公开(公告)号：KR101684193B1

公开(公告)日：2016-12-08

申请号：KR1020150176387

申请日：2015-12-10

Applicant: 현대자동차주식회사

Inventor： 장훈 ,  조정민

IPC: B62D21/02 ,  B62D21/08 ,  B62D21/00

CPC classification number: B62D27/02 ,  B60R13/02 ,  B60R2013/0287 ,  B62D29/048 ,  F16B5/065

Abstract: 부착면이형성된차량의제1멤버; 일정두께와면적을갖는패널형상이며, 하면이부착면에접착되어제1멤버에고정되고상면은개방되며, 복수의교차하는격벽을통해허니콤구조로형성되어상면이개방된복수의결합공간을구성하는복합재재질의체결브라켓; 및차량의제2멤버에마련되며, 제2멤버에서체결브라켓측으로돌출되고, 돌출된부분은결합공간에삽입되어고정됨으로써제1멤버와제2멤버가체결되도록하는체결공구;를포함하는차량의어셈블리가소개된다.

公开(公告)号：KR101620226B1

公开(公告)日：2016-05-24

申请号：KR1020140169942

申请日：2014-12-01

Applicant: 현대자동차주식회사

Inventor： 강경범 ,  민헌식 ,  조정민

IPC: B62D25/04 ,  B62D29/00 ,  B60R19/02

CPC classification number: B62D21/157 ,  B62D25/04 ,  B62D29/046 ,  B60R19/023 ,  B62D29/00

Abstract: 차체의결합되고, 루프면, 좌측면, 우측면및 플로어면으로구성되되, 환형으로연결되는 B필러;를포함하는차량용 B필러유닛이소개된다.

Abstract translation: 引入了一种用于车辆的B柱单元，其包括耦合到底盘的B柱，由屋顶表面，左表面，右表面和地板表面组成，并且连接成环形 。 因此，本发明即使在侧面碰撞的情况下也能够防止由焊接部引起的破损。

公开(公告)号：KR1020160024506A

公开(公告)日：2016-03-07

申请号：KR1020140111324

申请日：2014-08-26

Applicant: 현대자동차주식회사 ,  롯데케미칼 주식회사

Inventor： 최치훈 ,  조정민 ,  최영호 ,  박상윤 ,  양준호 ,  마성원 ,  조성민 ,  장은화 ,  최창휴

IPC: C08L77/00 ,  C08K7/06 ,  C08L23/26 ,  C08J5/04

CPC classification number: C08L77/00 ,  C08J5/04 ,  C08K3/04 ,  C08K7/06 ,  C08L23/26

Abstract: 본발명은폴리아마이드수지와탄소섬유이외에도상용화제로서피롤리딘-2,5-디온이그라프트된변성폴리프로필렌옥사이드를필수성분으로포함하고있음으로써인장강도, 굴곡강도, 굴곡탄성율, 충격강도등이우수하게개선된탄소섬유강화폴리아마이드수지조성물에관한것이다.

Abstract translation: 本发明涉及一种碳纤维增强聚酰胺树脂组合物，其除了聚酰胺树脂和碳纤维外，还包含与吡咯烷-2,5-二酮接枝的改性聚环氧丙烷作为增容剂和必要成分，从而具有良好的拉伸张力 强度，弯曲强度，弯曲模量，冲击强度等。

公开(公告)号：KR101417217B1

公开(公告)日：2014-07-09

申请号：KR1020110122476

申请日：2011-11-22

Applicant: 현대자동차주식회사

Inventor： 최영호 ,  조정민 ,  한도석 ,  최치훈

IPC: D01F6/40 ,  D01D5/00 ,  D02J1/22 ,  D01F9/22

CPC classification number: D01D5/12 ,  D01D5/16 ,  D01F6/18 ,  D01F6/38 ,  D01F9/22 ,  Y10T428/2913

Abstract: 본 발명은 탄소섬유용 전구체 섬유의 제조방법에 관한 것으로서, 더욱 상세하게는 인장강도와 압축강도가 우수한 탄소섬유를 생산하는 데 사용되는 전구체 섬유를 제조하기 위해 초연신(Superdrawing) 공정을 이용하여 종래의 단성분 방사구금(Single Component Spinneret)으로 미세 섬도(denier)의 전구체 섬유를 제조하여 안정화 시간의 단축과 더불어 고강력, 고탄성 탄소섬유를 얻을 수 있도록 하는 탄소섬유용 전구체 섬유의 제조방법에 관한 것이다.

