会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 2. 发明申请
    • Lithium-ion Battery Protection Method and Device
    • 锂离子电池保护方法及装置
    • US20070285062A1
    • 2007-12-13
    • US11423205
    • 2006-06-09
    • Jing-Yih CherngWei-Chen WuSteven Hou
    • Jing-Yih CherngWei-Chen WuSteven Hou
    • H02J7/00
    • H02J7/0031H02J7/0014H02J2007/0037H02J2007/004
    • A lithium-ion battery protection method and device controls an externally connected circuit to charge/discharge a rechargeable battery so as to prevent the rechargeable battery from over charging/discharging. The lithium-ion-ion battery protection device includes an abnormality detection circuit, a light coupling circuit, a balancing circuit, and a recognition circuit. The abnormality detection circuit is to detect the voltage of the lithium-ion-ion battery and output a detection signal. The battery continues to charge/discharge if the signal is normal, and terminate to charge/discharge if the signal is abnormal. Then, the balancing circuit determines whether the detection signal is an overcharged signal, and if yes, the rechargeable battery is discharged accordingly. Meanwhile, the light coupling circuit adjusts an impedance of the light coupling circuit based on the detection signal so as to break the connection between the rechargeable battery and the externally connected circuit, and the recognition circuit outputs signal identifying location of the battery.
    • 锂离子电池保护方法和装置控制外部连接的电路以对可充电电池进行充电/放电,以防止可再充电电池过充电/放电。 锂离子电池保护装置包括异常检测电路,光耦合电路,平衡电路和识别电路。 异常检测电路是检测锂离子电池的电压并输出检测信号。 如果信号正常,电池继续充电/放电,如果信号异常,则电池终止充电/放电。 然后,平衡电路确定检测信号是否是过充电信号,如果是,则可再充电电池相应地放电。 同时,光耦合电路基于检测信号调整光耦合电路的阻抗,以便断开可再充电电池和外部连接的电路之间的连接,并且识别电路输出电池的识别位置的信号。
    • 3. 发明申请
    • Protection device for a chargeable battery
    • 可充电电池的保护装置
    • US20060232245A1
    • 2006-10-19
    • US11106492
    • 2005-04-15
    • Jing-Yih CherngWei-Chen WuChen-Chin Chang
    • Jing-Yih CherngWei-Chen WuChen-Chin Chang
    • H02J7/00
    • H02J7/0031
    • A protection device for a rechargeable battery connected between a main current source and a large amperage power source, the protection device includes: a first protection loop which has: a main current load and a battery (set) connected to a main circuit; and a thermocouple sensing switch connected to the battery (set) and the main circuit; a second protection loop which has: a protection circuit connected to the main circuit and checking voltage of the battery to output an activation signal; and a heater next to the thermocouple sensing switch. When the battery is in over-charged or over-discharged condition, the protection circuit outputs a control signal to turn on the semiconductor switch and the thermocouple sensing switch related to the heater.
    • 一种用于连接在主电流源和大安培数电源之间的可再充电电池的保护装置,所述保护装置包括:第一保护回路,其具有:主电流负载和连接到主电路的电池(组); 和连接到电池(组合)和主电路的热电偶感测开关; 第二保护回路,其具有:连接到主电路的保护电路,并检查电池的电压以输出激活信号; 和加热器旁边的热电偶检测开关。 当电池处于过充电或过放电状态时,保护电路输出控制信号以接通半导体开关和与加热器相关的热电偶感测开关。
    • 6. 发明申请
    • Electrolyte injection and degas method of electric energy storage device
    • 电力储存装置的电解液注入和脱气方法
    • US20050244705A1
    • 2005-11-03
    • US10833139
    • 2004-04-28
    • Jing-Yih CherngMing-Lung Chen
    • Jing-Yih CherngMing-Lung Chen
    • H01M2/12H01M2/36
    • H01M2/1258H01M2/12H01M2/361
    • An electrolyte injection and degas method of electric energy storage device comprises the following steps. A pipeline connected with the exterior is installed in an electric energy storage device. Next, gas in the battery core of the electric energy storage device is extracted via the pipeline to form a vacuum negative pressure state. Electrolyte is then injected into the battery core via the pipeline. Next, the battery core is kept at the vacuum negative pressure state and charged for activation. Subsequently, gas generated when the battery core is charged for activation is extracted via the pipeline. A clamp layer for covering the pipeline of the electric energy storage device is then heat sealed. Finally, the pipeline is extruded by hot melt during heat sealing. A degas bag can be saved, and the size of the electric energy storage device can be decreased to lower the cost.
