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"},"keywords":[{"id":"25950fa3-6989-48d8-98c3-9ddb2901e26d","keyword":"结构型吸波材料","originalKeyword":"结构型吸波材料"},{"id":"9ea21943-50d6-4516-a125-3af6a418944e","keyword":"隐身特性","originalKeyword":"隐身特性"},{"id":"ce9848fe-c976-4992-8d33-97e68835f882","keyword":"有限元","originalKeyword":"有限元"},{"id":"450ab8ae-c1e3-42a1-8e78-ebb3a1c10c57","keyword":"参数优化","originalKeyword":"参数优化"},{"id":"a3b3d187-0a93-47de-938f-c746eee7a0fa","keyword":"序列二次规划","originalKeyword":"序列二次规划"}],"language":"zh","publisherId":"bqclkxygc200402003","title":"结构型吸波材料隐身特性的优化设计算法研究","volume":"27","year":"2004"},{"abstractinfo":"应用有限元数值计算方法结合吸收边界条件,对结构型吸波材料的隐身特性计算进行了算法分析研究;并据分层组配方案对二维层合板SRAM结构(二层和三层结构)的雷达散射截面进行计算,得到最优隐身特性的组配方案;最后对波纹板SRAM结构、波纹板斜面与底板夹角变化对雷达散射截面的影响进行了计算分析,得出正趋势的结论.","authors":[{"authorName":"李江海","id":"b21c6495-f697-4784-8290-e6e3741736cd","originalAuthorName":"李江海"},{"authorName":"孙秦","id":"ac80eb96-c4d3-454e-81cc-5142a1ce1ddb","originalAuthorName":"孙秦"},{"authorName":"马玉娥","id":"2fc0cd6b-c445-4265-b781-233b604a9933","originalAuthorName":"马玉娥"}],"doi":"10.3969/j.issn.1007-2330.2004.06.004","fpage":"16","id":"32de11aa-a080-4ab6-b682-7e2d8f9d5168","issue":"6","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺 "},"keywords":[{"id":"cb5f3b6a-f1c5-4d6d-9225-043e01ed2a0e","keyword":"结构型吸波材料","originalKeyword":"结构型吸波材料"},{"id":"85b79ea4-6d17-47c0-b1ad-fe92fdbefc14","keyword":"雷达截面","originalKeyword":"雷达截面"},{"id":"0d549858-11eb-4822-94ed-f6e53e8bf604","keyword":"有限元","originalKeyword":"有限元"},{"id":"e7bbb3fe-4b85-4e09-a854-a4a59ef396f5","keyword":"层合板结构","originalKeyword":"层合板结构"},{"id":"15e8eba5-f7c5-4b9a-8c97-613fa15e1b91","keyword":"波纹板结构","originalKeyword":"波纹板结构"}],"language":"zh","publisherId":"yhclgy200406004","title":"SRAM及其二维结构的隐身特性计算分析","volume":"34","year":"2004"},{"abstractinfo":"依据传输线理论和阻抗匹配原则,设计并制备了一种以磁性金属微粉为面层、多壁碳纳米管为底层、玻璃纤维布为环氧树脂基体增强体的低频段双层结构型吸波复合材料.采用透射电镜和扫描电镜对多壁碳纳米管和磁性金属微粉的微观形貌进行了表征,采用HP8722ES矢量网络分析仪测量了材料在2~18GHz频率范围内的复介电常数和复磁导率,采用弓形法测试了复合材料在2~8GHz扫频范围内的反射率特性.研究表明,该双层结构型吸波复合材料在低频S波段具有良好的吸波效果,当其匹配厚度为dm=4.0mm时,最大吸收峰在3.08GHz时达到-17dB,反射率小于—10dB的频宽为1.82GHz.","authors":[{"authorName":"张拦","id":"6ec7c8cc-8016-4de2-8323-62c289018485","originalAuthorName":"张拦"},{"authorName":"关润伶","id":"dd8de28e-6df2-43aa-a6ee-255848c86aee","originalAuthorName":"关润伶"},{"authorName":"王璐","id":"f11298db-3c8a-4468-965d-6a1411f1b6db","originalAuthorName":"王璐"},{"authorName":"杨双花","id":"fc592680-cf5e-473d-b67b-4ffa00ae4c02","originalAuthorName":"杨双花"}],"doi":"","fpage":"70","id":"c3e0c39c-1993-40cb-b76c-8bbe845e2b28","issue":"20","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"85dffaa1-2cc0-4bab-8495-901a065ed94c","keyword":"多壁碳纳米管","originalKeyword":"多壁碳纳米管"},{"id":"e8ff23c2-3640-4627-bf4a-44a678e4cf9a","