公开(公告)号：KR1020130120611A

公开(公告)日：2013-11-05

申请号：KR1020120043634

申请日：2012-04-26

Applicant: 현대자동차주식회사

Inventor： 신나리 ,  조정민

IPC: G01N25/18 ,  B82B1/00

CPC classification number: G01N25/18 ,  B82B1/00 ,  Y10S977/70

Abstract: The purpose of the present invention is to provide a method for measuring the thermal conductivity coefficient of boron nitride nanotube (BNNT), which is to measure a thermal conductivity coefficient, which is an important property among mechanical properties, using a simulation technique which is based on molecular dynamics without any direct experiment. To achieve the purpose above, the method for measuring the thermal conductivity coefficient of BNNT prepared by the present invention comprises the following steps of: setting a BNNT model into a simulation cell after setting the BNNT model based on a basic atomic structure; determining an atomic structure by minimizing the inner energy of the model due to interaction force between boron and nitrogen atoms; determining an atomic structure by stabilizing the volume of the model in temperature and pressure conditions for property calculation and by minimizing the total energy, and using a specimen cell obtained in this process for simulation; and calculating a thermal conductivity coefficient by making a difference between two sides of the specimen cell and by calculating the flow of energy on the both sides. [Reference numerals] (AA) Start;(BB) Set BNNT model;(CC) Optimize structure;(DD) Prepare simulation time slice;(EE) Calculate coefficient thermal conductivity;(FF) End

Abstract translation: 本发明的目的是提供一种用于测量导热系数的氮化硼纳米管（BNNT）的热导率系数的方法，其用于测量机械性能中的重要性质，使用基于 关于分子动力学，没有任何直接的实验。 为了达到上述目的，本发明制备的BNNT的导热系数测定方法包括以下步骤：在基于基本原子结构设定BNNT模型之后，将BNNT模型设定为模拟单元; 通过使由于硼和氮原子之间的相互作用力而使模型的内部能量最小化来确定原子结构; 通过在温度和压力条件下稳定模型的体积来进行性质计算并通过使总能量最小化并使用在该过程中获得的样本池进行模拟来确定原子结构; 并且通过使样本池的两侧之间的差异和通过计算两侧的能量流量来计算导热系数。 （AA）开始;（BB）设置BNNT模型;（CC）优化结构;（DD）准备模拟时间片;（EE）计算系数热导率;（FF）结束

公开(公告)号：KR1020130120610A

公开(公告)日：2013-11-05

申请号：KR1020120043633

申请日：2012-04-26

Applicant: 현대자동차주식회사

Inventor： 신나리 ,  조정민

IPC: G01N3/00 ,  B82B3/00

CPC classification number: G01N3/24 ,  B82Y30/00 ,  B82Y40/00 ,  C01B21/0641 ,  G01N2203/0025 ,  G01N2203/0075

Abstract: The purpose of the present invention is to provide a method for measuring the shear modulus of boron nitride nanotube (BNNT), which is to measure a shear modulus, which is an important property among mechanical properties, using a simulation technique which is based on molecular dynamics without any direct experiment. To achieve the purpose above, the method for measuring the shear modulus of BNNT prepared by the present invention comprises the following steps of: setting a BNNT model into a simulation cell after setting the BNNT model based on a basic atomic structure; determining an atomic structure by minimizing the inner energy of the model due to interaction force between boron and nitrogen atoms; determining an atomic structure by stabilizing the volume of the model and minimizing the total energy in temperature and pressure conditions for property calculation, and using a specimen cell obtained in this process for simulation; and calculating energy by applying twisting moment to the specimen cell, and calculating the shear modulus of the specimen cell from the relationship between the energy and the angle of twisting. [Reference numerals] (AA) Start;(BB) Set a BNNT model;(CC) Optimize a structure;(DD) Prepare simulation test slice;(EE) Calculate a shear coefficient;(FF) End

