公开(公告)号：KR100467325B1

公开(公告)日：2005-01-24

申请号：KR1020020075395

申请日：2002-11-29

Applicant: 한국전자통신연구원

Inventor： 오향란 ,  박용준 ,  류광선 ,  장순호 ,  홍영식

IPC: H01M4/04

CPC classification number: H01M4/505 ,  C01G45/1228 ,  C01P2002/54 ,  C01P2002/72 ,  C01P2004/03 ,  C01P2006/40 ,  H01M10/0525

Abstract: Li[Cr
x Li
(1/3-x/3) Mn
(2/3-2x/3) ]O
2 (0.1 ≤ X ≤0.5) 조성을 가지는 리튬 이차전지용 층상 구조의 리튬-크롬-망간계 산화물의 제조 방법에 관하여 개시한다. 본 발명에 따른 리튬-크롬-망간계 산화물의 제조 방법에서는 크롬 아세테이트 하이드록사이드 (Cr
3 (OH)
2 (CH
3 CO
2 )
7 ) 및 망간 아세테이트 테트라하이드레이트 ((CH
3 CO
2 )
2 Mnㆍ4H
2 O)가 혼합된 수용액에 리튬 하이드록사이드(LiOH) 수용액을 첨가하여 균일한 미세 침전을 형성한다. 상기 미세 침전을 연소시켜 Li[Cr
x Li
(1/3-x/3) Mn
(2/3-2x/3) ]O
2 (0.1 ≤ X ≤0.5) 조성의 모체(precursor) 산화물 분말을 형성한다. 상기 모체 산화물 분말을 고온으로 가열하여 층상 구조를 가지는 산화물 분말을 형성한다.

Abstract translation: 一种制备具有式Li [Cr x Li（1/3-x / 3）Mn 3/3的层状锂 - 锰 - 锰氧化物的方法 -2×3）2 O 2其中对于锂电池，0.1 <= X <= 0.5。 通过将氢氧化锂（LiOH）溶液加入到乙酸铬（Cr 3/3（OH）2）（CH 3）3的混合溶液中制备均匀沉淀， CO 2 2）7）和乙酸锰（（CH 3 CO 2）2 Mn 4 H 2 O），而通过烧制沉淀制备前体粉末。 之后，对前驱体粉末进行两次热处理，得到Li（Cr 1/3）（1/3-x / 3）Mn（2/3） -2x / 3）O 2与α-LiFeO 2结构结合。

公开(公告)号：KR100449073B1

公开(公告)日：2004-09-18

申请号：KR1020020062751

申请日：2002-10-15

Applicant: 한국전자통신연구원

Inventor： 홍영식 ,  류광선 ,  장순호 ,  박용준 ,  이영기 ,  김광만 ,  박남규 ,  강만구 ,  오향란

IPC: H01M4/58

CPC classification number: H01M4/525 ,  C01B25/45 ,  H01M4/131 ,  H01M4/136 ,  H01M4/485 ,  H01M4/5825 ,  H01M10/052

Abstract: 본 발명은 셀룰러 폰에 사용되는 리튬 이차 전지용 양극 활물질에 관한 것으로, LiCoO
2 와 이의 대체 양극 활물질로 연구되고 있는 LiMn
2 O
4 , Li(Ni,Co)O
2 및 V 계열 산화물과는 다른 고용량 및 장수명의 특징을 갖는 리튬 이차 전지용 양극 활물질 및 그 제조 방법을 제공한다. PO
4
3- , SO
4
2- 그리고 OH
- 음이온기를 포함하는 광물인 디아도카이트[Diadochite, Fe
2 (PO
4 )(SO
4 )(OH)·6H
2 O]를 열 혹은 화학적 처리하여 하기 화학식 1의 리튬 이차 전지용 양극 활물질을 제조한다.

Li
a Fe
b M
c (PO
4 )
x (SO
4 )
y (OH)
z


상기 식에서 M은 Mg, Ti, Cr, Mn, Co, Ni, Cu, Zn, Al, Si으로 이루어진 군에서 선택되는 하나 이상의 원소이고, 0 ≤ a, c ≤ 0.5, 1.5 ≤ b ≤ 2, 0.5 ≤ x, y, z ≤ 1.5 이다.