keyword":"磁性金属微粉","originalKeyword":"磁性金属微粉"},{"id":"e2ae7ffb-8673-4e5f-9e73-7c29a7340691","keyword":"结构型复合材料","originalKeyword":"结构型复合材料"},{"id":"d17cdeec-6efa-4b10-b653-6b9e20bd3872","keyword":"吸波性能","originalKeyword":"吸波性能"}],"language":"zh","publisherId":"cldb201120017","title":"双层结构型吸波复合材料的制备与吸波性能研究","volume":"25","year":"2011"},{"abstractinfo":"用改进的Hopkinson测试系统和适合于动载断裂的夹具,测量了结构型吸波复合材料的断裂韧性给出了系统参数(包括载荷-时间特性、应力强度因子响应特性和起裂时间特性)的确定方法.在纯树脂、普通玻璃钢和结构型吸波复合材料的性能测试中发现,纯树脂、普通玻璃钢和结构型吸波复合材料等结构型吸波材料的起裂点的选择具有较大的特殊性,其起裂时间和动态断裂韧性明显高于普通玻璃钢复合材料.这种比较高的裂纹扩展阻力或止裂作用来源于吸波粒子的引入.","authors":[{"authorName":"曹茂盛","id":"87a67de5-322c-419b-a621-660181665d62","originalAuthorName":"曹茂盛"},{"authorName":"张铁夫","id":"746fa1d9-cb45-4e6c-a031-fa823b4ef067","originalAuthorName":"张铁夫"},{"authorName":"邱成军","id":"289bc1c2-947d-4513-aead-7449fca98616","originalAuthorName":"邱成军"},{"authorName":"朱静","id":"1940c378-9a3f-4585-8e97-23dda4180178","originalAuthorName":"朱静"}],"doi":"10.3321/j.issn:1005-3093.2003.04.005","fpage":"365","id":"bf15922e-9919-4e09-b7df-2f3f2d8eefbc","issue":"4","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"7a4c9f9c-fda3-4127-81a9-24131b9d4b0b","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"aa5f781d-3e78-458f-856d-a0aee4b219d8","keyword":"吸波村料","originalKeyword":"吸波村料"},{"id":"2f539e47-b157-4197-9383-cde376230d3c","keyword":"冲击","originalKeyword":"冲击"},{"id":"9014e5a7-a1c6-4c51-8ce2-b8f8a4bf08fc","keyword":"SHPB","originalKeyword":"SHPB"}],"language":"zh","publisherId":"clyjxb200304005","title":"结构型吸波材料的动载断裂韧性","volume":"17","year":"2003"},{"abstractinfo":"在纤维增强树脂基复合材料中添加了四种微米级颗粒吸收剂,在保证良好隐身性能的前提下,赋予了材料一定的力学性能,动态力学性能测试结果表明,本结构型隐身材料具有良好的抗冲击性能.","authors":[{"authorName":"曹茂盛","id":"be343a4b-5d57-4a62-a568-7889f8f2e410","originalAuthorName":"曹茂盛"},{"authorName":"刘海涛","id":"bbe817d0-6af9-4657-acda-983d6b1f30fe","originalAuthorName":"刘海涛"},{"authorName":"张铁夫","id":"38b93ffb-2806-4e6d-b140-0a3c263670b3","originalAuthorName":"张铁夫"},{"authorName":"朱静","id":"976af6b7-af7f-4598-bb59-7b832e7dc84b","originalAuthorName":"朱静"}],"doi":"10.3969/j.issn.1001-4381.2002.10.007","fpage":"26","id":"10c6994d-4864-4dcc-b9d9-d15038d28367","issue":"10","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"b145047d-1409-4904-bca6-c8c1816e4ccf","keyword":"结构型吸波复合材料","originalKeyword":"结构型吸波复合材料"},{"id":"5848f3af-354d-4702-983d-49fd7216f553","keyword":"雷达波吸收材料","originalKeyword":"雷达波吸收材料"},{"id":"d7420a16-1bbc-403f-b587-76ed5949399f","keyword":"冲击","originalKeyword":"冲击"}],"language":"zh","publisherId":"clgc200210007","title":"双峰响应结构型吸波材料动/静态力学性能研究","volume":"","year":"2002"},{"abstractinfo":"针对毫米波吸波结构材料的组成配方、制作工艺过程及对材料的吸波性能的影响,通过试验进行了分析对比,提出了解决措施.","authors":[{"authorName":"吴键","id":"cc20c25b-6e0f-4c98-abb8-5d69f080d0e3","originalAuthorName":"