    • 电能储存装置的电解液注入和脱气方法包括以下步骤。 与外部连接的管道安装在电能存储装置中。 接下来,通过管线提取蓄电装置的电池芯的气体,形成真空负压状态。 电解液然后通过管道注入电池芯。 接下来,将电池芯保持在真空负压状态并充电以进行激活。 随后,通过管线提取当电池芯被充电用于激活时产生的气体。 然后将用于覆盖蓄电装置的管道的夹紧层热封。 最后,管道在热封过程中被热熔挤出。 可以节省脱气袋,可以降低蓄电装置的尺寸,降低成本。
    • 7. 发明授权
    • Power disconnection apparatus for soft-shell Li ion battery
    • 软壳锂离子电池断电装置
    • US07785731B2
    • 2010-08-31
    • US12046669
    • 2008-03-12
    • Jing-Yih Cherng
    • Jing-Yih Cherng
    • H01M2/00H01M2/18
    • H01M10/0525H01M2/021H01M2/0275H01M2/34H01M2200/00
    • A power disconnection apparatus includes a soft-shell Li ion battery and a power disconnection device. The soft-shell Li ion battery includes anode pin and a cathode pin and a soft shell enclosing the soft-shell Li ion battery. The power disconnection device includes a panel attaching to the surface of the shell of the soft-shell Li ion battery and a separation unit arranged at topside of the panel and corresponding to one of the anode pin and the cathode pin. The shell has expansion when the soft-shell Li ion battery is over-charged and the panel is move away from the soft-shell Li ion battery. Therefore, the separation unit disconnects power to the anode pin or the cathode pin.
    • 断电装置包括软壳锂离子电池和断电装置。 软壳锂离子电池包括阳极针和阴极针,软壳包围软壳锂离子电池。 断电装置包括安装在软壳锂离子电池的外壳表面上的面板和布置在面板顶部并对应于阳极针和阴极针之一的分离单元。 当软壳锂离子电池过充电并且面板离开软壳锂离子电池时,壳体具有膨胀。 因此,分离单元断开对阳极销或阴极销的电力。
    • 9. 发明申请
    • ELECTROLYTE STORAGE STRUCTURE FOR A LITHIUM BATTERY
    • 锂电池电解质储存结构
    • US20120301753A1
    • 2012-11-29
    • US13246836
    • 2011-09-27
    • Chin-Ming ChenTe-Chuan LaiJing-Yih Cherng
    • Chin-Ming ChenTe-Chuan LaiJing-Yih Cherng
    • H01M10/42
    • H01M10/052H01M2/38H01M10/0585H01M10/42
    • An electrolyte storage structure for a lithium battery made of a battery core having a stack with positive electrode plates, negative electrode plates and separating films, a battery core positive electrode welded with the positive electrode plate, a battery core negative electrode welded with the negative electrode plate, electrolyte, and a cup for receiving the battery core, positive electrode plate, the negative electrode plate and the electrolyte. The cup has a receiving space for accommodating the electrolyte core, the positive electrode plate and the negative electrode plate, and the electrolyte is disposed separately from the battery core. The electrolyte is released and flows into the receiving space for infiltrating the battery core before the battery is set to use. The battery core is infiltrated and saturated with the electrolyte. Then the saturated lithium battery undergoes following procedures of charging and activation to generate a finished lithium battery.
    • 一种由具有正极板,负极板和分离膜的堆叠的具有电池芯的锂电池的电解质储存结构,与正极板焊接的电池芯正极,与负极焊接的电池芯负极 板,电解质和用于接收电池芯,正极板,负极板和电解质的杯。 杯具有用于容纳电解质芯,正极板和负极板的容纳空间,电解质与电池芯分开设置。 在电池设置使用之前,电解液被释放并流入接收空间以渗透电池芯。 电池芯渗入并饱和电解质。 然后饱和锂电池进行充电和激活的以下步骤以产生成品锂电池。
    • 10. 发明申请
    • Manufacturing method of secondary battery and device thereof
    • 二次电池的制造方法及其装置
    • US20050202314A1
    • 2005-09-15
    • US10647322
    • 2003-08-26
    • Jing-Yih CherngMing-Lung Chen
    • Jing-Yih CherngMing-Lung Chen
    • H01M2/18H01M6/10H01M10/04
    • H01M10/0583H01M10/052H01M10/0565Y10T29/49108Y10T29/49115
    • A manufacturing method of secondary battery and the device thereof are proposed. In this method, conducting material is trimmed into positive and negative electrode plates. Positive and negative active materials are coated on the positive and negative electrode plates, respectively. The positive and negative electrode plates are alternately arranged on a strip-shaped separator in an appropriate order. The positive and negative electrode plates on the separator are folded and then stacked according to their arrangement order so that each of the positive and negative electrode plates can be separated by the separator, and opposed faces between the positive and negative electrode plates have the active material coated thereon. The manufacturing process can thus be simplified, and the size and specification can be quickly changed to accomplish convenience in expansion. Moreover, the yield can be enhanced to accomplish the optimum economic benefit of production.
    • 提出二次电池的制造方法及其装置。 在这种方法中,导电材料被修整成正极板和负极板。 正极和负极活性材料分别涂覆在正极板和负极板上。 正极板和负极板以适当的顺序交替地布置在条形隔膜上。 隔板上的正极板和负极板按照它们的排列顺序被折叠然后堆叠,使得正极板和负极板中的每一个可以被分离器分开,并且正极板和负极板之间的相对面具有活性材料 涂覆在其上。 因此,可以简化制造工序,能够快速地改变尺寸和规格,以实现扩展的方便。 此外,可以提高产量以实现生产的最佳经济效益。