Abstract translation: 公开了一种用于蜂窝电话的锂二次电池用正极活性物质。 用于锂二次电池的正极活性材料及其与LiCoO 2和LiMn 2 O 4不同的具有高容量和长寿命的方法， 提供了作为用于代替LiCoO 2 N 2的活性物质研究的Li（Ni，Co）O 2 2的V体系氧化物。 下一式1中的锂二次电池用正极活性物质是通过加热或化学处理二氧化钛[Fe 2 O 3（PO 4））（SO 4） /SUB>)(OH).6H₂O]，它是含有PO 3，SO 3，SO 4， ＆lt; 2＆gt;和＆lt; / SUP＆gt;。 <？in-line-formula description =“In-line Formulas”end =“lead”？？？？？？？？？？？（＆lt;＆lt; （SO 4）x（SO 4）x（OH）z（1） ）<？in-line-formula description =“In-line Formulas”end =“tail”？>在公式中，M是从由Mg，Ti，Cr，Mn，Co，Ni组成的基团中选择的至少一种元素 ，Cu，Zn，Al和Si，0≤a，c≤0.5,1≤b≤2,0.5≤x，y，z≤1.5。

公开(公告)号：KR1020040033599A

公开(公告)日：2004-04-28

申请号：KR1020020062751

申请日：2002-10-15

Applicant: 한국전자통신연구원

Inventor： 홍영식 ,  류광선 ,  장순호 ,  박용준 ,  이영기 ,  김광만 ,  박남규 ,  강만구 ,  오향란

IPC: H01M4/58

CPC classification number: H01M4/525 ,  C01B25/45 ,  H01M4/131 ,  H01M4/136 ,  H01M4/485 ,  H01M4/5825 ,  H01M10/052

Abstract: PURPOSE: A positive electrode active material for a lithium secondary battery and its preparation method are provided, to obtain an active material having high capacity and long lifetime. CONSTITUTION: The positive electrode active material contains diadochite represented by Fe2(PO4)(SO4)(OH) or Fe2(PO4)(SO4)(OH)·6H2O. The positive electrode active material is represented by LiaFebMc(PO4)x(SO4)y(OH)z, wherein M is at least one element selected from the group consisting of Mg, Ti, Cr, Mn, Co, Ni, Cu, Zn, Al and Si; 0

Abstract translation: 目的：提供一种锂二次电池用正极活性物质及其制备方法，以获得具有高容量且寿命长的活性物质。 构成：正极活性物质含有由Fe2（PO4）（SO4）（OH）或Fe2（PO4）（SO4）（OH）·6H2O表示的二氧化钛。 正极活性物质由LiaFebMc（PO4）x（SO4）y（OH）z表示，其中M为选自Mg，Ti，Cr，Mn，Co，Ni，Cu，Zn中的至少一种元素 ，Al和Si; 0 <= a，c <= 0.5; 1 <= B <= 2; 和0.5 <= x，y，z <= 1.5。 所述方法包括混合二淀粉，锂盐和金属盐的步骤; 干燥混合物; 并加热干燥的混合物。 另外该方法包括混合二淀粉，锂盐和金属氧化物的步骤; 干燥混合物; 并通过固态反应使干燥的混合物反应。

公开(公告)号：KR100392372B1

公开(公告)日：2003-07-22

申请号：KR1020000059752

申请日：2000-10-11

Applicant: 한국전자통신연구원

Inventor： 박용준 ,  류광선 ,  김광만 ,  박남규 ,  장순호

IPC: H01M10/44

Abstract: PURPOSE: Provided are a power supply device capable of charging a thin film secondary battery remotely, which can minimize the area of an energy supply system and maximize the integration of the system, and a micro-apparatus containing the power supply device. CONSTITUTION: The micro-apparatus comprises: the remote power supply device(200) containing a micro strip antenna(21) to receive electromagnetic waves, a diode to rectify the voltage generated from the received electromagnetic waves, and a filter(23) to remove high frequency from the voltage; a thin film secondary battery(100), which is charged by receiving the voltage from the remote power supply device(200); an IC chip to treat signals by receiving power from the thin film secondary battery(100).

