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    • 2. 发明申请
    • BATTERY HEATING CIRCUITS AND METHODS WITH RESONANCE COMPONENTS IN SERIES USING VOLTAGE INVERSION AND FREEWHEELING CIRCUIT COMPONENTS
    • 电池加热电路和使用电压反相和自由绕组组件的系列中的谐振组件的方法
    • US20120031890A1
    • 2012-02-09
    • US13187890
    • 2011-07-21
    • Yaochuan HanWenhui XuWei FengQinyao YangWenjin XiaXianyin Li
    • Yaochuan HanWenhui XuWei FengQinyao YangWenjin XiaXianyin Li
    • H05B1/00
    • H01L23/345H01L2924/0002H01M10/615H01M10/625H01M10/651H01M10/657H01M10/6571H01M10/6572H02J7/0014H02J7/0054H02J7/0075H02J7/0091H02J7/0093H02M3/158Y02E60/12Y02T10/7055H01L2924/00
    • Certain embodiments of the present invention provide a battery heating circuit, comprising a switch unit (1), a switching control module (100), a damping component R1, an energy storage circuit, a freewheeling circuit (20), and an energy superposition unit, the energy storage circuit is configured to connect with the battery to form a loop, and comprises a current storage component L1 and a charge storage component C1; the damping component R1, the switch unit (1), the current storage component L1, and the charge storage component C1 are connected in series; the switching control module (100) is connected with the switch unit (1), and is configured to control ON/OFF of the switch unit (1), so as to control the energy flowing between the battery and the energy storage circuit; the energy superposition unit is connected with the energy storage circuit, and is configured to superpose the energy in the energy storage circuit with the energy in the battery when the switch unit (1) switches on and then switches off; the freewheeling circuit (20) is configured to form a serial loop with the battery and the current storage component L1 to sustain current flow in the battery after the switch unit (1) switches on and then switches off.
    • 本发明的某些实施例提供了一种电池加热电路,包括开关单元(1),开关控制模块(100),阻尼组件R1,能量存储电路,续流电路(20)和能量叠加单元 能量存储电路被配置为与电池连接以形成环路,并且包括电流存储部件L1和电荷存储部件C1; 阻尼部件R1,开关单元(1),电流存储部件L1和电荷存储部件C1串联连接; 开关控制模块(100)与开关单元(1)连接,并且被配置为控制开关单元(1)的接通/断开,以便控制在电池和能量存储电路之间流动的能量; 能量叠加单元与能量存储电路连接,并且被配置为当开关单元(1)接通然后断开时,将蓄能电路中的能量与电池中的能量叠加; 续流电路(20)被配置为与电池和当前存储部件L1形成串联回路,以在开关单元(1)接通然后关断之后维持电池中的电流流动。
    • 4. 发明申请
    • BATTERY HEATING CIRCUITS AND METHODS BASED ON BATTERY DISCHARGING AND CHARGING USING RESONANCE COMPONENTS IN SERIES AND MULTIPLE CHARGE STORAGE COMPONENTS
    • 基于电池放电和充电的电池加热电路和方法使用系列中的谐振组件和多个充电存储组件
    • US20120025781A1
    • 2012-02-02
    • US13184915
    • 2011-07-18
    • Wenhui XuYaochuan HanWei FengQinyao YangWenjin XiaShibin MaXianyin Li
    • Wenhui XuYaochuan HanWei FengQinyao YangWenjin XiaShibin MaXianyin Li
    • H02J7/00
    • H01L23/345H01L2924/0002H01M10/615H01M10/625H01M10/651H01M10/657H01M10/6571H01M10/6572H02J7/0014H02J7/0054H02J7/0075H02J7/0091H02J7/0093H02M3/158Y02E60/12Y02T10/7055H01L2924/00
    • Certain embodiments of the present invention provide a battery heating circuit, comprising a plurality of switch units (1), a switching control module (100), a damping component R1, an energy storage circuit, and a polarity inversion unit (101), wherein: the energy storage circuit is connected with the battery, and comprises a current storage component L1 and a plurality of charge storage components C1; the plurality of charge storage components C1 are connected with the plurality of switch units (1) in series in one-to-one correspondence to form a plurality of branches; the plurality of branches are connected in parallel with each other and then connected with the current storage component L1 and damping component R1 in series; the switching control module (100) is connected with the switch units (1), and is configured to control ON/OFF of the switch units (1), so that the energy flows back-and-forth between the battery and the energy storage circuit when the switch units (1) switch on; the polarity inversion unit (101) is connected with the energy storage circuit, and is configured to invert the voltage polarity of the plurality of charge storage components C1 after the switch units (1) switch from ON state to OFF state. For example, the heating circuit provided in certain embodiments of the present invention can improve charge/discharge performance of the battery, as well as safety and work efficiency in the battery heating process.
    • 本发明的某些实施例提供一种电池加热电路,包括多个开关单元(1),开关控制模块(100),阻尼组件R1,能量存储电路和极性反转单元(101),其中 能量存储电路与电池连接,具有电流存储部L1和多个电荷存储部C1; 多个电荷存储组件C1与多个开关单元(1)一一对应地串联连接以形成多个分支; 多个分支彼此并联连接,然后与当前存储部件L1和阻尼部件R1串联连接; 切换控制模块(100)与开关单元(1)连接,并且被配置为控制开关单元(1)的接通/断开,使得能量在电池和能量存储器之间来回流动 电路当开关单元(1)接通时; 极性反转单元(101)与能量存储电路连接,并且被配置为在开关单元(1)从接通状态切换到断开状态之后反转多个电荷存储组件C1的电压极性。 例如,在本发明的某些实施例中提供的加热电路可以改善电池的充放电性能,以及电池加热过程中的安全性和工作效率。
    • 5. 发明申请
    • System For Line Powering
    • 线路供电系统
    • US20080122586A1
    • 2008-05-29
    • US11771228
    • 2007-06-29
    • Zhen QinXuefeng PanTianli JiangYingjie ZhouXianyin Li
    • Zhen QinXuefeng PanTianli JiangYingjie ZhouXianyin Li
    • G05B11/01
    • H04M19/005Y10T307/615
    • A system for line powering includes at least one office-end PSU, one standby PSU and one power switching unit. The office-end PSU provides power for a group of subscriber lines in a centralized manner. The power switching unit monitors the power supply status of the office-end PSU and controls the switching between the office-end PSU and standby PSU. In embodiments of the invention, different rectifier/boost circuits and different step-down circuits need not be set for each pair of subscriber lines between the office-end PSU and the remote device. When an office-end PSU fails to supply power, the standby PSU can be switched over quickly to supply power for the remote device, which cuts down the cost for designing the office-end PSU and the standby PSU while ensuring the reliability of power supply for the remote device.
    • 用于线路供电的系统包括至少一个办公室端PSU,一个备用PSU和一个电源交换单元。 办公室端PSU以集中的方式为一组用户线路提供电力。 电源开关单元监视办公室端PSU的电源状态,并控制办公室端PSU与待机PSU之间的切换。 在本发明的实施例中,不需要为办公室端PSU和远程设备之间的每对用户线路设置不同的整流器/升压电路和不同的降压电路。 当办公室端PSU无法供电时,可以快速切换待机PSU以为远程设备供电,从而降低设计办公室端PSU和待机PSU的成本,同时确保电源的可靠性 用于远程设备。