吴键"},{"authorName":"牟启初","id":"90d08e5e-97d2-42ea-8264-a25a3eed2784","originalAuthorName":"牟启初"},{"authorName":"李兵","id":"0d4aa821-081c-435d-abf2-eed4e92de1a1","originalAuthorName":"李兵"}],"doi":"10.3969/j.issn.1001-3660.2003.06.023","fpage":"67","id":"61820acb-adbc-4ec0-b192-8b08b2fc1e8d","issue":"6","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPp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"},"keywords":[{"id":"27d2e7b3-cd32-46b0-a0cc-ef08172d707d","keyword":"吸波结构","originalKeyword":"吸波结构"},{"id":"7ddf3092-5a5b-4046-b927-f4e50bb96efc","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"787fad28-44e3-4b66-8b57-0636a8b60b2f","keyword":"雷达波","originalKeyword":"雷达波"}],"language":"zh","publisherId":"bmjs200306023","title":"吸波结构材料研究试验分析","volume":"32","year":"2003"},{"abstractinfo":"本文制备了以石墨粉为添加剂的结构吸波复合材料,研究了吸波剂含量和材料厚度对材料吸波性能的影响并分析了其相关机理.结果表明:随着石墨粉含量、材料厚度的增加,复合材料的最大吸收峰均向低频方向移动,实验试样中最大反射率可达-16.8dB,有效带宽约3GHz,具有一定的工程实用价值.复合材料的吸波性能与石墨粉含量、材料厚度密切相关,含量、厚度引起材料的电磁参数发生改变,进而导致吸波性能发生变化,电磁参数与吸波性能的规律有待进一步深入探讨.","authors":[{"authorName":"邓京兰","id":"9fce37c1-6616-4fa5-8bdf-de4d7586ec60","originalAuthorName":"邓京兰"},{"authorName":"冯彬","id":"c89ff76a-e899-4fdd-add7-e9ea034a86de","originalAuthorName":"冯彬"}],"doi":"","fpage":"161","id":"6b8812f6-e3c9-4e5b-be14-f9f66c681d8f","issue":"2","journal":{"abbrevTitle":"CLKXYGCXB","coverImgSrc":"journal/img/cover/CLKXYGCXB.jpg","id":"13","issnPpub":"1673-2812","publisherId":"CLKXYGCXB","title":"材料科学与工程学报"},"keywords":[{"id":"4ec5b74d-dfec-42fd-a5b9-f7c64cf2649e","keyword":"吸波材料","originalKeyword":"吸波材料"},{"id":"fc7fb523-1aa8-4181-bb09-aaf160305051","keyword":"石墨粉","originalKeyword":"石墨粉"},{"id":"e106985c-949d-449d-a0e6-fd27a2d888c7","keyword":"电导率","originalKeyword":"电导率"},{"id":"e1875a26-93ff-41b8-ad67-9762792498f5","keyword":"吸收峰值","originalKeyword":"吸收峰值"}],"language":"zh","publisherId":"clkxygc201002001","title":"结构吸波复合材料的吸波性能","volume":"28","year":"2010"},{"abstractinfo":"综述了目前国内外新型吸波材料的研究动态,介绍了吸波材料的吸波原理和新型吸波材料,包括吸波涂层材料如铁氧体、纳米吸波材料、手性材料、雷达红外兼容吸波材料、等离子体吸波材料及结构型吸波材料的最新研究现状.\n","authors":[{"authorName":"赵九蓬","id":"09d93e26-3855-4904-8327-8389a3ebd4d5","originalAuthorName":"赵九蓬"},{"authorName":"李垚","id":"84f4c11a-434f-4e7f-a678-ab333ebe2eb7","originalAuthorName":"李垚"},{"authorName":"吴佩莲","id":"67337703-9333-48d2-afe2-06a9190791a7","originalAuthorName":"吴佩莲"}],"doi":"10.3969/j.issn.1005-0299.2002.02.027","fpage":"219","id":"61187754-f7be-45d2-a2d3-851fa60a4f34","issue":"2","journal":{"abbrevTitle":"CLKXYGY","coverImgSrc":"journal/img/cover/CLKXYGY.jpg","id":"14","issnPpub":"1005-0299","publisherId":"CLKXYGY","title":"材料科学与工艺"},"keywords":[{"id":"09f4cbb5-e594-49e4-bcb7-bb3039b07224","keyword":"吸波材料","originalKeyword":"吸波材料"},{"id":"6b7f445c-988e-437d-b02e-e839a23ee7d8","keyword":"吸波涂层","originalKeyword":"吸波涂层"},{"id":"9de51701-a65e-4ec5-9460-4022b656a974","keyword":"结构型","originalKeyword":"结构型"}],"language":"zh","publisherId":"clkxygy200202027","title":"新型吸波材料研究动态","volume":"10","year":"2002"},{"abstractinfo":"比较了高温背景下各类吸渡材料的特点,确定连续纤维增强陶瓷基复合材料是较理想的高温吸波材料体系.