Abstract translation: 本发明提供一种能够对薄膜二次电池进行远程充电的电源装置，该电源装置能够使能量供给系统的面积最小化并使系统的集成度最大化，并且提供一种包含该电源装置的微型装置。 本发明的微型设备包括：包含用于接收电磁波的微带天线（21）的远程供电装置（200），对从接收到的电磁波产生的电压进行整流的二极管，以及滤除（23） 来自电压的高频率; 薄膜二次电池（100），其通过接收来自远程供电装置（200）的电压而被充电; 通过从薄膜二次电池（100）接收电力来处理信号的IC芯片。

公开(公告)号：KR100384893B1

公开(公告)日：2003-05-23

申请号：KR1020010018600

申请日：2001-04-09

Applicant: 한국전자통신연구원

Inventor： 강만구 ,  박남규 ,  장순호

IPC: H01M14/00 ,  B82Y30/00

CPC classification number: Y02E10/542 ,  Y02P70/521

Abstract: PURPOSE: A nanoparticle oxide solar cell, its preparation method, a solar cell module using the solar cell and a transparent electric window are provided, to minimize the space between solar cells of the module for minimizing the loss of power and maximizing the contact between cells. CONSTITUTION: The nanoparticle oxide solar cell comprises a primary conductive plate(21) where a negative electrode(22) region is formed in one side; a secondary conductive plate(21') where a positive electrode(23) region is formed in the other side; a binding/sealing means which binds the primary and secondary conductive plates so that a primary and secondary conductive plates face each other and the two regions where the positive or negative electrode is not formed are not overlapped, and seals the regions where the positive electrode and the negative electrode face each other; a primary conductive adhesive(28a) which is formed in the unoverlapped region of the primary conductive plate; and a secondary conductive adhesive(28b) which is formed in the unoverlapped region of the secondary conductive plate. Preferably the sealed region formed by the binding/sealing means contains an electrolyte.

Abstract translation: 目的：提供一种纳米颗粒氧化物太阳能电池，其制备方法，使用该太阳能电池的太阳能电池模块和透明电窗，以最小化该模块的太阳能电池之间的空间，用于最小化功率损耗并最大化电池之间的接触 。 构成：纳米颗粒氧化物太阳能电池包括主导电板（21），其中负电极（22）区域形成在一侧; 在另一侧形成有正极（23）区域的二次导电板（21'）， 以一次导电板和二次导电板彼此面对的方式结合一次导电板和二次导电板的结合/密封装置不重叠，并且将正极或未形成正极或负极的两个区域不重叠， 负电极彼此面对; 主导电粘合剂（28a），其形成在主导电板的非重叠区域中; 以及形成在次导电板的未重叠区域中的次导电粘合剂（28b）。 优选地，由结合/密封装置形成的密封区域包含电解质。

公开(公告)号：KR100380993B1

公开(公告)日：2003-04-26

申请号：KR1020000056989

申请日：2000-09-28

Applicant: 한국전자통신연구원

Inventor： 류광선 ,  김광만 ,  박남규 ,  박용준 ,  장순호

IPC: H01G4/018

CPC classification number: Y02E60/13

Abstract: 본 발명은 리튬이 도핑된 폴리아닐린 분말 형성 방법과 그를 이용한 전극활물질 및 슈퍼 캐페시터 제조 방법에 관한 것으로서, 비전도성 폴리아닐린 분말과 리튬염 용액을 혼합하여 비전도성 폴리아닐린 분말을 리튬염으로 도핑시키고, 리튬염 용액으로부터 리튬염으로 도핑된 폴리아닐린 분말을 분리시킴으로써 리튬염으로 도핑된 폴리아닐린 분말을 형성하고, 그를 이용하여 전극활물질 및 슈퍼 캐페시터를 제조하는데 특징이 있다.

