高性能预混复合有机添加剂对微混AGM起停铅酸蓄电池负极性能的影响研究被引量：6

The effects of advanced premixed organic additives on the performance of negative active materials of valve-regulated lead-acid batteries for start-stop applications

下载PDF

导出

摘要有机添加剂对AGM阀控式起停铅酸蓄电池负极电化学性能有着显著性影响。采用单一有机添加剂已逐渐难以满足高端配套客户对AGM起停铅酸蓄电池的产品技术需求。本文首先通过粒径分布测试、傅里叶红外光谱测试、紫外光谱测试以及差示扫描量热-热重分析法对两种高性能有机添加剂的理化性质及热稳定性进行了研究。此外,通过设计混合水平正交试验,将两种有机添加剂按照一定质量比进行复配、预混,通过调控其复配质量比和添加总量,分别考察对AGM起停铅酸蓄电池负极活性物质利用率、充电接受能力、-18℃低温高倍率放电性能、部分荷电状态高倍率循环寿命的影响趋势。研究发现,当这两种有机添加剂的质量比为2∶1且总质量分数为0.3%时,负极综合性能最佳。 Organic additives had significant impacts on the electrochemical properties of negative active materials of AGM start-stop lead-acid battery. By using the single organic additive, it is difficult to meet the technology demand of high-end supporting customers（OEM） for micro hybrid start-stop applications. The physicochemical properties and thermal stability of two high-performance organic additives X and Y were studied by particle size distribution measurement, Fourier transform infrared spectroscopy（IR）, ultraviolet spectroscopy（UV） and differential scanning calorimetrythermal gravimetric analysis（DSC-TGA）. In addition, the impact trends of two organic additives on the AGM start-stop lead-acid battery were investigated in terms of negative active material utilization, charge acceptance, high-rate discharge performance under-18℃and cycle life under high rate partial state of charge（HRPSo C） applications by designing mixed-level DOE experiment whose scheme involved regulating the premixed X/Y mass ratio and the total content of organic additives X and Y. It was found that the best overall performance of negative electrode would be got when the premixed X/Y mass ratio was 2：1 and their total content was 0.3 wt%.

作者张兴张祖波夏诗忠

机构地区湖北骆驼蓄电池研究院有限公司

出处《蓄电池》 2016年第3期112-119,145,共9页 Chinese LABAT Man

关键词有机添加剂微混汽车 AGM 起停铅酸蓄电池预混负极充电接受能力活性物质耐久循环寿命 organic additive micro hybrid vehicle AGM start-stop lead-acid battery premix negative electrode charge acceptance active material durable cycle life

分类号 TM912.4 [电气工程—电力电子与电力传动]

引文网络
相关文献

参考文献8

1张兴,张祖波,夏诗忠,余萍,戴长松.高导电性炭材料OFB1对铅酸蓄电池负极性能的影响研究[J].蓄电池,2015,52(2):51-58. 被引量：7
2张兴,张祖波,夏诗忠,史俊雷,余萍,戴长松.复合电解液添加剂对充电接受能力和低温高倍率放电性能的影响研究[J].蓄电池,2015,52(3):109-114. 被引量：4
3Boden D E Comparison of methods for adding expander to lead-acid battery plates--advantages and disadvantages[J]. Journal of Power Sources, 2004, 133(1): 47-51.
4Matrakova M, Rogachev T, Pavlov D, et al. Influence of phenolic group content in lignin expanders on the performance of negative lead-acid battery plates[J]. Journal of Power Sources, 2003, 113(2): 345-354.
5Boden D R Selection of pre-blended expanders for optimum lead/acid battery performance[J]. Journal of Power Sources, 1998, 73(1): 89-92.
6Karami H, Alipour M. Investigation of organic expanders effects on the electrochemical behaviors of new synthesized nanostructured lead dioxide and commercial positive plates of lead-acid batteries[J]. Journal of Power Sources, 2009, 191 (2): 653-661.
7Pavlov D, Myrvold B O, Rogachev T, et al. A new generation of highly efficient expander products and correlation between their chemical composition and the performance of the lead-acid battery[J]. Journal of Power Sources, 2000, 85(1): 79 91.
8Mcnally T, Klang J. Benefit of increasing the organic expander dosage on the high temperature performance of the negative electrode of lead- acid batteries[J]. Journal of Power Sources, 2003, 116(1/2): 47-52.

二级参考文献28

1张胜永,乔锋华.循环用电池不可忽视的重要性能——充电接受能力[J].蓄电池,2005,42(4):168-172. 被引量：5
2Bullock, K. R. Carbon reactions and effects on valve-regulated lead-acid (VRLA) battery cycle life in high-rate, partial state-of-charge cycling[J]. Journal of Power Sources, 2010, 195(14): 4513-4519.
3Ebner, E., et al. Carbon blacks for the extension of the cycle life in flooded lead acid batteries for micro-hybrid applications[J]. Journal of Power Sources, 2013, 239: 483-489.
4P. T. Moseley, R. F. Nelson, A. F. Hollenkamp. The role of carbon in valve-regulated lead-acid battery technology[J]. Journal of Power Sources, 2006. 157(1): 3-10.
5D. Pavlov, E Nikolov. Capacitive carbon and electrochemical lead electrode systems at the negative plates of lead-acid batteries and elementary processes on cycling[J]. Journal of Power Sources, 2013, 242: 380-399.
6D. Pavlov, et al. Mechanism of action of electrochemically active carbons on the processes that take place at the negative plates of lead-acid batteries[J]. Journal of Power Sources, 2009, 191(1): 58-75.
7M. Thele, et al. Modeling of the charge acceptance of lead-acid batteries[J]. Journal of Power Sources, 2007, 168(1): 31-39.
8J. Valenciano, et al. Lead-acid batteries for micro- and mild-hybrid applications[J]. Journal of Power Sources, 2009, 187(2): 599-604.
9H. A. Catherino. Estimation of the heat generation rates in electrochemical cells[J]. Journal of Power Sources, 2013, 239: 505-512.
10Bhattacharya A, Basumallick I N. Effect of mixed additives on lead-acid battery electrolyte[J]. Journal of Power Sources, 2003, 113(2): 382-387.