从装备需求看鱼雷动力电池发展

高新龙; 王宇轩; 李学海

doi:10.11993/j.issn.1673-1948.2016.03.009

从装备需求看鱼雷动力电池发展

doi: 10.11993/j.issn.1673-1948.2016.03.009

天津电源研究所, 天津, 300384

详细信息

作者简介:
高新龙(1982-), 男, 工程师, 主要研究方向为水中兵器用电源系统.

中图分类号: TJ631.2; TM911
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- 文章访问数: 921
- HTML全文浏览量: 5
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- 被引次数: 0
出版历程
- 收稿日期: 2016-03-28
- 修回日期: 2016-04-19
- 刊出日期: 2016-06-20

Development Trend of Power Battery for Torpedo Based on Equipment Demand

Tianjin Institute of Power Sources, Tianjin 300384, China

摘要

摘要: 随着鱼雷武器向大航程、高航速和信息化方向发展, 鱼雷动力电池的研发也面临着新的挑战。从分析鱼雷装备发展特点出发, 介绍了锂氧化银电池、锂氟化碳电池、氢氧燃料电池、热电池等几种高能电池的发展情况, 并对其作为鱼雷动力电池的应用进行了分析, 展望了鱼雷动力电池以下三方面的发展方向: 深度挖掘铝氧化银电池的性能潜力; 开展新体系高能电池技术研究; 积极开发组合电源技术。
- 鱼雷 /
- 动力电池 /
- 铝氧化银电池 /
- 组合电源技术
Abstract: With the development of torpedo weapon towards long range, high speed and informatization, the research on torpedo power battery encounters new challenges. This paper describes the development features of torpedo weapon, reviews the development of the high energy batteries, e.g. lithium-silver oxide battery, lithium-carbon fluoride battery, hydrogen-oxygen fuel battery, and thermoelectric battery, and analyzes their applications to torpedo power source. Sub-sequently, three development trends of torpedo power battery are forecast as follows: 1) sufficiently increasing performance potential for the aluminum-silver oxide battery; 2) designing new-type high power battery; and 3) developing integrated power source technology.
- torpedo /
- power battery /
- aluminum-silver oxide battery /
- integrated power source technology

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参考文献(23)