Abstract translation: 目的：提供一种用于形成掺杂锂盐的聚苯胺粉末的方法，以及使用该方法制备电极活性材料和超级电容器的方法，以形成掺有锂盐并制备电极活性材料的聚苯胺导电聚合物粉末和使用 聚苯胺导电聚合物粉末。 规定：首先，制备非导电聚苯胺粉末。 然后，制备锂盐溶液。 接着，将非导电性聚苯胺粉末和锂盐溶液混合，由此将锂盐掺杂到非导电性聚苯胺粉末中。 然后，将具有锂盐的聚苯胺粉末与锂盐溶液分离。

公开(公告)号：KR100353867B1

公开(公告)日：2002-09-26

申请号：KR1019990053774

申请日：1999-11-30

Applicant: 한국전자통신연구원

Inventor： 김광만 ,  류광선 ,  강성구 ,  장순호

IPC: H01M10/0565

CPC classification number: H01M10/056 ,  H01M10/052

Abstract: 본발명은고분자뿐만아니라무기충진제로서실리카를포함하여고분자전해질의매트릭스인고분자막을형성하고, 이고분자매트릭스에리튬염의유기용매전해액을함침시킴으로써리튬 2차전지용고분자전해질을제조하는것이다. 본발명의고분자전해질은간단한방법으로제조될수 있으며, 기계적강도는물론, 이온전도도가우수하며, 리튬 2차전지에사용될때 계면저항이조속히안정된다.

Abstract translation: 目的：提供一种用于锂离子二次电池的聚合物电解质，其通过简单的制造工艺提高生产率，具有优异的机械强度和离子传导性，并且当应用于锂离子二次电池时可快速稳定界面电阻。 构成：用于锂离子二次电池的聚合物电解质包括：（i）由聚合物和二氧化硅形成的基体; 和（ii）浸渍基质的锂盐的有机溶剂电解液，其中所述聚合物是偏氟乙烯和六氟丙烯或偏二氟乙烯聚合物的共聚物。

公开(公告)号：KR1020020051292A

公开(公告)日：2002-06-28

申请号：KR1020000080898

申请日：2000-12-22

Applicant: 한국전자통신연구원

Inventor： 류광선 ,  박용준 ,  박남규 ,  김광만 ,  장순호

IPC: H02J7/35

Abstract: PURPOSE: A power supply element for self-charging high-rate charging/discharging is provided to make a power supply element act as an efficient energy source by operating a lithium secondary cell charged through a solar cell and a superhigh capacitor selectively. CONSTITUTION: A superhigh capacitor(2) which is charged through a solar cell(3) performs a high rate of discharge. A lithium secondary cell(1) which is able to be recharged and charged through the solar cell(3) performs a low rate of discharge. A logic switch(4) is connected with the solar cell(3) in case of charging and is separated from the solar cell(3) in case of discharging.

Abstract translation: 目的：提供用于自充电高速充电/放电的电源元件，通过选择性地操作通过太阳能电池和超高电容器充电的锂二次电池，使电源元件充当有效的能量源。 构成：通过太阳能电池（3）充电的超高电容器（2）执行高放电率。 能够通过太阳能电池（3）再充电和充电的锂二次电池（1）执行低放电率。 在充电的情况下，逻辑开关（4）与太阳能电池（3）连接，并且在放电的情况下与太阳能电池（3）分离。

公开(公告)号：KR1020020046450A

公开(公告)日：2002-06-21

申请号：KR1020000076646

申请日：2000-12-14

Applicant: 한국전자통신연구원

Inventor： 박남규 ,  김광만 ,  류광선 ,  박용준 ,  장순호

IPC: H01M10/36

CPC classification number: H01M4/485 ,  H01M4/13 ,  H01M4/131 ,  H01M4/137 ,  H01M4/362 ,  H01M4/364 ,  H01M4/382 ,  H01M4/60 ,  H01M4/602 ,  H01M10/052 ,  H01M2004/028

