| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
| Research Progress in Negative Additives for Lead-acid Batteries |
| LI Xiaobo1,2, ZHANG Panpan1,2, HE Yapeng1,2, HUANG Hui1,2,3, GUO Zhongcheng1,2,3
|
1 College of Metallurgy and Energy Engineering, Kunming University of Science and Technology, Kunming 650093, China;
2 Research Center of Metallurgical Electrode Materials Engineering Technology, Yunnan Province, Kunming 650106, China;
3 Kunming Hendera Science and Technology Co., Ltd., Kunming 650106, China |
|
|
|
Abstract In recent years, the environmental pollution and scarcity of fossil energy have led to the continuous development and updation of energy sto-rage equipment. As a new energy storage device, the battery has many advantages in the energy supply. At present, the lithium ion batteries and lead-acid batteries are the most widely used in the secondary battery market. Correspondingly, lithium ion batteries have the advantages of high energy density and low volume and a tendency to surpass lead-acid batteries. However, there are obvious limitations for lithium ion batteries due to the serious attenuation of low-temperature capacity and high-temperature explosion, and the reliability over wide temperature range and low price of lead-acid batteries make them more versatile in the energy industries.
The mainly failure modes of lead-acid battery are related to the early capacity loss of positive and negative plates, grid corrosion and lead sulfate sulphation at negative plate. As the common power source for hybrid vehicles, the lead-acid battery needs to be operated at high-rate partial state of charge (HRPSoC) state, where the factor determining the life mainly stems from the invalidation of the negative electrode. The invalidation of the negative plate would result into sharp drop in battery performance and shortened life, and negative additives could solve the negative plate failure problems in different aspects to a certain extent.
In this review, recent progress on the study of negative additives for lead-acid battery and existing problems are summarized while the future development tendency is also forecasted. Typical negative additives, which primarily contain carbon materials, conducting polymer, inorganic or metal oxides, could enhance the utilization rate of negative electrode active material (NAM), improve the discharge performance under large current and low temperature situations, and so on. Meanwhile, negative conducting additives could participate part of charge current to slow down the adverse impact under large current. Furthermore, failure mechanism of negative plate including lead sulfation, cycle stability, electrolyte loss could be solved to some extent. Meantime, the disadvantages of the negative additives are also discussed in the review.
|
|
Published: 16 January 2020
|
|
|
| About author:: Xiaobo Li received his B.E. Degree in engineering from Lanzhou University of Technology in 2017. He is currently pursuing his Master at College of Me-tallurgy and Energy Engineering, Kunming University of Science and Technology under the supervision of Prof. Hui Huang. His research is focused on energy storage electrode materials;Hui Huang received her B.E. degree in Polymer Scie-nce from Sichuan University in 2000, M.S. degree in inorganic material in Yunnan University, and obtained her PhD degree in Metallurgical Physical Chemistry from Kunming University of Science and Technology. She was as a visiting scholar in Florida University from 2014 to 2015. She is currently a full professor in Kunming University of Science and Technology, technical director of Kunming Hendera Technology Co., Ltd., deputy director of Yunnan Metallurgical Electrode Materials Engineering Technology Research Center. Her current research interests include conductive energy-saving polymer anode materials, special functional powder mate-rials, metallurgical electrochemical and hydrometallurgical new materials. At present, she has applied for 21 national invention patents, published 3 academic books and 47 researchpapers, including 35 SCI and EI. She