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材料导报  2024, Vol. 38 Issue (19): 23030049-9    https://doi.org/10.11896/cldb.23030049
  无机非金属及其复合材料 |
N、P/RC@Pb复合材料在铅碳电池负极中的应用
谢发之1,*, 张梦1, 张道德1, 杨少华2, 宋恒帅1, 马钰佳1, 方亮2, 邵永刚2
1 安徽建筑大学材料与化学工程学院,合肥 230601
2 安徽艾克瑞德科技有限公司,安徽 黄山 242700
Application of N, P/RC@Pb Composites to the Negative Electrode of Lead-Carbon Battery
XIE Fazhi1,*, ZHANG Meng1, ZHANG Daode1, YANG Shaohua2, SONG Hengshuai1, MA Yujia1, FANG Liang2, SHAO Yonggang2
1 School of Materials and Chemical Engineering, Anhui Jianzhu University, Hefei 230601, China
2 Anhui Accord Science and Technology Co., Ltd., Huangshan 242700, Anhui, China
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摘要 为改善铅碳混合不均和负极析氢的问题,以D418大孔螯合磷酸树脂为碳源,制备出与Pb复合的N、P掺杂碳材料(N、P/RC@Pb)。采用X射线衍射(XRD)、扫描电镜(SEM)等手段对复合材料进行表征,对添加N、P/RC@Pb复合材料的负极板和铅碳电池进行了研究。结果表明:Pb均匀分布在树脂碳表面,以Pb复合物的形式与树脂碳紧密结合。线性伏安(LSV)测试表明:N、P/RC@Pb的添加能有效抑制析氢反应(HER),在-0.46 V下1%N、P/RC@Pb电极板拥有最小的析氢电流(-0.087 A/cm2),更接近空白组(-0.053 A/cm2)。在电池循环测试中,添加1%N、P/RC@Pb的模拟电池的循环寿命为1 834次,而空白电池循环寿命为837次。在容量测试中,含量为1%的N、P/RC@Pb的电池容量为241.0 mAh,较空白电池(157.8 mAh)提升了53%。N、P/RC@Pb复合材料制备方法简单,价格低廉,改善了铅碳混合不均问题,有效抑制了碳上的析氢反应,在铅碳电池中具有潜在的应用前景。
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谢发之
张梦
张道德
杨少华
宋恒帅
马钰佳
方亮
邵永刚
关键词:  高倍率部分充电状态(HRPSoC)  铅碳电池  多孔碳材料  析氢反应(HER)    
Abstract: To ameliorate the problems of uneven Pb-carbon mixing and anode hydrogen precipitation, N, P-doped carbon materials compounded with Pb(N, P/RC@Pb) were prepared with D418 macroporous chelated phosphate resin as the carbon source. The materials were characterized by X-ray diffraction (XRD) and scanning electron microscopy (SEM), and the negative plates and lead-carbon batteries with N, P/RC@Pb composites added were investigated. The results show that Pb is uniformly distributed on the surface of the resin carbon and is tightly bound to the resin carbon in the form of Pb complexes. Linear voltammetry (LSV) tests showed that the addition of N, P/RC@Pb effectively suppressed the hydrogen precipitation reaction (HER), with the 1% N, P/RC@Pb electrode plate having the smallest hydrogen precipitation current (-0.087 A/cm2) at -0.46 V, closer to the blank group (-0.053 A/cm2). In battery cycling tests, the addition of 1wt% N, P/RC@Pb simulated battery life of 1 834 and the blank battery life of 837. In the capacity test, the N, P/RC@Pb battery has a capacity of 240.9 mAh, while the blank battery is only 157.8 mAh, an improvement of 53%. N, P/RC@Pb composites are simple and low-cost to prepare, improve the problem of uneven mixing of lead and carbon, effectively inhibit the hydrogen precipitation reaction on carbon, and have potential applications in lead-carbon batteries.
Key words:  high-rate partial state of charge(HRPSoC)    lead-carbon battery    porous carbon material    hydrogen evolution reaction(HER)
出版日期:  2024-10-10      发布日期:  2024-10-23
ZTFLH:  TM912  
基金资助: 安徽省教育厅高校自然科学研究项目 (KJ2018ZD049)
通讯作者:  *谢发之,通信作者,安徽建筑大学材料与化学工程学院教授、博士研究生导师。目前主要从事储能技术研究、水污染控制及监测等工作。先后主持国家自然科学基金、安徽省自然科学基金等国家级、省部级科研项目 20余项;发表学术论文62篇,其中SCI/EI收录 39篇;获国家授权发明专利12项。fzxie@ahjzu.edu.cn   
引用本文:    
谢发之, 张梦, 张道德, 杨少华, 宋恒帅, 马钰佳, 方亮, 邵永刚. N、P/RC@Pb复合材料在铅碳电池负极中的应用[J]. 材料导报, 2024, 38(19): 23030049-9.
XIE Fazhi, ZHANG Meng, ZHANG Daode, YANG Shaohua, SONG Hengshuai, MA Yujia, FANG Liang, SHAO Yonggang. Application of N, P/RC@Pb Composites to the Negative Electrode of Lead-Carbon Battery. Materials Reports, 2024, 38(19): 23030049-9.
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http://www.mater-rep.com/CN/10.11896/cldb.23030049  或          http://www.mater-rep.com/CN/Y2024/V38/I19/23030049
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