC: G01B5/06 ,  B65H61/00

Abstract: 본 발명은 웨브의 연속된 가공공정에서 두께를 복수지점에서 측정하는 웨브의 복수지점의 두께를 측정하는 회전롤이 구비된 두께측정장치 및 그 제어방법에 관한 것으로서, 본 발명의 일실시예에 따르면, 연속된 웨브가 이송되는 것을 일측에서 지지하는 회전롤과 이격된 위치에 상기 회전롤과 수평하며 같은 길이방향을 가지도록 구비되는 제1가이드, 상기 제1가이드와 대향된 위치에 구비되는 제2가이드, 상기 제1가이드를 따라 슬라이딩 이동되도록 배치되어 위치된 지점으로부터 상기 회전롤의 마주보는 지점의 거리를 측정하거나, 상기 웨브의 마주보는 지점과의 거리를 측정하는 제1측정센서모듈, 상기 제2가이드를 따라 슬라이딩 이동되도록 배치되어 위치된 지점으로부터 상기 회전롤까지의 거리를 측정하는 제2측정센서모듈, 상기 제1측정센서 모듈과 제2측정센서모듈을 상기 제1가이드와 제2가이드를 따라 슬라이딩 이송시키는 구동부 및 상기 회전롤에 웨브가 없을 때와 웨브가 접촉되면서 이송될 때에 상기 제1측정센서모듈과 제2측정센서모듈에서 측정한 거리의 차이로서 웨브의 두께를 계산하며, 상기 제1측정센서모듈과 제2측정센서모듈의 측정지점을 제어하는 제어부를 포함하여 이루어지는 웨브의 복수지점의 두께를 측정하는 회전롤이 구비된 두께측정장치가 제공된다.

公开(公告)号：KR1020130013205A

公开(公告)日：2013-02-06

申请号：KR1020110074718

申请日：2011-07-27

Applicant: 한국생산기술연구원

Inventor： 황정호 ,  이낙규 ,  강경태

IPC: G01B5/06 ,  B65H61/00

Abstract: PURPOSE: A thickness measuring device with a rotating roll measuring the thickness of several points of a web and a method for controlling the same are provided to effectively measure the web of a film which is sensitive to starches etc. as friction between the device and the web is small. CONSTITUTION: A thickness measuring device with a rotating roll(105) measuring the thickness of several points of a web comprises a first guide(130), a second guide(140), a first measuring sensor module(110), a second measuring sensor module, and a control unit. The first guide is parallel to the rotating roll supporting at a position spaced from the rotating roll and has a longitudinal direction identical to the rotating roll. The second guide is parallel to the rotating roll by being spaced at a position facing the first guide and has the longitudinal direction identical to the rotating roll. The first and second measuring sensor modules are slide-moved by the driving unit along the first and second guides. The control unit controls the driving unit, thereby controlling measurement points of the first and second measuring sensor modules.

Abstract translation: 目的：提供一种测量幅材几点厚度的旋转辊的厚度测量装置及其控制方法，以有效地测量对淀粉等敏感的膜的卷材，因为该装置和装置之间的摩擦 网页很小 一种厚度测量装置，其具有测量幅材的若干点的厚度的旋转辊（105），包括第一引导件（130），第二引导件（140），第一测量传感器模块（110），第二测量传感器 模块和控制单元。 第一引导件平行于在与旋转辊隔开的位置处支撑的旋转辊，并且具有与旋转辊相同的纵向方向。 第二引导件通过在与第一引导件相对的位置处间隔开并且具有与旋转辊相同的纵向方向平行于旋转辊。 第一和第二测量传感器模块通过驱动单元沿着第一和第二引导件滑动移动。 控制单元控制驱动单元，从而控制第一和第二测量传感器模块的测量点。

公开(公告)号：KR1020100080122A

公开(公告)日：2010-07-08

申请号：KR1020080138754

申请日：2008-12-31

Applicant: 한국생산기술연구원

Inventor： 이상호 ,  황준영 ,  강경태 ,  강희석 ,  조영준

IPC: H01L21/8247 ,  H01L27/115 ,  B82Y10/00

CPC classification number: H01L45/06 ,  B82Y10/00 ,  H01L45/1233 ,  H01L45/126 ,  H01L45/128 ,  H01L45/143 ,  H01L45/144

Abstract: PURPOSE: By using the inkjet printing technique, the phase-change memory manufacturing method using the inkjet printing manufactures the phase-change memory. It easily can manufacture without the complex process and produce-time and production cost are reduced. CONSTITUTION: A bottom electrode(100) is formed on the substrate(600). The heater(200) of the fixed level is formed in the upper side of the bottom electrode. The insulating layer(300) is formed in the upper side of the bottom electrode into the fixed region. The phase-change layer(400) is formed in order to be close with heater. The upper electrode(500) is formed in order to be close with the phase-change layer.