has won many titles including first prize of China Nonferrous Metals Industry Science and Technology Award, third prize of Yunnan Natural Science Award, and third prize of Yunnan Science and Technology Invention Award, Yunling Industrial Technology Leading Talents, yunnan province Young and Middle-aged Technical Innovation Talents of Yunnan Province and Young and Middle-aged Academic and Technical Lea-ders of Kunming;Zhongcheng Guo received his B.E. degree in Non-ferrous Metallurgy from Kunming University of Science and Technology in 1987 and received his PhD. degree from Kunming University of Science and Technology in 2001. In 1998 and 2006, he went to the Department of Materials at Monash University in Australia and the Center for Corrosion and Protection Research at University of Manchester, UK as a visiting scholar. He is currently a professor in Kunming University of Science and Technology, the chairman of Kunming Hendera Technology Co., Ltd., director of Yunnan Metallurgical Electrode Materials Engineering Technology Research Center, director of China Surface Engineering Association, and executive director of China Surface Engineering Association Electroplating Branch. His current research fields cover the research development and achievement transformation in metallurgical physical chemistry, metallurgical new materials, non-ferrous metal special powder materials, surface enginee-ring, materials physical chemistry and other fields. He has won 27 national invention patents and 7 provincial and ministerial-level scientific and technolo-gical achievements awards, published 8 monographs, and published more than 200 academic papers. He has won National Hundred Excellent Doctoral Dissertation Awards from the Ministry of Education, the first prize of the China Nonferrous Metals Industry Science and Technology Award twice, the special prize of Invention and Entrepreneurship Award of China Invention Association, National Ten Thousand Plan (National Innovation and Entrepreneurship Talents), the National New Century Talent Project, the winner of the New Century Excellent Talents Support Program of the Ministry of Education, the Yunnan Provincial Government Special Allowance Winner, and the Yunnan Young and Middle-aged Academic and Technical Leader. |
|
|
1 Zhang Y Y. Study on carbon nanometer conductive agent for lead carbon batteries. Master’s Thesis, Chongqing University, China, 2017(in Chinese).
张艳艳. 铅碳电池碳纳米导电剂的研究. 硕士学位论文, 重庆大学, 2017.
2 He H B. Chinese Journal of Power Sources, 2017, 41(10), 1455(in Chinese).
何海斌.电源技术, 2017, 41(10), 1455.
3 Lam L T, Louey R, Haigh N P, et al. Journal of Power Sources, 2007, 174(1), 16.
4 Huang B B. Research on plate polarization of VRLA batteries and its fai-lure modes. Master’s Thesis, Fuzhou University, China, 2014(in Chinese).
黄彬彬. VRLA电池极板极化及失效模式研究. 硕士学位论文, 福州大学, 2014.
5 Moseley P. Journal of Power Sources, 2004, 59(1-2), 191.
6 Guo Y, Hu J, Huang M. Journal of Power Sources, 2006, 158(2), 991.
7 Rice D M, Manders J E. Journal of Power Sources, 1997, 67(1), 251.
8 Lin X P, Guo Y L. Chinese Labat Man, 2008, 45(1), 5(in Chinese).
林雪平, 郭永榔. 蓄电池, 2008, 45(1), 5.
9 Zheng S, Jia F C. Chinese Journal of Power Sources, 2013, 37(7), 1271(in Chinese).
郑舒, 贾丰春. 电源技术, 2013, 37(7), 1271.
10 Huang B, Wang D L, Shang X L. Chinese Labat Man, 2017, 54(1), 23(in Chinese).
黄镔, 王殿龙, 尚晓丽. 蓄电池, 2017, 54(1), 23.
11 Pavlov D, Rogachev T, Nikolov P, et al. Journal of Power Sources, 2009, 191(1), 58.
12 Jia F N. Influence of carbon additive on the performance of lead-acid battery negative plate. Master’s Thesis, Harbin Institute of Technology, China, 2013(in Chinese).
贾方娜. 碳添加剂对铅酸电池负极性能影响的研究. 硕士学位论文, 哈尔滨工业大学, 2013.
13 Yang J. Research on failure modes and modification of lead-acid batte-ries. Master’s Thesis, Beijing University of Technology, China, 2017(in Chinese).
杨俊. 铅酸电池失效机理分析与改性研究. 硕士学位论文, 北京工业大学, 2017.
14 Chen X J. Modification and electrochemical properties of carbon material for anode of ultrabattery. Master’s Thesis, Central South University, China, 2011(in Chinese).
陈绪杰. 超级铅酸电池负极用炭材料的改性及电化学性能研究. 硕士学位论文, 中南大学, 2011.