Abstract: PURPOSE: An organic-inorganic composite oxide for the cathode of a lithium secondary battery and its preparation method are provided, which is improved in the charging-discharging effect by intercalating different polymers into V2O5 xerogel. CONSTITUTION: The organic-inorganic composite oxide comprises V2O5 xerogel where poly(2,5-dimercapto-1,3,4-thiadiazole) and polyaniline are intercalated. Preferably the ratio of V2O5 xerogel : poly(2,5-dimercapto-1,3,4-thiadiazole) : polyaniline is 1 : 0.2-1 : 0.2-2 by mol. The method comprises the steps of preparing powdered V2O5 xerogel; dissolving the powdered V2O5 xerogel into distilled water to obtain a V2O5 aqueous solution; dissolving 2,5-dimercapto-1,3,4-thiadiazole monomer into an organic solvent to obtain a 2,5-dimercapto-1,3,4-thiadiazole solution; adding the V2O5 aqueous solution to the 2,5-dimercapto-1,3,4-thiadiazole solution slowly; adding aniline to the obtained one; stirring the obtained one at a room temperature for 24 hours, filtering it under reduced pressure and washing it; and drying the product at a room temperature or 80 deg.C.

Abstract translation: 目的：提供一种用于锂二次电池阴极的有机 - 无机复合氧化物及其制备方法，其通过将不同聚合物嵌入V2O5干凝胶中而提高了充放电效果。 构成：有机 - 无机复合氧化物包含V 2 O 5干凝胶，其中插入聚（2,5-二巯基-1,3,4-噻二唑）和聚苯胺。 优选V 2 O 5干凝胶：聚（2,5-二巯基-1,3,4-噻二唑）：聚苯胺的比例为1:0.2-1:0.2-2摩尔。 该方法包括以下步骤：制备粉末状V2O5干凝胶; 将V2O5干凝胶溶解在蒸馏水中得到V2O5水溶液; 将2,5-二巯基-1,3,4-噻二唑单体溶解在有机溶剂中，得到2,5-二巯基-1,3,4-噻二唑溶液; 将V2O5水溶液缓慢加入到2,5-二巯基-1,3,4-噻二唑溶液中; 向所得的苯胺中加入苯胺; 将得到的物质在室温下搅拌24小时，在减压下过滤并洗涤; 并在室温或80℃下干燥产物。

公开(公告)号：KR1020020028643A

公开(公告)日：2002-04-17

申请号：KR1020000059754

申请日：2000-10-11

Applicant: 한국전자통신연구원

Inventor： 류광선 ,  박용준 ,  김광만 ,  박남규 ,  장순호

IPC: G06K19/07

Abstract: PURPOSE: A smart card embedding a super capacitor is provided to enable a rapid charge or an instant discharge at a remote place as well as by a wired connection by using the super capacitor for supplying electric power to a signal process circuit so that it can make only the card itself perform a data process. CONSTITUTION: The smart card comprises a super capacitor(SC), an antenna coil(A), a low pass filter(F), external connectors(11,12), a diode and an IC element(IC). Electromagnetic waves are received by the antenna coil(A), rectified in the diode, transferred to the low pass filter(F), filtered in the low pass filter(F), and converted to DC voltage signals. The DC voltage signals charge the super capacitor(SC). The super capacitor(SC) can be charged also via the external connectors(11,12). The super capacitor(SC) supplies necessary power to the IC elements for processing data or generating signals to external devices. The super capacitor has a specific capacity larger than a conventional capacitor by 100 to 1000, and a power density larger than the latest secondary battery by 10 more so that it can rapidly store the electric power.

Abstract translation: 目的：提供一种嵌入超级电容器的智能卡，用于通过使用超级电容器为信号处理电路提供电力，使远程位置的快速充电或即时放电以及有线连接，从而使其能够 只有卡本身执行数据处理。 构成：智能卡包括超级电容器（SC），天线线圈（A），低通滤波器（F），外部连接器（11,12），二极管和IC元件（IC）。 电磁波由天线线圈（A）接收，在二极管中整流，传输到低通滤波器（F），在低通滤波器（F）中滤波，并转换为直流电压信号。 直流电压信号为超级电容器（SC）充电。 超级电容器（SC）也可以通过外部连接器（11,12）进行充电。 超级电容器（SC）向用于处理数据或向外部设备产生信号的IC元件提供必要的电力。 超级电容器具有比常规电容器大100至1000的比容量，并且比最新的二次电池的功率密度大10倍，使得其能够快速地存储电力。