中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2015年
1期
119-124
,共6页
袁光明%高文秀%李成%赵小玲%郑奕%刘波
袁光明%高文秀%李成%趙小玲%鄭奕%劉波
원광명%고문수%리성%조소령%정혁%류파
熔盐电解质锂电池%自放电%锂硼合金%锂硅合金
鎔鹽電解質鋰電池%自放電%鋰硼閤金%鋰硅閤金
용염전해질리전지%자방전%리붕합금%리규합금
molten salt electrolyte lithium battery%self-discharge%lithium-boron alloy%lithium-silicon alloy
熔盐电解质锂电池在激活后由于自放电导致容量发生衰减,采用LiF-LiCl-LiBr低温共熔盐电解质,以二硫化铁为正极材料,分别以锂硅合金和锂硼合金作为负极材料制备单体电池,在500℃的温度下进行恒流放电试验。通过改变单体电池的工作电流可控制电池放电时间,并得到单体电池在经历不同工作时间后获得的可利用电容量。并将单体电池的工作时间和可利用电容量经一次线性回归分析。结果发现,使用锂硅合金作为负极材料时,电池的容量衰减率为40.6 C/min;而使用锂硼合金作为负极材料时,电池的容量衰减率仅为15.5 C/min。
鎔鹽電解質鋰電池在激活後由于自放電導緻容量髮生衰減,採用LiF-LiCl-LiBr低溫共鎔鹽電解質,以二硫化鐵為正極材料,分彆以鋰硅閤金和鋰硼閤金作為負極材料製備單體電池,在500℃的溫度下進行恆流放電試驗。通過改變單體電池的工作電流可控製電池放電時間,併得到單體電池在經歷不同工作時間後穫得的可利用電容量。併將單體電池的工作時間和可利用電容量經一次線性迴歸分析。結果髮現,使用鋰硅閤金作為負極材料時,電池的容量衰減率為40.6 C/min;而使用鋰硼閤金作為負極材料時,電池的容量衰減率僅為15.5 C/min。
용염전해질리전지재격활후유우자방전도치용량발생쇠감,채용LiF-LiCl-LiBr저온공용염전해질,이이류화철위정겁재료,분별이리규합금화리붕합금작위부겁재료제비단체전지,재500℃적온도하진행항류방전시험。통과개변단체전지적공작전류가공제전지방전시간,병득도단체전지재경력불동공작시간후획득적가이용전용량。병장단체전지적공작시간화가이용전용량경일차선성회귀분석。결과발현,사용리규합금작위부겁재료시,전지적용량쇠감솔위40.6 C/min;이사용리붕합금작위부겁재료시,전지적용량쇠감솔부위15.5 C/min。
The capacity decay occurs due to the self-discharge after activation in the molten salt electrolyte lithium batteries. Using LiF-LiCl-LiBr molten salts as electrolyte and FeS2 as cathode material, the lithium-silicon alloy and lithium-boron alloy as anode material to prepare single cells, which was then discharged at constant currents and 500℃. The working time of the single cells can be adjusted simply by varying the discharge current, the change of the available capacity is obtained. The working time and the measured capacity were analyzed by unary linear regression. The results show that the rate of the capacity loss is 40.6 C/min when lithium-silicon alloy is used as anode material, which is only 15.5 C/min when lithium-boron alloy is used as anode material.