15 Nakamura K, Shiomi M, Takahashi K, et al. Journal of Power Sources, 1996, 59(1-2), 153.
16 Vermesan H, Hirai N, Shiota M, et al. Journal of Power Sources, 2004, 133(1), 52.
17 Fu Y D. Study on the influence of different additives on the performance of lead acid battery negative electrode. Master’s Thesis, Central South University, China, 2011(in Chinese).
付颖达. 不同添加剂对铅酸电池负极性能影响的研究. 硕士学位论文, 中南大学, 2011.
18 Boden D P, Arias J, Fleming F A. Journal of Power Sources, 2001, 95(1-2), 277.
19 Chen X C.Chinese Battery Industry, 2008, 2, 5.
20 Bullock K R. Journal of Power Sources, 2010, 195(14), 4513.
21 Lam L T, Louey R. Journal of Power Sources, 2006, 158(2), 1140.
22 Wang L Z, Zhang K Q, Zhang L S, et al. Chinese Labat Man, 2012 (5), 198(in Chinese).
王力臻, 张凯庆, 张林森, 等. 蓄电池, 2012 (5), 198.
23 Yang H. Preparation of carbon-based composhes for the negative plate of lead-acid batterirs and study on their mechnisms. Ph.D. Thesis, Huazhong University of Science and Technology, China, 2017(in Chinese).
杨欢. 铅酸电池负极碳基复合材料的制备及其作用机理. 博士学位论文, 华中科技大学, 2017.
24 Ebner E, Burow D, Borger A, et al. Journal of Power Sources, 2013, 239,483.
25 Vinal G W. Storage Batteries, fourth ed., John Wiley & Sons, New York, USA, 1955.
26 Sadhasivam T, Park M J, Shim J Y, et al. Electrochimica Acta, 2019, 295,367.
27 Gao Y, Wan H, Xia Y, et al. ChemPlusChem, 2018, 83(12), 1119.
28 Shiomi M, Funato T, Nakamura K. Journal of Power Sources, 1997, 64(64), 147.
29 Zhu J S. Research on preparation of Pb-C composite anode and mechanism of carbon. Master’s Thesis, Harbin Institute of Technology, China, 2011(in Chinese).
朱俊生. Pb-C电池负极制备及碳作用机理研究. 硕士学位论文,哈尔滨工业大学, 2011.
30 Pavlov D, Nikolov P. Journal of Power Sources, 2013, 242, 380.
31 Moseley P T. Journal of Power Sources, 2009, 191(1), 134.
32 Zhang W, Lin H, Lu H, et al. Journal of Materials Chemistry A, 2015, 3(8), 4399.
33 Yin J, Lin N, Zhang W, et al. Journal of Energy Chemistry, 2018, 27(6), 1674.
34 Zhang W L, Yin J, Lin Z Q, et al. Journal of Power Sources, 2017, 342, 183.
35 Xiang J, Ding P, Zhang H, et al. Journal of Power Sources, 2013, 241, 150.
36 Calábek M, Micka K, Krivák P, et al. Journal of Power Sources, 2006, 158(2), 864.
37 Yin J, Lin N, Lin Z, et al. Journal of Electroanalytical Chemistry, 2018, 832, 266.
38 Zou X, Kang Z, Shu D, et al. Electrochimica Acta, 2015, 151, 89.
39 Wang L, Zhang H, Cao G, et al. Electrochimica Acta, 2015, 186, 654.
40 Wang L, Zhang H, Zhang W, et al. Chemical Engineering Journal, 2018, 337, 201.
41 Zhang X, Zhang Z B, Xia S Z, et al. Chinese Labat Man, 2015, 52(2), 51(in Chinese).
张兴, 张祖波, 夏诗忠, 等. 蓄电池, 2015, 52(2), 51.
42 Boden D P, Loosemore D V, Spence M A, et al. Journal of Power Sources, 2010, 195(14), 4470.
43 Bacˇa P, Micka K, Krˇivík P, et al. Journal of Power Sources, 2011, 196(8), 3988.
44 Wang H, Liu Z, Liang Q, et al. Journal of Cleaner Production, 2018, 197, 332.
45 Shang H T, Yue L P, Yang X K, et al. Chemical Engineering & Equipment, 2014(9), 177(in Chinese).
商洪涛, 岳立平, 杨献奎, 等. 化学工程与装备, 2014(9), 177.
