地面雷达罩材料的研究进展
PROGRESS OF MATERIALS APPLIED TO GROUND RADOMES
摘 要
综述了地面雷达罩用复合材料的国内外研究进展,简要总结高性能地面雷达罩材料需要满足的要求。并评述各种增强纤维、基体树脂和夹层材料优缺点及其改性方法,展望未来地面雷达罩材料的发展趋势。
复合材料
增强纤维
基体树脂
夹层结构
Radome
Composites
Reinforced fibers
Matrix resin
Sandwich structure
Abstract
The progress of composite materials applied to ground radomes was comprehensively reviewed. The requests of materials of high performance radomes needed was summed up briefly. It was also related to the comprehensive analysis of the advantages, disadvantages and modification methods of several kinds of reinforced fibers, matrix resin, and core materials. At the same time the developing trends of materials applied to ground radome were also described. The progress of composite materials applied to ground radomes was comprehensively reviewed. The requests of materials of high performance radomes needed was summed up briefly.
中图分类号 TN95
所属栏目
基金项目 上海市教育基金会“曙光计划”产学研攻关项目(005211083)
收稿日期 2005/12/28
修改稿日期
网络出版日期
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备注姜鑫(1981-),男,硕士研究生。
引用该论文: JIANG Xin,YANG Zhen-guo,JIANG Han-sheng,LV Yuan. PROGRESS OF MATERIALS APPLIED TO GROUND RADOMES[J]. Physical Testing and Chemical Analysis part A:Physical Testing, 2006, 42(5): 217~220
姜鑫,杨振国,蒋汉生,吕源. 地面雷达罩材料的研究进展[J]. 理化检验-物理分册, 2006, 42(5): 217~220
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参考文献
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【2】孙宝华,王 伟,孟松,等.低副瓣玻璃钢地面雷达天线罩的研制[J].纤维复合材料, 1999,16(4):36-38.
【3】Mayhan Joseph T, Simmons Alan J. Low Sidelobe Kα-Band Antenna-Radome Study[J]. IEEE Transaction on Antennas and Propagation, 1975,23(4):569-572.
【4】Shavit R, Ngai E C, Smolski A. High Performance Large Sandwich Radomes Operating in More Than One Frequency Band[J]. Antennas and Propagation, 1991,2(4):709-712.
【5】刘萝葳,曹运红,王 蕾,等.导弹雷达天线罩用的工艺材料[J].战术导弹技术, 2004,(1):23-28.
【6】Bleay S M, Humberstone L. Mechanical and Electrical Assessment of Hybrid Composites Containing Hollow Glass Reinforcement[J]. Composites Science and Technology, 1999,59:1321-1329.
【7】Lee-Sulivan P, Chian K S, Yue C Y, et al. Effects of Bromination and Hydrolysis Treatment on Morphology and Tensile Properties of Kevlar-29 Fibres[J]. J Material Science Letter, 1994,13:305-309.
【8】Benrashid R, Tesoro G C. Effect of Surface-Limited Reactions on the Properties of Kevlar Fibres[J]. J Textile Res, 1990,60(6):334-344.
【9】Wu S R, Sheu G S, Shyu S S. Kevlar Fibre-Epoxy Adhesion and Its Effect on Composite Mechanical and Fracture Properties by Plasma and Chemical Treatment[J]. J Applied Polymer Science, 1996,62:1347-1360.
【10】Lin T K, Kuo B H, Shyu S S, et al. Improvement of the Adhesion of Kevlar Fibre to Bismaleimide Resin by Surface Chemical Modification[J]. J Adhesion Science Technology, 1999,13(5):545-560.
【11】Wu G M, Hung C H, Lu J C. Effects of Plasma Treatment on High Performance Fibres for Composites[A]. International SAMPE Symposium and Exhibition[C]. Covina: Society for the Advancement of Material and Process Engineering, 1999.
【12】Takayanagi M, Katayose T. N-Substituted Poly (p-Phenylene Terephthalamide) [J]. J Polymer Science Polymer Chemstry Ed, 1981,19:113-1145.
【13】Takayanagi M, Katayose T. Surface-Modified Kevlar Fibre Reinforced Ionomer, Dynamic Mechanical Properties and Their Interpretation[J]. Polymer Engineering Science, 1984,24(13):1047-1055.
【14】Nardin M, Ward I M. Influence of Surface Treatment on Adhesion of Polyethylene Fibres[J]. Mater Science Technology, 1987,3:814-821.
【15】Woods D W, Ward IM. Study of the Oxygen Treatment of High-Modulus Polyethylene Fibres[J]. Surface Interface Anal, 1993,20:385-391.
【16】Nguyen H X, Riahi G, Wood G, et al. Optimization of Polyethylene Fibre Reinforced Composites Using a Plasma Surface Treatment[C]. Covina, CA, USA: SAMPE, 1988.
【17】Kaplan S L, Rose P W, Nguygen H X, et al. Gas Plasma Treatment of Spectra Fiber[A]. International SAMPE Symposium and Exhibition[C]. Covina: Society for the Advancement of Material and Process Engineering, 1988.
【18】Ladizesky N H, Ward I M. The Adhesion Behaviour of High Modulus Polyethylene Fibres Following Plasma and Chemical Treatment[J]. J Material Science 1989,24:3763-3773.
【19】Ramos V D, Da Costa H M, Soares V L P, et al. Hybrid Composites of Epoxy Resin Modified with Carboxyl Terminated Butadiene Acrilonitrile Copolymer and Fly Ash Microspheres[J]. Polymer Testing, 2005,24:219-226.
【20】D′Almeida J R M, Cella N. Analysis of the Fracture Behavior of Epoxy Resins Under Impact Conditions[J]. Applied Polymer Science, 2000,77:2486-2497.
【21】高树理,张明习.功能复合材料的性能与应用[A].第十一届全国复合材料学术会议[C].合肥:中国科学技术大学出版社, 2000.12-21.
【22】Li W, Lee L J. Low Temperature Cure of Unsaturated Polyester Resins with Thermoplastic Additives: I. Dilatometry and Morphology Study[J]. Polymer, 2000,41:685-696.
【23】Li W, Lee L J. Low Temperature Cure of Unsaturated Polyester Resins with Thermoplastic Additives. II. Structure Formation and Shrinkage Control Mechanism[J]. Polymer, 2000,41:697-710.
【24】Li W, Lee L J. Low Temperature Cure of Unsaturated Polyester Resins with Thermoplastic Additives III. Modification of Polyvinyl Acetate for Better Shrinkage Control[J]. Polymer, 2000,41:711-717.
【25】Cao Z Q, Me′chin F, Pascault J P. Effects of Rubbers and Thermoplastics as Additives on Cyanate Polymerization[J]. Polymer International, 1994,34:41-48.
【26】Hamerton I, Barton J M, Chaplin A, et al. The Development of Novel Functionalized Aryl Cyanate Esters. Part 2. Mechanical Properties of the Polymers and Composites[J]. Polymer, 2001,42:2307-2319.
【27】Gibson L J, Ashby M F. Cellular Solids: Structure and Properties. 2nd ed[M]. Cambridge, UK: Cambridge University Press, 1997.
【28】Smith F C, Scarpa F, Chambers B. Electromagnetic Properties of Re-Entrant Dielectric Honeycombs[J]. IEEE Microwave and Guided Wave Letters, 2000,10:451-453.
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