Abstract translation: 目的：通过使用喷墨打印技术，使用喷墨印刷的相变存储器制造方法制造相变存储器。 在不需要复杂工艺的情况下可以方便地制造，生产时间和生产成本降低。 构成：在基板（600）上形成底部电极（100）。 固定电平的加热器（200）形成在底部电极的上侧。 绝缘层（300）在底电极的上侧形成固定区域。 相变层（400）形成为与加热器接近。 上电极（500）形成为与相变层接近。

公开(公告)号：KR1020090012438A

公开(公告)日：2009-02-04

申请号：KR1020070076253

申请日：2007-07-30

Applicant: 한국생산기술연구원

Inventor： 이상호 ,  강경태 ,  강희석 ,  신권용 ,  이경균

IPC: H01L21/027 ,  G03F7/20

CPC classification number: H01L21/02274 ,  H01L21/02046 ,  H05K3/125

Abstract: An inkjet printing and a micro-pattern manufacturing method using a plasma surface treatment method are provided to exclude the irregularities of the micro-pattern implemented as the ink droplet. A micro-pattern manufacturing method using the inkjet printing and a plasma surface treatment method comprise the step for dry-cleaning a substrate(10); the step for coating the substrate with hydrophobic fluorination organic film(20); the step for heating the substrate(30); the step for forming the micro-pattern on the substrate. The dry-cleaning is performed in the oxygen plasma or ozone generator. The hydrophobic fluorination organic film is formed by using the gas for the semiconductor implantation. The micro-pattern is formed by spraying the ink droplet(1) onto the top of the substrate having the constant temperature.

Abstract translation: 提供使用等离子体表面处理方法的喷墨印刷和微图案制造方法，以排除作为墨滴实现的微图案的不规则性。 使用喷墨印刷和等离子体表面处理方法的微图案制造方法包括干燥基板（10）的步骤。 用疏水性氟化有机膜（20）涂布基材的步骤; 用于加热衬底（30）的步骤; 在衬底上形成微图案的步骤。 在氧等离子体或臭氧发生器中进行干洗。 通过使用用于半导体注入的气体形成疏水性氟化有机膜。 通过将墨滴（1）喷射到具有恒定温度的基板的顶部上来形成微图案。

公开(公告)号：KR100826584B1

公开(公告)日：2008-04-30

申请号：KR1020070039683

申请日：2007-04-24

Applicant: 한국생산기술연구원

Inventor： 이상호 ,  강경태 ,  박문수 ,  강희석

IPC: G01N33/00 ,  G01N27/00 ,  B81B3/00

Abstract: A fluidic channeling actuator for biochip analysis is provided to control channeling of more than two kinds of sample fluids using electrowetting phenomenon, thereby being very usefully used for analyzing reaction, diffusion and reaction speed of the fluids. A fluidic channeling actuator for biochip analysis comprises: a lower plate(20) having a plurality of microchannels through which fluid and a sample solution are injected; an electrode(30) installed on the lower plate and applied voltage from an external device and a portion of which is placed between the plurality of microchannels, a hydrophilic pattern formed on the upper side of the electrode; a hydrophobic pattern formed on the hydrophilic pattern upper side; an upper plate(10) which is equipped at the upper side of the lower plate to close the microchannel, has a mixture gate to allow the fluid and the sample solution flown in the microchannel to be mixed and is equipped with an inlet(13) to allow the fluid to be injected; and an air vent which is equipped at the upper plate and allows air in the within of the microchannel to be discharged by the fluid flowing in, wherein the hydrophobic pattern becomes hydrophilic by electrowetting phenomenon when voltage is applied to the electrode.

Abstract translation: 提供了用于生物芯片分析的流体通道致动器，以使用电润湿现象来控制两种以上样品流体的通道，从而非常有用地用于分析流体的反应，扩散和反应速度。 用于生物芯片分析的流体通道致动器包括：具有多个微通道的下板（20），流体和样品溶液通过该微通道注入; 电极（30），其安装在所述下板上并从外部装置施加电压，并且其一部分放置在所述多个微通道之间;形成在所述电极的上侧的亲水图案; 形成在亲水图案上侧的疏水图案; 设置在下板的上侧以关闭微通道的上板（10）具有混合浇口，以使流体和样品溶液在微通道中流动，并配备有入口（13）， 以允许流体被注入; 并且设置在上板处并允许在微通道内部的空气被流入的流体排出的排气口，其中当施加电压时，疏水图案通过电润湿现象变得亲水。