[1]	姜忆初. 电动鱼雷用动力电源及其发展方向[J]. 船电技术, 2005, 25(5): 46-48. Jiang Yi-chu. Electric Power Sources Used in Electric Torpedo and Its Development Trends[J]. Marine Electric & Electronic Engineering, 2005, 25(5): 46-48.
[2]	蔡年生. 国外鱼雷动力电池的发展及应用[J]. 鱼雷技术, 2003, 11(1): 12-15. Cai Nian-sheng. Development and Application of Batteries for Overseas Torpedo Propulsion[J]. Torpedo Technology, 2003, 11(1): 12-15.
[3]	尹韶平, 杨芸. 鱼雷总体技术的发展与展望[J]. 鱼雷技术, 2005, 13(3): 1-5, 10. Yin Shao-ping. Yang Yun. A Summary of Development in Torpedo Overall Design Technologies[J]. Torpedo Technology, 2005, 13(3): 1-5, 10.
[4]	卢军, 陈立强, 崔和. 先进的多任务轻型鱼雷MU90. 鱼雷技术, 2006, 14(1): 57-60. Lu Jun, Chen Li-qiang, Cui He. Advanced Multi-Role Lightweight Torpedo MU90[J]. Torpedo Technology. 2006, 14(1): 57-60.
[5]	邹宇. 来自罗马的“黑鲨”——意大利白头公司研制的重型鱼雷[J]. 国际展望, 2003(24): 73-75.
[6]	聂卫东, 王岚, 马玲. 水下网络中心战环境下鱼雷战术概念研究[J]. 鱼雷技术, 2015, 23(5): 384-387. Nie Wei-dong, Wang Lan, Ma Ling. Conceptual Study on Tactics of Torpedo in Underwater Network Centric Warfare[J]. Torpedo Technology, 2015, 23(5): 384-387.
[7]	淦华东, 冀邦杰, 周德善, 等. 网络鱼雷概念及关键技术探讨[J]. 鱼雷技术, 2008, 16(2): 5-8. Gan Hua-dong, Ji Bang-jie, Zhou De-shan, et al. Discussion on Concept and Key Technologies of Network Torpedo[J]. Torpedo Technology, 2008, 16(2): 5-8.
[8]	Multi-technology Battery Systems Integrated Solutions for Torpedo Propulsion[EB/OL]. http://www.saftbatteries. com/search/apachesolr_search/Torpedo_brochure09_13.
[9]	Lannot M.P, D′Ussel L, Hastings J. Comparison of Aluminum Silver Oxide and Lithium Oxyhalide Batteries Performances for Underwater Weapons Propulsion[C]// Power Sources Symposium, 1990 Proceedings of the 34th International. New Jersey: IEEE, 1990: 112-114.
[10]	丁文江, 袁广银. 新型镁合金的研究开发与应用[J]. 有色金属加工, 2002, 31(3): 27-32, 36.
[11]	吴军. 锂-氧化银电池正极材料的研究[D]. 武汉: 武汉船用电力推进装置研究所, 2014.
[12]	张祥功, 崔昌盛, 费新坤, 等. 鱼雷用锂-氧化银碱性电池研究进展[J]. 电池工业, 2008, 13(5): 349-352. Zhang Xiang-gong, Cui Chang-sheng, Fei Xin-kun, et al. Research Progress of Alkaline Li/AgO Battery for Torpedo[J]. Chinese Battery Industry, 2008, 13(5): 349-352.
[13]	Li H Q, Wang Y G, He P, et al. A Novel Echargeable Li-AgO Battery with Hybrid Electrlyte[EB/OL]. http://www. rsc. org/suppdata/cc/b9/b923706b/b923706b. pdf.
[14]	朱厚军, 郎俊山. 水下装备用锂离子动力电池研究进展[J]. 船电技术, 2012, 32(z): 96-99. Zhu Hou-jun, Lang Jun-shan. Advances in Lion-ion High-capacity Batteries for Underwater Equipment[J]. Marine Electric & Electronic Engineering, 2012, 32(z): 96-99.
[15]	陈新传, 宋强, 吕昊. 国内外锂离子动力电池发展概况及启示[J]. 船电技术, 2011, 31(4): 1-2, 7. Chen Xin-zhuan, Song Qiang, Lü Hao. Reviews of Lithiumion Batteries[J]. Marine Electric&Electronic Engineering, 2011, 31(4): 1-2, 7.
[16]	蔡年生. 锂离子电池用于海军装备的研究[J]. 船电技术, 2006, 26(3): 50-53. Cai Nian-sheng. Research on Lithium Ion Battery for Naval Application[J]. Marine Electric&Electronic Engineering, 2006, 26(3): 50-53.
[17]	Stoops B N, Nguye C T, Haberbusch M S. Multi-function Cryogenic Power Sources for Underwater Unmanned Vehicle[R/OL]. Milan, Ohio: Sierra Lobo, Inc.. [2016.02.21]. http://auvac.org/research/publications/files/2009/sli_uuv_fuel _cel.lpdf.
[18]	李阳, 陆文俊, 范靖华, 等. 燃料电池用于鱼雷动力装置的设想[J]. 四川兵工学报, 2013, 34(10): 44-45. Li Yang, Lu Wen-jun, Fan Jing-hua, et al. The Idea on Fuel Cell Used for Torpedo Power System[J]. Journal of Sichuan Ordnance, 2013, 34(10): 44-45.
[19]	刘春娜. 锂氟化碳电池技术进展[J]. 电源技术, 2012, 36(5): 624-625.
[20]	Shmuel De-Leon. Li/CFx Batteries the Renaissance[EB/ OL]. (2012-03-01)[2016-02-26]. http://www.sdle.co.il/ AllSites/809/Assets/26%20-%20li-cfx%20-%20the%20 renaissance%20v2.pdf.
[21]	杨凯, 刘雪省, 张晶, 等. 氟化碳与二氧化锰混合电极材料放电行为的研究[J]. 功能材料, 2014(22): 22075- 22078.
[22]	陈笛, 王兴贺, 孟宪玲, 等. 添加氟化碳的二氧化锰正极制备工艺[J]. 电源技术, 2013, 37(6): 973-975. Chen Di, Wang Xing-he, Meng Xian-ling, et al. Process for Preparing Cathode MnO2 with Additive CFx[J]. Chinese Journal of Power Sources, 2013, 37(6): 973-975.
[23]	高俊奎, 黄来和. 现代热电池电极材料现状及展望[J]. 电源技术, 2000, 24(6): 370-373.