Abstract translation: 本发明的目的是提供一种测量氮化硼纳米管（BNNT）的剪切模量的方法，该方法是使用基于分子的模拟技术来测量机械性能之间的重要性质的剪切模量 动力学没有任何直接的实验。 为了达到上述目的，通过本发明制备的BNNT的剪切模量的测定方法包括以下步骤：在基于基本原子结构设定BNNT模型之后，将BNNT模型设定为模拟单元; 通过使由于硼和氮原子之间的相互作用力而使模型的内部能量最小化来确定原子结构; 通过稳定模型的体积并最小化用于性质计算的温度和压力条件下的总能量并使用在该过程中获得的样本池进行模拟来确定原子结构; 并通过对试样细胞施加扭转力矩来计算能量，并根据能量与扭转角度之间的关系来计算试样细胞的剪切模量。 （AA）开始;（BB）设置BNNT模型;（CC）优化结构;（DD）准备模拟测试切片;（EE）计算剪切系数;（FF）结束

公开(公告)号：KR1020130120608A

公开(公告)日：2013-11-05

申请号：KR1020120043629

申请日：2012-04-26

Applicant: 현대자동차주식회사

Inventor： 신나리 ,  조정민

IPC: G01N25/16 ,  B82B1/00

CPC classification number: G01N25/16 ,  B82B1/00 ,  Y10S977/70

Abstract: The purpose of the present invention is to provide a method for measuring the thermal expansion coefficient of boron nitride nanotube (BNNT), which is to measure a thermal expansion coefficient, which is an important property among mechanical properties, using a simulation technique which is based on molecular dynamics without any direct experiment. To achieve the purpose above, the method for measuring the thermal expansion coefficient of BNNT prepared by the present invention comprises the following steps of: setting a BNNT model into a simulation cell after setting the BNNT model based on a basic atomic structure; determining an atomic structure by minimizing the inner energy of the model due to interaction force between boron and nitrogen atoms; determining an atomic structure by stabilizing the volume of the model and minimizing the total energy in temperature and pressure conditions for property calculation, and using a specimen cell obtained in this process for simulation; and calculating stress by increasing the temperature of the specimen cell at a temperature range between 0 and 300 K, measuring changes in the length of the specimen cell, and calculating the thermal expansion coefficient of the specimen cell. [Reference numerals] (AA) Start;(BB) Set a BNNT model;(CC) Optimize a structure;(DD) Prepare simulation test slice;(EE) Calculate coefficient of expansion;(FF) End

Abstract translation: 本发明的目的是提供一种用于测量热膨胀系数的氮化硼纳米管（BNNT）的热膨胀系数的方法，该热膨胀系数是机械性能中的重要性质，使用基于 关于分子动力学，没有任何直接的实验。 为了达到上述目的，本发明制备的BNNT的热膨胀系数的测定方法包括以下步骤：在基于碱性原子结构设定BNNT模型之后，将BNNT模型设定为模拟单元; 通过使由于硼和氮原子之间的相互作用力而使模型的内部能量最小化来确定原子结构; 通过稳定模型的体积并最小化用于性质计算的温度和压力条件下的总能量并使用在该过程中获得的样本池进行模拟来确定原子结构; 并通过在0〜300K的温度范围内增加试样池的温度来计算应力，测定试样池长度的变化，计算试样池的热膨胀系数。 （AA）开始;（BB）设置BNNT模型;（CC）优化结构;（DD）准备模拟测试切片;（EE）计算膨胀系数;（FF）结束

公开(公告)号：KR1020130120607A

公开(公告)日：2013-11-05

申请号：KR1020120043628

申请日：2012-04-26

Applicant: 현대자동차주식회사

Inventor： 신나리 ,  조정민

IPC: G01N3/00 ,  B82B3/00

CPC classification number: G01N3/24 ,  B82Y30/00 ,  B82Y40/00 ,  C01B21/0641 ,  G01N2203/0025 ,  G01N2203/0075