46 Fan M Q. Technology Outlook, 2015, 25(33), 65(in Chinese).
范美青. 科技展望, 2015, 25(33), 65.
47 Waidhas M, Mund K. Electrochemical Society Proceedings, 2002, 96(25), 180.
48 Li D, Huang J, Kaner R B. Accounts of Chemical Research, 2008, 42(1), 135.
49 Wu C G, Bein T. Science, 1994, 264(5166), 1757.
50 Yang R, Kang E W, Cui B, et al. Engineering Plastics Application, 2010, 38(5), 85(in Chinese).
杨蓉, 康二维, 崔斌, 等. 工程塑料应用, 2010, 38(5), 85.
51 Meng Q, Cai K, Chen Y, et al. Nano Energy, 2017, 36, 268.
52 Zhu Y, Murali S, Stoller M D, et al. Science, 2011, 332(6037), 1537.
53 Li J, Lai Y Q, Li J, et al. Materials Review, 2006, 20(12), 20(in Chinese).
李晶, 赖延清, 李颉,等. 材料导报, 2006, 20(12), 20.
54 Wang Q, Huang Y, Miao J, et al. Applied Surface Science, 2012, 258(24), 9896.
55 李新禄, 龙君君, 张艳艳,等. 中国专利, CN106953098 A, 2017.
56 王斌, 方明学. 中国专利, CN103199244 A, 2013.
57 Takayuki Funato, Kastuhiro Takahashi. USA patent, US5547783, 1996.
58 李庆余, 李泽胜, 王红强,等.中国专利, CN 101764264B, 2012.
59 Prengaman R D. JOM, 2001, 53(1), 36.
60 Liu Z H. The effects of carbon materials and polianilina on negative performance of ultrabattery. Master’s Thesis, Harbin Institute of Technology, China, 2012(in Chinese).
刘志豪. 碳材料和聚苯胺对超级电池负极性能的影响. 硕士学位论文, 哈尔滨工业大学, 2012.
61 Dubal D P, Ayyad O, Ruiz V, et al. Chemical Society Reviews, 2015, 44(7), 1777.
62 Simon P, Gogotsi Y. Nature Materials, 2008, 7(11), 845.
63 Sun H, Cao L, Lu L. Energy & Environmental Science, 2012, 5(3), 6206.
64 Guan C, Xia X, Meng N, et al. Energy & Environmental Science, 2012, 5(10), 9085.
65 Yin Y, Liu C, Fan S. RSC Advances, 2014, 4(50), 26378.
66 Peng C, Zhang S, Jewell D, et al. Progress in Natural Science, 2008, 18(7), 777.
67 高军, 张焱, 杨勇,等. 中国专利, CN103022503A, 2013.
68 舒红群, 赵古龙, 潘志刚,等. 中国专利, CN105140474A, 2015.
69 Zhu S P, Wu Z Y, Gu L Z, et al. Chinese Battery Industry, 2012, 17(6), 358(in Chinese).
朱守圃, 吴战宇, 顾立贞, 等. 电池工业, 2012, 17(6), 358.
70 Wessling B, Posdorfer J. Electrochimica Acta, 1999, 44(12), 213.
71 Martha S K, Hariprakash B, Gaffoor S A, et al. Journal of Chemical Sciences, 2006, 118(1), 93.
72 Hariprakash B, Gaffoor S A. Journal of Power Sources, 2007, 173(1), 565.
73 Wu S X, Lv G J, Lie X Z, et al. Chinese Journal of Power Sources, 1998(5), 225(in Chinese).
吴三械, 吕国金, 聂旭中,等. 电源技术, 1998(5), 225.
74 Micka K, Calábek M, Baca P, et al. Journal of Power Sources, 2009, 191(1), 154.
75 Zhao L, Chen B, Wu J, et al. Journal of Power Sources, 2014, 248(7), 1.
76 Hariprakash B, Gaffoor S A, Shukla A K. Journal of Power Sources, 2009, 191(1), 149. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2020, Vol. 34 
