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    • 71. 发明公开
    • 헤마토크리트 측정 방법 및 장치
    • 测量HEMATOCRIT的方法和装置
    • KR1020130046143A
    • 2013-05-07
    • KR1020110110527
    • 2011-10-27
    • 광주과학기술원
    • 양성김명곤
    • G01N33/49G01N15/05G01N15/12G01N27/04
    • A61B5/14535G01N27/06G01N33/49
    • PURPOSE: A method and an apparatus for measuring hematocrit are provided to accurately and simply measure hematocrit of blood using electric modeling. CONSTITUTION: A method for measuring hematocrit comprises: a step of measuring resistance data of a blood to be measured(S100); a step of calculating a hematocrit prediction parameter for measuring blood hematocrit using the resistance data of the blood(S200); and a step of determining a prediction value of hematocrit using the hematocrit prediction parameter(S300). The resistance data of the blood includes a plasma resistance value and a cytoplasm resistance value. [Reference numerals] (AA) Start; (BB) End; (S100) Step of measuring resistance data of target blood to be measured; (S200) Step of calculating a hematocrit prediction parameter for measuring hematocrit; (S300) Step of determining a prediction value of the hematocrit using the hematocrit prediction parameter
    • 目的:提供一种用于测量血细胞比容的方法和装置,以便使用电模拟来精确和简单地测量血液的血细胞比容。 构成:用于测量血细胞比容的方法包括:测量待测血液的阻力数据的步骤(S100); 使用血液的电阻数据计算用于测量血液血细胞比容的血细胞比容预测参数的步骤(S200); 以及使用血球比例预测参数确定血细胞比容的预测值的步骤(S300)。 血液的电阻数据包括血浆电阻值和细胞质抗性值。 (附图标记)(AA)开始; (BB)结束; (S100)测定被测定血液的电阻数据的步骤; (S200)计算用于测量血细胞比容的血细胞比容预测参数的步骤; (S300)使用血球比例预测参数来确定血细胞比容的预测值的步骤
    • 73. 发明公开
    • 유체 점도 측정 장치 및 점도 측정 방법
    • 流体粘度测量装置和流体粘度测量方法
    • KR1020120101251A
    • 2012-09-13
    • KR1020110019081
    • 2011-03-03
    • 광주과학기술원
    • 양성강양준
    • G01N11/04
    • PURPOSE: A device for measuring the velocity of a fluid and a method for measuring the velocity are provided to simply measure velocity by using a method counting the number of channels in which a specimen takes in each single step channel array. CONSTITUTION: A device for measuring the velocity of a fluid comprises a fluid injection unit(10) and a channel array(33). The fluid injection unit comprises a first inlet and a second inlet. A first fluid is injected through the first inlet. A second fluid is injected through the second inlet. The velocity of the second fluid is known and the second fluid is not mixed up with the first fluid. The channel array is connected to the fluid inlets and a plurality of channels having the same unit cross sectional area is arranged by being spaced toward a direction across flowing directions of the first and second fluids.
    • 目的:提供一种用于测量流体速度的装置和用于测量速度的方法,以简单地测量速度,方法是对每个单个步进通道阵列中的样本进行采样的通道数进行计数。 构成:用于测量流体速度的装置包括流体注入单元(10)和通道阵列(33)。 流体注射单元包括第一入口和第二入口。 第一流体通过第一入口注入。 第二流体通过第二入口注入。 第二流体的速度是已知的,并且第二流体不与第一流体混合。 通道阵列连接到流体入口,并且具有相同单元横截面面积的多个通道通过沿着横跨第一和第二流体的流动方向的方向间隔开来布置。
    • 74. 发明公开
    • 마이크로 니들 제조 방법 및 그에 의한 마이크로 니들
    • 从而制造微针和微针的方法
    • KR1020120012093A
    • 2012-02-09
    • KR1020100074014
    • 2010-07-30
    • 광주과학기술원
    • 양성
    • A61M37/00B81C1/00
    • A61M37/0015A61M2037/0053
    • PURPOSE: A micro needle and a manufacturing method thereof are provided to form a silicon pillar having a great ratio of length and breadths using an etching mask and reduce processing time and manufacturing cost. CONSTITUTION: A manufacturing method of a micro needle comprises the following steps: manufacturing an etching mask(40) which is formed by penetration of etching patterns; forming a silicon pillar(54) by etching a silicon block(50) using the etching mask; and making a sharp tip(54a) using isotropic etching method with the silicon pillar. The manufacturing of the etching mask comprises the following steps: preparing an upper mold and a lower mold; processing with plasma surfaces of the upper and lower molds; charging polymer resin solution in space between the upper and lower molds; solidifying the polymer resin solution; and transferring solidified polymer resin from the upper and lower molds.