Abstract: The purpose of the present invention is to provide a method for measuring the elastic modulus of boron nitride nanotube (BNNT), which is to measure an elastic modulus, which is an important property among mechanical properties, using a simulation technique which is based on molecular dynamics without any direct experiment. To achieve the purpose above, the method for measuring the elastic modulus of BNNT prepared by the present invention comprises the following steps of: setting a BNNT model into a simulation cell after setting the BNNT model based on a basic atomic structure; determining an atomic structure by minimizing the inner energy of the model due to interaction force between boron and nitrogen atoms; determining an atomic structure by stabilizing the volume of the model and minimizing the total energy in temperature and pressure conditions for property calculation, and using a specimen cell obtained in this process for simulation; and calculating stress by applying displacement to the specimen cell in a desired direction and measuring the elastic modulus of the specimen cell. [Reference numerals] (AA) Start;(BB) Set a BNNT model;(CC) Optimize a structure;(DD) Prepare simulation test slice;(EE) Calculate elastic modulus;(FF) End

Abstract translation: 本发明的目的是提供一种用于测量弹性模量的氮化硼纳米管（BNNT）的弹性模量的方法，该弹性模量是机械性能之间的重要性质，使用基于分子的模拟技术 动力学没有任何直接的实验。 为了达到上述目的，本发明制备的BNNT的弹性模量测定方法包括以下步骤：在基于基本原子结构设定BNNT模型之后，将BNNT模型设定为模拟单元; 通过使由于硼和氮原子之间的相互作用力而使模型的内部能量最小化来确定原子结构; 通过稳定模型的体积并最小化用于性质计算的温度和压力条件下的总能量并使用在该过程中获得的样本池进行模拟来确定原子结构; 并且通过在所需方向上向样品池施加位移并测量样品池的弹性模量来计算应力。 （AA）开始;（BB）设置BNNT模型;（CC）优化结构;（DD）准备模拟测试切片;（EE）计算弹性模量;（FF）结束

公开(公告)号：KR1020090118537A

公开(公告)日：2009-11-18

申请号：KR1020080044385

申请日：2008-05-14

Applicant: 현대자동차주식회사

Inventor： 조정민

IPC: B60R16/04 ,  B60R16/00

Abstract: PURPOSE: A battery cable connector and a battery terminal connecting assembly are provided to facilitate the assembly and the disassembly of the cable by preventing a tool for coupling a battery terminal and a cable from being interfered. CONSTITUTION: A battery cable connector comprises first and second terminals(210,220). The first terminal is connected to a cable(1). The first terminal surrounds the side of the battery terminal to be apart from the outside of a battery terminal(120). The second terminal is inserted between the battery terminal and the first terminal. The second terminal is coupled with the battery terminal and the first terminal.

Abstract translation: 目的：提供电池电缆连接器和电池端子连接组件，以通过防止用于联接电池端子和电缆的工具受到干扰而有助于电缆的组装和拆卸。 构成：电池电缆连接器包括第一和第二端子（210,220）。 第一端子连接到电缆（1）。 第一端子围绕电池端子的一侧与电池端子（120）的外部分开。 第二端子插入电池端子和第一端子之间。 第二端子与电池端子和第一端子连接。

公开(公告)号：KR101755917B1

公开(公告)日：2017-07-10

申请号：KR1020150173347

申请日：2015-12-07

Applicant: 현대자동차주식회사

Inventor： 양준호 ,  최치훈 ,  박상윤 ,  조정민 ,  최영호

IPC: B29B17/02

CPC classification number: B29B17/02 ,  B29B2017/0293 ,  B29K2105/06 ,  B29K2105/26 ,  B29K2307/04 ,  Y02W30/622

Abstract: 강화섬유가와인딩되고수지에함침된강화부품으로부터수지를분리하며강화섬유를풀어내는언와인딩(unwinding)단계; 언와인딩된강화섬유를사이징액에통과시켜강화섬유에사이징액을코팅하는사이징단계; 및사이징액이코팅된강화섬유를맨드렐에와인딩하는와인딩(winding)단계;를포함하는강화섬유회수방법이소개된다.

Abstract translation: 退绕步骤，卷绕增强纤维并从浸渍在树脂中的增强部分分离树脂并释放增强纤维; 使未发泡的增强纤维通过上浆溶液以将上浆溶液涂布到增强纤维上的上浆步骤; 以及将涂布有上浆液的增强纤维卷绕在心轴上的卷绕工序。