金属学报  2005, Vol. 41 Issue (12): 1293-1297

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网络化的ANN-GA系统优化中空纤维镍基板制备工艺参数

李钒; 王习东; 张登君; 张梅; 盖鑫磊

北京科技大学物理化学系; 北京 100083; 中国科学院过程工程研究所; 北京 100080

OPTIMIZATION OF PROCESS PARAMETERS PREPARING HOLLOW FIBROUS NICKEL PLAQUE BY WEB-BASED ANN-GA SYSTEM

LI Fan; WANG Xidong; ZHANG Dengjun; ZHANG Mei; GE Xinlei

Department of Physical Chemistry; University of Science and Technology Beijing; Beijing 100083; Institute of Process Engineering; The Chinese Academy of Sciences; Beijing 100080

李钒; 王习东; 张登君; 张梅; 盖鑫磊 . 网络化的ANN-GA系统优化中空纤维镍基板制备工艺参数[J]. 金属学报, 2005, 41(12): 1293-1297 .
, , , , . OPTIMIZATION OF PROCESS PARAMETERS PREPARING HOLLOW FIBROUS NICKEL PLAQUE BY WEB-BASED ANN-GA SYSTEM[J]. Acta Metall Sin, 2005, 41(12): 1293-1297 .

摘要 参考文献 相关文章 Metrics 全文: PDF(210 KB)   摘要: 在实验室研究中空纤维镍基板的制备工艺的基础上, 采用自制的网络化的ANN-GA系统对58个样本进行了 工艺参数优化和寻优, 得到的最佳工艺参数如下: 中空镍纤维含量为97%; 烧结温度为1275 K; 保温 时间为20 min; 造孔剂 PVB, PP和Ni(OH)2的含量 分别为5%, 3.5%和1%. 在最优工艺条件基础上, 获得 了性能优异、孔率接近87%的基板材料. 并用计算机分析和预报了各单因素的影响规律, 预测结果与 文献报道的实验结果一致. 关键词 ： 中空纤维镍基板,  网络化ANN-GA系统     Abstract：Based on the amount of preparation work of hollow fibrous nickel plaque in laboratory, ANN-GA programs on computer network which were designed by our group was used in optimizing the process parameters and looking for the optimized condition. The optimized condition was that the content of nickel fiber was 97%, sintering temperature 1275 K and holding time 20 min, PVB 5%, PP 3.5% and Ni(OH)2 1%. Under the optimized condition the satisfactory plaque with almost 87% porosity has been carried out and every single factor effect on the plaque porosity during preparing the plaque was analyzed and predicted with computer. These results coincided with those obtained by other researchers' experiments. Key words： hollow fibrous nickel plaque    ANN-GA program on computer network 收稿日期: 2005-04-07      ZTFLH:  TM912.2   服务 把本文推荐给朋友 加入引用管理器 E-mail Alert RSS 作者相关文章 李钒 王习东 张登君 张梅 盖鑫磊 44.8K 链接本文: https://www.ams.org.cn/CN/      或      https://www.ams.org.cn/CN/Y2005/V41/I12/1293 [1] Dhar S K, Ovshinsky S R, Gifford P R, Corrigan D A. J Power Source, 1997; 65: 1 [2] Ohms D, Kohlhase M, Benczur-Urmossy G, Schadlich G. J Power Source, 2002; 105: 127 [3] Ilic D, Kilb M, Holl K, Praas H W, Pytlik E. J Power Source, 1999; 80: 112 [4] Kim H S, Itoh T, Nishizama M, Mohamedi M, Umeda M, Uchidc I. Int J Hydrogen Energy, 2002; 27: 295 [5] Rade I, Andersson B A. J Power Source, 2001; 93: 55 [6] Zhu W H, Durben P J, Tatarchuk B J. J Power Source, 2002; 111: 221 [7] Zhu W H. PhD Thesis, Institute of Chemical Metallurgy, The Chinese Academy of Sciences, Beijing, 1996 (朱文化．中国科学院化工冶金研究所博士学位论文,北京, 1996) [8] Zhang D J, Luo S M, Wang Z K. Chin Pat, CN No.ZL1034880, 1989 (张登君,罗世民,王志宽．中国专利, CN No．ZL1034880, 1989) [9] Li F, Zhang D J, Zhang H, Li B H, Tang Q, Zhang G D. Chin J Power Source, 1999; 23: 87 (李钒,张登君,张慧,李报厚,唐清,张冠东．电源技 术,1999;23:87 [10] Liu G H. PhD Thesis, University of Science and Technology Beijing, 2002 (刘国华．北京科技大学博士学位论文, 2002) [11] Zhu W H, Zhang D J, Zhang G D, Ke J J. Mater Res Bull, 1995; 30: 1133 [1] 彭斌; 陈振华; 黄可龙; 黄培云 . 锂离子电池正极材料非计量氧化锂锰的缺陷模型[J]. 金属学报, 1999, 35(7): 773-776 . Viewed Full text Abstract Cited   Shared      Discussed