分析了常用陶瓷基复合材料中连续纤维以及陶瓷基体的介电性能,确定连续碳化硅纤维增强碳化硅基(SiG/SiC)复合材料是目前较有前途的高温结构吸波材料.综述了高温结构吸波材料的国内外研究现状,重点介绍了国防科技大学的最新研究进展,最后讨论了高温结构吸渡材料存在的问题.","authors":[{"authorName":"刘海韬","id":"4acae90a-11d3-4ff1-b668-c453d302bbc8","originalAuthorName":"刘海韬"},{"authorName":"程海峰","id":"424254e1-708b-404b-8826-a1b76fa70655","originalAuthorName":"程海峰"},{"authorName":"王军","id":"2bc1c71e-34bc-415e-89cc-e35c7ea18f18","originalAuthorName":"王军"},{"authorName":"唐耿平","id":"066027b0-e920-4145-9fbb-92571015ce71","originalAuthorName":"唐耿平"},{"authorName":"郑文伟","id":"c0eda597-016f-4636-8fde-742357869fef","originalAuthorName":"郑文伟"}],"doi":"","fpage":"24","id":"05cfff09-5f8b-4980-bbd1-0b3cee7a6a5c","issue":"19","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"3a343297-9274-4a12-901d-dca8452d89e8","keyword":"雷达吸波材料","originalKeyword":"雷达吸波材料"},{"id":"a1076ec1-cd20-4a5a-bd7a-d6f627b148ad","keyword":"陶瓷","originalKeyword":"陶瓷"},{"id":"0ee4518d-70a8-4dd9-9ca6-939cbf4be08a","keyword":"高温","originalKeyword":"高温"},{"id":"2e7e3d8c-4d3c-4c6a-a27c-c226ce144129","keyword":"SiCf/SiC","originalKeyword":"SiCf/SiC"}],"language":"zh","publisherId":"cldb200919006","title":"高温结构吸波材料综述","volume":"23","year":"2009"},{"abstractinfo":"将两种雷达吸波材料(RAM)按照1:1的体积比设计成不同的周期结构,利用电磁场有限元软件对反射率进行计算.计算结果表明,周期结构吸波材料的吸收峰位于两种吸波材料之间,周期结构的大小、形状以及吸波材料在周期结构中的位置对吸波性能均有较大影响.","authors":[{"authorName":"程海峰","id":"2d260e67-c9af-4668-b97c-c3efc067640d","originalAuthorName":"程海峰"},{"authorName":"刘海韬","id":"bbf3d7cc-67b0-4bf0-97dd-af553b50d599","originalAuthorName":"刘海韬"},{"authorName":"楚增勇","id":"742e52ca-9a93-4d9f-8cf1-4ce8b2e04090","originalAuthorName":"楚增勇"},{"authorName":"周永江","id":"e1024902-cb77-420d-be7d-1ce7154229fc","originalAuthorName":"周永江"},{"authorName":"唐耿平","id":"79e3e8c1-f315-4d4f-b4f1-1320211b6057","originalAuthorName":"唐耿平"}],"doi":"10.3969/j.issn.1005-5053.2006.04.018","fpage":"80","id":"847cbb77-86bd-4b9a-8cef-3cd023080141","issue":"4","journal":{"abbrevTitle":"HKCLXB","coverImgSrc":"journal/img/cover/HKCLXB.jpg","id":"41","issnPpub":"1005-5053","publisherId":"HKCLXB","title":"航空材料学报"},"keywords":[{"id":"8fc387fd-aec3-43c8-94ab-386cde81216b","keyword":"雷达吸波材料","originalKeyword":"雷达吸波材料"},{"id":"6af0d019-bf77-4390-929f-48e9884de6f9","keyword":"周期结构","originalKeyword":"周期结构"},{"id":"32b904f3-a257-43dc-89dd-5e240644b8e9","keyword":"有限元","originalKeyword":"有限元"}],"language":"zh","publisherId":"hkclxb200604018","title":"一类周期结构雷达吸波材料的设计与吸波性能研究","volume":"26","year":"2006"}],"totalpage":9674,"totalrecord":96734}