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作为国家重要的战略金属资源,钒钛及其化合物被广泛用于冶金、航空航天、化工等领域。近年来,随着资源、能源及环境压力的逐步增大,储能、环境及智慧建筑领域中新型钒钛材料研究越发活跃,未来钒钛产业绿色化和高端化的步伐将加快,钒钛产品的需求量将快速增长,钒钛产业的高端化是钢铁产业转型升级的强力支撑。重点介绍了钒在新能源领域、环保领域的应用现状,钛合金的应用及产业现状,以及钒钛高强钢铁材料及过程副产物在结构住宅和智慧建筑中的应用。为钒钛新材料未来的开发应用提供了思路。
Abstract:As an important strategic metal resource, vanadium titanium and its compounds are widely used in metallurgy, aerospace, chemical industry and other fields. In recent years, with the gradual increasing of resources, energy and environmental pressure, new vanadium and titanium materials of energy storage, environment and intelligent building are more and more active. The pace of green and high-end vanadium and titanium industry will be accelerated in the future, the demand for vanadium and titanium products will increase rapidly. High-end vanadium and titanium industry is a strong support for transformation and upgrading of iron and steel industry. The application of vanadium in new energy and environmental protection, the application and industry status of titanium alloy, and the application of vanadium-titanium high-strength steel materials and process by-products in structural housing and smart building are introduced. It provides ideas for the development and application of new vanadium and titanium materials in the future.
[1]Mars G F. Vanadium alloy oxidation corrosion [J]. Ind. Eng. Chem., 1950, 42(10): 65A~66A.
[2]Moskalyk R R; Alfantazi A M. Processing of vanadium: a review [J].Minerals Engineering, 2003, (16): 793~805.
[3]Raja B V R. Vanadium market in the world present status, price trends and future prospects [J].Steelworld, 2007:19~22.
[4]莫畏,邓国珠,罗方承. 钛冶金[M]. 北京: 冶金工业出版社, 1998:118~132.
[5]邓国珠,王向东,车小奎. 钛工业的现状与未来[J]. 钢铁钒钛, 2003, 24(1):1~7.
[6]王向东,郝斌,逯福生,等. 钛的基本性质、应用及我国钛工业概况[J].钛工业进展,2004,(01):6~10.
[7]王镐,李献军. 钛在海洋工程应用的最新进展[J]. 中国钛业,2012,(01):11~14.
[8]朱顺泉,孙娓荣,汪钱,等. 大规模蓄电储能全钒液流电池研究进展[J].化工进展,2007,(02):207~211.
[9]Xiong-wei Wu,Jun Liu,Xiao-juan Xiang,et al. Electrolytes for vanadium redox flow batteries[J]. Pure and Applied Chemistry,2014,86(5).
[10]张华民.储能与液流电池技术[J]. 储能科学与技术,2012,1(01):58~63.
[11]谢仲华,康丽惠,莫海宁. 光伏储能一体化系统的研究及运用[J]. 上海节能,2016,(03):132~138.
[12]方华,韩静,李守信. 选择性催化还原法烟气脱硝催化剂市场分析[J]. 中国环保产业,2010,(04):37~40.
[13]Bosch H., Janssen F., et al. Formation and control of nitrogen oxides[J]. Catalysis Today, 1988, 2(4): 369~379.
[14]Bauerle G. L., Wu S., Nobe K. Parametric and durability studies of Nox reduction with NH3 on V2O5 catalysts[J]. Industrial & Engineering Chemistry Product Research and Development,1978,17(2):117~122.
[15]顾卫荣,周明吉.火电厂烟气脱硝国内市场分析[J].化工进展,2012,31(11):2581~2585.
[16]李霖,任卫峰.中国钛材市场近年发展趋势分析[J].新材料产业,2018,(02):39~41.
[17]盛利.钛材在新材料领域的新应用[J].中国有色金属,2017,(18):35~38.
[18]Srivatsan T S, Sudarshan S T. Additive Manufacturing: Innovations,Advances, and Application [M]. UK: Taylor & Francis Group, 2016:2~5.
[19]张胜,徐艳松,孙姗姗,等. 3D 打印材料的研究及发展现状[J]. 中国塑料,2016, 30(1): 7~14.
[20]谢元林.钒在钢中的合金化作用及应用[J].特钢技术,2015,21(01):1~5.
[21]张彩.浅谈智慧城市与智慧建筑[J].智能城市,2016,2(09):210~211.
[22]徐开琦.新型绿色节能建筑——被动式超低能耗建筑(被动房)[J].橡塑技术与装备,2018,44(01):57~63.
[23]张述明, 贺超, 刘宇. 利用高炉渣生产微晶材料技术研究[C].冶金渣处理工艺与综合利用先进技术成果交流会论文集,2016.
基本信息:
DOI:10.13630/j.cnki.13-1172.2019.0301
中图分类号:TG146.23;TG146.413
引用信息:
[1]白瑞国.钒钛新材料的应用及展望[J].河北冶金,2019,No.279(03):1-8.DOI:10.13630/j.cnki.13-1172.2019.0301.
基金信息:
国家重点研发计划资助项目(编号:2017YFB0603504)
2019-03-28
2019-03-28