    • 目的:提供微针及其制造方法,以使用蚀刻掩模形成具有大的长度和宽度比的硅柱,并减少加工时间和制造成本。 构成:微针的制造方法包括以下步骤:制造通过蚀刻图案的穿透形成的蚀刻掩模(40); 通过使用所述蚀刻掩模蚀刻硅块(50)来形成硅柱(54); 并使用硅柱的各向同性蚀刻方法制成尖端(54a)。 蚀刻掩模的制造包括以下步骤:制备上模和下模; 用上下模具的等离子体表面加工; 在上模和下模之间的空间中加入聚合物树脂溶液; 固化聚合物树脂溶液; 并从上模和下模转移凝固的聚合物树脂。
    • 75. 发明授权
    • 유체 점도 측정 장치
    • 流体粘度分析仪
    • KR101103635B1
    • 2012-01-11
    • KR1020090095026
    • 2009-10-07
    • 광주과학기술원
    • 양성강양준
    • G01N11/02G01N13/00G01N33/49
    • 기준 점도를 갖는 기준 유체와 점도 측정 대상 유체의 상대적인 점도 차이에 의한 경계면 변화를 이용하여 측정 유체의 점도를 쉽게 측정할 수 있는 유체 점도 측정 장치가 개시된다. 본 발명에 따른 유체 점도 측정 장치는, 점도(viscosity)를 측정하고자 하는 제 1 유체를 주입하기 위한 제 1 주입구와 제 1 유체와 혼합되지 않고 점도를 알고 있는 제 2 유체를 주입하기 위한 제 2 주입구가 형성되는 유체 주입부, 및 유체 주입부와 연결되며 제 1 유체와 제 2 유체의 점도 차이에 의한 유체 경계면을 표시하기 위해 다수 개의 표시 채널이 형성되는 표시 채널부를 포함할 수 있다.
      점도(viscosity), 점도계(viscometer), 혈액(blood), 경계면, 채널
    • 基于所述测量流体的粘度,可以容易地测量使用参考流体和界面的变化的粘度测量的流体的粘度,由于在具有粘性的目标流体的相对粘度差被公开。 根据本发明的用于测量流体粘度的设备包括用于注入用于测量粘度的第一流体的第一入口和用于注入未与第一流体混合且粘度已知的第二流体的第二入口, 并且显示通道单元连接到流体注入单元并且具有用于显示流体界面的多个显示通道,由于第一流体和第二流体之间的粘度差异。
    • 76. 发明公开
    • 유체 점도 측정 장치
    • 用于测量流体粘度的装置
    • KR1020110039823A
    • 2011-04-20
    • KR1020090096835
    • 2009-10-12
    • 광주과학기술원
    • 양성강양준
    • G01N11/08G01N27/06G01N33/49
    • PURPOSE: A device for measuring fluid viscosity is provided to easily measure the viscosity of fluid by detecting a movement change of a fluid boundary face. CONSTITUTION: A device(100) for measuring fluid viscosity comprises a first channel part(120), a second channel part(130), and a third channel part(140). First fluid, which is required for measuring viscosity, flows in the first channel part. Second fluid, which is not mixed with the first fluid, flows in the second channel part. The first and second channel parts are symmetrical to each other. The third channel part connects the first and second channel parts. The cross section of the third channel part is smaller than the cross sections of the first and second channel parts.
    • 目的:提供一种用于测量流体粘度的装置,通过检测流体界面的运动变化来容易地测量流体的粘度。 构成:用于测量流体粘度的装置(100)包括第一通道部分(120),第二通道部分(130)和第三通道部分(140)。 测量粘度所需的第一流体在第一通道部分流动。 不与第一流体混合的第二流体在第二通道部分中流动。 第一和第二通道部分彼此对称。 第三通道部分连接第一和第二通道部分。 第三通道部分的横截面小于第一和第二通道部分的横截面。