放电电位 meaning in Chinese
discharge potential
discharge voltage
potential, discharge
Examples
- Moreover , the impedance values decreased , the reactions became more easily , and the charge and discharge performance became better as the discharging potential decreased and the reactions also became easily as the cycling times increased
且随着放电电位的降低,阻抗值下降,反应变的越容易,充放电性能越好,随着循环次数的进行,反应会变得容易。 - The charging - discharging curves look like the letter " v " and have no flat plateaus due to the different sizes of the micropores . increasing the httmax , the micropores in ant samples become fewer and smaller , therefore the charging - discharging capacities decrease . when httmax = 2100 , the charging - discharging capacity reaches the minimum since the number of the micropores reaches the minimum and the size of them become very small , the number of graphite crystallite in ant samples is still few and the size of them is also small
在htt _ ( max ) 2100的范围内, ant试样属于乱层结构,石墨微晶尚未出现或数量很少,贮锂机制为“孔隙贮锂” ,由于孔隙的大小不一,插锂时克服阻力所需的电位也不同,因此充、放电曲线呈“ v ”字形,无平稳的充、放电电位平台;随着htt _ ( max )的增大,试样中孔隙逐渐变小、变少,充、放电容量也逐渐变小。 - The mechanism of storing lithium - ions was to store lithium ions in the micropores of the samples . since the micropores which formed in the process of liquid phase carbonization had different sizes , the smaller the micropores , the lower the potential to overcome the resistance for inserting lithium ions . the charging - discharging curves looked like the letter " v " and had no flat plateaus , the charging - discharging capacities were high but faded rapidly
Htt _ ( max ) = 2000以前,石墨微晶尚未出现,贮锂机制为“微孔贮锂” ;由于微孔的大小不同,插锂时克服阻力所需的电位也不同,微孔愈小,所需电位愈低,因此充、放电曲线为“ v ”字形,无充、放电电位平台,充、放电容量高,但容量衰减快;随着htt _ ( max )的增大,液相炭化过程中所形成的微孔逐渐变小、变少,因此充、放电容量也逐渐变小。 - Nano - sacle coo is apt to dissolve in the electrode homogeneously , and better conductive net of coooh come into being , thus contribute a lot to the procedure of the activation . the electrode with nano - scale coo and cnts shows higher discharge voltage and higher discharge capacity . nano - scale additives can improve the specific capacity of the electrode , the volume specific capacity and the mass specific capacity of the electrode with nano - scale coo are 784mah / cm3 and 224mah / g , respectively
结果表明:添加剂为纳米coo的电极的活化性能最好,纳米coo相对于普通coo能更加均匀的分布在镍电极内,也更易溶解、反应生成coooh导电网路,从而加快了镍电极的活化进程;添加纳米coo和添加cnts的极片具有较高的放电电位和较大的放电容量,纳米添加剂能有效提高镍正极活性物质的放电效率和利用率;纳米添加剂可以有效地提高镍正极片的容量密度,其中添加纳米coo的极片体积容量密度达到784mah cm ~ 3 ,质量容量密度达到224mah g ;添加cnts的极片体积容量密度达到778mah cm ~ 3 ,质量容量密度达到223mah g 。