若放电电流增加,在随后的第一周充放电过程中最高充电电压迅速增加、放电容量显著小于稳定值。
If the discharge current was increased, the discharge capacity was obviously less than the stabilized value and maximum charge voltage was also changed suddenly.
随着充放电电压的升高,首次不可逆放电容量增大,循环稳定性减弱。
With the increase of the charge-discharge voltage, electrochemical stability was reduced and irreversible capacity loss occurred during the first cycle.
采用进口名牌急充放电电容器,容量稳定,寿命长。
Use imported well-known charging and discharging condenser, it has stable capacity and long service life;
在充放电30次以后,材料的放电比电容基本不再发生变化,趋于稳定。
The specific capacitance of composites shows no obvious fading after 30 times in the charge-discharge process.
采用开关元件控制的恒流充放电是产生稳定非正弦振荡波的主要方法。
Constant current charging by switch control is the main method to generate non-sinusoid oscillation waveform.
循环寿命测试结果表明非对称电容器具有稳定的充放电性能。
At the same time, the asymmetric capacitor also showed stable cycle performance.
材料的充放电效率较高,稳定性较好。
The material have higher charge-discharge efficiency and good stability.
经过1 500次恒流循环充放电,比电容衰减为初始容量的10%,显示其具有良好的电化学稳定性。
Also, the all-solid-state supercapacitor exhibited a good electrochemical(stability) with a capacitance degradation of 10% over 1 500 cycles.
通过恒流充放电法测试不同电容器的电容性能,并考察了超级电容器的电容衰减率、循环稳定性和循环寿命。
Capacitive performance of various supercapacitors is tested by galvanostatic charge and discharge. And capacitive decay rate, cyclical stability and cycle life are also investigated.
通过恒流充放电法测试不同电容器的电容性能,并考察了超级电容器的电容衰减率、循环稳定性和循环寿命。
Capacitive performance of various supercapacitors is tested by galvanostatic charge and discharge. And capacitive decay rate, cyclical stability and cycle life are also investigated.
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