快速充电

采用新型PIC单片机的快速充电智能控制系统

The Intelligent Control System of Quick Charge with the Use of New PIC Microcontroller

又采用新型正极材料LiMnxNiyCozO2开发出性能更优越的18650型高功率锂离子电池，该电池可10C连续放电和8C快速充电，并具有优秀的循环性能和搁置性能。

Another 18650 high power lithium-ion secondary battery is prepared with innovative cathode material LiMn_xNi_yCo_zO_2 , which presents superior performance . The battery endures continuous discharge under 10C and quick charge under 8C , and presents excellent cycling and storage performance .

我们相信，用户会喜欢优化了交互界面、迄今最耐用和支持快速充电的Series7。

We think customers will love the optimized user interface , best-ever durability , and faster charging of Series 7 .

配备的USB插口可以通电脑对其进行快速充电。

You also can charge it with USB by computer .

RFID手持机锂电池快速充电电路设计

Design of a Power Charge Circuit for the Lithium Battery of RFID

基于PWM蓄电池可编程快速充电系统的研究

Rapid Programming Charge System Based on PWM Accumulator

VRLA蓄电池变电流间歇快速充电方法

A rapid intermittent charge method with variable current for VRLA battery

基于AVR单片机的镍镉电池快速充电装置设计

The Design of Ni-cd Battery Fast-charging Device Based on AVR - SCM

慢脉冲快速充电在VRLA电池容量恢复中的应用

Application of slow pulse fast charge in capacity restoration of VRLA battery

高功率Ni-MH电池快速充电技术研究

Fast charge study of high power Ni-MH battery

选择NTC器件制造快速充电设备

Selecting NTC Devices for Fast Charging Applications

因此，得知中国国家电网（StateGrid）已完成1200公里京沪高速沿线快速充电站的建设，我感到很欣慰，并且很想试驾一下电动汽车。

So I was delighted to learn that China 's State Grid had finished building quick-charging stations for electric cars along the 1200km motorway from Shanghai to Beijing - and eager to give the vehicles a test drive .

结合引脚复用技术，将Ad-hoc可测性方法应用于一个快速充电管理芯片的可测性设计实践中。

With Pin Reuse technique , use Ad hoc DFT method in a Fast Charging management Chip DFT design .

本文就板栅合金、和膏方程、装配压力、快速充电等方面阐述VRLA蓄电池技术。

Techniques for VRLA batteries such as grid alloy paste-mixing equation . assembling pressure and rapid charge were explained .

密封MH-Ni电池快速充电控制方法的研究

Study on the control method for rapid charge of sealed Ni-MH battery

根据SOC来调节电流的充电方法，能降低MH/Ni电池快速充电时的内压。

The inner pressure of Ni / MH battery during fast charging could be decreased by using the charging method which regulated the current for SOC .

快速充电D型MH-Ni蓄电池研究

Development of fast charge D type Ni-MH battery

MH-Ni蓄电池快速充电性能的研究

The study of rapid charging Ni-MH battery performance

应用慢脉冲快速充电方法，对报废的VRLA电池进行容量恢复。

The capacity of the failed valve-regulated lead acid ( VRLA ) battery was restored by the slow pulse fast charge method .

这种继电器用于ESD测试设备、电缆测试设备和心脏起搏器，是理想的电容器快速充电或放电的开关元件。

These relays are ideal for high in-rush capacitive make and capacitive discharge loads found in ESD test equipment , cable test equipment and heart defibrillators .

分析了限制MH-Ni蓄电池快速充电性能的一个原因是因为MH-Ni蓄电池在快速充电过程中产生大量热所致。

One of the reasons why the fast charging ability of Ni-MH battery is limited was analyzed .

快速充电型Cd-Ni电池的研究

R & D of rapid-charge Ni - Cd battery

在充电时智能充电机始终与BMS保持通信联系，以保证电池组安全快速充电。

The intelligent charging machine keeps all-time communication with the BMS during the charging process , to guarantee the safe and fast charging .

本设计的a-SiTFT中的驱动方式采用动态驱动的高压驱动，完成对TFT的快速充电，较理想的提高响应速度，响应速度可以达到12～16ms。

In the designed a-Si TFT construct , it took high voltage driving circuit of dynamic driving to charge a-Si TFT quickly to reduce response time .

研制的AA型发泡式镉镍电池性能优良，放电容量为700mAh以上，可用1.5小时快速充电，循环寿命超过400次。

AA size foamed nickel cadmium batteries had excellent performances with the discharge capacity greater than 700 mAh . This battery could be fast charged in 1 . 5 hours and its cycle life was over 400 times .

同时，研究分析了正极添加剂、正极活性物质、隔膜类型和电解液组成等对MH-Ni蓄电池快速充电性能的影响。

At the same time , the effect of doped agents in positive electrode , active material , separators and electrolyte on the rapid charging performance were also studied and analysed .

在智能快速充电阶段，实时采集电压、电流和温度值，然后由Fuzzy-PI控制器得到充电电压。

During the intelligent fast charging stage , the real-time collection of voltage , current and temperature were firstly gathered and then the charging voltage by reasoning with the Fuzzy-PI controller was obtained .

以采用泡沫镍正极的8AhD型MH-Ni电池为例，从四个方面减少MH-Ni蓄电池在快速充电过程中产生的热量：1.优化电池结构设计，降低电池内阻；

The reason is that Ni-MH battery generates much heat during fast charging . Try to reduce the heat by the below four means : 1.Optimizing the battery structure to lower the internal resistance ;

通过对比该快速充电策略、保护电压恒流充电策略和40A恒流充电策略下的仿真结果，验证了所提出的电池分阶段恒流充电控制策略的正确性和可行性。

By Modeling and simulating the process of NiMH battery quick charging with this strategy , constant voltage charge method and constant current charge method , validates this control strategy .

论文根据48V磷酸铁锂电池组充电技术要求，设计了快速充电主电路拓扑及其控制方式，搭建了充电实验平台，完成了对电池组的快速充电实验。

Based on the charging requirements of 48V lithium iron phosphate battery pack , designed a rapid charging main circuit topology and its control method , built charging experimental platform and completed the battery fast charging experiment .